diff --git a/sys-kernel/hardened-kernel/files/linux-5.10/1190-reiser4-v5.patch b/sys-kernel/hardened-kernel/files/linux-5.10/1190-reiser4-v5.patch new file mode 100644 index 0000000..d69b3b6 --- /dev/null +++ b/sys-kernel/hardened-kernel/files/linux-5.10/1190-reiser4-v5.patch @@ -0,0 +1,97098 @@ +diff -urN --no-dereference linux-5.10.2.orig/Documentation/filesystems/reiser4.txt linux-5.10.2/Documentation/filesystems/reiser4.txt +--- linux-5.10.2.orig/Documentation/filesystems/reiser4.txt 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/Documentation/filesystems/reiser4.txt 2020-12-23 16:07:46.109812997 +0100 +@@ -0,0 +1,75 @@ ++Reiser4 filesystem ++================== ++Reiser4 is a file system based on dancing tree algorithms, and is ++described at http://www.namesys.com ++ ++ ++References ++========== ++web page http://namesys.com/v4/v4.html ++source code ftp://ftp.namesys.com/pub/reiser4-for-2.6/ ++userland tools ftp://ftp.namesys.com/pub/reiser4progs/ ++install page http://www.namesys.com/install_v4.html ++ ++Compile options ++=============== ++Enable reiser4 debug mode ++ This checks everything imaginable while reiser4 ++ runs ++ ++Mount options ++============= ++tmgr.atom_max_size=N ++ Atoms containing more than N blocks will be forced to commit. ++ N is decimal. ++ Default is nr_free_pagecache_pages() / 2 at mount time. ++ ++tmgr.atom_max_age=N ++ Atoms older than N seconds will be forced to commit. N is decimal. ++ Default is 600. ++ ++tmgr.atom_max_flushers=N ++ Limit of concurrent flushers for one atom. 0 means no limit. ++ Default is 0. ++ ++tree.cbk_cache.nr_slots=N ++ Number of slots in the cbk cache. ++ ++flush.relocate_threshold=N ++ If flush finds more than N adjacent dirty leaf-level blocks it ++ will force them to be relocated. ++ Default is 64. ++ ++flush.relocate_distance=N ++ If flush finds can find a block allocation closer than at most ++ N from the preceder it will relocate to that position. ++ Default is 64. ++ ++flush.scan_maxnodes=N ++ The maximum number of nodes to scan left on a level during ++ flush. ++ Default is 10000. ++ ++optimal_io_size=N ++ Preferred IO size. This value is used to set st_blksize of ++ struct stat. ++ Default is 65536. ++ ++bsdgroups ++ Turn on BSD-style gid assignment. ++ ++32bittimes ++ By default file in reiser4 have 64 bit timestamps. Files ++ created when filesystem is mounted with 32bittimes mount ++ option will get 32 bit timestamps. ++ ++mtflush ++ Turn off concurrent flushing. ++ ++nopseudo ++ Disable pseudo files support. See ++ http://namesys.com/v4/pseudo.html for more about pseudo files. ++ ++dont_load_bitmap ++ Don't load all bitmap blocks at mount time, it is useful for ++ machines with tiny RAM and large disks. +diff -urN --no-dereference linux-5.10.2.orig/Documentation/process/changes.rst linux-5.10.2/Documentation/process/changes.rst +--- linux-5.10.2.orig/Documentation/process/changes.rst 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/Documentation/process/changes.rst 2020-12-23 16:07:46.109812997 +0100 +@@ -204,6 +204,13 @@ + versions of ``mkreiserfs``, ``resize_reiserfs``, ``debugreiserfs`` and + ``reiserfsck``. These utils work on both i386 and alpha platforms. + ++Reiser4progs ++------------ ++ ++The reiser4progs package contains utilities for the reiser4 file system. ++Detailed instructions are provided in the README file located at: ++. ++ + Xfsprogs + -------- + +@@ -411,6 +418,11 @@ + + - + ++Reiser4progs ++------------ ++ ++- ++ + Xfsprogs + -------- + +diff -urN --no-dereference linux-5.10.2.orig/fs/fs-writeback.c linux-5.10.2/fs/fs-writeback.c +--- linux-5.10.2.orig/fs/fs-writeback.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/fs/fs-writeback.c 2020-12-23 16:08:55.163816600 +0100 +@@ -37,25 +37,6 @@ + #define MIN_WRITEBACK_PAGES (4096UL >> (PAGE_SHIFT - 10)) + + /* +- * Passed into wb_writeback(), essentially a subset of writeback_control +- */ +-struct wb_writeback_work { +- long nr_pages; +- struct super_block *sb; +- enum writeback_sync_modes sync_mode; +- unsigned int tagged_writepages:1; +- unsigned int for_kupdate:1; +- unsigned int range_cyclic:1; +- unsigned int for_background:1; +- unsigned int for_sync:1; /* sync(2) WB_SYNC_ALL writeback */ +- unsigned int auto_free:1; /* free on completion */ +- enum wb_reason reason; /* why was writeback initiated? */ +- +- struct list_head list; /* pending work list */ +- struct wb_completion *done; /* set if the caller waits */ +-}; +- +-/* + * If an inode is constantly having its pages dirtied, but then the + * updates stop dirtytime_expire_interval seconds in the past, it's + * possible for the worst case time between when an inode has its +@@ -1626,20 +1607,12 @@ + * unlock and relock that for each inode it ends up doing + * IO for. + */ +-static long writeback_sb_inodes(struct super_block *sb, +- struct bdi_writeback *wb, +- struct wb_writeback_work *work) ++long generic_writeback_sb_inodes(struct super_block *sb, ++ struct bdi_writeback *wb, ++ struct writeback_control *wbc, ++ struct wb_writeback_work *work, ++ bool flush_all) + { +- struct writeback_control wbc = { +- .sync_mode = work->sync_mode, +- .tagged_writepages = work->tagged_writepages, +- .for_kupdate = work->for_kupdate, +- .for_background = work->for_background, +- .for_sync = work->for_sync, +- .range_cyclic = work->range_cyclic, +- .range_start = 0, +- .range_end = LLONG_MAX, +- }; + unsigned long start_time = jiffies; + long write_chunk; + long wrote = 0; /* count both pages and inodes */ +@@ -1678,7 +1651,7 @@ + spin_unlock(&inode->i_lock); + continue; + } +- if ((inode->i_state & I_SYNC) && wbc.sync_mode != WB_SYNC_ALL) { ++ if ((inode->i_state & I_SYNC) && wbc->sync_mode != WB_SYNC_ALL) { + /* + * If this inode is locked for writeback and we are not + * doing writeback-for-data-integrity, move it to +@@ -1708,21 +1681,21 @@ + continue; + } + inode->i_state |= I_SYNC; +- wbc_attach_and_unlock_inode(&wbc, inode); ++ wbc_attach_and_unlock_inode(wbc, inode); + + write_chunk = writeback_chunk_size(wb, work); +- wbc.nr_to_write = write_chunk; +- wbc.pages_skipped = 0; ++ wbc->nr_to_write = write_chunk; ++ wbc->pages_skipped = 0; + + /* + * We use I_SYNC to pin the inode in memory. While it is set + * evict_inode() will wait so the inode cannot be freed. + */ +- __writeback_single_inode(inode, &wbc); ++ __writeback_single_inode(inode, wbc); + +- wbc_detach_inode(&wbc); +- work->nr_pages -= write_chunk - wbc.nr_to_write; +- wrote += write_chunk - wbc.nr_to_write; ++ wbc_detach_inode(wbc); ++ work->nr_pages -= write_chunk - wbc->nr_to_write; ++ wrote += write_chunk - wbc->nr_to_write; + + if (need_resched()) { + /* +@@ -1745,7 +1718,7 @@ + spin_lock(&inode->i_lock); + if (!(inode->i_state & I_DIRTY_ALL)) + wrote++; +- requeue_inode(inode, tmp_wb, &wbc); ++ requeue_inode(inode, tmp_wb, wbc); + inode_sync_complete(inode); + spin_unlock(&inode->i_lock); + +@@ -1759,7 +1732,7 @@ + * background threshold and other termination conditions. + */ + if (wrote) { +- if (time_is_before_jiffies(start_time + HZ / 10UL)) ++ if (!flush_all && time_is_before_jiffies(start_time + HZ / 10UL)) + break; + if (work->nr_pages <= 0) + break; +@@ -1767,6 +1740,26 @@ + } + return wrote; + } ++EXPORT_SYMBOL(generic_writeback_sb_inodes); ++ ++long writeback_sb_inodes(struct super_block *sb, ++ struct bdi_writeback *wb, ++ struct wb_writeback_work *work) ++{ ++ struct writeback_control wbc = { ++ .sync_mode = work->sync_mode, ++ .tagged_writepages = work->tagged_writepages, ++ .for_kupdate = work->for_kupdate, ++ .for_background = work->for_background, ++ .range_cyclic = work->range_cyclic, ++ .range_start = 0, ++ .range_end = LLONG_MAX, ++ }; ++ if (sb->s_op->writeback_inodes) ++ return sb->s_op->writeback_inodes(sb, wb, &wbc, work, false); ++ else ++ return generic_writeback_sb_inodes(sb, wb, &wbc, work, false); ++} + + static long __writeback_inodes_wb(struct bdi_writeback *wb, + struct wb_writeback_work *work) +@@ -2056,6 +2049,31 @@ + } + + /* ++ * This function is for file systems which have their ++ * own means of periodical write-out of old data. ++ * NOTE: inode_lock should be hold. ++ * ++ * Skip a portion of b_io inodes which belong to @sb ++ * and go sequentially in reverse order. ++ */ ++void writeback_skip_sb_inodes(struct super_block *sb, ++ struct bdi_writeback *wb) ++{ ++ while (1) { ++ struct inode *inode; ++ ++ if (list_empty(&wb->b_io)) ++ break; ++ inode = wb_inode(wb->b_io.prev); ++ if (sb != inode->i_sb) ++ break; ++ redirty_tail(inode, wb); ++ } ++} ++EXPORT_SYMBOL(writeback_skip_sb_inodes); ++ ++ ++/* + * Handle writeback of dirty data for the device backed by this bdi. Also + * reschedules periodically and does kupdated style flushing. + */ +diff -urN --no-dereference linux-5.10.2.orig/fs/Kconfig linux-5.10.2/fs/Kconfig +--- linux-5.10.2.orig/fs/Kconfig 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/fs/Kconfig 2020-12-23 16:07:46.112813041 +0100 +@@ -31,6 +31,7 @@ + default y if EXT4_FS=y + default m if EXT2_FS_XATTR || EXT4_FS + ++source "fs/reiser4/Kconfig" + source "fs/reiserfs/Kconfig" + source "fs/jfs/Kconfig" + +diff -urN --no-dereference linux-5.10.2.orig/fs/Makefile linux-5.10.2/fs/Makefile +--- linux-5.10.2.orig/fs/Makefile 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/fs/Makefile 2020-12-23 16:07:46.112813041 +0100 +@@ -70,6 +70,7 @@ + # Do not add any filesystems before this line + obj-$(CONFIG_FSCACHE) += fscache/ + obj-$(CONFIG_REISERFS_FS) += reiserfs/ ++obj-$(CONFIG_REISER4_FS) += reiser4/ + obj-$(CONFIG_EXT4_FS) += ext4/ + # We place ext4 before ext2 so that clean ext3 root fs's do NOT mount using the + # ext2 driver, which doesn't know about journalling! Explicitly request ext2 +diff -urN --no-dereference linux-5.10.2.orig/fs/read_write.c linux-5.10.2/fs/read_write.c +--- linux-5.10.2.orig/fs/read_write.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/fs/read_write.c 2020-12-23 16:07:46.113813056 +0100 +@@ -233,12 +233,11 @@ + } + EXPORT_SYMBOL(no_llseek); + +-loff_t default_llseek(struct file *file, loff_t offset, int whence) ++loff_t default_llseek_unlocked(struct file *file, loff_t offset, int whence) + { + struct inode *inode = file_inode(file); + loff_t retval; + +- inode_lock(inode); + switch (whence) { + case SEEK_END: + offset += i_size_read(inode); +@@ -283,9 +282,19 @@ + retval = offset; + } + out: +- inode_unlock(inode); + return retval; + } ++EXPORT_SYMBOL(default_llseek_unlocked); ++ ++loff_t default_llseek(struct file *file, loff_t offset, int origin) ++{ ++ loff_t retval; ++ ++ inode_lock(file_inode(file)); ++ retval = default_llseek_unlocked(file, offset, origin); ++ inode_unlock(file_inode(file)); ++ return retval; ++} + EXPORT_SYMBOL(default_llseek); + + loff_t vfs_llseek(struct file *file, loff_t offset, int whence) +@@ -401,7 +410,7 @@ + read_write == READ ? MAY_READ : MAY_WRITE); + } + +-static ssize_t new_sync_read(struct file *filp, char __user *buf, size_t len, loff_t *ppos) ++ssize_t new_sync_read(struct file *filp, char __user *buf, size_t len, loff_t *ppos) + { + struct iovec iov = { .iov_base = buf, .iov_len = len }; + struct kiocb kiocb; +@@ -418,6 +427,7 @@ + *ppos = kiocb.ki_pos; + return ret; + } ++EXPORT_SYMBOL(new_sync_read); + + static int warn_unsupported(struct file *file, const char *op) + { +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/as_ops.c linux-5.10.2/fs/reiser4/as_ops.c +--- linux-5.10.2.orig/fs/reiser4/as_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/as_ops.c 2020-12-23 16:07:46.113813056 +0100 +@@ -0,0 +1,348 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Interface to VFS. Reiser4 address_space_operations are defined here. */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/file/file.h" ++#include "plugin/security/perm.h" ++#include "plugin/disk_format/disk_format.h" ++#include "plugin/plugin.h" ++#include "plugin/plugin_set.h" ++#include "plugin/object.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "page_cache.h" ++#include "ktxnmgrd.h" ++#include "super.h" ++#include "reiser4.h" ++#include "entd.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* address space operations */ ++ ++/** ++ * reiser4_set_page_dirty - set dirty bit, tag in page tree, dirty accounting ++ * @page: page to be dirtied ++ * ++ * Operation of struct address_space_operations. This implementation is used by ++ * unix and cryptcompress file plugins. ++ * ++ * This is called when reiser4 page gets dirtied outside of reiser4, for ++ * example, when dirty bit is moved from pte to physical page. ++ * ++ * Tags page in the mapping's page tree with special tag so that it is possible ++ * to do all the reiser4 specific work wrt dirty pages (jnode creation, ++ * capturing by an atom) later because it can not be done in the contexts where ++ * set_page_dirty is called. ++ */ ++int reiser4_set_page_dirty(struct page *page) ++{ ++ /* this page can be unformatted only */ ++ assert("vs-1734", (page->mapping && ++ page->mapping->host && ++ reiser4_get_super_fake(page->mapping->host->i_sb) != ++ page->mapping->host && ++ reiser4_get_cc_fake(page->mapping->host->i_sb) != ++ page->mapping->host && ++ reiser4_get_bitmap_fake(page->mapping->host->i_sb) != ++ page->mapping->host)); ++ return __set_page_dirty_nobuffers(page); ++} ++ ++/* ->invalidatepage method for reiser4 */ ++ ++/* ++ * this is called for each truncated page from ++ * truncate_inode_pages()->truncate_{complete,partial}_page(). ++ * ++ * At the moment of call, page is under lock, and outstanding io (if any) has ++ * completed. ++ */ ++ ++/** ++ * reiser4_invalidatepage ++ * @page: page to invalidate ++ * @offset: starting offset for partial invalidation ++ * ++ */ ++void reiser4_invalidatepage(struct page *page, unsigned int offset, unsigned int length) ++{ ++ int ret = 0; ++ int partial_page = (offset || length < PAGE_SIZE); ++ reiser4_context *ctx; ++ struct inode *inode; ++ jnode *node; ++ ++ /* ++ * This is called to truncate file's page. ++ * ++ * Originally, reiser4 implemented truncate in a standard way ++ * (vmtruncate() calls ->invalidatepage() on all truncated pages ++ * first, then file system ->truncate() call-back is invoked). ++ * ++ * This lead to the problem when ->invalidatepage() was called on a ++ * page with jnode that was captured into atom in ASTAGE_PRE_COMMIT ++ * process. That is, truncate was bypassing transactions. To avoid ++ * this, try_capture_page_to_invalidate() call was added here. ++ * ++ * After many troubles with vmtruncate() based truncate (including ++ * races with flush, tail conversion, etc.) it was re-written in the ++ * top-to-bottom style: items are killed in reiser4_cut_tree_object() ++ * and pages belonging to extent are invalidated in kill_hook_extent(). ++ * So probably now additional call to capture is not needed here. ++ */ ++ ++ assert("nikita-3137", PageLocked(page)); ++ assert("nikita-3138", !PageWriteback(page)); ++ inode = page->mapping->host; ++ ++ /* ++ * ->invalidatepage() should only be called for the unformatted ++ * jnodes. Destruction of all other types of jnodes is performed ++ * separately. But, during some corner cases (like handling errors ++ * during mount) it is simpler to let ->invalidatepage to be called on ++ * them. Check for this, and do nothing. ++ */ ++ if (reiser4_get_super_fake(inode->i_sb) == inode) ++ return; ++ if (reiser4_get_cc_fake(inode->i_sb) == inode) ++ return; ++ if (reiser4_get_bitmap_fake(inode->i_sb) == inode) ++ return; ++ assert("vs-1426", PagePrivate(page)); ++ assert("vs-1427", ++ page->mapping == jnode_get_mapping(jnode_by_page(page))); ++ assert("", jprivate(page) != NULL); ++ assert("", ergo(inode_file_plugin(inode) != ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID), ++ offset == 0)); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return; ++ ++ node = jprivate(page); ++ spin_lock_jnode(node); ++ if (!(node->state & ((1 << JNODE_DIRTY) | (1 << JNODE_FLUSH_QUEUED) | ++ (1 << JNODE_WRITEBACK) | (1 << JNODE_OVRWR)))) { ++ /* there is not need to capture */ ++ jref(node); ++ JF_SET(node, JNODE_HEARD_BANSHEE); ++ page_clear_jnode(page, node); ++ reiser4_uncapture_jnode(node); ++ unhash_unformatted_jnode(node); ++ jput(node); ++ reiser4_exit_context(ctx); ++ return; ++ } ++ spin_unlock_jnode(node); ++ ++ /* capture page being truncated. */ ++ ret = try_capture_page_to_invalidate(page); ++ if (ret != 0) ++ warning("nikita-3141", "Cannot capture: %i", ret); ++ ++ if (!partial_page) { ++ /* remove jnode from transaction and detach it from page. */ ++ jref(node); ++ JF_SET(node, JNODE_HEARD_BANSHEE); ++ /* page cannot be detached from jnode concurrently, because it ++ * is locked */ ++ reiser4_uncapture_page(page); ++ ++ /* this detaches page from jnode, so that jdelete will not try ++ * to lock page which is already locked */ ++ spin_lock_jnode(node); ++ page_clear_jnode(page, node); ++ spin_unlock_jnode(node); ++ unhash_unformatted_jnode(node); ++ ++ jput(node); ++ } ++ ++ reiser4_exit_context(ctx); ++} ++ ++/* help function called from reiser4_releasepage(). It returns true if jnode ++ * can be detached from its page and page released. */ ++int jnode_is_releasable(jnode * node/* node to check */) ++{ ++ assert("nikita-2781", node != NULL); ++ assert_spin_locked(&(node->guard)); ++ assert_spin_locked(&(node->load)); ++ ++ /* is some thread is currently using jnode page, later cannot be ++ * detached */ ++ if (atomic_read(&node->d_count) != 0) ++ return 0; ++ ++ assert("vs-1214", !jnode_is_loaded(node)); ++ ++ /* ++ * can only release page if real block number is assigned to it. Simple ++ * check for ->atom wouldn't do, because it is possible for node to be ++ * clean, not it atom yet, and still having fake block number. For ++ * example, node just created in jinit_new(). ++ */ ++ if (reiser4_blocknr_is_fake(jnode_get_block(node))) ++ return 0; ++ ++ /* ++ * pages prepared for write can not be released anyway, so avoid ++ * detaching jnode from the page ++ */ ++ if (JF_ISSET(node, JNODE_WRITE_PREPARED)) ++ return 0; ++ ++ /* ++ * dirty jnode cannot be released. It can however be submitted to disk ++ * as part of early flushing, but only after getting flush-prepped. ++ */ ++ if (JF_ISSET(node, JNODE_DIRTY)) ++ return 0; ++ ++ /* overwrite set is only written by log writer. */ ++ if (JF_ISSET(node, JNODE_OVRWR)) ++ return 0; ++ ++ /* jnode is already under writeback */ ++ if (JF_ISSET(node, JNODE_WRITEBACK)) ++ return 0; ++ ++ /* don't flush bitmaps or journal records */ ++ if (!jnode_is_znode(node) && !jnode_is_unformatted(node)) ++ return 0; ++ ++ return 1; ++} ++ ++/* ++ * ->releasepage method for reiser4 ++ * ++ * This is called by VM scanner when it comes across clean page. What we have ++ * to do here is to check whether page can really be released (freed that is) ++ * and if so, detach jnode from it and remove page from the page cache. ++ * ++ * Check for releasability is done by releasable() function. ++ */ ++int reiser4_releasepage(struct page *page, gfp_t gfp UNUSED_ARG) ++{ ++ jnode *node; ++ ++ assert("nikita-2257", PagePrivate(page)); ++ assert("nikita-2259", PageLocked(page)); ++ assert("nikita-2892", !PageWriteback(page)); ++ assert("nikita-3019", reiser4_schedulable()); ++ ++ /* NOTE-NIKITA: this can be called in the context of reiser4 call. It ++ is not clear what to do in this case. A lot of deadlocks seems be ++ possible. */ ++ ++ node = jnode_by_page(page); ++ assert("nikita-2258", node != NULL); ++ assert("reiser4-4", page->mapping != NULL); ++ assert("reiser4-5", page->mapping->host != NULL); ++ ++ if (PageDirty(page)) ++ return 0; ++ ++ /* extra page reference is used by reiser4 to protect ++ * jnode<->page link from this ->releasepage(). */ ++ if (page_count(page) > 3) ++ return 0; ++ ++ /* releasable() needs jnode lock, because it looks at the jnode fields ++ * and we need jload_lock here to avoid races with jload(). */ ++ spin_lock_jnode(node); ++ spin_lock(&(node->load)); ++ if (jnode_is_releasable(node)) { ++ struct address_space *mapping; ++ ++ mapping = page->mapping; ++ jref(node); ++ /* there is no need to synchronize against ++ * jnode_extent_write() here, because pages seen by ++ * jnode_extent_write() are !releasable(). */ ++ page_clear_jnode(page, node); ++ spin_unlock(&(node->load)); ++ spin_unlock_jnode(node); ++ ++ /* we are under memory pressure so release jnode also. */ ++ jput(node); ++ ++ return 1; ++ } else { ++ spin_unlock(&(node->load)); ++ spin_unlock_jnode(node); ++ assert("nikita-3020", reiser4_schedulable()); ++ return 0; ++ } ++} ++ ++#ifdef CONFIG_MIGRATION ++int reiser4_migratepage(struct address_space *mapping, struct page *newpage, ++ struct page *page, enum migrate_mode mode) ++{ ++ /* TODO: implement movable mapping ++ */ ++ return -EIO; ++} ++#endif /* CONFIG_MIGRATION */ ++ ++int reiser4_readpage_dispatch(struct file *file, struct page *page) ++{ ++ assert("edward-1533", PageLocked(page)); ++ assert("edward-1534", !PageUptodate(page)); ++ assert("edward-1535", page->mapping && page->mapping->host); ++ ++ return inode_file_plugin(page->mapping->host)->readpage(file, page); ++} ++ ++int reiser4_readpages_dispatch(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages) ++{ ++ return inode_file_plugin(mapping->host)->readpages(file, mapping, ++ pages, nr_pages); ++} ++ ++int reiser4_writepages_dispatch(struct address_space *mapping, ++ struct writeback_control *wbc) ++{ ++ return inode_file_plugin(mapping->host)->writepages(mapping, wbc); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/block_alloc.c linux-5.10.2/fs/reiser4/block_alloc.c +--- linux-5.10.2.orig/fs/reiser4/block_alloc.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/block_alloc.c 2020-12-23 16:07:46.113813056 +0100 +@@ -0,0 +1,1395 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++reiser4/README */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "plugin/plugin.h" ++#include "txnmgr.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "super.h" ++#include "discard.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block */ ++#include ++ ++/* THE REISER4 DISK SPACE RESERVATION SCHEME. */ ++ ++/* We need to be able to reserve enough disk space to ensure that an atomic ++ operation will have enough disk space to flush (see flush.c and ++ http://namesys.com/v4/v4.html) and commit it once it is started. ++ ++ In our design a call for reserving disk space may fail but not an actual ++ block allocation. ++ ++ All free blocks, already allocated blocks, and all kinds of reserved blocks ++ are counted in different per-fs block counters. ++ ++ A reiser4 super block's set of block counters currently is: ++ ++ free -- free blocks, ++ used -- already allocated blocks, ++ ++ grabbed -- initially reserved for performing an fs operation, those blocks ++ are taken from free blocks, then grabbed disk space leaks from grabbed ++ blocks counter to other counters like "fake allocated", "flush ++ reserved", "used", the rest of not used grabbed space is returned to ++ free space at the end of fs operation; ++ ++ fake allocated -- counts all nodes without real disk block numbers assigned, ++ we have separate accounting for formatted and unformatted ++ nodes (for easier debugging); ++ ++ flush reserved -- disk space needed for flushing and committing an atom. ++ Each dirty already allocated block could be written as a ++ part of atom's overwrite set or as a part of atom's ++ relocate set. In both case one additional block is needed, ++ it is used as a wandered block if we do overwrite or as a ++ new location for a relocated block. ++ ++ In addition, blocks in some states are counted on per-thread and per-atom ++ basis. A reiser4 context has a counter of blocks grabbed by this transaction ++ and the sb's grabbed blocks counter is a sum of grabbed blocks counter values ++ of each reiser4 context. Each reiser4 atom has a counter of "flush reserved" ++ blocks, which are reserved for flush processing and atom commit, and the sb's ++ counter of flush reserved blocks is a sum of respective counters of each atom ++*/ ++ ++/* AN EXAMPLE: suppose we insert new item to the reiser4 tree. We estimate ++ number of blocks to grab for most expensive case of balancing when the leaf ++ node we insert new item to gets split and new leaf node is allocated. ++ ++ So, we need to grab blocks for ++ ++ 1) one block for possible dirtying the node we insert an item to. That block ++ would be used for node relocation at flush time or for allocating of a ++ wandered one, it depends what will be a result (what set, relocate or ++ overwrite the node gets assigned to) of the node processing by the flush ++ algorithm. ++ ++ 2) one block for either allocating a new node, or dirtying of right or left ++ clean neighbor, only one case may happen. ++ ++ VS-FIXME-HANS: why can only one case happen? I would expect to see dirtying ++ of left neighbor, right neighbor, current node, and creation of new node. ++ Have I forgotten something? email me. ++ ++ These grabbed blocks are counted in both reiser4 context "grabbed blocks" ++ counter and in the fs-wide one (both ctx->ctx_grabbed_blocks and ++ sbinfo->blocks_grabbed get incremented by 2), sb's free blocks counter is ++ decremented by 2. ++ ++ Suppose both two blocks were spent for dirtying of an already allocated clean ++ node (one block went from "grabbed" to "flush reserved") and for new block ++ allocating (one block went from "grabbed" to "fake allocated formatted"). ++ ++ Inserting of a child pointer to the parent node caused parent node to be ++ split, the balancing code takes care about this grabbing necessary space ++ immediately by calling reiser4_grab with BA_RESERVED flag set which means ++ "can use the 5% reserved disk space". ++ ++ At this moment insertion completes and grabbed blocks (if they were not used) ++ should be returned to the free space counter. ++ ++ However the atom life-cycle is not completed. The atom had one "flush ++ reserved" block added by our insertion and the new fake allocated node is ++ counted as a "fake allocated formatted" one. The atom has to be fully ++ processed by flush before commit. Suppose that the flush moved the first, ++ already allocated node to the atom's overwrite list, the new fake allocated ++ node, obviously, went into the atom relocate set. The reiser4 flush ++ allocates the new node using one unit from "fake allocated formatted" ++ counter, the log writer uses one from "flush reserved" for wandered block ++ allocation. ++ ++ And, it is not the end. When the wandered block is deallocated after the ++ atom gets fully played (see wander.c for term description), the disk space ++ occupied for it is returned to free blocks. */ ++ ++/* BLOCK NUMBERS */ ++ ++/* Any reiser4 node has a block number assigned to it. We use these numbers for ++ indexing in hash tables, so if a block has not yet been assigned a location ++ on disk we need to give it a temporary fake block number. ++ ++ Current implementation of reiser4 uses 64-bit integers for block numbers. We ++ use highest bit in 64-bit block number to distinguish fake and real block ++ numbers. So, only 63 bits may be used to addressing of real device ++ blocks. That "fake" block numbers space is divided into subspaces of fake ++ block numbers for data blocks and for shadow (working) bitmap blocks. ++ ++ Fake block numbers for data blocks are generated by a cyclic counter, which ++ gets incremented after each real block allocation. We assume that it is ++ impossible to overload this counter during one transaction life. */ ++ ++/* Initialize a blocknr hint. */ ++void reiser4_blocknr_hint_init(reiser4_blocknr_hint * hint) ++{ ++ memset(hint, 0, sizeof(reiser4_blocknr_hint)); ++} ++ ++/* Release any resources of a blocknr hint. */ ++void reiser4_blocknr_hint_done(reiser4_blocknr_hint * hint UNUSED_ARG) ++{ ++/* No resources should be freed in current blocknr_hint implementation. */ ++} ++ ++/* see above for explanation of fake block number. */ ++/* Audited by: green(2002.06.11) */ ++int reiser4_blocknr_is_fake(const reiser4_block_nr * da) ++{ ++ /* The reason for not simply returning result of '&' operation is that ++ while return value is (possibly 32bit) int, the reiser4_block_nr is ++ at least 64 bits long, and high bit (which is the only possible ++ non zero bit after the masking) would be stripped off */ ++ return (*da & REISER4_FAKE_BLOCKNR_BIT_MASK) ? 1 : 0; ++} ++ ++__u64 ctx_subvol_grabbed(reiser4_context *ctx, __u32 subv_id) ++{ ++ struct ctx_brick_info *cbi; ++ ++ cbi = find_context_brick_info(ctx, subv_id); ++ return cbi != NULL ? cbi->grabbed_blocks : 0; ++} ++ ++/* ++ * Static functions for / ++ * block counters arithmetic. Mostly, they are isolated to not ++ * to code same assertions in several places ++ */ ++ ++static inline void sub_from_cbi_grabbed(struct ctx_brick_info *cbi, ++ __u64 count) ++{ ++ if (count != 0) { ++ assert("edward-1976", cbi != NULL); ++ assert("zam-527", cbi->grabbed_blocks >= count); ++ BUG_ON(cbi == NULL); ++ BUG_ON(cbi->grabbed_blocks < count); ++ ++ cbi->grabbed_blocks -= count; ++ } ++} ++ ++static inline void sub_from_ctx_grabbed(reiser4_context *ctx, ++ u64 count, reiser4_subvol *subv) ++{ ++ sub_from_cbi_grabbed(find_context_brick_info(ctx, subv->id), ++ count); ++} ++ ++static inline void add_to_cbi_grabbed(struct ctx_brick_info *cbi, u64 count) ++{ ++ cbi->grabbed_blocks += count; ++} ++ ++static void add_to_ctx_grabbed(reiser4_context *ctx, ++ __u64 count, __u32 subv_id) ++{ ++ struct ctx_brick_info *cbi; ++ ++ cbi = find_context_brick_info(ctx, subv_id); ++ if (cbi == NULL) { ++ assert("edward-1989", reiser4_schedulable()); ++ ++ cbi = alloc_context_brick_info(); ++ BUG_ON(cbi == NULL); ++ init_context_brick_info(cbi, subv_id); ++ insert_context_brick_info(ctx, cbi); ++ } ++ add_to_cbi_grabbed(cbi, count); ++} ++ ++static void sub_from_subvol_grabbed(reiser4_subvol *subv, __u64 count) ++{ ++ assert("zam-525", subv->blocks_grabbed >= count); ++ subv->blocks_grabbed -= count; ++} ++ ++static void sub_from_subvol_flush_reserved(reiser4_subvol *subv, ++ __u64 count) ++{ ++ assert("edward-1990", subvol_check_block_counters(subv)); ++ assert("vpf-291", subv->blocks_flush_reserved >= count); ++ ++ subv->blocks_flush_reserved -= count; ++} ++ ++static void sub_from_subvol_fake_allocated(reiser4_subvol *subv, ++ __u64 count, reiser4_ba_flags_t flags) ++{ ++ if (flags & BA_FORMATTED) { ++ assert("zam-806", subv->blocks_fake_allocated >= count); ++ subv->blocks_fake_allocated -= count; ++ } else { ++ assert("zam-528", ++ subv->blocks_fake_allocated_unformatted >= count); ++ subv->blocks_fake_allocated_unformatted -= count; ++ } ++} ++ ++static void sub_from_subvol_used(reiser4_subvol *subv, __u64 count) ++{ ++ assert("zam-530", ++ subv->blocks_used >= count + subv->min_blocks_used); ++ ++ subv->blocks_used -= count; ++} ++ ++static void sub_from_cluster_reserved(reiser4_subvol *subv, __u64 count) ++{ ++ assert("edward-501", subv->blocks_clustered >= count); ++ subv->blocks_clustered -= count; ++} ++ ++static inline void add_to_abi_flush_reserved(struct atom_brick_info *abi, ++ u32 count) ++{ ++ assert("edward-1991", abi != NULL); ++ BUG_ON(abi == NULL); ++ ++ abi->atom_flush_reserved += count; ++} ++ ++static void add_to_atom_flush_reserved(txn_atom *atom, __u32 count, ++ __u32 subv_id) ++{ ++ assert("zam-772", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ add_to_abi_flush_reserved(find_atom_brick_info(&atom->bricks_info, ++ subv_id), count); ++} ++ ++static void sub_from_abi_flush_reserved(struct atom_brick_info *abi, ++ u32 count) ++{ ++ assert("edward-1992", abi != NULL); ++ assert("nikita-2790", abi->atom_flush_reserved >= count); ++ ++ abi->atom_flush_reserved -= count; ++} ++ ++/* ++ * subvolume has 7 counters: free, used, grabbed, fake allocated ++ * (formatted and unformatted), clustered and flush reserved. ++ * Their sum must be number of blocks on a device. ++ */ ++int subvol_check_block_counters(const reiser4_subvol *subv) ++{ ++ __u64 sum; ++ ++ sum = ++ reiser4_subvol_grabbed_blocks(subv) + ++ reiser4_subvol_free_blocks(subv) + ++ reiser4_subvol_used_blocks(subv) + ++ reiser4_subvol_fake_allocated_fmt(subv) + ++ reiser4_subvol_fake_allocated_unf(subv) + ++ reiser4_subvol_flush_reserved(subv) + ++ reiser4_subvol_clustered_blocks(subv); ++ ++ if (reiser4_subvol_block_count(subv) != sum) { ++ printk("subvol (%s) block counters: " ++ "used %llu, free %llu, " ++ "grabbed %llu, " ++ "fake allocated (formatetd %llu, unformatted %llu), " ++ "reserved %llu, clustered %llu, " ++ "sum %llu, must be (block count) %llu\n", ++ subv->name, ++ (unsigned long long)reiser4_subvol_used_blocks(subv), ++ (unsigned long long)reiser4_subvol_free_blocks(subv), ++ (unsigned long long)reiser4_subvol_grabbed_blocks(subv), ++ (unsigned long long)reiser4_subvol_fake_allocated_fmt(subv), ++ (unsigned long long)reiser4_subvol_fake_allocated_unf(subv), ++ (unsigned long long)reiser4_subvol_flush_reserved(subv), ++ (unsigned long long)reiser4_subvol_clustered_blocks(subv), ++ (unsigned long long)sum, ++ (unsigned long long)reiser4_subvol_block_count(subv)); ++ return 0; ++ } ++ return 1; ++} ++ ++/* Adjust "working" free blocks counter for number of blocks we are going to ++ allocate. Record number of grabbed blocks in fs-wide and per-thread ++ counters. This function should be called before bitmap scanning or ++ allocating fake block numbers ++ ++ @super -- pointer to reiser4 super block; ++ @count -- number of blocks we reserve; ++ ++ @return -- 0 if success, -ENOSPC, if all ++ free blocks are preserved or already allocated. ++*/ ++ ++static int reiser4_grab(reiser4_context *ctx, __u64 count, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv) ++{ ++ __u64 free_blocks; ++ int use_reserved = flags & BA_RESERVED; ++ reiser4_super_info_data *sbinfo; ++ ++ assert("vs-1276", ctx == get_current_context()); ++ /* ++ * Do not grab anything on ro-mounted fs ++ */ ++ if (sb_rdonly(ctx->super)) { ++ ctx->grab_enabled = 0; ++ ctx->ro = 1; ++ return 0; ++ } ++ sbinfo = get_super_private(ctx->super); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ free_blocks = subv->blocks_free; ++ ++ if ((use_reserved && free_blocks < count) || ++ (!use_reserved && free_blocks < count + subv->blocks_reserved)) { ++ ++ spin_unlock_reiser4_super(sbinfo); ++ return RETERR(-ENOSPC); ++ } ++ subv->blocks_grabbed += count; ++ subv->blocks_free -= count; ++ ++ assert("nikita-2986", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++ ++ add_to_ctx_grabbed(ctx, count, subv->id); ++ /* ++ * disable grab space in current context ++ */ ++ ctx->grab_enabled = 0; ++ return 0; ++} ++ ++int reiser4_grab_space(__u64 count, reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ reiser4_context *ctx; ++ ++ assert("nikita-2964", ++ ergo(flags & BA_CAN_COMMIT, ++ lock_stack_isclean(get_current_lock_stack()))); ++ ctx = get_current_context(); ++ ++ if (!(flags & BA_FORCE) && !is_grab_enabled(ctx)) ++ return 0; ++ ++ ret = reiser4_grab(ctx, count, flags, subv); ++ if (ret == -ENOSPC) { ++ /* ++ * Try to commit the all transactions ++ * if BA_CAN_COMMIT flag is present ++ */ ++ if (flags & BA_CAN_COMMIT) { ++ txnmgr_force_commit_all(ctx->super, 0); ++ ctx->grab_enabled = 1; ++ ret = reiser4_grab(ctx, count, flags, subv); ++ } ++ } ++ /* ++ * allocation from reserved pool cannot fail. This is severe error. ++ */ ++ assert("nikita-3005", ergo(flags & BA_RESERVED, ret == 0)); ++ return ret; ++} ++ ++/** ++ * SPACE RESERVATION FOR UNLINK/TRUNCATE ++ * ++ * Unlink and truncate require space in transaction (to update stat data, ++ * at least). But we don't want rm(1) to fail with "No space on device" error. ++ * ++ * Solution is to reserve 5% of disk space for truncates and unlinks. ++ * Specifically, normal space grabbing requests don't grab space from ++ * reserved area. Only requests with BA_RESERVED bit in flags are allowed ++ * to drain it. Per super block delete mutex is used to allow only one ++ * thread at a time to grab from reserved area. ++ * ++ * Grabbing from reserved area should always be performed with BA_CAN_COMMIT ++ * flag. ++ * ++ * FIXME-EDWARD: Make delete mutex per-subvolume (not per-superblock). ++ */ ++int reiser4_grab_reserved(struct super_block *super, __u64 count, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv) ++{ ++ int ret; ++ reiser4_super_info_data *sbinfo = get_super_private(super); ++ ++ assert("nikita-3175", flags & BA_CAN_COMMIT); ++ /* ++ * Check the delete mutex already taken by us. ++ * We assume that reading of machine word is atomic ++ */ ++ if (sbinfo->delete_mutex_owner == current) { ++ ret = reiser4_grab_space(count, ++ (flags | BA_RESERVED) & ~BA_CAN_COMMIT, ++ subv); ++ if (ret) { ++ warning("zam-1003", ++ "nested call of grab_reserved fails count=(%llu)", ++ (unsigned long long)count); ++ reiser4_release_reserved(super); ++ return RETERR(-ENOSPC); ++ } ++ return 0; ++ } ++ /* ++ * first, try to grab space without reservation flag ++ */ ++ ret = reiser4_grab_space(count, flags, subv); ++ if (ret) { ++ /* ++ * normal grab failed, so try to grab from reserved area * ++ */ ++ mutex_lock(&sbinfo->delete_mutex); ++ assert("nikita-2929", sbinfo->delete_mutex_owner == NULL); ++ sbinfo->delete_mutex_owner = current; ++ ++ ret = reiser4_grab_space(count, flags | BA_RESERVED, subv); ++ if (ret){ ++ warning("zam-833", ++ "reserved space is not enough (%llu)", ++ (unsigned long long)count); ++ reiser4_release_reserved(super); ++ return RETERR(-ENOSPC); ++ } ++ } ++ return 0; ++} ++ ++void reiser4_release_reserved(struct super_block *super) ++{ ++ reiser4_super_info_data *info; ++ ++ info = get_super_private(super); ++ if (info->delete_mutex_owner == current) { ++ info->delete_mutex_owner = NULL; ++ mutex_unlock(&info->delete_mutex); ++ } ++} ++ ++static reiser4_super_info_data *grabbed2fake_allocated_head(int count, ++ reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ ctx = get_current_context(); ++ ++ sub_from_ctx_grabbed(ctx, count, subv); ++ ++ sbinfo = get_super_private(ctx->super); ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_grabbed(subv, count); ++ /* return sbinfo locked */ ++ return sbinfo; ++} ++ ++/* is called after @count fake block numbers are allocated and pointer to ++ those blocks are inserted into tree. */ ++static void grabbed2fake_allocated_formatted(reiser4_subvol *subv) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = grabbed2fake_allocated_head(1, subv); ++ subv->blocks_fake_allocated++; ++ ++ assert("vs-922", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/** ++ * grabbed2fake_allocated_unformatted ++ * @count: ++ * ++ */ ++static void grabbed2fake_allocated_unformatted(int count, reiser4_subvol *subv) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = grabbed2fake_allocated_head(count, subv); ++ subv->blocks_fake_allocated_unformatted += count; ++ ++ assert("vs-9221", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++void grabbed2cluster_reserved(int count, reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ ctx = get_current_context(); ++ ++ sub_from_ctx_grabbed(ctx, count, subv); ++ ++ sbinfo = get_super_private(ctx->super); ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_grabbed(subv, count); ++ subv->blocks_clustered += count; ++ ++ assert("edward-504", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++void cluster_reserved2grabbed(int count, reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ ctx = get_current_context(); ++ ++ sbinfo = get_super_private(ctx->super); ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_cluster_reserved(subv, count); ++ subv->blocks_grabbed += count; ++ ++ assert("edward-505", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++ add_to_ctx_grabbed(ctx, count, subv->id); ++} ++ ++void cluster_reserved2free(int count, reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ ++ cluster_reserved2grabbed(count, subv); ++ grabbed2free(ctx, sbinfo, count, subv); ++} ++ ++/* ++ * FIXME-EDWARD: This is per-subvolume thing ++ */ ++static DEFINE_SPINLOCK(fake_lock); ++static reiser4_block_nr fake_gen = 0; ++ ++/** ++ * assign_fake_blocknr ++ * @blocknr: ++ * @count: ++ * ++ * Obtain a fake block number for new node which will be used to refer to ++ * this newly allocated node until real allocation is done. ++ */ ++static void assign_fake_blocknr(reiser4_block_nr *blocknr, int count, ++ reiser4_subvol *subv) ++{ ++ spin_lock(&fake_lock); ++ *blocknr = fake_gen; ++ fake_gen += count; ++ spin_unlock(&fake_lock); ++ ++ BUG_ON(*blocknr & REISER4_BLOCKNR_STATUS_BIT_MASK); ++ /**blocknr &= ~REISER4_BLOCKNR_STATUS_BIT_MASK;*/ ++ *blocknr |= REISER4_UNALLOCATED_STATUS_VALUE; ++ assert("zam-394", zlook(&subv->tree, blocknr) == NULL); ++} ++ ++int assign_fake_blocknr_formatted(reiser4_block_nr *blocknr, ++ reiser4_subvol *subv) ++{ ++ assign_fake_blocknr(blocknr, 1, subv); ++ grabbed2fake_allocated_formatted(subv); ++ return 0; ++} ++ ++/** ++ * fake_blocknrs_unformatted ++ * @count: number of fake numbers to get ++ * ++ * Allocates @count fake block numbers which will be assigned to jnodes ++ */ ++reiser4_block_nr fake_blocknr_unformatted(int count, reiser4_subvol *subv) ++{ ++ reiser4_block_nr blocknr; ++ ++ assign_fake_blocknr(&blocknr, count, subv); ++ grabbed2fake_allocated_unformatted(count, subv); ++ ++ return blocknr; ++} ++ ++/* ++ * adjust sb block counters, if real (on-disk) block allocation immediately ++ * follows grabbing of free disk space ++ */ ++static void grabbed2used(reiser4_context *ctx, reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv) ++{ ++ sub_from_ctx_grabbed(ctx, count, subv); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_grabbed(subv, count); ++ subv->blocks_used += count; ++ ++ assert("nikita-2679", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* ++ * adjust sb block counters when @count unallocated blocks get mapped to disk ++ */ ++static void fake_allocated2used(reiser4_super_info_data *sbinfo, __u64 count, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv) ++{ ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_fake_allocated(subv, count, flags); ++ subv->blocks_used += count; ++ ++ assert("nikita-2680", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++static void flush_reserved2used(txn_atom *atom, u64 count, reiser4_subvol *subv) ++{ ++ reiser4_super_info_data *sbinfo; ++ struct atom_brick_info *abi; ++ ++ assert("zam-787", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ abi = find_atom_brick_info(&atom->bricks_info, subv->id); ++ ++ assert("edward-1993", abi != NULL); ++ assert("edward-1994", abi->brick_id == subv->id); ++ assert("edward-1995", ++ abi->atom_flush_reserved <= subv->blocks_flush_reserved); ++ ++ sub_from_abi_flush_reserved(abi, count); ++ sbinfo = get_current_super_private(); ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_flush_reserved(subv, count); ++ ++ assert("edward-1996", ++ abi->atom_flush_reserved <= subv->blocks_flush_reserved); ++ ++ subv->blocks_used += count; ++ ++ assert("zam-789", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* update the per fs blocknr hint default value. */ ++void update_blocknr_hint_default(const struct super_block *s, ++ struct reiser4_subvol *subv, ++ const reiser4_block_nr *block) ++{ ++ reiser4_super_info_data *sbinfo = get_super_private(s); ++ ++ assert("nikita-3342", !reiser4_blocknr_is_fake(block)); ++ ++ spin_lock_reiser4_super(sbinfo); ++ if (*block < subv->block_count) { ++ subv->blocknr_hint_default = *block; ++ } else { ++ warning("zam-676", ++ "block number %llu is too large to be used in a blocknr hint\n", ++ (unsigned long long)*block); ++ dump_stack(); ++ DEBUGON(1); ++ } ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* get current value of the default blocknr hint. */ ++void get_blocknr_hint_default(reiser4_block_nr *result, reiser4_subvol *subv) ++{ ++ reiser4_super_info_data *sbinfo = get_current_super_private(); ++ ++ spin_lock_reiser4_super(sbinfo); ++ *result = subv->blocknr_hint_default; ++ assert("zam-677", *result < subv->block_count); ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* Allocate "real" disk blocks by calling a proper space allocation plugin ++ * method. Blocks are allocated in one contiguous disk region. The plugin ++ * independent part accounts blocks by subtracting allocated amount from grabbed ++ * or fake block counter and add the same amount to the counter of allocated ++ * blocks. ++ * ++ * @hint -- a reiser4 blocknr hint object which contains further block ++ * allocation hints and parameters (search start, a stage of block ++ * which will be mapped to disk, etc.), ++ * @blk -- an out parameter for the beginning of the allocated region, ++ * @len -- in/out parameter, it should contain the maximum number of allocated ++ * blocks, after block allocation completes, it contains the length of ++ * allocated disk region. ++ * @flags -- see reiser4_ba_flags_t description. ++ * ++ * @return -- 0 if success, error code otherwise. ++ */ ++int reiser4_alloc_blocks(reiser4_blocknr_hint *hint, reiser4_block_nr *blk, ++ reiser4_block_nr *len, reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ __u64 needed = *len; ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ int ret; ++ ++ assert("zam-986", hint != NULL); ++ assert("edward-1776", subv != NULL); ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ /* ++ * For write-optimized data we use default search start value, which is ++ * close to last write location ++ */ ++ if (flags & BA_USE_DEFAULT_SEARCH_START) ++ get_blocknr_hint_default(&hint->blk, subv); ++ /* ++ * VITALY: allocator should grab this for internal/tx-lists/similar only ++ */ ++ if (hint->block_stage == BLOCK_NOT_COUNTED) { ++ ret = reiser4_grab_space_force(*len, flags, subv); ++ if (ret != 0) ++ return ret; ++ } ++ ret = sa_alloc_blocks(reiser4_get_space_allocator(subv), hint, ++ (int)needed, blk, len, subv); ++ if (!ret) { ++ assert("zam-680", ++ *blk < reiser4_subvol_block_count(subv)); ++ assert("zam-681", ++ *blk + *len <= reiser4_subvol_block_count(subv)); ++ ++ if (flags & BA_PERMANENT) { ++ /* ++ * we assume that current atom exists at this moment ++ */ ++ struct atom_brick_info *abi; ++ txn_atom *atom = get_current_atom_locked(); ++ ++ ret = __check_insert_atom_brick_info(&atom, ++ subv->id, &abi); ++ if (ret) ++ return ret; ++ abi->nr_blocks_allocated += *len; ++ spin_unlock_atom(atom); ++ } ++ switch (hint->block_stage) { ++ case BLOCK_NOT_COUNTED: ++ case BLOCK_GRABBED: ++ grabbed2used(ctx, sbinfo, *len, subv); ++ break; ++ case BLOCK_UNALLOCATED: ++ fake_allocated2used(sbinfo, *len, flags, subv); ++ break; ++ case BLOCK_FLUSH_RESERVED: ++ { ++ txn_atom *atom = get_current_atom_locked(); ++ flush_reserved2used(atom, *len, subv); ++ spin_unlock_atom(atom); ++ } ++ break; ++ default: ++ impossible("zam-531", "wrong block stage"); ++ } ++ } else { ++ assert("zam-821", ++ ergo(hint->max_dist == 0 ++ && !hint->backward, ret != -ENOSPC)); ++ if (hint->block_stage == BLOCK_NOT_COUNTED) ++ grabbed2free(ctx, sbinfo, needed, subv); ++ } ++ ++ return ret; ++} ++ ++/** ++ * ask block allocator for some unformatted blocks ++ */ ++void allocate_blocks_unformatted(reiser4_blocknr_hint *preceder, ++ reiser4_block_nr wanted_count, ++ reiser4_block_nr *first_allocated, ++ reiser4_block_nr *allocated, ++ block_stage_t block_stage, ++ reiser4_subvol *subv) ++{ ++ *allocated = wanted_count; ++ preceder->max_dist = 0; /* scan whole disk, if needed */ ++ ++ /* that number of blocks (wanted_count) is either in UNALLOCATED or in GRABBED */ ++ preceder->block_stage = block_stage; ++ ++ /* FIXME: we do not handle errors here now */ ++ check_me("vs-420", reiser4_alloc_blocks(preceder, first_allocated, ++ allocated, BA_PERMANENT, ++ subv) == 0); ++ /* update flush_pos's preceder to last allocated block number */ ++ preceder->blk = *first_allocated + *allocated - 1; ++} ++ ++/* used -> fake_allocated -> grabbed -> free */ ++ ++/* ++ * adjust block counters when @count unallocated blocks get unmapped from disk ++ */ ++static void used2fake_allocated(reiser4_super_info_data *sbinfo, __u64 count, ++ int formatted, reiser4_subvol *subv) ++{ ++ spin_lock_reiser4_super(sbinfo); ++ ++ if (formatted) ++ subv->blocks_fake_allocated += count; ++ else ++ subv->blocks_fake_allocated_unformatted += count; ++ ++ sub_from_subvol_used(subv, count); ++ ++ assert("nikita-2681", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++static void used2flush_reserved(reiser4_super_info_data *sbinfo, txn_atom *atom, ++ __u64 count, reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ assert("nikita-2791", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ add_to_atom_flush_reserved(atom, (__u32)count, subv->id); ++ spin_lock_reiser4_super(sbinfo); ++ ++ subv->blocks_flush_reserved += count; ++ sub_from_subvol_used(subv, count); ++ ++ assert("nikita-2681", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* ++ * disk space, virtually used by fake block numbers is counted as "grabbed" again ++ */ ++static void fake_allocated2grabbed(reiser4_context *ctx, ++ reiser4_super_info_data *sbinfo, __u64 count, ++ reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ add_to_ctx_grabbed(ctx, count, subv->id); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ assert("nikita-2682", subvol_check_block_counters(subv)); ++ ++ subv->blocks_grabbed += count; ++ sub_from_subvol_fake_allocated(subv, count, flags & BA_FORMATTED); ++ ++ assert("nikita-2683", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++void fake_allocated2free(__u64 count, reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ ++ fake_allocated2grabbed(ctx, sbinfo, count, flags, subv); ++ grabbed2free(ctx, sbinfo, count, subv); ++} ++ ++void grabbed2free_mark(__u64 mark, reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ u64 ctx_grabbed; ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ ctx_grabbed = ctx_subvol_grabbed(ctx, subv->id); ++ ++ assert("nikita-3007", (__s64) mark >= 0); ++ assert("nikita-3006", ctx_grabbed >= mark); ++ ++ grabbed2free(ctx, sbinfo, ctx_grabbed - mark, subv); ++} ++ ++void __grabbed2free(struct ctx_brick_info *cbi, reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv) ++{ ++ assert("edward-1977", cbi != NULL); ++ ++ sub_from_cbi_grabbed(cbi, count); ++ ++ spin_lock_reiser4_super(sbinfo); ++ sub_from_subvol_grabbed(subv, count); ++ subv->blocks_free += count; ++ assert("nikita-2684", subvol_check_block_counters(subv)); ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/** ++ * grabbed2free - adjust grabbed and free block counters ++ * @ctx: context to update grabbed block counter of ++ * @sbinfo: super block to update grabbed and free block counters of ++ * @count: number of blocks to adjust counters by ++ * ++ * Decreases context's and per filesystem's counters of grabbed ++ * blocks. Increases per filesystem's counter of free blocks. ++ */ ++void grabbed2free(reiser4_context *ctx, reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv) ++{ ++ if (count != 0) { ++ struct ctx_brick_info *cbi; ++ ++ cbi = find_context_brick_info(ctx, subv->id); ++ ++ assert("edward-1997", cbi != NULL); ++ ++ __grabbed2free(cbi, sbinfo, count, subv); ++ } ++} ++ ++void grabbed2flush_reserved_nolock(txn_atom *atom, ++ __u64 count, reiser4_subvol *subv) ++{ ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ ++ assert("vs-1095", atom); ++ ++ ctx = get_current_context(); ++ ++ sbinfo = get_super_private(ctx->super); ++ ++ sub_from_ctx_grabbed(ctx, count, subv); ++ ++ add_to_atom_flush_reserved(atom, count, subv->id); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ subv->blocks_flush_reserved += count; ++ sub_from_subvol_grabbed(subv, count); ++ ++ assert("vpf-292", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++void grabbed2flush_reserved(__u64 count, reiser4_subvol *subv) ++{ ++ txn_atom *atom = get_current_atom_locked(); ++ ++ grabbed2flush_reserved_nolock(atom, count, subv); ++ ++ spin_unlock_atom(atom); ++} ++ ++void flush_reserved2grabbed(struct atom_brick_info *abi, ++ struct ctx_brick_info *cbi, ++ u64 count, reiser4_subvol *subv) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ assert("edward-1998", abi != NULL); ++ assert("edward-1999", cbi != NULL); ++ assert("edward-2000", abi->brick_id == subv->id); ++ assert("edward-2001", cbi->brick_id == subv->id); ++ ++ sbinfo = get_current_super_private(); ++ ++ add_to_cbi_grabbed(cbi, count); ++ ++ sub_from_abi_flush_reserved(abi, count); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ sub_from_subvol_flush_reserved(subv, count); ++ ++ subv->blocks_grabbed += count; ++ ++ assert("vpf-292", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++u64 all_flush_reserved2grabbed(txn_atom *atom) ++{ ++ struct rb_root *root; ++ struct rb_node *node; ++ u64 flush_reserved = 0; ++ reiser4_context *ctx = get_current_context(); ++ ++ spin_lock_atom(atom); ++ ++ root = &atom->bricks_info; ++ ++ check_atom_flush_reserved(atom); ++ ++ for (node = rb_first(root); node; node = rb_next(node)) { ++ struct atom_brick_info *abi; ++ struct ctx_brick_info *cbi; ++ reiser4_subvol *subv; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ subv = current_origin(abi->brick_id); ++ /* ++ * make sure that respective context brick info exists ++ */ ++ cbi = find_context_brick_info(ctx, abi->brick_id); ++ if (cbi == NULL) { ++#if 0 ++ warning("edward-2002", ++ "Context info for brick %d not found.", ++ abi->brick_id); ++#endif ++ spin_unlock_atom(atom); ++ cbi = alloc_context_brick_info(); ++ if (!cbi) ++ return -ENOMEM; ++ init_context_brick_info(cbi, abi->brick_id); ++ insert_context_brick_info(ctx, cbi); ++ spin_lock_atom(atom); ++ } ++ flush_reserved += abi->atom_flush_reserved; ++ flush_reserved2grabbed(abi, cbi, ++ abi->atom_flush_reserved, subv); ++ } ++ check_atom_flush_reserved(atom); ++ ++ spin_unlock_atom(atom); ++ return flush_reserved; ++} ++ ++/** ++ * all_grabbed2free - releases all blocks grabbed in context ++ * ++ * Decreases context's and super block's grabbed block counters by number of ++ * blocks grabbed by current context and increases super block's free block ++ * counter correspondingly. ++ */ ++void all_grabbed2free(void) ++{ ++ reiser4_context *ctx = get_current_context(); ++ struct rb_root *root = &ctx->bricks_info; ++ struct rb_node *node; ++ ++ if (!get_current_super_private() || !current_lv_conf()) ++ /* volume hasn't been activated */ ++ return; ++ ++ for (node = rb_first(root); node; node = rb_next(node)) { ++ struct ctx_brick_info *cbi; ++ ++ cbi = rb_entry(node, struct ctx_brick_info, node); ++ if (cbi->grabbed_blocks) ++ __grabbed2free(cbi, ++ get_super_private(ctx->super), ++ cbi->grabbed_blocks, ++ current_origin(cbi->brick_id)); ++ } ++} ++ ++/* ++ * adjust sb block counters if real (on-disk) blocks do not become unallocated ++ * after freeing, @count blocks become "grabbed" ++ */ ++static void used2grabbed(reiser4_context *ctx, reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv) ++{ ++ add_to_ctx_grabbed(ctx, count, subv->id); ++ ++ spin_lock_reiser4_super(sbinfo); ++ ++ subv->blocks_grabbed += count; ++ sub_from_subvol_used(subv, count); ++ ++ assert("nikita-2685", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* ++ * this used to be done through used2grabbed and grabbed2free ++ */ ++static void used2free(reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv) ++{ ++ spin_lock_reiser4_super(sbinfo); ++ ++ subv->blocks_free += count; ++ sub_from_subvol_used(subv, count); ++ ++ assert("nikita-2685", subvol_check_block_counters(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++} ++ ++/* ++ * check "allocated" state of given block range ++ */ ++int reiser4_check_blocks(const reiser4_block_nr *start, ++ const reiser4_block_nr *len, int desired, ++ reiser4_subvol *subv) ++{ ++ return sa_check_blocks(start, len, desired, subv); ++} ++ ++/* Blocks deallocation function may do an actual deallocation through space ++ plugin allocation or store deleted block numbers in atom's delete_set data ++ structure depend on @defer parameter. */ ++ ++/* if BA_DEFER bit is not turned on, @target_stage means the stage of blocks ++ which will be deleted from WORKING bitmap. They might be just unmapped from ++ disk, or freed but disk space is still grabbed by current thread, or these ++ blocks must not be counted in any reiser4 sb block counters, ++ see block_stage_t comment */ ++ ++/* BA_FORMATTED bit is only used when BA_DEFER in not present: it is used to ++ distinguish blocks allocated for unformatted and formatted nodes */ ++ ++/** ++ * Deallocate an extent of @len blocks with the beginning at @start ++ * on the block device associated with @subv. ++ */ ++int reiser4_dealloc_blocks(const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ block_stage_t target_stage, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv) ++{ ++ txn_atom *atom = NULL; ++ int ret; ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ void *new_entry = NULL; ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ ++ if (REISER4_DEBUG) { ++ assert("zam-431", *len != 0); ++ assert("zam-432", *start != 0); ++ assert("zam-558", !reiser4_blocknr_is_fake(start)); ++ ++ spin_lock_reiser4_super(sbinfo); ++ assert("zam-562", *start < reiser4_subvol_block_count(subv)); ++ spin_unlock_reiser4_super(sbinfo); ++ } ++ ++ if (flags & BA_DEFER) { ++ /* ++ * These blocks will be later deallocated by apply_dset(). ++ * It is equivalent to a non-deferred deallocation with target ++ * stage BLOCK_NOT_COUNTED. ++ */ ++ ++ /* store deleted block numbers in the atom's deferred delete set ++ for further actual deletion */ ++ do { ++ struct atom_brick_info *abi; ++ ++ atom = get_current_atom_locked(); ++ assert("zam-430", atom != NULL); ++ ++ ret = __check_insert_atom_brick_info(&atom, ++ subv->id, ++ &abi); ++ if (ret) ++ return ret; ++ ret = atom_dset_deferred_add_extent(atom, ++ &new_entry, ++ start, len, ++ subv->id); ++ ++ if (ret == -ENOMEM) ++ return ret; ++ ++ /* This loop might spin at most two times */ ++ } while (ret == -E_REPEAT); ++ ++ assert("zam-477", ret == 0); ++ assert("zam-433", atom != NULL); ++ ++ spin_unlock_atom(atom); ++ ++ } else { ++ assert("zam-425", get_current_super_private() != NULL); ++ sa_dealloc_blocks(reiser4_get_space_allocator(subv), ++ *start, *len, subv); ++ ++ if (flags & BA_PERMANENT) { ++ /* ++ * These blocks were counted as allocated, we have ++ * to revert it back if allocation is discarded. ++ */ ++ txn_atom *atom = get_current_atom_locked(); ++ struct atom_brick_info *abi; ++ ++ abi = find_atom_brick_info(&atom->bricks_info, subv->id); ++ /* ++ * has to be found as we inserted that ++ * item, see reiser4_alloc_blocks(), ++ * case (flags & BA_PERMANENT) ++ */ ++ assert("edward-2003", abi != NULL); ++ assert("edward-2004", abi->nr_blocks_allocated >= *len); ++ ++ abi->nr_blocks_allocated -= *len; ++ spin_unlock_atom(atom); ++ } ++ ++ switch (target_stage) { ++ case BLOCK_NOT_COUNTED: ++ assert("vs-960", flags & BA_FORMATTED); ++ /* VITALY: This is what was grabbed for ++ internal/tx-lists/similar only */ ++ used2free(sbinfo, *len, subv); ++ break; ++ ++ case BLOCK_GRABBED: ++ used2grabbed(ctx, sbinfo, *len, subv); ++ break; ++ ++ case BLOCK_UNALLOCATED: ++ used2fake_allocated(sbinfo, ++ *len, flags & BA_FORMATTED, subv); ++ break; ++ ++ case BLOCK_FLUSH_RESERVED:{ ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked(); ++ used2flush_reserved(sbinfo, atom, *len, ++ flags & BA_FORMATTED, subv); ++ spin_unlock_atom(atom); ++ break; ++ } ++ default: ++ impossible("zam-532", "wrong block stage"); ++ } ++ } ++ ++ return 0; ++} ++ ++/* wrappers for block allocator plugin methods */ ++int reiser4_pre_commit_hook(void) ++{ ++ assert("zam-502", get_current_super_private() != NULL); ++ sa_pre_commit_hook(); ++ return 0; ++} ++ ++/** ++ * an actor which applies a single delete set entry to block allocator ++ * data (actually to working bitmap) ++ */ ++static int apply_dset(txn_atom *atom UNUSED_ARG, const reiser4_block_nr *a, ++ const reiser4_block_nr *b, __u32 subv_id, ++ void *data UNUSED_ARG) ++{ ++ __u64 len = 1; ++ reiser4_subvol *subv; ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_current_super_private(); ++ assert("zam-552", sbinfo != NULL); ++ ++ subv = current_origin(subv_id); ++ ++ assert("zam-877", atom->stage >= ASTAGE_PRE_COMMIT); ++ ++ ++ if (b != NULL) ++ len = *b; ++ ++ if (REISER4_DEBUG) { ++ spin_lock_reiser4_super(sbinfo); ++ ++ assert("zam-554", *a < reiser4_subvol_block_count(subv)); ++ assert("zam-555", *a + len <= reiser4_subvol_block_count(subv)); ++ ++ spin_unlock_reiser4_super(sbinfo); ++ } ++ sa_dealloc_blocks(&subv->space_allocator, *a, len, subv); ++ used2free(sbinfo, len, subv); ++ return 0; ++} ++ ++void reiser4_post_commit_hook(void) ++{ ++#ifdef REISER4_DEBUG ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked(); ++ assert("zam-452", atom->stage == ASTAGE_POST_COMMIT); ++ spin_unlock_atom(atom); ++#endif ++ ++ assert("zam-504", get_current_super_private() != NULL); ++ sa_post_commit_hook(); ++} ++ ++void reiser4_post_write_back_hook(void) ++{ ++ struct list_head discarded_set; ++ txn_atom *atom; ++ int ret; ++ ++ /* process and issue discard requests */ ++ blocknr_list_init (&discarded_set); ++ do { ++ atom = get_current_atom_locked(); ++ ret = discard_atom(atom, &discarded_set); ++ } while (ret == -E_REPEAT); ++ ++ if (ret) { ++ warning("intelfx-8", "discard atom failed (%d)", ret); ++ } ++ ++ atom = get_current_atom_locked(); ++ discard_atom_post(atom, &discarded_set); ++ ++ /* do the block deallocation which was deferred ++ until commit is done */ ++ atom_dset_deferred_apply(atom, apply_dset, NULL, 1); ++ ++ assert("zam-504", get_current_super_private() != NULL); ++ sa_post_write_back_hook(); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/block_alloc.h linux-5.10.2/fs/reiser4/block_alloc.h +--- linux-5.10.2.orig/fs/reiser4/block_alloc.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/block_alloc.h 2020-12-23 16:07:46.113813056 +0100 +@@ -0,0 +1,195 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined(__FS_REISER4_BLOCK_ALLOC_H__) ++#define __FS_REISER4_BLOCK_ALLOC_H__ ++ ++#include "dformat.h" ++#include "forward.h" ++ ++#include /* for __u?? */ ++#include ++ ++/* Mask when is applied to given block number shows is that block number is a ++ fake one */ ++#define REISER4_FAKE_BLOCKNR_BIT_MASK 0x8000000000000000ULL ++/* Mask which isolates a type of object this fake block number was assigned ++ to */ ++#define REISER4_BLOCKNR_STATUS_BIT_MASK 0xC000000000000000ULL ++ ++/*result after applying the REISER4_BLOCKNR_STATUS_BIT_MASK should be compared ++ against these two values to understand is the object unallocated or bitmap ++ shadow object (WORKING BITMAP block, look at the plugin/space/bitmap.c) */ ++#define REISER4_UNALLOCATED_STATUS_VALUE 0xC000000000000000ULL ++#define REISER4_BITMAP_BLOCKS_STATUS_VALUE 0x8000000000000000ULL ++ ++/* specification how block allocation was counted in sb block counters */ ++typedef enum { ++ BLOCK_NOT_COUNTED = 0, /* reiser4 has no info about this block yet */ ++ BLOCK_GRABBED = 1, /* free space grabbed for further allocation ++ of this block */ ++ BLOCK_FLUSH_RESERVED = 2, /* block is reserved for flush needs. */ ++ BLOCK_UNALLOCATED = 3, /* block is used for existing in-memory object ++ ( unallocated formatted or unformatted ++ node) */ ++ BLOCK_ALLOCATED = 4 /* block is mapped to disk, real on-disk block ++ number assigned */ ++} block_stage_t; ++ ++/* a hint for block allocator */ ++struct reiser4_blocknr_hint { ++ /* FIXME: I think we want to add a longterm lock on the bitmap block ++ here. This is to prevent jnode_flush() calls from interleaving ++ allocations on the same bitmap, once a hint is established. */ ++ ++ /* search start hint */ ++ reiser4_block_nr blk; ++ /* if not zero, it is a region size we search for free blocks in */ ++ reiser4_block_nr max_dist; ++ /* level for allocation, may be useful have branch-level and higher ++ write-optimized. */ ++ tree_level level; ++ /* block allocator assumes that blocks, which will be mapped to disk, ++ are in this specified block_stage */ ++ block_stage_t block_stage; ++ /* If direction = 1 allocate blocks in backward direction from the end ++ * of disk to the beginning of disk. */ ++ unsigned int backward:1; ++ ++}; ++ ++/* These flags control block allocation/deallocation behavior */ ++enum reiser4_ba_flags { ++ /* do allocatations from reserved (5%) area */ ++ BA_RESERVED = (1 << 0), ++ ++ /* block allocator can do commit trying to recover free space */ ++ BA_CAN_COMMIT = (1 << 1), ++ ++ /* if operation will be applied to formatted block */ ++ BA_FORMATTED = (1 << 2), ++ ++ /* defer actual block freeing until transaction commit */ ++ BA_DEFER = (1 << 3), ++ ++ /* allocate blocks for permanent fs objects (formatted or unformatted), ++ not wandered of log blocks */ ++ BA_PERMANENT = (1 << 4), ++ ++ /* grab space even it was disabled */ ++ BA_FORCE = (1 << 5), ++ ++ /* use default start value for free blocks search. */ ++ BA_USE_DEFAULT_SEARCH_START = (1 << 6) ++}; ++ ++typedef enum reiser4_ba_flags reiser4_ba_flags_t; ++ ++extern void reiser4_blocknr_hint_init(reiser4_blocknr_hint * hint); ++extern void reiser4_blocknr_hint_done(reiser4_blocknr_hint * hint); ++extern void update_blocknr_hint_default(const struct super_block *, ++ struct reiser4_subvol *, ++ const reiser4_block_nr *); ++extern void get_blocknr_hint_default(reiser4_block_nr *, reiser4_subvol *); ++ ++extern reiser4_block_nr reiser4_fs_reserved_space(struct super_block *super); ++ ++int assign_fake_blocknr_formatted(reiser4_block_nr *, reiser4_subvol *subv); ++reiser4_block_nr fake_blocknr_unformatted(int, reiser4_subvol *subv); ++ ++/* free -> grabbed -> fake_allocated -> used */ ++ ++int reiser4_grab_space(__u64 count, reiser4_ba_flags_t flags, reiser4_subvol *); ++void all_grabbed2free(void); ++void __grabbed2free(struct ctx_brick_info *cbi, reiser4_super_info_data *sbinfo, ++ __u64 count, reiser4_subvol *subv); ++void grabbed2free(reiser4_context *, reiser4_super_info_data *, __u64 count, ++ reiser4_subvol *); ++void fake_allocated2free(__u64 count, ++ reiser4_ba_flags_t flags, reiser4_subvol *); ++void grabbed2flush_reserved_nolock(txn_atom * atom, __u64 count, ++ reiser4_subvol *); ++void grabbed2flush_reserved(__u64 count, reiser4_subvol *subv); ++__u64 ctx_subvol_grabbed(reiser4_context *ctx, __u32 subvol_id); ++int reiser4_alloc_blocks(reiser4_blocknr_hint *hint, ++ reiser4_block_nr *start, reiser4_block_nr *len, ++ reiser4_ba_flags_t flags, reiser4_subvol *subvol); ++int reiser4_dealloc_blocks(const reiser4_block_nr *, ++ const reiser4_block_nr *, ++ block_stage_t, reiser4_ba_flags_t flags, ++ reiser4_subvol *); ++ ++static inline int reiser4_alloc_block(reiser4_blocknr_hint *hint, ++ reiser4_block_nr *start, ++ reiser4_ba_flags_t flags, ++ reiser4_subvol *subvol) ++{ ++ reiser4_block_nr one = 1; ++ return reiser4_alloc_blocks(hint, start, &one, flags, subvol); ++} ++ ++static inline int reiser4_dealloc_block(const reiser4_block_nr * block, ++ block_stage_t stage, ++ reiser4_ba_flags_t flags, ++ reiser4_subvol *subv) ++{ ++ const reiser4_block_nr one = 1; ++ return reiser4_dealloc_blocks(block, &one, stage, flags, subv); ++} ++#define reiser4_grab_space_force(count, flags, subvol) \ ++ reiser4_grab_space(count, flags | BA_FORCE, subvol) ++ ++extern void allocate_blocks_unformatted(reiser4_blocknr_hint *preceder, ++ reiser4_block_nr wanted_count, ++ reiser4_block_nr *first_allocated, ++ reiser4_block_nr *allocated, ++ block_stage_t block_stage, ++ reiser4_subvol *subv); ++extern void grabbed2free_mark(__u64 mark, reiser4_subvol *subv); ++extern int reiser4_grab_reserved(struct super_block *, __u64, ++ reiser4_ba_flags_t, reiser4_subvol *); ++extern void reiser4_release_reserved(struct super_block *super); ++ ++/* grabbed -> fake_allocated */ ++ ++/* fake_allocated -> used */ ++ ++/* used -> fake_allocated -> grabbed -> free */ ++ ++extern void flush_reserved2grabbed(atom_brick_info *abi, ctx_brick_info *cbi, ++ __u64 count, reiser4_subvol *subv); ++extern u64 all_flush_reserved2grabbed(txn_atom *atom); ++extern int reiser4_blocknr_is_fake(const reiser4_block_nr * da); ++ ++extern void grabbed2cluster_reserved(int count, reiser4_subvol *); ++extern void cluster_reserved2grabbed(int count, reiser4_subvol *); ++extern void cluster_reserved2free(int count, reiser4_subvol *); ++ ++extern int subvol_check_block_counters(const reiser4_subvol *); ++extern int volume_check_block_counters(const struct super_block *super); ++ ++extern int reiser4_check_blocks(const reiser4_block_nr *start, ++ const reiser4_block_nr *len, int desired, ++ reiser4_subvol *subv); ++ ++static inline int reiser4_check_block(const reiser4_block_nr *start, ++ int desired, reiser4_subvol *subv) ++{ ++ return reiser4_check_blocks(start, NULL, desired, subv); ++} ++ ++extern int reiser4_pre_commit_hook(void); ++extern void reiser4_post_commit_hook(void); ++extern void reiser4_post_write_back_hook(void); ++ ++ ++#endif /* __FS_REISER4_BLOCK_ALLOC_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/blocknrlist.c linux-5.10.2/fs/reiser4/blocknrlist.c +--- linux-5.10.2.orig/fs/reiser4/blocknrlist.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/blocknrlist.c 2020-12-23 16:07:46.113813056 +0100 +@@ -0,0 +1,349 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* This is a block list implementation, used to create ordered block sets ++ (at the cost of being less memory efficient than blocknr_set). ++ It is used by discard code. */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "txnmgr.h" ++#include "context.h" ++#include "super.h" ++#include "plugin/volume/volume.h" ++ ++#include ++#include ++ ++static struct kmem_cache *blocknr_list_slab = NULL; ++ ++/** ++ * Represents an extent range [@start; @end). ++ */ ++struct blocknr_list_entry { ++ reiser4_block_nr start, len; ++ __u32 subv_id; ++ struct list_head link; ++}; ++ ++#define blocknr_list_entry(ptr) list_entry(ptr, blocknr_list_entry, link) ++ ++static void blocknr_list_entry_init(blocknr_list_entry *entry) ++{ ++ assert("intelfx-11", entry != NULL); ++ ++ entry->start = 0; ++ entry->len = 0; ++ entry->subv_id = INVALID_SUBVOL_ID; ++ INIT_LIST_HEAD(&entry->link); ++} ++ ++static blocknr_list_entry *blocknr_list_entry_alloc(void) ++{ ++ blocknr_list_entry *entry; ++ ++ entry = (blocknr_list_entry *)kmem_cache_alloc(blocknr_list_slab, ++ reiser4_ctx_gfp_mask_get()); ++ if (entry == NULL) { ++ return NULL; ++ } ++ ++ blocknr_list_entry_init(entry); ++ ++ return entry; ++} ++ ++static void blocknr_list_entry_free(blocknr_list_entry *entry) ++{ ++ assert("intelfx-12", entry != NULL); ++ ++ kmem_cache_free(blocknr_list_slab, entry); ++} ++ ++/** ++ * Given ranges @to and [@start; @end), if they overlap, their union ++ * is calculated and saved in @to. ++ */ ++static int blocknr_list_entry_merge(blocknr_list_entry *to, ++ reiser4_block_nr start, ++ reiser4_block_nr len, ++ __u32 subv_id) ++{ ++ reiser4_block_nr end, to_end; ++ ++ assert("intelfx-13", to != NULL); ++ ++ assert("intelfx-16", to->len > 0); ++ assert("intelfx-17", len > 0); ++ assert("edward-1806", subv_id != INVALID_SUBVOL_ID); ++ assert("edward-1807", to->subv_id != INVALID_SUBVOL_ID); ++ ++ end = start + len; ++ to_end = to->start + to->len; ++ ++ if ((to->subv_id == subv_id) && ++ (to->start <= end) && (start <= to_end)) { ++ ++ if (start < to->start) ++ to->start = start; ++ if (end > to_end) ++ to_end = end; ++ to->len = to_end - to->start; ++ return 0; ++ } ++ return -1; ++} ++ ++static int blocknr_list_entry_merge_entry(blocknr_list_entry *to, ++ blocknr_list_entry *from) ++{ ++ assert("intelfx-18", from != NULL); ++ ++ return blocknr_list_entry_merge(to, from->start, from->len, ++ from->subv_id); ++} ++ ++/** ++ * A comparison function for list_sort(). ++ * ++ * "The comparison function @cmp must return a negative value if @a ++ * should sort before @b, and a positive value if @a should sort after ++ * @b. If @a and @b are equivalent, and their original relative ++ * ordering is to be preserved, @cmp must return 0." ++ */ ++static int blocknr_list_entry_compare(void* priv UNUSED_ARG, ++ struct list_head *a, struct list_head *b) ++{ ++ blocknr_list_entry *entry_a, *entry_b; ++ reiser4_block_nr entry_a_end, entry_b_end; ++ ++ assert("intelfx-19", a != NULL); ++ assert("intelfx-20", b != NULL); ++ ++ entry_a = blocknr_list_entry(a); ++ entry_b = blocknr_list_entry(b); ++ ++ assert("edward-1808", entry_a->subv_id != INVALID_SUBVOL_ID); ++ assert("edward-1809", entry_b->subv_id != INVALID_SUBVOL_ID); ++ ++ entry_a_end = entry_a->start + entry_a->len; ++ entry_b_end = entry_b->start + entry_b->len; ++ ++ /* First sort by subvolume ids... */ ++ ++ if (entry_a->subv_id < entry_b->subv_id) ++ return -1; ++ if (entry_a->subv_id > entry_b->subv_id) ++ return 1; ++ ++ /* Then sort by starting block numbers... */ ++ ++ if (entry_a->start < entry_b->start) ++ return -1; ++ if (entry_a->start > entry_b->start) ++ return 1; ++ ++ /** Then by ending block numbers. ++ * If @a contains @b, it will be sorted before. */ ++ if (entry_a_end > entry_b_end) ++ return -1; ++ if (entry_a_end < entry_b_end) ++ return 1; ++ return 0; ++} ++ ++int blocknr_list_init_static(void) ++{ ++ assert("intelfx-54", blocknr_list_slab == NULL); ++ ++ blocknr_list_slab = kmem_cache_create("blocknr_list_entry", ++ sizeof(blocknr_list_entry), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, ++ NULL); ++ if (blocknr_list_slab == NULL) { ++ return RETERR(-ENOMEM); ++ } ++ ++ return 0; ++} ++ ++void blocknr_list_done_static(void) ++{ ++ destroy_reiser4_cache(&blocknr_list_slab); ++} ++ ++void blocknr_list_init(struct list_head* blist) ++{ ++ assert("intelfx-24", blist != NULL); ++ ++ INIT_LIST_HEAD(blist); ++} ++ ++void blocknr_list_destroy(struct list_head* blist) ++{ ++ struct list_head *pos, *tmp; ++ blocknr_list_entry *entry; ++ ++ assert("intelfx-25", blist != NULL); ++ ++ list_for_each_safe(pos, tmp, blist) { ++ entry = blocknr_list_entry(pos); ++ list_del_init(pos); ++ blocknr_list_entry_free(entry); ++ } ++ ++ assert("intelfx-48", list_empty(blist)); ++} ++ ++void blocknr_list_merge(struct list_head *from, struct list_head *to) ++{ ++ assert("intelfx-26", from != NULL); ++ assert("intelfx-27", to != NULL); ++ ++ list_splice_tail_init(from, to); ++ ++ assert("intelfx-49", list_empty(from)); ++} ++ ++void blocknr_list_sort_and_join(struct list_head *blist) ++{ ++ struct list_head *pos, *next; ++ struct blocknr_list_entry *entry, *next_entry; ++ ++ assert("intelfx-50", blist != NULL); ++ ++ /* Step 1. Sort the extent list. */ ++ list_sort(NULL, blist, blocknr_list_entry_compare); ++ ++ /* Step 2. Join adjacent extents in the list. */ ++ pos = blist->next; ++ next = pos->next; ++ entry = blocknr_list_entry(pos); ++ ++ for (; next != blist; next = pos->next) { ++ /** @next is a valid node at this point */ ++ next_entry = blocknr_list_entry(next); ++ ++ /** try to merge @next into @pos */ ++ if (!blocknr_list_entry_merge_entry(entry, next_entry)) { ++ /** successful; delete the @next node. ++ * next merge will be attempted into the same node. */ ++ list_del_init(next); ++ blocknr_list_entry_free(next_entry); ++ } else { ++ /** otherwise advance @pos. */ ++ pos = next; ++ entry = next_entry; ++ } ++ } ++} ++ ++int blocknr_list_add_extent(txn_atom *atom, ++ struct list_head *blist, ++ blocknr_list_entry **new_entry, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ __u32 subv_id) ++{ ++ assert("intelfx-29", atom != NULL); ++ assert("intelfx-42", atom_is_protected(atom)); ++ assert("intelfx-43", blist != NULL); ++ assert("intelfx-30", new_entry != NULL); ++ assert("intelfx-31", start != NULL); ++ assert("intelfx-32", len != NULL && *len > 0); ++ ++ if (*new_entry == NULL) { ++ /* ++ * Optimization: try to merge new extent into the last one. ++ */ ++ if (!list_empty(blist)) { ++ blocknr_list_entry *last_entry; ++ last_entry = blocknr_list_entry(blist->prev); ++ if (!blocknr_list_entry_merge(last_entry, ++ *start, *len, ++ subv_id)) { ++ return 0; ++ } ++ } ++ ++ /* ++ * Otherwise, allocate a new entry and tell -E_REPEAT. ++ * Next time we'll take the branch below. ++ */ ++ spin_unlock_atom(atom); ++ *new_entry = blocknr_list_entry_alloc(); ++ return (*new_entry != NULL) ? -E_REPEAT : RETERR(-ENOMEM); ++ } ++ ++ /* ++ * The entry has been allocated beforehand, fill it and link to the list. ++ */ ++ (*new_entry)->start = *start; ++ (*new_entry)->len = *len; ++ (*new_entry)->subv_id = subv_id; ++ list_add_tail(&(*new_entry)->link, blist); ++ ++ return 0; ++} ++ ++int blocknr_list_iterator(txn_atom *atom, ++ struct list_head *blist, ++ blocknr_set_actor_f actor, ++ void *data, ++ int delete) ++{ ++ struct list_head *pos; ++ blocknr_list_entry *entry; ++ int ret = 0; ++ ++ assert("intelfx-46", blist != NULL); ++ assert("intelfx-47", actor != NULL); ++ ++ if (delete) { ++ struct list_head *tmp; ++ ++ list_for_each_safe(pos, tmp, blist) { ++ entry = blocknr_list_entry(pos); ++ ++ /* ++ * Do not exit, delete flag is set. Instead, on the first error we ++ * downgrade from iterating to just deleting. ++ */ ++ if (ret == 0) { ++ ret = actor(atom, &entry->start, &entry->len, ++ entry->subv_id, data); ++ } ++ ++ list_del_init(pos); ++ blocknr_list_entry_free(entry); ++ } ++ ++ assert("intelfx-44", list_empty(blist)); ++ } else { ++ list_for_each(pos, blist) { ++ entry = blocknr_list_entry(pos); ++ ++ ret = actor(atom, &entry->start, &entry->len, ++ entry->subv_id, data); ++ ++ if (ret != 0) { ++ return ret; ++ } ++ } ++ } ++ ++ return ret; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/blocknrset.c linux-5.10.2/fs/reiser4/blocknrset.c +--- linux-5.10.2.orig/fs/reiser4/blocknrset.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/blocknrset.c 2020-12-23 16:07:46.113813056 +0100 +@@ -0,0 +1,402 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++reiser4/README */ ++ ++/* This file contains code for various block number sets used by the atom to ++ track the deleted set and wandered block mappings. */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "txnmgr.h" ++#include "context.h" ++#include "super.h" ++ ++#include ++ ++/* The proposed data structure for storing unordered block number sets is a ++ list of elements, each of which contains an array of block number or/and ++ array of block number pairs. That element called blocknr_set_entry is used ++ to store block numbers from the beginning and for extents from the end of ++ the data field (char data[...]). The ->nr_blocks and ->nr_pairs fields ++ count numbers of blocks and extents. ++ ++ +------------------- blocknr_set_entry->data ------------------+ ++ |block1|block2| ... ... |pair3|pair2|pair1| ++ +------------------------------------------------------------+ ++ ++ When current blocknr_set_entry is full, allocate a new one. */ ++ ++/* Usage examples: blocknr sets are used in reiser4 for storing atom's delete ++ * set (single blocks and block extents), in that case blocknr pair represent an ++ * extent; atom's wandered map is also stored as a blocknr set, blocknr pairs ++ * there represent a (real block) -> (wandered block) mapping. */ ++ ++/* Protection: blocknr sets belong to reiser4 atom, and ++ * their modifications are performed with the atom lock held */ ++ ++/* The total size of a blocknr_set_entry. */ ++#define BLOCKNR_SET_ENTRY_SIZE 128 ++ ++/* The number of blocks that can fit the blocknr data area. */ ++#define BLOCKNR_SET_ENTRIES_NUMBER \ ++ ((BLOCKNR_SET_ENTRY_SIZE - \ ++ 2 * sizeof(unsigned) - \ ++ sizeof(struct list_head)) / \ ++ sizeof(reiser4_block_nr)) ++ ++static struct kmem_cache *blocknr_set_slab = NULL; ++ ++/* An entry of the blocknr_set */ ++struct blocknr_set_entry { ++ unsigned nr_singles; ++ unsigned nr_pairs; ++ struct list_head link; ++ reiser4_block_nr entries[BLOCKNR_SET_ENTRIES_NUMBER]; ++}; ++ ++static_assert(sizeof(blocknr_set_entry) == BLOCKNR_SET_ENTRY_SIZE); ++ ++/* A pair of blocks as recorded in the blocknr_set_entry data. */ ++struct blocknr_pair { ++ reiser4_block_nr a; ++ reiser4_block_nr b; ++}; ++ ++/* Return the number of blocknr slots available in a blocknr_set_entry. */ ++/* Audited by: green(2002.06.11) */ ++static unsigned bse_avail(blocknr_set_entry * bse) ++{ ++ unsigned used = bse->nr_singles + 2 * bse->nr_pairs; ++ ++ assert("jmacd-5088", BLOCKNR_SET_ENTRIES_NUMBER >= used); ++ ++ return BLOCKNR_SET_ENTRIES_NUMBER - used; ++} ++ ++/* Initialize a blocknr_set_entry. */ ++static void bse_init(blocknr_set_entry *bse) ++{ ++ bse->nr_singles = 0; ++ bse->nr_pairs = 0; ++ INIT_LIST_HEAD(&bse->link); ++} ++ ++/* Allocate and initialize a blocknr_set_entry. */ ++/* Audited by: green(2002.06.11) */ ++static blocknr_set_entry *bse_alloc(void) ++{ ++ blocknr_set_entry *e; ++ ++ if ((e = (blocknr_set_entry *) kmem_cache_alloc(blocknr_set_slab, ++ reiser4_ctx_gfp_mask_get())) == NULL) ++ return NULL; ++ ++ bse_init(e); ++ ++ return e; ++} ++ ++/* Free a blocknr_set_entry. */ ++/* Audited by: green(2002.06.11) */ ++static void bse_free(blocknr_set_entry * bse) ++{ ++ kmem_cache_free(blocknr_set_slab, bse); ++} ++ ++/* Add a block number to a blocknr_set_entry */ ++/* Audited by: green(2002.06.11) */ ++static void ++bse_put_single(blocknr_set_entry * bse, const reiser4_block_nr * block) ++{ ++ assert("jmacd-5099", bse_avail(bse) >= 1); ++ ++ bse->entries[bse->nr_singles++] = *block; ++} ++ ++/* Get a pair of block numbers */ ++/* Audited by: green(2002.06.11) */ ++static inline struct blocknr_pair *bse_get_pair(blocknr_set_entry * bse, ++ unsigned pno) ++{ ++ assert("green-1", BLOCKNR_SET_ENTRIES_NUMBER >= 2 * (pno + 1)); ++ ++ return (struct blocknr_pair *) (bse->entries + ++ BLOCKNR_SET_ENTRIES_NUMBER - ++ 2 * (pno + 1)); ++} ++ ++/* Add a pair of block numbers to a blocknr_set_entry */ ++/* Audited by: green(2002.06.11) */ ++static void ++bse_put_pair(blocknr_set_entry * bse, const reiser4_block_nr * a, ++ const reiser4_block_nr * b) ++{ ++ struct blocknr_pair *pair; ++ ++ assert("jmacd-5100", bse_avail(bse) >= 2 && a != NULL && b != NULL); ++ ++ pair = bse_get_pair(bse, bse->nr_pairs++); ++ ++ pair->a = *a; ++ pair->b = *b; ++} ++ ++/* Add either a block or pair of blocks to the block number set. The first ++ blocknr (@a) must be non-NULL. If @b is NULL a single blocknr is added, if ++ @b is non-NULL a pair is added. The block number set belongs to atom, and ++ the call is made with the atom lock held. There may not be enough space in ++ the current blocknr_set_entry. If new_bsep points to a non-NULL ++ blocknr_set_entry then it will be added to the blocknr_set and new_bsep ++ will be set to NULL. If new_bsep contains NULL then the atom lock will be ++ released and a new bse will be allocated in new_bsep. E_REPEAT will be ++ returned with the atom unlocked for the operation to be tried again. If ++ the operation succeeds, 0 is returned. If new_bsep is non-NULL and not ++ used during the call, it will be freed automatically. */ ++static int blocknr_set_add(txn_atom *atom, struct list_head *bset, ++ blocknr_set_entry **new_bsep, const reiser4_block_nr *a, ++ const reiser4_block_nr *b, __u32 subvol_id) ++{ ++ blocknr_set_entry *bse; ++ unsigned entries_needed; ++ ++ assert("jmacd-5101", a != NULL); ++ ++ entries_needed = (b == NULL) ? 1 : 2; ++ if (list_empty(bset) || ++ bse_avail(list_entry(bset->next, blocknr_set_entry, link)) < entries_needed) { ++ /* See if a bse was previously allocated. */ ++ if (*new_bsep == NULL) { ++ spin_unlock_atom(atom); ++ *new_bsep = bse_alloc(); ++ return (*new_bsep != NULL) ? -E_REPEAT : ++ RETERR(-ENOMEM); ++ } ++ ++ /* Put it on the head of the list. */ ++ list_add(&((*new_bsep)->link), bset); ++ ++ *new_bsep = NULL; ++ } ++ ++ /* Add the single or pair. */ ++ bse = list_entry(bset->next, blocknr_set_entry, link); ++ if (b == NULL) { ++ bse_put_single(bse, a); ++ } else { ++ bse_put_pair(bse, a, b); ++ } ++ ++ /* If new_bsep is non-NULL then there was an allocation race, free this ++ copy. */ ++ if (*new_bsep != NULL) { ++ bse_free(*new_bsep); ++ *new_bsep = NULL; ++ } ++ ++ return 0; ++} ++ ++/* Add an extent to the block set. If the length is 1, it is treated as a ++ single block (e.g., reiser4_set_add_block). */ ++/* Audited by: green(2002.06.11) */ ++/* Auditor note: Entire call chain cannot hold any spinlocks, because ++ kmalloc might schedule. The only exception is atom spinlock, which is ++ properly freed. ++*/ ++int blocknr_set_add_extent(txn_atom * atom, ++ struct list_head *bset, ++ blocknr_set_entry **new_bsep, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ const __u32 subvol_id) ++{ ++ assert("jmacd-5102", start != NULL && len != NULL && *len > 0); ++ return blocknr_set_add(atom, bset, new_bsep, start, ++ *len == 1 ? NULL : len, subvol_id); ++} ++ ++/* Add a block pair to the block set. It adds exactly a pair, which is checked ++ * by an assertion that both arguments are not null.*/ ++/* Audited by: green(2002.06.11) */ ++/* Auditor note: Entire call chain cannot hold any spinlocks, because ++ kmalloc might schedule. The only exception is atom spinlock, which is ++ properly freed ++*/ ++int blocknr_set_add_pair(txn_atom * atom, ++ struct list_head *bset, blocknr_set_entry **new_bsep, ++ const reiser4_block_nr *a, const reiser4_block_nr *b, ++ __u32 subvol_id) ++{ ++ assert("jmacd-5103", a != NULL && b != NULL); ++ return blocknr_set_add(atom, bset, new_bsep, a, b, subvol_id); ++} ++ ++/* Initialize slab cache of blocknr_set_entry objects. */ ++int blocknr_set_init_static(void) ++{ ++ assert("intelfx-55", blocknr_set_slab == NULL); ++ ++ blocknr_set_slab = kmem_cache_create("blocknr_set_entry", ++ sizeof(blocknr_set_entry), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, ++ NULL); ++ ++ if (blocknr_set_slab == NULL) { ++ return RETERR(-ENOMEM); ++ } ++ ++ return 0; ++} ++ ++/* Destroy slab cache of blocknr_set_entry objects. */ ++void blocknr_set_done_static(void) ++{ ++ destroy_reiser4_cache(&blocknr_set_slab); ++} ++ ++/* Initialize a blocknr_set. */ ++void blocknr_set_init(struct list_head *bset) ++{ ++ INIT_LIST_HEAD(bset); ++} ++ ++/* Release the entries of a blocknr_set. */ ++void blocknr_set_destroy(struct list_head *bset) ++{ ++ blocknr_set_entry *bse; ++ ++ while (!list_empty(bset)) { ++ bse = list_entry(bset->next, blocknr_set_entry, link); ++ list_del_init(&bse->link); ++ bse_free(bse); ++ } ++} ++ ++/* Merge blocknr_set entries out of @from into @into. */ ++/* Audited by: green(2002.06.11) */ ++/* Auditor comments: This merge does not know if merged sets contain ++ blocks pairs (As for wandered sets) or extents, so it cannot really merge ++ overlapping ranges if there is some. So I believe it may lead to ++ some blocks being presented several times in one blocknr_set. To help ++ debugging such problems it might help to check for duplicate entries on ++ actual processing of this set. Testing this kind of stuff right here is ++ also complicated by the fact that these sets are not sorted and going ++ through whole set on each element addition is going to be CPU-heavy task */ ++void blocknr_set_merge(struct list_head *from, struct list_head *into) ++{ ++ blocknr_set_entry *bse_into = NULL; ++ ++ /* If @from is empty, no work to perform. */ ++ if (list_empty(from)) ++ return; ++ /* If @into is not empty, try merging partial-entries. */ ++ if (!list_empty(into)) { ++ ++ /* Neither set is empty, pop the front to members and try to ++ combine them. */ ++ blocknr_set_entry *bse_from; ++ unsigned into_avail; ++ ++ bse_into = list_entry(into->next, blocknr_set_entry, link); ++ list_del_init(&bse_into->link); ++ bse_from = list_entry(from->next, blocknr_set_entry, link); ++ list_del_init(&bse_from->link); ++ ++ /* Combine singles. */ ++ for (into_avail = bse_avail(bse_into); ++ into_avail != 0 && bse_from->nr_singles != 0; ++ into_avail -= 1) { ++ bse_put_single(bse_into, ++ &bse_from->entries[--bse_from-> ++ nr_singles]); ++ } ++ ++ /* Combine pairs. */ ++ for (; into_avail > 1 && bse_from->nr_pairs != 0; ++ into_avail -= 2) { ++ struct blocknr_pair *pair = ++ bse_get_pair(bse_from, --bse_from->nr_pairs); ++ bse_put_pair(bse_into, &pair->a, &pair->b); ++ } ++ ++ /* If bse_from is empty, delete it now. */ ++ if (bse_avail(bse_from) == BLOCKNR_SET_ENTRIES_NUMBER) { ++ bse_free(bse_from); ++ } else { ++ /* Otherwise, bse_into is full or nearly full (e.g., ++ it could have one slot avail and bse_from has one ++ pair left). Push it back onto the list. bse_from ++ becomes bse_into, which will be the new partial. */ ++ list_add(&bse_into->link, into); ++ bse_into = bse_from; ++ } ++ } ++ ++ /* Splice lists together. */ ++ list_splice_init(from, into->prev); ++ ++ /* Add the partial entry back to the head of the list. */ ++ if (bse_into != NULL) ++ list_add(&bse_into->link, into); ++} ++ ++/* Iterate over all blocknr set elements. */ ++int blocknr_set_iterator(txn_atom *atom, struct list_head *bset, ++ blocknr_set_actor_f actor, void *data, int delete, ++ u32 subv_id) ++{ ++ ++ blocknr_set_entry *entry; ++ ++ assert("zam-429", atom != NULL); ++ assert("zam-430", atom_is_protected(atom)); ++ assert("zam-431", bset != 0); ++ assert("zam-432", actor != NULL); ++ ++ entry = list_entry(bset->next, blocknr_set_entry, link); ++ while (bset != &entry->link) { ++ blocknr_set_entry *tmp = list_entry(entry->link.next, blocknr_set_entry, link); ++ unsigned int i; ++ int ret; ++ ++ for (i = 0; i < entry->nr_singles; i++) { ++ ret = actor(atom, &entry->entries[i], NULL, 0, data); ++ ++ /* We can't break a loop if delete flag is set. */ ++ if (ret != 0 && !delete) ++ return ret; ++ } ++ ++ for (i = 0; i < entry->nr_pairs; i++) { ++ struct blocknr_pair *ab; ++ ++ ab = bse_get_pair(entry, i); ++ ++ ret = actor(atom, &ab->a, &ab->b, subv_id, data); ++ ++ if (ret != 0 && !delete) ++ return ret; ++ } ++ ++ if (delete) { ++ list_del(&entry->link); ++ bse_free(entry); ++ } ++ ++ entry = tmp; ++ } ++ ++ return 0; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/carry.c linux-5.10.2/fs/reiser4/carry.c +--- linux-5.10.2.orig/fs/reiser4/carry.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/carry.c 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,1408 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++/* Functions to "carry" tree modification(s) upward. */ ++/* Tree is modified one level at a time. As we modify a level we accumulate a ++ set of changes that need to be propagated to the next level. We manage ++ node locking such that any searches that collide with carrying are ++ restarted, from the root if necessary. ++ ++ Insertion of a new item may result in items being moved among nodes and ++ this requires the delimiting key to be updated at the least common parent ++ of the nodes modified to preserve search tree invariants. Also, insertion ++ may require allocation of a new node. A pointer to the new node has to be ++ inserted into some node on the parent level, etc. ++ ++ Tree carrying is meant to be analogous to arithmetic carrying. ++ ++ A carry operation is always associated with some node (&carry_node). ++ ++ Carry process starts with some initial set of operations to be performed ++ and an initial set of already locked nodes. Operations are performed one ++ by one. Performing each single operation has following possible effects: ++ ++ - content of carry node associated with operation is modified ++ - new carry nodes are locked and involved into carry process on this level ++ - new carry operations are posted to the next level ++ ++ After all carry operations on this level are done, process is repeated for ++ the accumulated sequence on carry operations for the next level. This ++ starts by trying to lock (in left to right order) all carry nodes ++ associated with carry operations on the parent level. After this, we decide ++ whether more nodes are required on the left of already locked set. If so, ++ all locks taken on the parent level are released, new carry nodes are ++ added, and locking process repeats. ++ ++ It may happen that balancing process fails owing to unrecoverable error on ++ some of upper levels of a tree (possible causes are io error, failure to ++ allocate new node, etc.). In this case we should unmount the filesystem, ++ rebooting if it is the root, and possibly advise the use of fsck. ++ ++ USAGE: ++ ++ int some_tree_operation( znode *node, ... ) ++ { ++ // Allocate on a stack pool of carry objects: operations and nodes. ++ // Most carry processes will only take objects from here, without ++ // dynamic allocation. ++ ++I feel uneasy about this pool. It adds to code complexity, I understand why it ++exists, but.... -Hans ++ ++ carry_pool pool; ++ carry_level lowest_level; ++ carry_op *op; ++ ++ init_carry_pool( &pool ); ++ init_carry_level( &lowest_level, &pool ); ++ ++ // operation may be one of: ++ // COP_INSERT --- insert new item into node ++ // COP_CUT --- remove part of or whole node ++ // COP_PASTE --- increase size of item ++ // COP_DELETE --- delete pointer from parent node ++ // COP_UPDATE --- update delimiting key in least ++ // common ancestor of two ++ ++ op = reiser4_post_carry( &lowest_level, operation, node, 0 ); ++ if( IS_ERR( op ) || ( op == NULL ) ) { ++ handle error ++ } else { ++ // fill in remaining fields in @op, according to carry.h:carry_op ++ result = carry(&lowest_level, NULL); ++ } ++ done_carry_pool(&pool); ++ } ++ ++ When you are implementing node plugin method that participates in carry ++ (shifting, insertion, deletion, etc.), do the following: ++ ++ int foo_node_method(znode * node, ..., carry_level * todo) ++ { ++ carry_op *op; ++ ++ .... ++ ++ // note, that last argument to reiser4_post_carry() is non-null ++ // here, because @op is to be applied to the parent of @node, rather ++ // than to the @node itself as in the previous case. ++ ++ op = node_post_carry(todo, operation, node, 1); ++ // fill in remaining fields in @op, according to carry.h:carry_op ++ ++ .... ++ ++ } ++ ++ BATCHING: ++ ++ One of the main advantages of level-by-level balancing implemented here is ++ ability to batch updates on a parent level and to peform them more ++ efficiently as a result. ++ ++ Description To Be Done (TBD). ++ ++ DIFFICULTIES AND SUBTLE POINTS: ++ ++ 1. complex plumbing is required, because: ++ ++ a. effective allocation through pools is needed ++ ++ b. target of operation is not exactly known when operation is ++ posted. This is worked around through bitfields in &carry_node and ++ logic in lock_carry_node() ++ ++ c. of interaction with locking code: node should be added into sibling ++ list when pointer to it is inserted into its parent, which is some time ++ after node was created. Between these moments, node is somewhat in ++ suspended state and is only registered in the carry lists ++ ++ 2. whole balancing logic is implemented here, in particular, insertion ++ logic is coded in make_space(). ++ ++ 3. special cases like insertion (reiser4_add_tree_root()) or deletion ++ (reiser4_kill_tree_root()) of tree root and morphing of paste into insert ++ (insert_paste()) have to be handled. ++ ++ 4. there is non-trivial interdependency between allocation of new nodes ++ and almost everything else. This is mainly due to the (1.c) above. I shall ++ write about this later. ++ ++*/ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/item/extent.h" ++#include "plugin/node/node.h" ++#include "jnode.h" ++#include "znode.h" ++#include "tree_mod.h" ++#include "tree_walk.h" ++#include "block_alloc.h" ++#include "pool.h" ++#include "tree.h" ++#include "carry.h" ++#include "carry_ops.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include ++ ++/* level locking/unlocking */ ++static int lock_carry_level(carry_level * level); ++static void unlock_carry_level(carry_level * level, int failure); ++static void done_carry_level(carry_level * level); ++static void unlock_carry_node(carry_level * level, carry_node * node, int fail); ++ ++int lock_carry_node(carry_level * level, carry_node * node); ++int lock_carry_node_tail(carry_node * node); ++ ++/* carry processing proper */ ++static int carry_on_level(carry_level * doing, carry_level * todo); ++ ++static carry_op *add_op(carry_level * level, pool_ordering order, ++ carry_op * reference); ++ ++/* handlers for carry operations. */ ++ ++static void fatal_carry_error(carry_level * doing, int ecode); ++static int add_new_root(carry_level * level, carry_node * node, znode * fake); ++ ++static void print_level(const char *prefix, carry_level * level); ++ ++#if REISER4_DEBUG ++typedef enum { ++ CARRY_TODO, ++ CARRY_DOING ++} carry_queue_state; ++static int carry_level_invariant(carry_level * level, carry_queue_state state); ++#endif ++ ++/* main entry point for tree balancing. ++ ++ Tree carry performs operations from @doing and while doing so accumulates ++ information about operations to be performed on the next level ("carried" ++ to the parent level). Carried operations are performed, causing possibly ++ more operations to be carried upward etc. carry() takes care about ++ locking and pinning znodes while operating on them. ++ ++ For usage, see comment at the top of fs/reiser4/carry.c ++ ++*/ ++int reiser4_carry(carry_level * doing /* set of carry operations to be ++ * performed */ , ++ carry_level * done /* set of nodes, already performed ++ * at the previous level. ++ * NULL in most cases */) ++{ ++ int result = 0; ++ gfp_t old_mask; ++ /* queue of new requests */ ++ carry_level *todo; ++ ON_DEBUG(STORE_COUNTERS); ++ ++ assert("nikita-888", doing != NULL); ++ BUG_ON(done != NULL); ++ ++ todo = doing + 1; ++ init_carry_level(todo, doing->pool); ++ ++ /* queue of requests preformed on the previous level */ ++ done = todo + 1; ++ init_carry_level(done, doing->pool); ++ /* ++ * NOTE: We are not allowed to fail in the loop below. ++ * Incomplete carry (even if carry_on_level is complete) ++ * can leave the tree in an inconsistent state (broken ++ * order of keys in a node, etc). ++ */ ++ old_mask = get_current_context()->gfp_mask; ++ get_current_context()->gfp_mask |= __GFP_NOFAIL; ++ ++ /* iterate until there is nothing more to do */ ++ while (result == 0 && doing->ops_num > 0) { ++ carry_level *tmp; ++ ++ /* at this point @done is locked. */ ++ /* repeat lock/do/unlock while ++ ++ (1) lock_carry_level() fails due to deadlock avoidance, or ++ ++ (2) carry_on_level() decides that more nodes have to ++ be involved. ++ ++ (3) some unexpected error occurred while balancing on the ++ upper levels. In this case all changes are rolled back. ++ ++ */ ++ while (1) { ++ result = lock_carry_level(doing); ++ if (result == 0) { ++ /* perform operations from @doing and ++ accumulate new requests in @todo */ ++ result = carry_on_level(doing, todo); ++ if (result == 0) ++ break; ++ else if (result != -E_REPEAT || ++ !doing->restartable) { ++ warning("nikita-1043", ++ "Fatal error during carry: %i", ++ result); ++ print_level("done", done); ++ print_level("doing", doing); ++ print_level("todo", todo); ++ /* do some rough stuff like aborting ++ all pending transcrashes and thus ++ pushing tree back to the consistent ++ state. Alternatvely, just panic. ++ */ ++ fatal_carry_error(doing, result); ++ return result; ++ } ++ } else if (result != -E_REPEAT) { ++ fatal_carry_error(doing, result); ++ return result; ++ } ++ unlock_carry_level(doing, 1); ++ } ++ /* at this point @done can be safely unlocked */ ++ done_carry_level(done); ++ ++ /* cyclically shift queues */ ++ tmp = done; ++ done = doing; ++ doing = todo; ++ todo = tmp; ++ init_carry_level(todo, doing->pool); ++ ++ /* give other threads chance to run */ ++ reiser4_preempt_point(); ++ } ++ get_current_context()->gfp_mask = old_mask; ++ done_carry_level(done); ++ ++ /* all counters, but x_refs should remain the same. x_refs can change ++ owing to transaction manager */ ++ ON_DEBUG(CHECK_COUNTERS); ++ return result; ++} ++ ++/* perform carry operations on given level. ++ ++ Optimizations proposed by pooh: ++ ++ (1) don't lock all nodes from queue at the same time. Lock nodes lazily as ++ required; ++ ++ (2) unlock node if there are no more operations to be performed upon it and ++ node didn't add any operation to @todo. This can be implemented by ++ attaching to each node two counters: counter of operaions working on this ++ node and counter and operations carried upward from this node. ++ ++*/ ++static int carry_on_level(carry_level * doing /* queue of carry operations to ++ * do on this level */ , ++ carry_level * todo /* queue where new carry ++ * operations to be performed on ++ * the * parent level are ++ * accumulated during @doing ++ * processing. */ ) ++{ ++ int result; ++ int (*f) (carry_op *, carry_level *, carry_level *); ++ carry_op *op; ++ carry_op *tmp_op; ++ ++ assert("nikita-1034", doing != NULL); ++ assert("nikita-1035", todo != NULL); ++ ++ /* @doing->nodes are locked. */ ++ ++ /* This function can be split into two phases: analysis and modification ++ ++ Analysis calculates precisely what items should be moved between ++ nodes. This information is gathered in some structures attached to ++ each carry_node in a @doing queue. Analysis also determines whether ++ new nodes are to be allocated etc. ++ ++ After analysis is completed, actual modification is performed. Here ++ we can take advantage of "batch modification": if there are several ++ operations acting on the same node, modifications can be performed ++ more efficiently when batched together. ++ ++ Above is an optimization left for the future. ++ */ ++ /* Important, but delayed optimization: it's possible to batch ++ operations together and perform them more efficiently as a ++ result. For example, deletion of several neighboring items from a ++ node can be converted to a single ->cut() operation. ++ ++ Before processing queue, it should be scanned and "mergeable" ++ operations merged. ++ */ ++ result = 0; ++ for_all_ops(doing, op, tmp_op) { ++ carry_opcode opcode; ++ ++ assert("nikita-1041", op != NULL); ++ opcode = op->op; ++ assert("nikita-1042", op->op < COP_LAST_OP); ++ f = op_dispatch_table[op->op].cop_handler; ++ result = f(op, doing, todo); ++ /* locking can fail with -E_REPEAT. Any different error is fatal ++ and will be handled by fatal_carry_error() sledgehammer. ++ */ ++ if (result != 0) ++ break; ++ } ++ if (result == 0) { ++ carry_plugin_info info; ++ carry_node *scan; ++ carry_node *tmp_scan; ++ ++ info.doing = doing; ++ info.todo = todo; ++ ++ assert("nikita-3002", ++ carry_level_invariant(doing, CARRY_DOING)); ++ for_all_nodes(doing, scan, tmp_scan) { ++ znode *node; ++ ++ node = reiser4_carry_real(scan); ++ assert("nikita-2547", node != NULL); ++ if (node_is_empty(node)) { ++ result = ++ node_plugin_by_node(node)-> ++ prepare_removal(node, &info); ++ if (result != 0) ++ break; ++ } ++ } ++ } ++ return result; ++} ++ ++/* post carry operation ++ ++ This is main function used by external carry clients: node layout plugins ++ and tree operations to create new carry operation to be performed on some ++ level. ++ ++ New operation will be included in the @level queue. To actually perform it, ++ call carry( level, ... ). This function takes write lock on @node. Carry ++ manages all its locks by itself, don't worry about this. ++ ++ This function adds operation and node at the end of the queue. It is up to ++ caller to guarantee proper ordering of node queue. ++ ++*/ ++carry_op * reiser4_post_carry(carry_level * level /* queue where new operation ++ * is to be posted at */ , ++ carry_opcode op /* opcode of operation */ , ++ znode * node /* node on which this operation ++ * will operate */ , ++ int apply_to_parent_p /* whether operation will ++ * operate directly on @node ++ * or on it parent. */) ++{ ++ carry_op *result; ++ carry_node *child; ++ ++ assert("nikita-1046", level != NULL); ++ assert("nikita-1788", znode_is_write_locked(node)); ++ ++ result = add_op(level, POOLO_LAST, NULL); ++ if (IS_ERR(result)) ++ return result; ++ child = reiser4_add_carry(level, POOLO_LAST, NULL); ++ if (IS_ERR(child)) { ++ reiser4_pool_free(&level->pool->op_pool, &result->header); ++ return (carry_op *) child; ++ } ++ result->node = child; ++ result->op = op; ++ child->parent = apply_to_parent_p; ++ if (ZF_ISSET(node, JNODE_ORPHAN)) ++ child->left_before = 1; ++ child->node = node; ++ return result; ++} ++ ++/* initialize carry queue */ ++void init_carry_level(carry_level * level /* level to initialize */ , ++ carry_pool * pool /* pool @level will allocate objects ++ * from */ ) ++{ ++ assert("nikita-1045", level != NULL); ++ assert("nikita-967", pool != NULL); ++ ++ memset(level, 0, sizeof *level); ++ level->pool = pool; ++ ++ INIT_LIST_HEAD(&level->nodes); ++ INIT_LIST_HEAD(&level->ops); ++} ++ ++/* allocate carry pool and initialize pools within queue */ ++carry_pool *init_carry_pool(int size) ++{ ++ carry_pool *pool; ++ ++ assert("", size >= sizeof(carry_pool) + 3 * sizeof(carry_level)); ++ pool = kmalloc(size, reiser4_ctx_gfp_mask_get()); ++ if (pool == NULL) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ ++ reiser4_init_pool(&pool->op_pool, sizeof(carry_op), CARRIES_POOL_SIZE, ++ (char *)pool->op); ++ reiser4_init_pool(&pool->node_pool, sizeof(carry_node), ++ NODES_LOCKED_POOL_SIZE, (char *)pool->node); ++ return pool; ++} ++ ++/* finish with queue pools */ ++void done_carry_pool(carry_pool * pool/* pool to destroy */) ++{ ++ reiser4_done_pool(&pool->op_pool); ++ reiser4_done_pool(&pool->node_pool); ++ kfree(pool); ++} ++ ++/* add new carry node to the @level. ++ ++ Returns pointer to the new carry node allocated from pool. It's up to ++ callers to maintain proper order in the @level. Assumption is that if carry ++ nodes on one level are already sorted and modifications are peroformed from ++ left to right, carry nodes added on the parent level will be ordered ++ automatically. To control ordering use @order and @reference parameters. ++ ++*/ ++carry_node *reiser4_add_carry_skip(carry_level * level /* &carry_level to add ++ * node to */ , ++ pool_ordering order /* where to insert: ++ * at the beginning of ++ * @level, ++ * before @reference, ++ * after @reference, ++ * at the end of @level ++ */ , ++ carry_node * reference/* reference node for ++ * insertion */) ++{ ++ ON_DEBUG(carry_node * orig_ref = reference); ++ ++ if (order == POOLO_BEFORE) { ++ reference = find_left_carry(reference, level); ++ if (reference == NULL) ++ reference = list_entry(level->nodes.next, carry_node, ++ header.level_linkage); ++ else ++ reference = list_entry(reference->header.level_linkage.next, ++ carry_node, header.level_linkage); ++ } else if (order == POOLO_AFTER) { ++ reference = find_right_carry(reference, level); ++ if (reference == NULL) ++ reference = list_entry(level->nodes.prev, carry_node, ++ header.level_linkage); ++ else ++ reference = list_entry(reference->header.level_linkage.prev, ++ carry_node, header.level_linkage); ++ } ++ assert("nikita-2209", ++ ergo(orig_ref != NULL, ++ reiser4_carry_real(reference) == ++ reiser4_carry_real(orig_ref))); ++ return reiser4_add_carry(level, order, reference); ++} ++ ++carry_node *reiser4_add_carry(carry_level * level, /* carry_level to add ++ node to */ ++ pool_ordering order, /* where to insert: ++ * at the beginning of ++ * @level; ++ * before @reference; ++ * after @reference; ++ * at the end of @level ++ */ ++ carry_node * reference /* reference node for ++ * insertion */) ++{ ++ carry_node *result; ++ ++ result = ++ (carry_node *) reiser4_add_obj(&level->pool->node_pool, ++ &level->nodes, ++ order, &reference->header); ++ if (!IS_ERR(result) && (result != NULL)) ++ ++level->nodes_num; ++ return result; ++} ++ ++/** ++ * add new carry operation to the @level. ++ * ++ * Returns pointer to the new carry operations allocated from pool. It's up to ++ * callers to maintain proper order in the @level. To control ordering use ++ * @order and @reference parameters. ++ */ ++static carry_op *add_op(carry_level * level, /* &carry_level to add node to */ ++ pool_ordering order, /* where to insert: ++ * at the beginning of @level; ++ * before @reference; ++ * after @reference; ++ * at the end of @level */ ++ carry_op * reference /* reference node for insertion */) ++{ ++ carry_op *result; ++ ++ result = ++ (carry_op *) reiser4_add_obj(&level->pool->op_pool, &level->ops, ++ order, &reference->header); ++ if (!IS_ERR(result) && (result != NULL)) ++ ++level->ops_num; ++ return result; ++} ++ ++/** ++ * Return node on the right of which @node was created. ++ * ++ * Each node is created on the right of some existing node (or it is new root, ++ * which is special case not handled here). ++ * ++ * @node is new node created on some level, but not yet inserted into its ++ * parent, it has corresponding bit (JNODE_ORPHAN) set in zstate. ++ */ ++static carry_node *find_begetting_brother(carry_node * node,/* node to start ++ search from */ ++ carry_level * kin UNUSED_ARG ++ /* level to scan */) ++{ ++ carry_node *scan; ++ ++ assert("nikita-1614", node != NULL); ++ assert("nikita-1615", kin != NULL); ++ assert("nikita-1616", LOCK_CNT_GTZ(rw_locked_tree)); ++ assert("nikita-1619", ergo(reiser4_carry_real(node) != NULL, ++ ZF_ISSET(reiser4_carry_real(node), ++ JNODE_ORPHAN))); ++ for (scan = node;; ++ scan = list_entry(scan->header.level_linkage.prev, carry_node, ++ header.level_linkage)) { ++ assert("nikita-1617", &kin->nodes != &scan->header.level_linkage); ++ if ((scan->node != node->node) && ++ !ZF_ISSET(scan->node, JNODE_ORPHAN)) { ++ assert("nikita-1618", reiser4_carry_real(scan) != NULL); ++ break; ++ } ++ } ++ return scan; ++} ++ ++static cmp_t ++carry_node_cmp(carry_level * level, carry_node * n1, carry_node * n2) ++{ ++ assert("nikita-2199", n1 != NULL); ++ assert("nikita-2200", n2 != NULL); ++ ++ if (n1 == n2) ++ return EQUAL_TO; ++ while (1) { ++ n1 = carry_node_next(n1); ++ if (carry_node_end(level, n1)) ++ return GREATER_THAN; ++ if (n1 == n2) ++ return LESS_THAN; ++ } ++ impossible("nikita-2201", "End of level reached"); ++} ++ ++carry_node *find_carry_node(carry_level * level, const znode * node) ++{ ++ carry_node *scan; ++ carry_node *tmp_scan; ++ ++ assert("nikita-2202", level != NULL); ++ assert("nikita-2203", node != NULL); ++ ++ for_all_nodes(level, scan, tmp_scan) { ++ if (reiser4_carry_real(scan) == node) ++ return scan; ++ } ++ return NULL; ++} ++ ++znode *reiser4_carry_real(const carry_node * node) ++{ ++ assert("nikita-3061", node != NULL); ++ ++ return node->lock_handle.node; ++} ++ ++carry_node *insert_carry_node(carry_level * doing, carry_level * todo, ++ const znode * node) ++{ ++ carry_node *base; ++ carry_node *scan; ++ carry_node *tmp_scan; ++ carry_node *proj; ++ ++ base = find_carry_node(doing, node); ++ assert("nikita-2204", base != NULL); ++ ++ for_all_nodes(todo, scan, tmp_scan) { ++ proj = find_carry_node(doing, scan->node); ++ assert("nikita-2205", proj != NULL); ++ if (carry_node_cmp(doing, proj, base) != LESS_THAN) ++ break; ++ } ++ return scan; ++} ++ ++static carry_node *add_carry_atplace(carry_level * doing, carry_level * todo, ++ znode * node) ++{ ++ carry_node *reference; ++ ++ assert("nikita-2994", doing != NULL); ++ assert("nikita-2995", todo != NULL); ++ assert("nikita-2996", node != NULL); ++ ++ reference = insert_carry_node(doing, todo, node); ++ assert("nikita-2997", reference != NULL); ++ ++ return reiser4_add_carry(todo, POOLO_BEFORE, reference); ++} ++ ++/* like reiser4_post_carry(), but designed to be called from node plugin ++ methods. This function is different from reiser4_post_carry() in that it ++ finds proper place to insert node in the queue. */ ++carry_op *node_post_carry(carry_plugin_info * info /* carry parameters ++ * passed down to node ++ * plugin */ , ++ carry_opcode op /* opcode of operation */ , ++ znode * node /* node on which this ++ * operation will operate */ , ++ int apply_to_parent_p /* whether operation will ++ * operate directly on @node ++ * or on it parent. */ ) ++{ ++ carry_op *result; ++ carry_node *child; ++ ++ assert("nikita-2207", info != NULL); ++ assert("nikita-2208", info->todo != NULL); ++ ++ if (info->doing == NULL) ++ return reiser4_post_carry(info->todo, op, node, ++ apply_to_parent_p); ++ ++ result = add_op(info->todo, POOLO_LAST, NULL); ++ if (IS_ERR(result)) ++ return result; ++ child = add_carry_atplace(info->doing, info->todo, node); ++ if (IS_ERR(child)) { ++ reiser4_pool_free(&info->todo->pool->op_pool, &result->header); ++ return (carry_op *) child; ++ } ++ result->node = child; ++ result->op = op; ++ child->parent = apply_to_parent_p; ++ if (ZF_ISSET(node, JNODE_ORPHAN)) ++ child->left_before = 1; ++ child->node = node; ++ return result; ++} ++ ++/* lock all carry nodes in @level */ ++static int lock_carry_level(carry_level * level/* level to lock */) ++{ ++ int result; ++ carry_node *node; ++ carry_node *tmp_node; ++ ++ assert("nikita-881", level != NULL); ++ assert("nikita-2229", carry_level_invariant(level, CARRY_TODO)); ++ ++ /* lock nodes from left to right */ ++ result = 0; ++ for_all_nodes(level, node, tmp_node) { ++ result = lock_carry_node(level, node); ++ if (result != 0) ++ break; ++ } ++ return result; ++} ++ ++/* Synchronize delimiting keys between @node and its left neighbor. ++ ++ To reduce contention on dk key and simplify carry code, we synchronize ++ delimiting keys only when carry ultimately leaves tree level (carrying ++ changes upward) and unlocks nodes at this level. ++ ++ This function first finds left neighbor of @node and then updates left ++ neighbor's right delimiting key to conincide with least key in @node. ++ ++*/ ++ ++ON_DEBUG(extern atomic_t delim_key_version; ++ ) ++ ++static void sync_dkeys(znode * spot/* node to update */) ++{ ++ reiser4_key pivot; ++ reiser4_tree *tree; ++ ++ assert("nikita-1610", spot != NULL); ++ assert("nikita-1612", LOCK_CNT_NIL(rw_locked_dk)); ++ ++ tree = znode_get_tree(spot); ++ read_lock_tree(); ++ write_lock_dk(tree); ++ ++ assert("nikita-2192", znode_is_loaded(spot)); ++ ++ /* sync left delimiting key of @spot with key in its leftmost item */ ++ if (node_is_empty(spot)) ++ pivot = *znode_get_rd_key(spot); ++ else ++ leftmost_key_in_node(spot, &pivot); ++ ++ znode_set_ld_key(spot, &pivot); ++ ++ /* there can be sequence of empty nodes pending removal on the left of ++ @spot. Scan them and update their left and right delimiting keys to ++ match left delimiting key of @spot. Also, update right delimiting ++ key of first non-empty left neighbor. ++ */ ++ while (1) { ++ if (!ZF_ISSET(spot, JNODE_LEFT_CONNECTED)) ++ break; ++ ++ spot = spot->left; ++ if (spot == NULL) ++ break; ++ ++ znode_set_rd_key(spot, &pivot); ++ /* don't sink into the domain of another balancing */ ++ if (!znode_is_write_locked(spot)) ++ break; ++ if (ZF_ISSET(spot, JNODE_HEARD_BANSHEE)) ++ znode_set_ld_key(spot, &pivot); ++ else ++ break; ++ } ++ ++ write_unlock_dk(tree); ++ read_unlock_tree(); ++} ++ ++/* unlock all carry nodes in @level */ ++static void unlock_carry_level(carry_level * level /* level to unlock */ , ++ int failure /* true if unlocking owing to ++ * failure */ ) ++{ ++ carry_node *node; ++ carry_node *tmp_node; ++ ++ assert("nikita-889", level != NULL); ++ ++ if (!failure) { ++ znode *spot; ++ ++ spot = NULL; ++ /* update delimiting keys */ ++ for_all_nodes(level, node, tmp_node) { ++ if (reiser4_carry_real(node) != spot) { ++ spot = reiser4_carry_real(node); ++ sync_dkeys(spot); ++ } ++ } ++ } ++ ++ /* nodes can be unlocked in arbitrary order. In preemptible ++ environment it's better to unlock in reverse order of locking, ++ though. ++ */ ++ for_all_nodes_back(level, node, tmp_node) { ++ /* all allocated nodes should be already linked to their ++ parents at this moment. */ ++ assert("nikita-1631", ++ ergo(!failure, !ZF_ISSET(reiser4_carry_real(node), ++ JNODE_ORPHAN))); ++ ON_DEBUG(check_dkeys(reiser4_carry_real(node))); ++ unlock_carry_node(level, node, failure); ++ } ++ level->new_root = NULL; ++} ++ ++/* finish with @level ++ ++ Unlock nodes and release all allocated resources */ ++static void done_carry_level(carry_level * level/* level to finish */) ++{ ++ carry_node *node; ++ carry_node *tmp_node; ++ carry_op *op; ++ carry_op *tmp_op; ++ ++ assert("nikita-1076", level != NULL); ++ ++ unlock_carry_level(level, 0); ++ for_all_nodes(level, node, tmp_node) { ++ assert("nikita-2113", list_empty_careful(&node->lock_handle.locks_link)); ++ assert("nikita-2114", list_empty_careful(&node->lock_handle.owners_link)); ++ reiser4_pool_free(&level->pool->node_pool, &node->header); ++ } ++ for_all_ops(level, op, tmp_op) ++ reiser4_pool_free(&level->pool->op_pool, &op->header); ++} ++ ++/* helper function to complete locking of carry node ++ ++ Finish locking of carry node. There are several ways in which new carry ++ node can be added into carry level and locked. Normal is through ++ lock_carry_node(), but also from find_{left|right}_neighbor(). This ++ function factors out common final part of all locking scenarios. It ++ supposes that @node -> lock_handle is lock handle for lock just taken and ++ fills ->real_node from this lock handle. ++ ++*/ ++int lock_carry_node_tail(carry_node * node/* node to complete locking of */) ++{ ++ assert("nikita-1052", node != NULL); ++ assert("nikita-1187", reiser4_carry_real(node) != NULL); ++ assert("nikita-1188", !node->unlock); ++ ++ node->unlock = 1; ++ /* Load node content into memory and install node plugin by ++ looking at the node header. ++ ++ Most of the time this call is cheap because the node is ++ already in memory. ++ ++ Corresponding zrelse() is in unlock_carry_node() ++ */ ++ return zload(reiser4_carry_real(node)); ++} ++ ++/* lock carry node ++ ++ "Resolve" node to real znode, lock it and mark as locked. ++ This requires recursive locking of znodes. ++ ++ When operation is posted to the parent level, node it will be applied to is ++ not yet known. For example, when shifting data between two nodes, ++ delimiting has to be updated in parent or parents of nodes involved. But ++ their parents is not yet locked and, moreover said nodes can be reparented ++ by concurrent balancing. ++ ++ To work around this, carry operation is applied to special "carry node" ++ rather than to the znode itself. Carry node consists of some "base" or ++ "reference" znode and flags indicating how to get to the target of carry ++ operation (->real_node field of carry_node) from base. ++ ++*/ ++int lock_carry_node(carry_level * level /* level @node is in */ , ++ carry_node * node/* node to lock */) ++{ ++ int result; ++ znode *reference_point; ++ lock_handle lh; ++ lock_handle tmp_lh; ++ reiser4_tree *tree; ++ ++ assert("nikita-887", level != NULL); ++ assert("nikita-882", node != NULL); ++ ++ result = 0; ++ reference_point = node->node; ++ init_lh(&lh); ++ init_lh(&tmp_lh); ++ if (node->left_before) { ++ /* handling of new nodes, allocated on the previous level: ++ ++ some carry ops were propably posted from the new node, but ++ this node neither has parent pointer set, nor is ++ connected. This will be done in ->create_hook() for ++ internal item. ++ ++ No then less, parent of new node has to be locked. To do ++ this, first go to the "left" in the carry order. This ++ depends on the decision to always allocate new node on the ++ right of existing one. ++ ++ Loop handles case when multiple nodes, all orphans, were ++ inserted. ++ ++ Strictly speaking, taking tree lock is not necessary here, ++ because all nodes scanned by loop in ++ find_begetting_brother() are write-locked by this thread, ++ and thus, their sibling linkage cannot change. ++ ++ */ ++ tree = znode_get_tree(reference_point); ++ read_lock_tree(); ++ reference_point = find_begetting_brother(node, level)->node; ++ read_unlock_tree(); ++ assert("nikita-1186", reference_point != NULL); ++ } ++ if (node->parent && (result == 0)) { ++ result = ++ reiser4_get_parent(&tmp_lh, reference_point, ++ ZNODE_WRITE_LOCK); ++ if (result != 0) { ++ ; /* nothing */ ++ } else if (znode_get_level(tmp_lh.node) == 0) { ++ assert("nikita-1347", znode_above_root(tmp_lh.node)); ++ result = add_new_root(level, node, tmp_lh.node); ++ if (result == 0) { ++ reference_point = level->new_root; ++ move_lh(&lh, &node->lock_handle); ++ } ++ } else if ((level->new_root != NULL) ++ && (level->new_root != ++ znode_parent_nolock(reference_point))) { ++ /* parent of node exists, but this level aready ++ created different new root, so */ ++ warning("nikita-1109", ++ /* it should be "radicis", but tradition is ++ tradition. do banshees read latin? */ ++ "hodie natus est radici frater"); ++ result = -EIO; ++ } else { ++ move_lh(&lh, &tmp_lh); ++ reference_point = lh.node; ++ } ++ } ++ if (node->left && (result == 0)) { ++ assert("nikita-1183", node->parent); ++ assert("nikita-883", reference_point != NULL); ++ result = ++ reiser4_get_left_neighbor(&tmp_lh, reference_point, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result == 0) { ++ done_lh(&lh); ++ move_lh(&lh, &tmp_lh); ++ reference_point = lh.node; ++ } ++ } ++ if (!node->parent && !node->left && !node->left_before) { ++ result = ++ longterm_lock_znode(&lh, reference_point, ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_HIPRI); ++ } ++ if (result == 0) { ++ move_lh(&node->lock_handle, &lh); ++ result = lock_carry_node_tail(node); ++ } ++ done_lh(&tmp_lh); ++ done_lh(&lh); ++ return result; ++} ++ ++/* release a lock on &carry_node. ++ ++ Release if necessary lock on @node. This opearion is pair of ++ lock_carry_node() and is idempotent: you can call it more than once on the ++ same node. ++ ++*/ ++static void ++unlock_carry_node(carry_level * level, ++ carry_node * node /* node to be released */ , ++ int failure /* 0 if node is unlocked due ++ * to some error */ ) ++{ ++ znode *real_node; ++ ++ assert("nikita-884", node != NULL); ++ ++ real_node = reiser4_carry_real(node); ++ /* pair to zload() in lock_carry_node_tail() */ ++ zrelse(real_node); ++ if (node->unlock && (real_node != NULL)) { ++ assert("nikita-899", real_node == node->lock_handle.node); ++ longterm_unlock_znode(&node->lock_handle); ++ } ++ if (failure) { ++ if (node->deallocate && (real_node != NULL)) { ++ /* free node in bitmap ++ ++ Prepare node for removal. Last zput() will finish ++ with it. ++ */ ++ ZF_SET(real_node, JNODE_HEARD_BANSHEE); ++ } ++ if (node->free) { ++ assert("nikita-2177", ++ list_empty_careful(&node->lock_handle.locks_link)); ++ assert("nikita-2112", ++ list_empty_careful(&node->lock_handle.owners_link)); ++ reiser4_pool_free(&level->pool->node_pool, ++ &node->header); ++ } ++ } ++} ++ ++/* fatal_carry_error() - all-catching error handling function ++ ++ It is possible that carry faces unrecoverable error, like unability to ++ insert pointer at the internal level. Our simple solution is just panic in ++ this situation. More sophisticated things like attempt to remount ++ file-system as read-only can be implemented without much difficlties. ++ ++ It is believed, that: ++ ++ 1. in stead of panicking, all current transactions can be aborted rolling ++ system back to the consistent state. ++ ++Umm, if you simply panic without doing anything more at all, then all current ++transactions are aborted and the system is rolled back to a consistent state, ++by virtue of the design of the transactional mechanism. Well, wait, let's be ++precise. If an internal node is corrupted on disk due to hardware failure, ++then there may be no consistent state that can be rolled back to, so instead ++we should say that it will rollback the transactions, which barring other ++factors means rolling back to a consistent state. ++ ++# Nikita: there is a subtle difference between panic and aborting ++# transactions: machine doesn't reboot. Processes aren't killed. Processes ++# don't using reiser4 (not that we care about such processes), or using other ++# reiser4 mounts (about them we do care) will simply continue to run. With ++# some luck, even application using aborted file system can survive: it will ++# get some error, like EBADF, from each file descriptor on failed file system, ++# but applications that do care about tolerance will cope with this (squid ++# will). ++ ++It would be a nice feature though to support rollback without rebooting ++followed by remount, but this can wait for later versions. ++ ++ 2. once isolated transactions will be implemented it will be possible to ++ roll back offending transaction. ++ ++2. is additional code complexity of inconsistent value (it implies that a ++broken tree should be kept in operation), so we must think about it more ++before deciding if it should be done. -Hans ++ ++*/ ++static void fatal_carry_error(carry_level * doing UNUSED_ARG /* carry level ++ * where ++ * unrecoverable ++ * error ++ * occurred */ , ++ int ecode/* error code */) ++{ ++ assert("nikita-1230", doing != NULL); ++ assert("nikita-1231", ecode < 0); ++ ++ reiser4_panic("nikita-1232", "Carry failed: %i", ecode); ++} ++ ++/** ++ * Add new root to the tree ++ * ++ * This function itself only manages changes in carry structures and delegates ++ * all hard work (allocation of znode for new root, changes of parent and ++ * sibling pointers) to the reiser4_add_tree_root(). ++ * ++ * Locking: old tree root is locked by carry at this point. Fake znode is also ++ * locked. ++ */ ++static int add_new_root(carry_level * level,/* carry level in context of which ++ * operation is performed */ ++ carry_node * node, /* carry node for existing root */ ++ znode * fake /* "fake" znode already locked by ++ * us */) ++{ ++ int result; ++ ++ assert("nikita-1104", level != NULL); ++ assert("nikita-1105", node != NULL); ++ ++ assert("nikita-1403", znode_is_write_locked(node->node)); ++ assert("nikita-1404", znode_is_write_locked(fake)); ++ ++ /* trying to create new root. */ ++ /* @node is root and it's already locked by us. This ++ means that nobody else can be trying to add/remove ++ tree root right now. ++ */ ++ if (level->new_root == NULL) ++ level->new_root = reiser4_add_tree_root(node->node, fake); ++ if (!IS_ERR(level->new_root)) { ++ assert("nikita-1210", znode_is_root(level->new_root)); ++ node->deallocate = 1; ++ result = ++ longterm_lock_znode(&node->lock_handle, level->new_root, ++ ZNODE_WRITE_LOCK, ZNODE_LOCK_LOPRI); ++ if (result == 0) ++ zput(level->new_root); ++ } else { ++ result = PTR_ERR(level->new_root); ++ level->new_root = NULL; ++ } ++ return result; ++} ++ ++/* allocate new znode and add the operation that inserts the ++ pointer to it into the parent node into the todo level ++ ++ Allocate new znode, add it into carry queue and post into @todo queue ++ request to add pointer to new node into its parent. ++ ++ This is carry related routing that calls reiser4_new_node() to allocate new ++ node. ++*/ ++carry_node *add_new_znode(znode * brother /* existing left neighbor of new ++ * node */ , ++ carry_node * ref /* carry node after which new ++ * carry node is to be inserted ++ * into queue. This affects ++ * locking. */ , ++ carry_level * doing /* carry queue where new node is ++ * to be added */ , ++ carry_level * todo /* carry queue where COP_INSERT ++ * operation to add pointer to ++ * new node will ne added */ ) ++{ ++ carry_node *fresh; ++ znode *new_znode; ++ carry_op *add_pointer; ++ carry_plugin_info info; ++ ++ assert("nikita-1048", brother != NULL); ++ assert("nikita-1049", todo != NULL); ++ ++ /* There is a lot of possible variations here: to what parent ++ new node will be attached and where. For simplicity, always ++ do the following: ++ ++ (1) new node and @brother will have the same parent. ++ ++ (2) new node is added on the right of @brother ++ ++ */ ++ ++ fresh = reiser4_add_carry_skip(doing, ++ ref ? POOLO_AFTER : POOLO_LAST, ref); ++ if (IS_ERR(fresh)) ++ return fresh; ++ ++ fresh->deallocate = 1; ++ fresh->free = 1; ++ ++ new_znode = reiser4_new_node(brother, znode_get_level(brother)); ++ if (IS_ERR(new_znode)) ++ /* @fresh will be deallocated automatically by error ++ handling code in the caller. */ ++ return (carry_node *) new_znode; ++ ++ /* new_znode returned znode with x_count 1. Caller has to decrease ++ it. make_space() does. */ ++ ++ ZF_SET(new_znode, JNODE_ORPHAN); ++ fresh->node = new_znode; ++ ++ while (ZF_ISSET(reiser4_carry_real(ref), JNODE_ORPHAN)) { ++ ref = carry_node_prev(ref); ++ assert("nikita-1606", !carry_node_end(doing, ref)); ++ } ++ ++ info.todo = todo; ++ info.doing = doing; ++ add_pointer = node_post_carry(&info, COP_INSERT, ++ reiser4_carry_real(ref), 1); ++ if (IS_ERR(add_pointer)) { ++ /* no need to deallocate @new_znode here: it will be ++ deallocated during carry error handling. */ ++ return (carry_node *) add_pointer; ++ } ++ ++ add_pointer->u.insert.type = COPT_CHILD; ++ add_pointer->u.insert.child = fresh; ++ add_pointer->u.insert.brother = brother; ++ /* initially new node spawns empty key range */ ++ write_lock_dk(znode_get_tree(brother)); ++ znode_set_ld_key(new_znode, ++ znode_set_rd_key(new_znode, ++ znode_get_rd_key(brother))); ++ write_unlock_dk(znode_get_tree(brother)); ++ return fresh; ++} ++ ++/* DEBUGGING FUNCTIONS. ++ ++ Probably we also should leave them on even when ++ debugging is turned off to print dumps at errors. ++*/ ++#if REISER4_DEBUG ++static int carry_level_invariant(carry_level * level, carry_queue_state state) ++{ ++ carry_node *node; ++ carry_node *tmp_node; ++ ++ if (level == NULL) ++ return 0; ++ ++ if (level->track_type != 0 && ++ level->track_type != CARRY_TRACK_NODE && ++ level->track_type != CARRY_TRACK_CHANGE) ++ return 0; ++ ++ /* check that nodes are in ascending order */ ++ for_all_nodes(level, node, tmp_node) { ++ znode *left; ++ znode *right; ++ ++ reiser4_key lkey; ++ reiser4_key rkey; ++ ++ if (node != carry_node_front(level)) { ++ if (state == CARRY_TODO) { ++ right = node->node; ++ left = carry_node_prev(node)->node; ++ } else { ++ right = reiser4_carry_real(node); ++ left = reiser4_carry_real(carry_node_prev(node)); ++ } ++ if (right == NULL || left == NULL) ++ continue; ++ if (node_is_empty(right) || node_is_empty(left)) ++ continue; ++ if (!keyle(leftmost_key_in_node(left, &lkey), ++ leftmost_key_in_node(right, &rkey))) { ++ warning("", "wrong key order"); ++ return 0; ++ } ++ } ++ } ++ return 1; ++} ++#endif ++ ++/* get symbolic name for boolean */ ++static const char *tf(int boolean/* truth value */) ++{ ++ return boolean ? "t" : "f"; ++} ++ ++/* symbolic name for carry operation */ ++static const char *carry_op_name(carry_opcode op/* carry opcode */) ++{ ++ switch (op) { ++ case COP_INSERT: ++ return "COP_INSERT"; ++ case COP_DELETE: ++ return "COP_DELETE"; ++ case COP_CUT: ++ return "COP_CUT"; ++ case COP_PASTE: ++ return "COP_PASTE"; ++ case COP_UPDATE: ++ return "COP_UPDATE"; ++ case COP_EXTENT: ++ return "COP_EXTENT"; ++ case COP_INSERT_FLOW: ++ return "COP_INSERT_FLOW"; ++ default:{ ++ /* not mt safe, but who cares? */ ++ static char buf[20]; ++ ++ sprintf(buf, "unknown op: %x", op); ++ return buf; ++ } ++ } ++} ++ ++/* dump information about carry node */ ++static void print_carry(const char *prefix /* prefix to print */ , ++ carry_node * node/* node to print */) ++{ ++ if (node == NULL) { ++ printk("%s: null\n", prefix); ++ return; ++ } ++ printk ++ ("%s: %p parent: %s, left: %s, unlock: %s, free: %s, dealloc: %s\n", ++ prefix, node, tf(node->parent), tf(node->left), tf(node->unlock), ++ tf(node->free), tf(node->deallocate)); ++} ++ ++/* dump information about carry operation */ ++static void print_op(const char *prefix /* prefix to print */ , ++ carry_op * op/* operation to print */) ++{ ++ if (op == NULL) { ++ printk("%s: null\n", prefix); ++ return; ++ } ++ printk("%s: %p carry_opcode: %s\n", prefix, op, carry_op_name(op->op)); ++ print_carry("\tnode", op->node); ++ switch (op->op) { ++ case COP_INSERT: ++ case COP_PASTE: ++ print_coord("\tcoord", ++ op->u.insert.d ? op->u.insert.d->coord : NULL, 0); ++ reiser4_print_key("\tkey", ++ op->u.insert.d ? op->u.insert.d->key : NULL); ++ print_carry("\tchild", op->u.insert.child); ++ break; ++ case COP_DELETE: ++ print_carry("\tchild", op->u.delete.child); ++ break; ++ case COP_CUT: ++ if (op->u.cut_or_kill.is_cut) { ++ print_coord("\tfrom", ++ op->u.cut_or_kill.u.kill->params.from, 0); ++ print_coord("\tto", op->u.cut_or_kill.u.kill->params.to, ++ 0); ++ } else { ++ print_coord("\tfrom", ++ op->u.cut_or_kill.u.cut->params.from, 0); ++ print_coord("\tto", op->u.cut_or_kill.u.cut->params.to, ++ 0); ++ } ++ break; ++ case COP_UPDATE: ++ print_carry("\tleft", op->u.update.left); ++ break; ++ default: ++ /* do nothing */ ++ break; ++ } ++} ++ ++/* dump information about all nodes and operations in a @level */ ++static void print_level(const char *prefix /* prefix to print */ , ++ carry_level * level/* level to print */) ++{ ++ carry_node *node; ++ carry_node *tmp_node; ++ carry_op *op; ++ carry_op *tmp_op; ++ ++ if (level == NULL) { ++ printk("%s: null\n", prefix); ++ return; ++ } ++ printk("%s: %p, restartable: %s\n", ++ prefix, level, tf(level->restartable)); ++ ++ for_all_nodes(level, node, tmp_node) ++ print_carry("\tcarry node", node); ++ for_all_ops(level, op, tmp_op) ++ print_op("\tcarry op", op); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/carry.h linux-5.10.2/fs/reiser4/carry.h +--- linux-5.10.2.orig/fs/reiser4/carry.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/carry.h 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,445 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Functions and data types to "carry" tree modification(s) upward. ++ See fs/reiser4/carry.c for details. */ ++ ++#if !defined(__FS_REISER4_CARRY_H__) ++#define __FS_REISER4_CARRY_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "pool.h" ++#include "znode.h" ++ ++#include ++ ++/* &carry_node - "location" of carry node. ++ ++ "location" of node that is involved or going to be involved into ++ carry process. Node where operation will be carried to on the ++ parent level cannot be recorded explicitly. Operation will be carried ++ usually to the parent of some node (where changes are performed at ++ the current level) or, to the left neighbor of its parent. But while ++ modifications are performed at the current level, parent may ++ change. So, we have to allow some indirection (or, positevly, ++ flexibility) in locating carry nodes. ++ ++*/ ++typedef struct carry_node { ++ /* pool linkage */ ++ struct reiser4_pool_header header; ++ ++ /* base node from which real_node is calculated. See ++ fs/reiser4/carry.c:lock_carry_node(). */ ++ znode *node; ++ ++ /* how to get ->real_node */ ++ /* to get ->real_node obtain parent of ->node */ ++ __u32 parent:1; ++ /* to get ->real_node obtain left neighbor of parent of ++ ->node */ ++ __u32 left:1; ++ __u32 left_before:1; ++ ++ /* locking */ ++ ++ /* this node was locked by carry process and should be ++ unlocked when carry leaves a level */ ++ __u32 unlock:1; ++ ++ /* disk block for this node was allocated by carry process and ++ should be deallocated when carry leaves a level */ ++ __u32 deallocate:1; ++ /* this carry node was allocated by carry process and should be ++ freed when carry leaves a level */ ++ __u32 free:1; ++ ++ /* type of lock we want to take on this node */ ++ lock_handle lock_handle; ++} carry_node; ++ ++/* &carry_opcode - elementary operations that can be carried upward ++ ++ Operations that carry() can handle. This list is supposed to be ++ expanded. ++ ++ Each carry operation (cop) is handled by appropriate function defined ++ in fs/reiser4/carry.c. For example COP_INSERT is handled by ++ fs/reiser4/carry.c:carry_insert() etc. These functions in turn ++ call plugins of nodes affected by operation to modify nodes' content ++ and to gather operations to be performed on the next level. ++ ++*/ ++typedef enum { ++ /* insert new item into node. */ ++ COP_INSERT, ++ /* delete pointer from parent node */ ++ COP_DELETE, ++ /* remove part of or whole node. */ ++ COP_CUT, ++ /* increase size of item. */ ++ COP_PASTE, ++ /* insert extent (that is sequence of unformatted nodes). */ ++ COP_EXTENT, ++ /* update delimiting key in least common ancestor of two ++ nodes. This is performed when items are moved between two ++ nodes. ++ */ ++ COP_UPDATE, ++ /* insert flow */ ++ COP_INSERT_FLOW, ++ COP_LAST_OP, ++} carry_opcode; ++ ++#define CARRY_FLOW_NEW_NODES_LIMIT 20 ++ ++/* mode (or subtype) of COP_{INSERT|PASTE} operation. Specifies how target ++ item is determined. */ ++typedef enum { ++ /* target item is one containing pointer to the ->child node */ ++ COPT_CHILD, ++ /* target item is given explicitly by @coord */ ++ COPT_ITEM_DATA, ++ /* target item is given by key */ ++ COPT_KEY, ++ /* see insert_paste_common() for more comments on this. */ ++ COPT_PASTE_RESTARTED, ++} cop_insert_pos_type; ++ ++/* flags to cut and delete */ ++typedef enum { ++ /* don't kill node even if it became completely empty as results of ++ * cut. This is needed for eottl handling. See carry_extent() for ++ * details. */ ++ DELETE_RETAIN_EMPTY = (1 << 0) ++} cop_delete_flag; ++ ++/* ++ * carry() implements "lock handle tracking" feature. ++ * ++ * Callers supply carry with node where to perform initial operation and lock ++ * handle on this node. Trying to optimize node utilization carry may actually ++ * move insertion point to different node. Callers expect that lock handle ++ * will rebe transferred to the new node also. ++ * ++ */ ++typedef enum { ++ /* transfer lock handle along with insertion point */ ++ CARRY_TRACK_CHANGE = 1, ++ /* acquire new lock handle to the node where insertion point is. This ++ * is used when carry() client doesn't initially possess lock handle ++ * on the insertion point node, for example, by extent insertion ++ * code. See carry_extent(). */ ++ CARRY_TRACK_NODE = 2 ++} carry_track_type; ++ ++/* data supplied to COP_{INSERT|PASTE} by callers */ ++typedef struct carry_insert_data { ++ /* position where new item is to be inserted */ ++ coord_t *coord; ++ /* new item description */ ++ reiser4_item_data * data; ++ /* key of new item */ ++ const reiser4_key * key; ++} carry_insert_data; ++ ++/* cut and kill are similar, so carry_cut_data and carry_kill_data share the ++ below structure of parameters */ ++struct cut_kill_params { ++ /* coord where cut starts (inclusive) */ ++ coord_t *from; ++ /* coord where cut stops (inclusive, this item/unit will also be ++ * cut) */ ++ coord_t *to; ++ /* starting key. This is necessary when item and unit pos don't ++ * uniquely identify what portion or tree to remove. For example, this ++ * indicates what portion of extent unit will be affected. */ ++ const reiser4_key * from_key; ++ /* exclusive stop key */ ++ const reiser4_key * to_key; ++ /* if this is not NULL, smallest actually removed key is stored ++ * here. */ ++ reiser4_key *smallest_removed; ++ /* kill_node_content() is called for file truncate */ ++ int truncate; ++}; ++ ++struct carry_cut_data { ++ struct cut_kill_params params; ++}; ++ ++struct carry_kill_data { ++ struct cut_kill_params params; ++ /* parameter to be passed to the ->kill_hook() method of item ++ * plugin */ ++ /*void *iplug_params; *//* FIXME: unused currently */ ++ /* if not NULL---inode whose items are being removed. This is needed ++ * for ->kill_hook() of extent item to update VM structures when ++ * removing pages. */ ++ struct inode *inode; ++ /* sibling list maintenance is complicated by existence of eottl. When ++ * eottl whose left and right neighbors are formatted leaves is ++ * removed, one has to connect said leaves in the sibling list. This ++ * cannot be done when extent removal is just started as locking rules ++ * require sibling list update to happen atomically with removal of ++ * extent item. Therefore: 1. pointers to left and right neighbors ++ * have to be passed down to the ->kill_hook() of extent item, and ++ * 2. said neighbors have to be locked. */ ++ lock_handle *left; ++ lock_handle *right; ++ /* flags modifying behavior of kill. Currently, it may have ++ DELETE_RETAIN_EMPTY set. */ ++ unsigned flags; ++ char *buf; ++}; ++ ++/* &carry_tree_op - operation to "carry" upward. ++ ++ Description of an operation we want to "carry" to the upper level of ++ a tree: e.g, when we insert something and there is not enough space ++ we allocate a new node and "carry" the operation of inserting a ++ pointer to the new node to the upper level, on removal of empty node, ++ we carry up operation of removing appropriate entry from parent. ++ ++ There are two types of carry ops: when adding or deleting node we ++ node at the parent level where appropriate modification has to be ++ performed is known in advance. When shifting items between nodes ++ (split, merge), delimiting key should be changed in the least common ++ parent of the nodes involved that is not known in advance. ++ ++ For the operations of the first type we store in &carry_op pointer to ++ the &carry_node at the parent level. For the operation of the second ++ type we store &carry_node or parents of the left and right nodes ++ modified and keep track of them upward until they coincide. ++ ++*/ ++typedef struct carry_op { ++ /* pool linkage */ ++ struct reiser4_pool_header header; ++ carry_opcode op; ++ /* node on which operation is to be performed: ++ ++ for insert, paste: node where new item is to be inserted ++ ++ for delete: node where pointer is to be deleted ++ ++ for cut: node to cut from ++ ++ for update: node where delimiting key is to be modified ++ ++ for modify: parent of modified node ++ ++ */ ++ carry_node *node; ++ union { ++ struct { ++ /* (sub-)type of insertion/paste. Taken from ++ cop_insert_pos_type. */ ++ __u8 type; ++ /* various operation flags. Taken from ++ cop_insert_flag. */ ++ __u8 flags; ++ carry_insert_data *d; ++ carry_node *child; ++ znode *brother; ++ } insert, paste, extent; ++ ++ struct { ++ int is_cut; ++ union { ++ carry_kill_data *kill; ++ carry_cut_data *cut; ++ } u; ++ } cut_or_kill; ++ ++ struct { ++ carry_node *left; ++ } update; ++ struct { ++ /* changed child */ ++ carry_node *child; ++ /* bitmask of changes. See &cop_modify_flag */ ++ __u32 flag; ++ } modify; ++ struct { ++ /* flags to deletion operation. Are taken from ++ cop_delete_flag */ ++ __u32 flags; ++ /* child to delete from parent. If this is ++ NULL, delete op->node. */ ++ carry_node *child; ++ } delete; ++ struct { ++ /* various operation flags. Taken from ++ cop_insert_flag. */ ++ __u32 flags; ++ flow_t *flow; ++ coord_t *insert_point; ++ reiser4_item_data *data; ++ /* flow insertion is limited by number of new blocks ++ added in that operation which do not get any data ++ but part of flow. This limit is set by macro ++ CARRY_FLOW_NEW_NODES_LIMIT. This field stores number ++ of nodes added already during one carry_flow */ ++ int new_nodes; ++ } insert_flow; ++ } u; ++} carry_op; ++ ++/* &carry_op_pool - preallocated pool of carry operations, and nodes */ ++typedef struct carry_pool { ++ carry_op op[CARRIES_POOL_SIZE]; ++ struct reiser4_pool op_pool; ++ carry_node node[NODES_LOCKED_POOL_SIZE]; ++ struct reiser4_pool node_pool; ++} carry_pool; ++ ++/* &carry_tree_level - carry process on given level ++ ++ Description of balancing process on the given level. ++ ++ No need for locking here, as carry_tree_level is essentially per ++ thread thing (for now). ++ ++*/ ++struct carry_level { ++ /* this level may be restarted */ ++ __u32 restartable:1; ++ /* list of carry nodes on this level, ordered by key order */ ++ struct list_head nodes; ++ struct list_head ops; ++ /* pool where new objects are allocated from */ ++ carry_pool *pool; ++ int ops_num; ++ int nodes_num; ++ /* new root created on this level, if any */ ++ znode *new_root; ++ /* This is set by caller (insert_by_key(), reiser4_resize_item(), etc.) ++ when they want ->tracked to automagically wander to the node where ++ insertion point moved after insert or paste. ++ */ ++ carry_track_type track_type; ++ /* lock handle supplied by user that we are tracking. See ++ above. */ ++ lock_handle *tracked; ++}; ++ ++/* information carry passes to plugin methods that may add new operations to ++ the @todo queue */ ++struct carry_plugin_info { ++ carry_level *doing; ++ carry_level *todo; ++}; ++ ++int reiser4_carry(carry_level * doing, carry_level * done); ++ ++carry_node *reiser4_add_carry(carry_level * level, pool_ordering order, ++ carry_node * reference); ++carry_node *reiser4_add_carry_skip(carry_level * level, pool_ordering order, ++ carry_node * reference); ++ ++extern carry_node *insert_carry_node(carry_level * doing, ++ carry_level * todo, const znode * node); ++ ++extern carry_pool *init_carry_pool(int); ++extern void done_carry_pool(carry_pool * pool); ++ ++extern void init_carry_level(carry_level * level, carry_pool * pool); ++ ++extern carry_op *reiser4_post_carry(carry_level * level, carry_opcode op, ++ znode * node, int apply_to_parent); ++extern carry_op *node_post_carry(carry_plugin_info * info, carry_opcode op, ++ znode * node, int apply_to_parent_p); ++ ++carry_node *add_new_znode(znode * brother, carry_node * reference, ++ carry_level * doing, carry_level * todo); ++ ++carry_node *find_carry_node(carry_level * level, const znode * node); ++ ++extern znode *reiser4_carry_real(const carry_node * node); ++ ++/* helper macros to iterate over carry queues */ ++ ++#define carry_node_next(node) \ ++ list_entry((node)->header.level_linkage.next, carry_node, \ ++ header.level_linkage) ++ ++#define carry_node_prev(node) \ ++ list_entry((node)->header.level_linkage.prev, carry_node, \ ++ header.level_linkage) ++ ++#define carry_node_front(level) \ ++ list_entry((level)->nodes.next, carry_node, header.level_linkage) ++ ++#define carry_node_back(level) \ ++ list_entry((level)->nodes.prev, carry_node, header.level_linkage) ++ ++#define carry_node_end(level, node) \ ++ (&(level)->nodes == &(node)->header.level_linkage) ++ ++/* macro to iterate over all operations in a @level */ ++#define for_all_ops(level /* carry level (of type carry_level *) */, \ ++ op /* pointer to carry operation, modified by loop (of \ ++ * type carry_op *) */, \ ++ tmp /* pointer to carry operation (of type carry_op *), \ ++ * used to make iterator stable in the face of \ ++ * deletions from the level */ ) \ ++for (op = list_entry(level->ops.next, carry_op, header.level_linkage), \ ++ tmp = list_entry(op->header.level_linkage.next, carry_op, header.level_linkage); \ ++ &op->header.level_linkage != &level->ops; \ ++ op = tmp, \ ++ tmp = list_entry(op->header.level_linkage.next, carry_op, header.level_linkage)) ++ ++#if 0 ++for (op = (carry_op *) pool_level_list_front(&level->ops), \ ++ tmp = (carry_op *) pool_level_list_next(&op->header) ; \ ++ !pool_level_list_end(&level->ops, &op->header) ; \ ++ op = tmp, tmp = (carry_op *) pool_level_list_next(&op->header)) ++#endif ++ ++/* macro to iterate over all nodes in a @level */ \ ++#define for_all_nodes(level /* carry level (of type carry_level *) */, \ ++ node /* pointer to carry node, modified by loop (of \ ++ * type carry_node *) */, \ ++ tmp /* pointer to carry node (of type carry_node *), \ ++ * used to make iterator stable in the face of * \ ++ * deletions from the level */ ) \ ++for (node = list_entry(level->nodes.next, carry_node, header.level_linkage), \ ++ tmp = list_entry(node->header.level_linkage.next, carry_node, header.level_linkage); \ ++ &node->header.level_linkage != &level->nodes; \ ++ node = tmp, \ ++ tmp = list_entry(node->header.level_linkage.next, carry_node, header.level_linkage)) ++ ++#if 0 ++for (node = carry_node_front(level), \ ++ tmp = carry_node_next(node) ; !carry_node_end(level, node) ; \ ++ node = tmp, tmp = carry_node_next(node)) ++#endif ++ ++/* macro to iterate over all nodes in a @level in reverse order ++ ++ This is used, because nodes are unlocked in reversed order of locking */ ++#define for_all_nodes_back(level /* carry level (of type carry_level *) */, \ ++ node /* pointer to carry node, modified by loop \ ++ * (of type carry_node *) */, \ ++ tmp /* pointer to carry node (of type carry_node \ ++ * *), used to make iterator stable in the \ ++ * face of deletions from the level */ ) \ ++for (node = carry_node_back(level), \ ++ tmp = carry_node_prev(node) ; !carry_node_end(level, node) ; \ ++ node = tmp, tmp = carry_node_prev(node)) ++ ++/* __FS_REISER4_CARRY_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/carry_ops.c linux-5.10.2/fs/reiser4/carry_ops.c +--- linux-5.10.2.orig/fs/reiser4/carry_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/carry_ops.c 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,2159 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* implementation of carry operations */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/node/node.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "pool.h" ++#include "tree_mod.h" ++#include "carry.h" ++#include "carry_ops.h" ++#include "tree.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include ++#include ++ ++static int carry_shift_data(sideof side, coord_t *insert_coord, znode * node, ++ carry_level * doing, carry_level * todo, ++ unsigned int including_insert_coord_p); ++ ++extern int lock_carry_node(carry_level * level, carry_node * node); ++extern int lock_carry_node_tail(carry_node * node); ++ ++/* find left neighbor of a carry node ++ ++ Look for left neighbor of @node and add it to the @doing queue. See ++ comments in the body. ++ ++*/ ++static carry_node *find_left_neighbor(carry_op * op /* node to find left ++ * neighbor of */ , ++ carry_level * doing/* level to scan */) ++{ ++ int result; ++ carry_node *node; ++ carry_node *left; ++ int flags; ++ reiser4_tree *tree; ++ ++ node = op->node; ++ tree = znode_get_tree(node->node); ++ ++ read_lock_tree(); ++ /* first, check whether left neighbor is already in a @doing queue */ ++ if (reiser4_carry_real(node)->left != NULL) { ++ /* NOTE: there is locking subtlety here. Look into ++ * find_right_neighbor() for more info */ ++ if (find_carry_node(doing, ++ reiser4_carry_real(node)->left) != NULL) { ++ read_unlock_tree(); ++ left = node; ++ do { ++ left = list_entry(left->header.level_linkage.prev, ++ carry_node, header.level_linkage); ++ assert("nikita-3408", !carry_node_end(doing, ++ left)); ++ } while (reiser4_carry_real(left) == ++ reiser4_carry_real(node)); ++ return left; ++ } ++ } ++ read_unlock_tree(); ++ ++ left = reiser4_add_carry_skip(doing, POOLO_BEFORE, node); ++ if (IS_ERR(left)) ++ return left; ++ ++ left->node = node->node; ++ left->free = 1; ++ ++ flags = GN_TRY_LOCK; ++ if (!(op->u.insert.flags & COPI_LOAD_LEFT)) ++ flags |= GN_NO_ALLOC; ++ ++ /* then, feeling lucky, peek left neighbor in the cache. */ ++ result = reiser4_get_left_neighbor(&left->lock_handle, ++ reiser4_carry_real(node), ++ ZNODE_WRITE_LOCK, flags); ++ if (result == 0) { ++ /* ok, node found and locked. */ ++ result = lock_carry_node_tail(left); ++ if (result != 0) ++ left = ERR_PTR(result); ++ } else if (result == -E_NO_NEIGHBOR || result == -ENOENT) { ++ /* node is leftmost node in a tree, or neighbor wasn't in ++ cache, or there is an extent on the left. */ ++ reiser4_pool_free(&doing->pool->node_pool, &left->header); ++ left = NULL; ++ } else if (doing->restartable) { ++ /* if left neighbor is locked, and level is restartable, add ++ new node to @doing and restart. */ ++ assert("nikita-913", node->parent != 0); ++ assert("nikita-914", node->node != NULL); ++ left->left = 1; ++ left->free = 0; ++ left = ERR_PTR(-E_REPEAT); ++ } else { ++ /* left neighbor is locked, level cannot be restarted. Just ++ ignore left neighbor. */ ++ reiser4_pool_free(&doing->pool->node_pool, &left->header); ++ left = NULL; ++ } ++ return left; ++} ++ ++/* find right neighbor of a carry node ++ ++ Look for right neighbor of @node and add it to the @doing queue. See ++ comments in the body. ++ ++*/ ++static carry_node *find_right_neighbor(carry_op * op /* node to find right ++ * neighbor of */ , ++ carry_level * doing/* level to scan */) ++{ ++ int result; ++ carry_node *node; ++ carry_node *right; ++ lock_handle lh; ++ int flags; ++ reiser4_tree *tree; ++ ++ init_lh(&lh); ++ ++ node = op->node; ++ tree = znode_get_tree(node->node); ++ ++ read_lock_tree(); ++ /* first, check whether right neighbor is already in a @doing queue */ ++ if (reiser4_carry_real(node)->right != NULL) { ++ /* ++ * Tree lock is taken here anyway, because, even if _outcome_ ++ * of (find_carry_node() != NULL) doesn't depends on ++ * concurrent updates to ->right, find_carry_node() cannot ++ * work with second argument NULL. Hence, following comment is ++ * of historic importance only. ++ * ++ * Subtle: ++ * ++ * Q: why don't we need tree lock here, looking for the right ++ * neighbor? ++ * ++ * A: even if value of node->real_node->right were changed ++ * during find_carry_node() execution, outcome of execution ++ * wouldn't change, because (in short) other thread cannot add ++ * elements to the @doing, and if node->real_node->right ++ * already was in @doing, value of node->real_node->right ++ * couldn't change, because node cannot be inserted between ++ * locked neighbors. ++ */ ++ if (find_carry_node(doing, ++ reiser4_carry_real(node)->right) != NULL) { ++ read_unlock_tree(); ++ /* ++ * What we are doing here (this is also applicable to ++ * the find_left_neighbor()). ++ * ++ * tree_walk.c code requires that insertion of a ++ * pointer to a child, modification of parent pointer ++ * in the child, and insertion of the child into ++ * sibling list are atomic (see ++ * plugin/item/internal.c:create_hook_internal()). ++ * ++ * carry allocates new node long before pointer to it ++ * is inserted into parent and, actually, long before ++ * parent is even known. Such allocated-but-orphaned ++ * nodes are only trackable through carry level lists. ++ * ++ * Situation that is handled here is following: @node ++ * has valid ->right pointer, but there is ++ * allocated-but-orphaned node in the carry queue that ++ * is logically between @node and @node->right. Here ++ * we are searching for it. Critical point is that ++ * this is only possible if @node->right is also in ++ * the carry queue (this is checked above), because ++ * this is the only way new orphaned node could be ++ * inserted between them (before inserting new node, ++ * make_space() first tries to shift to the right, so, ++ * right neighbor will be locked and queued). ++ * ++ */ ++ right = node; ++ do { ++ right = list_entry(right->header.level_linkage.next, ++ carry_node, header.level_linkage); ++ assert("nikita-3408", !carry_node_end(doing, ++ right)); ++ } while (reiser4_carry_real(right) == ++ reiser4_carry_real(node)); ++ return right; ++ } ++ } ++ read_unlock_tree(); ++ ++ flags = GN_CAN_USE_UPPER_LEVELS; ++ if (!(op->u.insert.flags & COPI_LOAD_RIGHT)) ++ flags = GN_NO_ALLOC; ++ ++ /* then, try to lock right neighbor */ ++ init_lh(&lh); ++ result = reiser4_get_right_neighbor(&lh, ++ reiser4_carry_real(node), ++ ZNODE_WRITE_LOCK, flags); ++ if (result == 0) { ++ /* ok, node found and locked. */ ++ right = reiser4_add_carry_skip(doing, POOLO_AFTER, node); ++ if (!IS_ERR(right)) { ++ right->node = lh.node; ++ move_lh(&right->lock_handle, &lh); ++ right->free = 1; ++ result = lock_carry_node_tail(right); ++ if (result != 0) ++ right = ERR_PTR(result); ++ } ++ } else if ((result == -E_NO_NEIGHBOR) || (result == -ENOENT)) { ++ /* node is rightmost node in a tree, or neighbor wasn't in ++ cache, or there is an extent on the right. */ ++ right = NULL; ++ } else ++ right = ERR_PTR(result); ++ done_lh(&lh); ++ return right; ++} ++ ++/* how much free space in a @node is needed for @op ++ ++ How much space in @node is required for completion of @op, where @op is ++ insert or paste operation. ++*/ ++static unsigned int space_needed_for_op(znode * node /* znode data are ++ * inserted or ++ * pasted in */ , ++ carry_op * op /* carry ++ operation */ ) ++{ ++ assert("nikita-919", op != NULL); ++ ++ switch (op->op) { ++ default: ++ impossible("nikita-1701", "Wrong opcode"); ++ case COP_INSERT: ++ return space_needed(node, NULL, op->u.insert.d->data, 1); ++ case COP_PASTE: ++ return space_needed(node, op->u.insert.d->coord, ++ op->u.insert.d->data, 0); ++ } ++} ++ ++/* how much space in @node is required to insert or paste @data at ++ @coord. */ ++unsigned int space_needed(const znode * node /* node data are inserted or ++ * pasted in */ , ++ const coord_t *coord /* coord where data are ++ * inserted or pasted ++ * at */ , ++ const reiser4_item_data * data /* data to insert or ++ * paste */ , ++ int insertion/* non-0 is inserting, 0---paste */) ++{ ++ int result; ++ item_plugin *iplug; ++ ++ assert("nikita-917", node != NULL); ++ assert("nikita-918", node_plugin_by_node(node) != NULL); ++ assert("vs-230", !insertion || (coord == NULL)); ++ ++ result = 0; ++ iplug = data->iplug; ++ if (iplug->b.estimate != NULL) { ++ /* ask item plugin how much space is needed to insert this ++ item */ ++ result += iplug->b.estimate(insertion ? NULL : coord, data); ++ } else { ++ /* reasonable default */ ++ result += data->length; ++ } ++ if (insertion) { ++ node_plugin *nplug; ++ ++ nplug = node->nplug; ++ /* and add node overhead */ ++ if (nplug->item_overhead != NULL) ++ result += nplug->item_overhead(node, NULL); ++ } ++ return result; ++} ++ ++/* find &coord in parent where pointer to new child is to be stored. */ ++static int find_new_child_coord(carry_op * op /* COP_INSERT carry operation to ++ * insert pointer to new ++ * child */ ) ++{ ++ int result; ++ znode *node; ++ znode *child; ++ ++ assert("nikita-941", op != NULL); ++ assert("nikita-942", op->op == COP_INSERT); ++ ++ node = reiser4_carry_real(op->node); ++ assert("nikita-943", node != NULL); ++ assert("nikita-944", node_plugin_by_node(node) != NULL); ++ ++ child = reiser4_carry_real(op->u.insert.child); ++ result = ++ find_new_child_ptr(node, child, op->u.insert.brother, ++ op->u.insert.d->coord); ++ ++ build_child_ptr_data(child, op->u.insert.d->data); ++ return result; ++} ++ ++/* additional amount of free space in @node required to complete @op */ ++static int free_space_shortage(znode * node /* node to check */ , ++ carry_op * op/* operation being performed */) ++{ ++ assert("nikita-1061", node != NULL); ++ assert("nikita-1062", op != NULL); ++ ++ switch (op->op) { ++ default: ++ impossible("nikita-1702", "Wrong opcode"); ++ case COP_INSERT: ++ case COP_PASTE: ++ return space_needed_for_op(node, op) - znode_free_space(node); ++ case COP_EXTENT: ++ /* when inserting extent shift data around until insertion ++ point is utmost in the node. */ ++ if (coord_wrt(op->u.insert.d->coord) == COORD_INSIDE) ++ return +1; ++ else ++ return -1; ++ } ++} ++ ++/* helper function: update node pointer in operation after insertion ++ point was probably shifted into @target. */ ++static znode *sync_op(carry_op * op, carry_node * target) ++{ ++ znode *insertion_node; ++ ++ /* reget node from coord: shift might move insertion coord to ++ the neighbor */ ++ insertion_node = op->u.insert.d->coord->node; ++ /* if insertion point was actually moved into new node, ++ update carry node pointer in operation. */ ++ if (insertion_node != reiser4_carry_real(op->node)) { ++ op->node = target; ++ assert("nikita-2540", ++ reiser4_carry_real(target) == insertion_node); ++ } ++ assert("nikita-2541", ++ reiser4_carry_real(op->node) == op->u.insert.d->coord->node); ++ return insertion_node; ++} ++ ++/* ++ * complete make_space() call: update tracked lock handle if necessary. See ++ * comments for fs/reiser4/carry.h:carry_track_type ++ */ ++static int ++make_space_tail(carry_op * op, carry_level * doing, znode * orig_node) ++{ ++ int result; ++ carry_track_type tracking; ++ znode *node; ++ ++ tracking = doing->track_type; ++ node = op->u.insert.d->coord->node; ++ ++ if (tracking == CARRY_TRACK_NODE || ++ (tracking == CARRY_TRACK_CHANGE && node != orig_node)) { ++ /* inserting or pasting into node different from ++ original. Update lock handle supplied by caller. */ ++ assert("nikita-1417", doing->tracked != NULL); ++ done_lh(doing->tracked); ++ init_lh(doing->tracked); ++ result = longterm_lock_znode(doing->tracked, node, ++ ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_HIPRI); ++ } else ++ result = 0; ++ return result; ++} ++ ++/* This is insertion policy function. It shifts data to the left and right ++ neighbors of insertion coord and allocates new nodes until there is enough ++ free space to complete @op. ++ ++ See comments in the body. ++ ++ Assumes that the node format favors insertions at the right end of the node ++ as node40 does. ++ ++ See carry_flow() on detail about flow insertion ++*/ ++static int make_space(carry_op * op /* carry operation, insert or paste */ , ++ carry_level * doing /* current carry queue */ , ++ carry_level * todo/* carry queue on the parent level */) ++{ ++ znode *node; ++ int result; ++ int not_enough_space; ++ int blk_alloc; ++ znode *orig_node; ++ __u32 flags; ++ ++ coord_t *coord; ++ ++ assert("nikita-890", op != NULL); ++ assert("nikita-891", todo != NULL); ++ assert("nikita-892", ++ op->op == COP_INSERT || ++ op->op == COP_PASTE || op->op == COP_EXTENT); ++ assert("nikita-1607", ++ reiser4_carry_real(op->node) == op->u.insert.d->coord->node); ++ ++ flags = op->u.insert.flags; ++ ++ /* NOTE check that new node can only be allocated after checking left ++ * and right neighbors. This is necessary for proper work of ++ * find_{left,right}_neighbor(). */ ++ assert("nikita-3410", ergo(flags & COPI_DONT_ALLOCATE, ++ flags & COPI_DONT_SHIFT_LEFT)); ++ assert("nikita-3411", ergo(flags & COPI_DONT_ALLOCATE, ++ flags & COPI_DONT_SHIFT_RIGHT)); ++ ++ coord = op->u.insert.d->coord; ++ orig_node = node = coord->node; ++ ++ assert("nikita-908", node != NULL); ++ assert("nikita-909", node_plugin_by_node(node) != NULL); ++ ++ result = 0; ++ /* If there is not enough space in a node, try to shift something to ++ the left neighbor. This is a bit tricky, as locking to the left is ++ low priority. This is handled by restart logic in carry(). ++ */ ++ not_enough_space = free_space_shortage(node, op); ++ if (not_enough_space <= 0) ++ /* it is possible that carry was called when there actually ++ was enough space in the node. For example, when inserting ++ leftmost item so that delimiting keys have to be updated. ++ */ ++ return make_space_tail(op, doing, orig_node); ++ if (!(flags & COPI_DONT_SHIFT_LEFT)) { ++ carry_node *left; ++ /* make note in statistics of an attempt to move ++ something into the left neighbor */ ++ left = find_left_neighbor(op, doing); ++ if (unlikely(IS_ERR(left))) { ++ if (PTR_ERR(left) == -E_REPEAT) ++ return -E_REPEAT; ++ else { ++ /* some error other than restart request ++ occurred. This shouldn't happen. Issue a ++ warning and continue as if left neighbor ++ weren't existing. ++ */ ++ warning("nikita-924", ++ "Error accessing left neighbor: %li", ++ PTR_ERR(left)); ++ } ++ } else if (left != NULL) { ++ ++ /* shift everything possible on the left of and ++ including insertion coord into the left neighbor */ ++ result = carry_shift_data(LEFT_SIDE, coord, ++ reiser4_carry_real(left), ++ doing, todo, ++ flags & COPI_GO_LEFT); ++ ++ /* reget node from coord: shift_left() might move ++ insertion coord to the left neighbor */ ++ node = sync_op(op, left); ++ ++ not_enough_space = free_space_shortage(node, op); ++ /* There is not enough free space in @node, but ++ may be, there is enough free space in ++ @left. Various balancing decisions are valid here. ++ The same for the shifiting to the right. ++ */ ++ } ++ } ++ /* If there still is not enough space, shift to the right */ ++ if (not_enough_space > 0 && !(flags & COPI_DONT_SHIFT_RIGHT)) { ++ carry_node *right; ++ ++ right = find_right_neighbor(op, doing); ++ if (IS_ERR(right)) { ++ warning("nikita-1065", ++ "Error accessing right neighbor: %li", ++ PTR_ERR(right)); ++ } else if (right != NULL) { ++ /* node containing insertion point, and its right ++ neighbor node are write locked by now. ++ ++ shift everything possible on the right of but ++ excluding insertion coord into the right neighbor ++ */ ++ result = carry_shift_data(RIGHT_SIDE, coord, ++ reiser4_carry_real(right), ++ doing, todo, ++ 1 /* go to right neighbor ++ if there is nothing ++ to shift */); ++ /* ++ NOTE-EDWARD: If there is nothing to shift, then ++ moving insertion point to the right neighbor is ++ a must! Otherwise, tree degeneration is possible. ++ E.g. in the following scenario: suppose current node ++ and its left neighbor are full. We plug a hole with ++ one logical block at offset OFF in a file, and the ++ current position in the tree is at the end of the ++ node. Since we don't go to right, a new node will be ++ inserted with only one item in it. In the next ++ iteration we plug a hole at offset (OFF - BLOCK_SIZE). ++ Note that in that next iteration the insertion point ++ will be the same (i.e. before the new node). Thus, ++ again, we don't go to right and insert a second new ++ node with only one item in it, etc... ++ */ ++ /* reget node from coord after moving the insertion ++ coord to the right neighbor */ ++ node = sync_op(op, right); ++ not_enough_space = free_space_shortage(node, op); ++ } ++ } ++ /* If there is still not enough space, allocate new node(s). ++ ++ We try to allocate new blocks if COPI_DONT_ALLOCATE is not set in ++ the carry operation flags (currently this is needed during flush ++ only). ++ */ ++ for (blk_alloc = 0; ++ not_enough_space > 0 && result == 0 && blk_alloc < 2 && ++ !(flags & COPI_DONT_ALLOCATE); ++blk_alloc) { ++ carry_node *fresh; /* new node we are allocating */ ++ coord_t coord_shadow; /* remembered insertion point before ++ * shifting data into new node */ ++ carry_node *node_shadow; /* remembered insertion node ++ * before shifting */ ++ unsigned int gointo; /* whether insertion point should move ++ * into newly allocated node */ ++ ++ /* allocate new node on the right of @node. Znode and disk ++ fake block number for new node are allocated. ++ ++ add_new_znode() posts carry operation COP_INSERT with ++ COPT_CHILD option to the parent level to add ++ pointer to newly created node to its parent. ++ ++ Subtle point: if several new nodes are required to complete ++ insertion operation at this level, they will be inserted ++ into their parents in the order of creation, which means ++ that @node will be valid "cookie" at the time of insertion. ++ ++ */ ++ fresh = add_new_znode(node, op->node, doing, todo); ++ if (IS_ERR(fresh)) ++ return PTR_ERR(fresh); ++ ++ /* Try to shift into new node. */ ++ result = lock_carry_node(doing, fresh); ++ zput(reiser4_carry_real(fresh)); ++ if (result != 0) { ++ warning("nikita-947", ++ "Cannot lock new node: %i", result); ++ return result; ++ } ++ ++ /* both nodes are write locked by now. ++ ++ shift everything possible on the right of and ++ including insertion coord into the right neighbor. ++ */ ++ coord_dup(&coord_shadow, op->u.insert.d->coord); ++ node_shadow = op->node; ++ /* move insertion point into newly created node if: ++ ++ . insertion point is rightmost in the source node, or ++ . this is not the first node we are allocating in a row. ++ */ ++ gointo = ++ (blk_alloc > 0) || ++ coord_is_after_rightmost(op->u.insert.d->coord); ++ ++ if (gointo && ++ op->op == COP_PASTE && ++ coord_is_existing_item(op->u.insert.d->coord) && ++ is_solid_item((item_plugin_by_coord(op->u.insert.d->coord)))) { ++ /* paste into solid (atomic) item, which can contain ++ only one unit, so we need to shift it right, where ++ insertion point supposed to be */ ++ ++ assert("edward-1444", op->u.insert.d->data->iplug == ++ item_plugin_by_id(STATIC_STAT_DATA_ID)); ++ assert("edward-1445", ++ op->u.insert.d->data->length > ++ node_plugin_by_node(coord->node)->free_space ++ (coord->node)); ++ ++ op->u.insert.d->coord->between = BEFORE_UNIT; ++ } ++ ++ result = carry_shift_data(RIGHT_SIDE, coord, ++ reiser4_carry_real(fresh), ++ doing, todo, gointo); ++ /* if insertion point was actually moved into new node, ++ update carry node pointer in operation. */ ++ node = sync_op(op, fresh); ++ not_enough_space = free_space_shortage(node, op); ++ if ((not_enough_space > 0) && (node != coord_shadow.node)) { ++ /* there is not enough free in new node. Shift ++ insertion point back to the @shadow_node so that ++ next new node would be inserted between ++ @shadow_node and @fresh. ++ */ ++ coord_normalize(&coord_shadow); ++ coord_dup(coord, &coord_shadow); ++ node = coord->node; ++ op->node = node_shadow; ++ if (1 || (flags & COPI_STEP_BACK)) { ++ /* still not enough space?! Maybe there is ++ enough space in the source node (i.e., node ++ data are moved from) now. ++ */ ++ not_enough_space = ++ free_space_shortage(node, op); ++ } ++ } ++ } ++ if (not_enough_space > 0) { ++ if (!(flags & COPI_DONT_ALLOCATE)) ++ warning("nikita-948", "Cannot insert new item"); ++ result = -E_NODE_FULL; ++ } ++ assert("nikita-1622", ergo(result == 0, ++ reiser4_carry_real(op->node) == coord->node)); ++ assert("nikita-2616", coord == op->u.insert.d->coord); ++ if (result == 0) ++ result = make_space_tail(op, doing, orig_node); ++ return result; ++} ++ ++/* insert_paste_common() - common part of insert and paste operations ++ ++ This function performs common part of COP_INSERT and COP_PASTE. ++ ++ There are two ways in which insertion/paste can be requested: ++ ++ . by directly supplying reiser4_item_data. In this case, op -> ++ u.insert.type is set to COPT_ITEM_DATA. ++ ++ . by supplying child pointer to which is to inserted into parent. In this ++ case op -> u.insert.type == COPT_CHILD. ++ ++ . by supplying key of new item/unit. This is currently only used during ++ extent insertion ++ ++ This is required, because when new node is allocated we don't know at what ++ position pointer to it is to be stored in the parent. Actually, we don't ++ even know what its parent will be, because parent can be re-balanced ++ concurrently and new node re-parented, and because parent can be full and ++ pointer to the new node will go into some other node. ++ ++ insert_paste_common() resolves pointer to child node into position in the ++ parent by calling find_new_child_coord(), that fills ++ reiser4_item_data. After this, insertion/paste proceeds uniformly. ++ ++ Another complication is with finding free space during pasting. It may ++ happen that while shifting items to the neighbors and newly allocated ++ nodes, insertion coord can no longer be in the item we wanted to paste ++ into. At this point, paste becomes (morphs) into insert. Moreover free ++ space analysis has to be repeated, because amount of space required for ++ insertion is different from that of paste (item header overhead, etc). ++ ++ This function "unifies" different insertion modes (by resolving child ++ pointer or key into insertion coord), and then calls make_space() to free ++ enough space in the node by shifting data to the left and right and by ++ allocating new nodes if necessary. Carry operation knows amount of space ++ required for its completion. After enough free space is obtained, caller of ++ this function (carry_{insert,paste,etc.}) performs actual insertion/paste ++ by calling item plugin method. ++ ++*/ ++static int insert_paste_common(carry_op * op /* carry operation being ++ * performed */ , ++ carry_level * doing /* current carry level */ , ++ carry_level * todo /* next carry level */ , ++ carry_insert_data * cdata /* pointer to ++ * cdata */ , ++ coord_t *coord /* insertion/paste coord */ , ++ reiser4_item_data * data /* data to be ++ * inserted/pasted */ ) ++{ ++ assert("nikita-981", op != NULL); ++ assert("nikita-980", todo != NULL); ++ assert("nikita-979", (op->op == COP_INSERT) || (op->op == COP_PASTE) ++ || (op->op == COP_EXTENT)); ++ ++ if (op->u.insert.type == COPT_PASTE_RESTARTED) { ++ /* nothing to do. Fall through to make_space(). */ ++ ; ++ } else if (op->u.insert.type == COPT_KEY) { ++ node_search_result intra_node; ++ znode *node; ++ /* Problem with doing batching at the lowest level, is that ++ operations here are given by coords where modification is ++ to be performed, and one modification can invalidate coords ++ of all following operations. ++ ++ So, we are implementing yet another type for operation that ++ will use (the only) "locator" stable across shifting of ++ data between nodes, etc.: key (COPT_KEY). ++ ++ This clause resolves key to the coord in the node. ++ ++ But node can change also. Probably some pieces have to be ++ added to the lock_carry_node(), to lock node by its key. ++ ++ */ ++ /* NOTE-NIKITA Lookup bias is fixed to FIND_EXACT. Complain ++ if you need something else. */ ++ op->u.insert.d->coord = coord; ++ node = reiser4_carry_real(op->node); ++ intra_node = node_plugin_by_node(node)->lookup ++ (node, op->u.insert.d->key, FIND_EXACT, ++ op->u.insert.d->coord); ++ if ((intra_node != NS_FOUND) && (intra_node != NS_NOT_FOUND)) { ++ warning("nikita-1715", "Intra node lookup failure: %i", ++ intra_node); ++ return intra_node; ++ } ++ } else if (op->u.insert.type == COPT_CHILD) { ++ /* if we are asked to insert pointer to the child into ++ internal node, first convert pointer to the child into ++ coord within parent node. ++ */ ++ znode *child; ++ int result; ++ ++ op->u.insert.d = cdata; ++ op->u.insert.d->coord = coord; ++ op->u.insert.d->data = data; ++ op->u.insert.d->coord->node = reiser4_carry_real(op->node); ++ result = find_new_child_coord(op); ++ child = reiser4_carry_real(op->u.insert.child); ++ if (result != NS_NOT_FOUND) { ++ warning("nikita-993", ++ "Cannot find a place for child pointer: %i", ++ result); ++ return result; ++ } ++ /* This only happens when we did multiple insertions at ++ the previous level, trying to insert single item and ++ it so happened, that insertion of pointers to all new ++ nodes before this one already caused parent node to ++ split (may be several times). ++ ++ I am going to come up with better solution. ++ ++ You are not expected to understand this. ++ -- v6root/usr/sys/ken/slp.c ++ ++ Basically, what happens here is the following: carry came ++ to the parent level and is about to insert internal item ++ pointing to the child node that it just inserted in the ++ level below. Position where internal item is to be inserted ++ was found by find_new_child_coord() above, but node of the ++ current carry operation (that is, parent node of child ++ inserted on the previous level), was determined earlier in ++ the lock_carry_level/lock_carry_node. It could so happen ++ that other carry operations already performed on the parent ++ level already split parent node, so that insertion point ++ moved into another node. Handle this by creating new carry ++ node for insertion point if necessary. ++ */ ++ if (reiser4_carry_real(op->node) != ++ op->u.insert.d->coord->node) { ++ pool_ordering direction; ++ znode *z1; ++ znode *z2; ++ reiser4_key k1; ++ reiser4_key k2; ++ ++ /* ++ * determine in what direction insertion point ++ * moved. Do this by comparing delimiting keys. ++ */ ++ z1 = op->u.insert.d->coord->node; ++ z2 = reiser4_carry_real(op->node); ++ if (keyle(leftmost_key_in_node(z1, &k1), ++ leftmost_key_in_node(z2, &k2))) ++ /* insertion point moved to the left */ ++ direction = POOLO_BEFORE; ++ else ++ /* insertion point moved to the right */ ++ direction = POOLO_AFTER; ++ ++ op->node = reiser4_add_carry_skip(doing, ++ direction, op->node); ++ if (IS_ERR(op->node)) ++ return PTR_ERR(op->node); ++ op->node->node = op->u.insert.d->coord->node; ++ op->node->free = 1; ++ result = lock_carry_node(doing, op->node); ++ if (result != 0) ++ return result; ++ } ++ ++ /* ++ * set up key of an item being inserted: we are inserting ++ * internal item and its key is (by the very definition of ++ * search tree) is leftmost key in the child node. ++ */ ++ write_lock_dk(znode_get_tree(child)); ++ op->u.insert.d->key = leftmost_key_in_node(child, ++ znode_get_ld_key(child)); ++ write_unlock_dk(znode_get_tree(child)); ++ op->u.insert.d->data->arg = op->u.insert.brother; ++ } else { ++ assert("vs-243", op->u.insert.d->coord != NULL); ++ op->u.insert.d->coord->node = reiser4_carry_real(op->node); ++ } ++ ++ /* find free space. */ ++ return make_space(op, doing, todo); ++} ++ ++/* handle carry COP_INSERT operation. ++ ++ Insert new item into node. New item can be given in one of two ways: ++ ++ - by passing &tree_coord and &reiser4_item_data as part of @op. This is ++ only applicable at the leaf/twig level. ++ ++ - by passing a child node pointer to which is to be inserted by this ++ operation. ++ ++*/ ++static int carry_insert(carry_op * op /* operation to perform */ , ++ carry_level * doing /* queue of operations @op ++ * is part of */ , ++ carry_level * todo /* queue where new operations ++ * are accumulated */ ) ++{ ++ znode *node; ++ carry_insert_data cdata; ++ coord_t coord; ++ reiser4_item_data data; ++ carry_plugin_info info; ++ int result; ++ ++ assert("nikita-1036", op != NULL); ++ assert("nikita-1037", todo != NULL); ++ assert("nikita-1038", op->op == COP_INSERT); ++ ++ coord_init_zero(&coord); ++ ++ /* perform common functionality of insert and paste. */ ++ result = insert_paste_common(op, doing, todo, &cdata, &coord, &data); ++ if (result != 0) ++ return result; ++ ++ node = op->u.insert.d->coord->node; ++ assert("nikita-1039", node != NULL); ++ assert("nikita-1040", node_plugin_by_node(node) != NULL); ++ ++ assert("nikita-949", ++ space_needed_for_op(node, op) <= znode_free_space(node)); ++ ++ /* ask node layout to create new item. */ ++ info.doing = doing; ++ info.todo = todo; ++ result = node_plugin_by_node(node)->create_item ++ (op->u.insert.d->coord, op->u.insert.d->key, op->u.insert.d->data, ++ &info); ++ doing->restartable = 0; ++ znode_make_dirty(node); ++ ++ return result; ++} ++ ++/* ++ * Flow insertion code. COP_INSERT_FLOW is special tree operation that is ++ * supplied with a "flow" (that is, a stream of data) and inserts it into tree ++ * by slicing into multiple items. ++ */ ++ ++#define flow_insert_point(op) ((op)->u.insert_flow.insert_point) ++#define flow_insert_flow(op) ((op)->u.insert_flow.flow) ++#define flow_insert_data(op) ((op)->u.insert_flow.data) ++ ++static size_t item_data_overhead(carry_op * op) ++{ ++ if (flow_insert_data(op)->iplug->b.estimate == NULL) ++ return 0; ++ return (flow_insert_data(op)->iplug->b. ++ estimate(NULL /* estimate insertion */ , flow_insert_data(op)) - ++ flow_insert_data(op)->length); ++} ++ ++/* FIXME-VS: this is called several times during one make_flow_for_insertion ++ and it will always return the same result. Some optimization could be made ++ by calculating this value once at the beginning and passing it around. That ++ would reduce some flexibility in future changes ++*/ ++static int can_paste(coord_t *, const reiser4_key *, const reiser4_item_data *); ++static size_t flow_insertion_overhead(carry_op * op) ++{ ++ znode *node; ++ size_t insertion_overhead; ++ ++ node = flow_insert_point(op)->node; ++ insertion_overhead = 0; ++ if (node->nplug->item_overhead && ++ !can_paste(flow_insert_point(op), &flow_insert_flow(op)->key, ++ flow_insert_data(op))) ++ insertion_overhead = ++ node->nplug->item_overhead(node, NULL) + ++ item_data_overhead(op); ++ return insertion_overhead; ++} ++ ++/* how many bytes of flow does fit to the node */ ++static int what_can_fit_into_node(carry_op * op) ++{ ++ size_t free, overhead; ++ ++ overhead = flow_insertion_overhead(op); ++ free = znode_free_space(flow_insert_point(op)->node); ++ if (free <= overhead) ++ return 0; ++ free -= overhead; ++ /* FIXME: flow->length is loff_t only to not get overflowed in case of ++ expandign truncate */ ++ if (free < op->u.insert_flow.flow->length) ++ return free; ++ return (int)op->u.insert_flow.flow->length; ++} ++ ++/* in make_space_for_flow_insertion we need to check either whether whole flow ++ fits into a node or whether minimal fraction of flow fits into a node */ ++static int enough_space_for_whole_flow(carry_op * op) ++{ ++ return (unsigned)what_can_fit_into_node(op) == ++ op->u.insert_flow.flow->length; ++} ++ ++#define MIN_FLOW_FRACTION 1 ++static int enough_space_for_min_flow_fraction(carry_op * op) ++{ ++ //assert("vs-902", coord_is_after_rightmost(flow_insert_point(op))); ++ ++ return what_can_fit_into_node(op) >= MIN_FLOW_FRACTION; ++} ++ ++/* this returns 0 if left neighbor was obtained successfully and everything ++ upto insertion point including it were shifted and left neighbor still has ++ some free space to put minimal fraction of flow into it */ ++static int ++make_space_by_shift_left(carry_op * op, carry_level * doing, carry_level * todo) ++{ ++ carry_node *left; ++ znode *orig; ++ ++ left = find_left_neighbor(op, doing); ++ if (unlikely(IS_ERR(left))) { ++ warning("vs-899", ++ "make_space_by_shift_left: " ++ "error accessing left neighbor: %li", PTR_ERR(left)); ++ return 1; ++ } ++ if (left == NULL) ++ /* left neighbor either does not exist or is unformatted ++ node */ ++ return 1; ++ ++ orig = flow_insert_point(op)->node; ++ /* try to shift content of node @orig from its head upto insert point ++ including insertion point into the left neighbor */ ++ carry_shift_data(LEFT_SIDE, flow_insert_point(op), ++ reiser4_carry_real(left), doing, todo, ++ 1/* including insert point */); ++ if (reiser4_carry_real(left) != flow_insert_point(op)->node) { ++ /* insertion point did not move */ ++ return 1; ++ } ++ ++ /* insertion point is set after last item in the node */ ++ assert("vs-900", coord_is_after_rightmost(flow_insert_point(op))); ++ ++ if (!enough_space_for_min_flow_fraction(op)) { ++ /* insertion point node does not have enough free space to put ++ even minimal portion of flow into it, therefore, move ++ insertion point back to orig node (before first item) */ ++ coord_init_before_first_item(flow_insert_point(op), orig); ++ return 1; ++ } ++ ++ /* part of flow is to be written to the end of node */ ++ op->node = left; ++ return 0; ++} ++ ++/* this returns 0 if right neighbor was obtained successfully and everything to ++ the right of insertion point was shifted to it and node got enough free ++ space to put minimal fraction of flow into it */ ++static int ++make_space_by_shift_right(carry_op * op, carry_level * doing, ++ carry_level * todo) ++{ ++ carry_node *right; ++ ++ right = find_right_neighbor(op, doing); ++ if (unlikely(IS_ERR(right))) { ++ warning("nikita-1065", "shift_right_excluding_insert_point: " ++ "error accessing right neighbor: %li", PTR_ERR(right)); ++ return 1; ++ } ++ if (right) { ++ /* shift everything possible on the right of but excluding ++ insertion coord into the right neighbor */ ++ carry_shift_data(RIGHT_SIDE, flow_insert_point(op), ++ reiser4_carry_real(right), doing, todo, ++ 0/* not including insert point */); ++ } else { ++ /* right neighbor either does not exist or is unformatted ++ node */ ++ ; ++ } ++ if (coord_is_after_rightmost(flow_insert_point(op))) { ++ if (enough_space_for_min_flow_fraction(op)) { ++ /* part of flow is to be written to the end of node */ ++ return 0; ++ } ++ } ++ ++ /* new node is to be added if insert point node did not get enough ++ space for whole flow */ ++ return 1; ++} ++ ++/* this returns 0 when insert coord is set at the node end and fraction of flow ++ fits into that node */ ++static int ++make_space_by_new_nodes(carry_op * op, carry_level * doing, carry_level * todo) ++{ ++ int result; ++ znode *node; ++ carry_node *new; ++ ++ node = flow_insert_point(op)->node; ++ ++ if (op->u.insert_flow.new_nodes == CARRY_FLOW_NEW_NODES_LIMIT) ++ return RETERR(-E_NODE_FULL); ++ /* add new node after insert point node */ ++ new = add_new_znode(node, op->node, doing, todo); ++ if (unlikely(IS_ERR(new))) ++ return PTR_ERR(new); ++ result = lock_carry_node(doing, new); ++ zput(reiser4_carry_real(new)); ++ if (unlikely(result)) ++ return result; ++ op->u.insert_flow.new_nodes++; ++ if (!coord_is_after_rightmost(flow_insert_point(op))) { ++ carry_shift_data(RIGHT_SIDE, flow_insert_point(op), ++ reiser4_carry_real(new), doing, todo, ++ 0/* not including insert point */); ++ assert("vs-901", ++ coord_is_after_rightmost(flow_insert_point(op))); ++ ++ if (enough_space_for_min_flow_fraction(op)) ++ return 0; ++ if (op->u.insert_flow.new_nodes == CARRY_FLOW_NEW_NODES_LIMIT) ++ return RETERR(-E_NODE_FULL); ++ ++ /* add one more new node */ ++ new = add_new_znode(node, op->node, doing, todo); ++ if (unlikely(IS_ERR(new))) ++ return PTR_ERR(new); ++ result = lock_carry_node(doing, new); ++ zput(reiser4_carry_real(new)); ++ if (unlikely(result)) ++ return result; ++ op->u.insert_flow.new_nodes++; ++ } ++ ++ /* move insertion point to new node */ ++ coord_init_before_first_item(flow_insert_point(op), ++ reiser4_carry_real(new)); ++ op->node = new; ++ return 0; ++} ++ ++static int ++make_space_for_flow_insertion(carry_op * op, carry_level * doing, ++ carry_level * todo) ++{ ++ __u32 flags = op->u.insert_flow.flags; ++ ++ if (enough_space_for_whole_flow(op)) { ++ /* whole flow fits into insert point node */ ++ return 0; ++ } ++ if ((flags & COPI_SWEEP) && ++ enough_space_for_min_flow_fraction(op)) ++ /* use the rest of space in the current node */ ++ return 0; ++ ++ if (!(flags & COPI_DONT_SHIFT_LEFT) ++ && (make_space_by_shift_left(op, doing, todo) == 0)) { ++ /* insert point is shifted to left neighbor of original insert ++ point node and is set after last unit in that node. It has ++ enough space to fit at least minimal fraction of flow. */ ++ return 0; ++ } ++ ++ if (enough_space_for_whole_flow(op)) { ++ /* whole flow fits into insert point node */ ++ return 0; ++ } ++ ++ if (!(flags & COPI_DONT_SHIFT_RIGHT) ++ && (make_space_by_shift_right(op, doing, todo) == 0)) { ++ /* insert point is still set to the same node, but there is ++ nothing to the right of insert point. */ ++ return 0; ++ } ++ ++ if (enough_space_for_whole_flow(op)) { ++ /* whole flow fits into insert point node */ ++ return 0; ++ } ++ ++ return make_space_by_new_nodes(op, doing, todo); ++} ++ ++/** ++ * Implements COP_INSERT_FLOW operation ++ */ ++static int carry_insert_flow(carry_op *op, ++ carry_level *doing, carry_level *todo) ++{ ++ int result; ++ flow_t *f; ++ coord_t *insert_point; ++ node_plugin *nplug; ++ carry_plugin_info info; ++ znode *orig_node; ++ lock_handle *orig_lh; ++ ++ f = op->u.insert_flow.flow; ++ result = 0; ++ ++ /* carry system needs this to work */ ++ info.doing = doing; ++ info.todo = todo; ++ ++ orig_node = flow_insert_point(op)->node; ++ orig_lh = doing->tracked; ++ ++ while (f->length) { ++ result = make_space_for_flow_insertion(op, doing, todo); ++ if (result) ++ break; ++ ++ insert_point = flow_insert_point(op); ++ nplug = node_plugin_by_node(insert_point->node); ++ ++ /* compose item data for insertion/pasting */ ++ flow_insert_data(op)->data = f->data; ++ flow_insert_data(op)->length = what_can_fit_into_node(op); ++ ++ if (can_paste(insert_point, &f->key, flow_insert_data(op))) { ++ /* insert point is set to item of file we are writing to ++ and we have to append to it */ ++ assert("vs-903", insert_point->between == AFTER_UNIT); ++ nplug->change_item_size(insert_point, ++ flow_insert_data(op)->length); ++ flow_insert_data(op)->iplug->b.paste(insert_point, ++ flow_insert_data ++ (op), &info); ++ } else { ++ /* new item must be inserted */ ++ pos_in_node_t new_pos; ++ flow_insert_data(op)->length += item_data_overhead(op); ++ ++ /* FIXME-VS: this is because node40_create_item changes ++ insert_point for obscure reasons */ ++ switch (insert_point->between) { ++ case AFTER_ITEM: ++ new_pos = insert_point->item_pos + 1; ++ break; ++ case EMPTY_NODE: ++ new_pos = 0; ++ break; ++ case BEFORE_ITEM: ++ assert("vs-905", insert_point->item_pos == 0); ++ new_pos = 0; ++ break; ++ default: ++ impossible("vs-906", ++ "carry_insert_flow: invalid coord"); ++ new_pos = 0; ++ break; ++ } ++ ++ nplug->create_item(insert_point, &f->key, ++ flow_insert_data(op), &info); ++ coord_set_item_pos(insert_point, new_pos); ++ } ++ coord_init_after_item_end(insert_point); ++ doing->restartable = 0; ++ znode_make_dirty(insert_point->node); ++ ++ move_flow_forward(f, (unsigned)flow_insert_data(op)->length); ++ } ++ ++ if (orig_node != flow_insert_point(op)->node) { ++ /* move lock to new insert point */ ++ done_lh(orig_lh); ++ init_lh(orig_lh); ++ result = ++ longterm_lock_znode(orig_lh, flow_insert_point(op)->node, ++ ZNODE_WRITE_LOCK, ZNODE_LOCK_HIPRI); ++ } ++ ++ return result; ++} ++ ++/** ++ * Implements COP_DELETE operation ++ * ++ * Remove pointer to @op -> u.delete.child from it's parent. ++ * This operation is called to delete internal item pointing to the ++ * child node that was removed by carry from the tree on the previous ++ * tree level. * ++ * This function also handles killing of a tree root is last pointer from it ++ * was removed. This is complicated by our handling of "twig" level: root on ++ * twig level is never killed. ++ */ ++static int carry_delete(carry_op *op, carry_level *doing, carry_level *todo) ++{ ++ int result; ++ coord_t coord; ++ coord_t coord2; ++ znode *parent; ++ znode *child; ++ carry_plugin_info info; ++ reiser4_tree *tree; ++ ++ assert("nikita-893", op != NULL); ++ assert("nikita-894", todo != NULL); ++ assert("nikita-895", op->op == COP_DELETE); ++ ++ coord_init_zero(&coord); ++ coord_init_zero(&coord2); ++ ++ parent = reiser4_carry_real(op->node); ++ child = op->u.delete.child ? ++ reiser4_carry_real(op->u.delete.child) : op->node->node; ++ tree = znode_get_tree(child); ++ read_lock_tree(); ++ /* ++ * @parent was determined when carry entered parent level ++ * (lock_carry_level/lock_carry_node). Since then, actual parent of ++ * @child node could change due to other carry operations performed on ++ * the parent level. Check for this. ++ */ ++ if (znode_parent(child) != parent) { ++ /* NOTE-NIKITA add stat counter for this. */ ++ parent = znode_parent(child); ++ assert("nikita-2581", find_carry_node(doing, parent)); ++ } ++ read_unlock_tree(); ++ ++ assert("nikita-1213", znode_get_level(parent) > LEAF_LEVEL); ++ /* ++ * Twig level horrors: tree should be of height at least 2. So, last ++ * pointer from the root at twig level is preserved even if child is ++ * empty. This is ugly, but so it was architectured. ++ */ ++ if (znode_is_root(parent) && ++ znode_get_level(parent) <= REISER4_MIN_TREE_HEIGHT && ++ node_num_items(parent) == 1) { ++ /* Delimiting key manipulations. */ ++ write_lock_dk(tree); ++ znode_set_ld_key(child, znode_set_ld_key(parent, reiser4_min_key())); ++ znode_set_rd_key(child, znode_set_rd_key(parent, reiser4_max_key())); ++ ZF_SET(child, JNODE_DKSET); ++ write_unlock_dk(tree); ++ ++ /* @child escaped imminent death! */ ++ ZF_CLR(child, JNODE_HEARD_BANSHEE); ++ return 0; ++ } ++ /* ++ * construct a coord of the pointer to the child ++ */ ++ result = find_child_ptr(parent, child, &coord); ++ if (result != NS_FOUND) { ++ warning("nikita-994", "Cannot find child pointer: %i", result); ++ print_coord_content("coord", &coord); ++ return result; ++ } ++ coord_dup(&coord2, &coord); ++ info.doing = doing; ++ info.todo = todo; ++ { ++ /* ++ * Actually kill internal item: prepare structure with ++ * arguments for ->cut_and_kill() method... ++ */ ++ struct carry_kill_data kdata; ++ kdata.params.from = &coord; ++ kdata.params.to = &coord2; ++ kdata.params.from_key = NULL; ++ kdata.params.to_key = NULL; ++ kdata.params.smallest_removed = NULL; ++ kdata.params.truncate = 1; ++ kdata.flags = op->u.delete.flags; ++ kdata.inode = NULL; ++ kdata.left = NULL; ++ kdata.right = NULL; ++ kdata.buf = NULL; ++ /* ... and call it. */ ++ result = node_plugin_by_node(parent)->cut_and_kill(&kdata, ++ &info); ++ } ++ doing->restartable = 0; ++ /* ++ * kill the root if needed. ++ * we don't kill roots at and lower than twig level ++ */ ++ if (znode_is_root(parent) && ++ znode_get_level(parent) > REISER4_MIN_TREE_HEIGHT && ++ node_num_items(parent) == 1) ++ result = reiser4_kill_tree_root(coord.node); ++ ++ return result < 0 ? result : 0; ++} ++ ++/* implements COP_CUT opration ++ ++ Cuts part or whole content of node. ++ ++*/ ++static int carry_cut(carry_op * op /* operation to be performed */ , ++ carry_level * doing /* current carry level */ , ++ carry_level * todo/* next carry level */) ++{ ++ int result; ++ carry_plugin_info info; ++ node_plugin *nplug; ++ ++ assert("nikita-896", op != NULL); ++ assert("nikita-897", todo != NULL); ++ assert("nikita-898", op->op == COP_CUT); ++ ++ info.doing = doing; ++ info.todo = todo; ++ ++ nplug = node_plugin_by_node(reiser4_carry_real(op->node)); ++ if (op->u.cut_or_kill.is_cut) ++ result = nplug->cut(op->u.cut_or_kill.u.cut, &info); ++ else ++ result = nplug->cut_and_kill(op->u.cut_or_kill.u.kill, &info); ++ ++ doing->restartable = 0; ++ return result < 0 ? result : 0; ++} ++ ++/** ++ * Helper function for carry_paste(): returns true if @op can be ++ * continued as paste ++ */ ++static int can_paste(coord_t *icoord, const reiser4_key *key, ++ const reiser4_item_data *data) ++{ ++ coord_t circa; ++ item_plugin *new_iplug; ++ item_plugin *old_iplug; ++ int result = 0; /* to keep gcc shut */ ++ ++ assert("", icoord->between != AT_UNIT); ++ ++ /* obviously, one cannot paste when node is empty---there is nothing ++ to paste into. */ ++ if (node_is_empty(icoord->node)) ++ return 0; ++ /* if insertion point is at the middle of the item, then paste */ ++ if (!coord_is_between_items(icoord)) ++ return 1; ++ coord_dup(&circa, icoord); ++ circa.between = AT_UNIT; ++ ++ old_iplug = item_plugin_by_coord(&circa); ++ new_iplug = data->iplug; ++ ++ /* check whether we can paste to the item @icoord is "at" when we ++ ignore ->between field */ ++ if (old_iplug == new_iplug && item_can_contain_key(&circa, key, data)) ++ result = 1; ++ else if (icoord->between == BEFORE_UNIT ++ || icoord->between == BEFORE_ITEM) { ++ /* otherwise, try to glue to the item at the left, if any */ ++ coord_dup(&circa, icoord); ++ if (coord_set_to_left(&circa)) { ++ result = 0; ++ coord_init_before_item(icoord); ++ } else { ++ old_iplug = item_plugin_by_coord(&circa); ++ result = (old_iplug == new_iplug) ++ && item_can_contain_key(icoord, key, data); ++ if (result) { ++ coord_dup(icoord, &circa); ++ icoord->between = AFTER_UNIT; ++ } ++ } ++ } else if (icoord->between == AFTER_UNIT ++ || icoord->between == AFTER_ITEM) { ++ coord_dup(&circa, icoord); ++ /* otherwise, try to glue to the item at the right, if any */ ++ if (coord_set_to_right(&circa)) { ++ result = 0; ++ coord_init_after_item(icoord); ++ } else { ++ int (*cck) (const coord_t *, const reiser4_key *, ++ const reiser4_item_data *); ++ ++ old_iplug = item_plugin_by_coord(&circa); ++ ++ cck = old_iplug->b.can_contain_key; ++ if (cck == NULL) ++ /* item doesn't define ->can_contain_key ++ method? So it is not expandable. */ ++ result = 0; ++ else { ++ result = (old_iplug == new_iplug) ++ && cck(&circa /*icoord */ , key, data); ++ if (result) { ++ coord_dup(icoord, &circa); ++ icoord->between = BEFORE_UNIT; ++ } ++ } ++ } ++ } else ++ impossible("nikita-2513", "Nothing works"); ++ if (result) { ++ if (icoord->between == BEFORE_ITEM) { ++ assert("vs-912", icoord->unit_pos == 0); ++ icoord->between = BEFORE_UNIT; ++ } else if (icoord->between == AFTER_ITEM) { ++ coord_init_after_item_end(icoord); ++ } ++ } ++ return result; ++} ++ ++/* implements COP_PASTE operation ++ ++ Paste data into existing item. This is complicated by the fact that after ++ we shifted something to the left or right neighbors trying to free some ++ space, item we were supposed to paste into can be in different node than ++ insertion coord. If so, we are no longer doing paste, but insert. See ++ comments in insert_paste_common(). ++ ++*/ ++static int carry_paste(carry_op * op /* operation to be performed */ , ++ carry_level * doing UNUSED_ARG /* current carry ++ * level */ , ++ carry_level * todo/* next carry level */) ++{ ++ znode *node; ++ carry_insert_data cdata; ++ coord_t dcoord; ++ reiser4_item_data data; ++ int result; ++ int real_size; ++ item_plugin *iplug; ++ carry_plugin_info info; ++ coord_t *coord; ++ ++ assert("nikita-982", op != NULL); ++ assert("nikita-983", todo != NULL); ++ assert("nikita-984", op->op == COP_PASTE); ++ ++ coord_init_zero(&dcoord); ++ ++ result = insert_paste_common(op, doing, todo, &cdata, &dcoord, &data); ++ if (result != 0) ++ return result; ++ ++ coord = op->u.insert.d->coord; ++ ++ /* handle case when op -> u.insert.coord doesn't point to the item ++ of required type. restart as insert. */ ++ if (!can_paste(coord, op->u.insert.d->key, op->u.insert.d->data)) { ++ op->op = COP_INSERT; ++ op->u.insert.type = COPT_PASTE_RESTARTED; ++ result = op_dispatch_table[COP_INSERT].cop_handler(op, ++ doing, todo); ++ ++ return result; ++ } ++ ++ node = coord->node; ++ iplug = item_plugin_by_coord(coord); ++ assert("nikita-992", iplug != NULL); ++ ++ assert("nikita-985", node != NULL); ++ assert("nikita-986", node_plugin_by_node(node) != NULL); ++ ++ assert("nikita-987", ++ space_needed_for_op(node, op) <= znode_free_space(node)); ++ ++ assert("nikita-1286", coord_is_existing_item(coord)); ++ ++ /* ++ * if item is expanded as a result of this operation, we should first ++ * change item size, than call ->b.paste item method. If item is ++ * shrunk, it should be done other way around: first call ->b.paste ++ * method, then reduce item size. ++ */ ++ ++ real_size = space_needed_for_op(node, op); ++ if (real_size > 0) ++ node->nplug->change_item_size(coord, real_size); ++ ++ doing->restartable = 0; ++ info.doing = doing; ++ info.todo = todo; ++ ++ result = iplug->b.paste(coord, op->u.insert.d->data, &info); ++ ++ if (real_size < 0) ++ node->nplug->change_item_size(coord, real_size); ++ ++ /* if we pasted at the beginning of the item, update item's key. */ ++ if (coord->unit_pos == 0 && coord->between != AFTER_UNIT) ++ node->nplug->update_item_key(coord, op->u.insert.d->key, &info); ++ ++ znode_make_dirty(node); ++ return result; ++} ++ ++/* handle carry COP_EXTENT operation. */ ++static int carry_extent(carry_op * op /* operation to perform */ , ++ carry_level * doing /* queue of operations @op ++ * is part of */ , ++ carry_level * todo /* queue where new operations ++ * are accumulated */ ) ++{ ++ znode *node; ++ carry_insert_data cdata; ++ coord_t coord; ++ reiser4_item_data data; ++ carry_op *delete_dummy; ++ carry_op *insert_extent; ++ int result; ++ carry_plugin_info info; ++ ++ assert("nikita-1751", op != NULL); ++ assert("nikita-1752", todo != NULL); ++ assert("nikita-1753", op->op == COP_EXTENT); ++ ++ /* extent insertion overview: ++ ++ extents live on the TWIG LEVEL, which is level one above the leaf ++ one. This complicates extent insertion logic somewhat: it may ++ happen (and going to happen all the time) that in logical key ++ ordering extent has to be placed between items I1 and I2, located ++ at the leaf level, but I1 and I2 are in the same formatted leaf ++ node N1. To insert extent one has to ++ ++ (1) reach node N1 and shift data between N1, its neighbors and ++ possibly newly allocated nodes until I1 and I2 fall into different ++ nodes. Since I1 and I2 are still neighboring items in logical key ++ order, they will be necessary utmost items in their respective ++ nodes. ++ ++ (2) After this new extent item is inserted into node on the twig ++ level. ++ ++ Fortunately this process can reuse almost all code from standard ++ insertion procedure (viz. make_space() and insert_paste_common()), ++ due to the following observation: make_space() only shifts data up ++ to and excluding or including insertion point. It never ++ "over-moves" through insertion point. Thus, one can use ++ make_space() to perform step (1). All required for this is just to ++ instruct free_space_shortage() to keep make_space() shifting data ++ until insertion point is at the node border. ++ ++ */ ++ ++ /* perform common functionality of insert and paste. */ ++ result = insert_paste_common(op, doing, todo, &cdata, &coord, &data); ++ if (result != 0) ++ return result; ++ ++ node = op->u.extent.d->coord->node; ++ assert("nikita-1754", node != NULL); ++ assert("nikita-1755", node_plugin_by_node(node) != NULL); ++ assert("nikita-1700", coord_wrt(op->u.extent.d->coord) != COORD_INSIDE); ++ ++ /* NOTE-NIKITA add some checks here. Not assertions, -EIO. Check that ++ extent fits between items. */ ++ ++ info.doing = doing; ++ info.todo = todo; ++ ++ /* there is another complication due to placement of extents on the ++ twig level: extents are "rigid" in the sense that key-range ++ occupied by extent cannot grow indefinitely to the right as it is ++ for the formatted leaf nodes. Because of this when search finds two ++ adjacent extents on the twig level, it has to "drill" to the leaf ++ level, creating new node. Here we are removing this node. ++ */ ++ if (node_is_empty(node)) { ++ delete_dummy = node_post_carry(&info, COP_DELETE, node, 1); ++ if (IS_ERR(delete_dummy)) ++ return PTR_ERR(delete_dummy); ++ delete_dummy->u.delete.child = NULL; ++ delete_dummy->u.delete.flags = DELETE_RETAIN_EMPTY; ++ ZF_SET(node, JNODE_HEARD_BANSHEE); ++ } ++ ++ /* proceed with inserting extent item into parent. We are definitely ++ inserting rather than pasting if we get that far. */ ++ insert_extent = node_post_carry(&info, COP_INSERT, node, 1); ++ if (IS_ERR(insert_extent)) ++ /* @delete_dummy will be automatically destroyed on the level ++ exiting */ ++ return PTR_ERR(insert_extent); ++ /* NOTE-NIKITA insertion by key is simplest option here. Another ++ possibility is to insert on the left or right of already existing ++ item. ++ */ ++ insert_extent->u.insert.type = COPT_KEY; ++ insert_extent->u.insert.d = op->u.extent.d; ++ assert("nikita-1719", op->u.extent.d->key != NULL); ++ insert_extent->u.insert.d->data->arg = op->u.extent.d->coord; ++ insert_extent->u.insert.flags = ++ znode_get_tree(node)->carry.new_extent_flags; ++ ++ /* ++ * if carry was asked to track lock handle we should actually track ++ * lock handle on the twig node rather than on the leaf where ++ * operation was started from. Transfer tracked lock handle. ++ */ ++ if (doing->track_type) { ++ assert("nikita-3242", doing->tracked != NULL); ++ assert("nikita-3244", todo->tracked == NULL); ++ todo->tracked = doing->tracked; ++ todo->track_type = CARRY_TRACK_NODE; ++ doing->tracked = NULL; ++ doing->track_type = 0; ++ } ++ ++ return 0; ++} ++ ++/* update key in @parent between pointers to @left and @right. ++ ++ Find coords of @left and @right and update delimiting key between them. ++ This is helper function called by carry_update(). Finds position of ++ internal item involved. Updates item key. Updates delimiting keys of child ++ nodes involved. ++*/ ++static int update_delimiting_key(znode * parent /* node key is updated ++ * in */ , ++ znode * left /* child of @parent */ , ++ znode * right /* child of @parent */ , ++ carry_level * doing /* current carry ++ * level */ , ++ carry_level * todo /* parent carry ++ * level */ , ++ const char **error_msg /* place to ++ * store error ++ * message */ ) ++{ ++ coord_t left_pos; ++ coord_t right_pos; ++ int result; ++ reiser4_key ldkey; ++ carry_plugin_info info; ++ ++ assert("nikita-1177", right != NULL); ++ /* find position of right left child in a parent */ ++ result = find_child_ptr(parent, right, &right_pos); ++ if (result != NS_FOUND) { ++ *error_msg = "Cannot find position of right child"; ++ return result; ++ } ++ ++ if ((left != NULL) && !coord_is_leftmost_unit(&right_pos)) { ++ /* find position of the left child in a parent */ ++ result = find_child_ptr(parent, left, &left_pos); ++ if (result != NS_FOUND) { ++ *error_msg = "Cannot find position of left child"; ++ return result; ++ } ++ assert("nikita-1355", left_pos.node != NULL); ++ } else ++ left_pos.node = NULL; ++ ++ /* check that they are separated by exactly one key and are basically ++ sane */ ++ if (REISER4_DEBUG) { ++ if ((left_pos.node != NULL) ++ && !coord_is_existing_unit(&left_pos)) { ++ *error_msg = "Left child is bastard"; ++ return RETERR(-EIO); ++ } ++ if (!coord_is_existing_unit(&right_pos)) { ++ *error_msg = "Right child is bastard"; ++ return RETERR(-EIO); ++ } ++ if (left_pos.node != NULL && ++ !coord_are_neighbors(&left_pos, &right_pos)) { ++ *error_msg = "Children are not direct siblings"; ++ return RETERR(-EIO); ++ } ++ } ++ *error_msg = NULL; ++ ++ info.doing = doing; ++ info.todo = todo; ++ ++ /* ++ * If child node is not empty, new key of internal item is a key of ++ * leftmost item in the child node. If the child is empty, take its ++ * right delimiting key as a new key of the internal item. Precise key ++ * in the latter case is not important per se, because the child (and ++ * the internal item) are going to be killed shortly anyway, but we ++ * have to preserve correct order of keys in the parent node. ++ */ ++ ++ if (!ZF_ISSET(right, JNODE_HEARD_BANSHEE)) ++ leftmost_key_in_node(right, &ldkey); ++ else { ++ read_lock_dk(znode_get_tree(parent)); ++ ldkey = *znode_get_rd_key(right); ++ read_unlock_dk(znode_get_tree(parent)); ++ } ++ node_plugin_by_node(parent)->update_item_key(&right_pos, &ldkey, &info); ++ doing->restartable = 0; ++ znode_make_dirty(parent); ++ return 0; ++} ++ ++/* implements COP_UPDATE opration ++ ++ Update delimiting keys. ++ ++*/ ++static int carry_update(carry_op * op /* operation to be performed */ , ++ carry_level * doing /* current carry level */ , ++ carry_level * todo/* next carry level */) ++{ ++ int result; ++ carry_node *missing UNUSED_ARG; ++ znode *left; ++ znode *right; ++ carry_node *lchild; ++ carry_node *rchild; ++ const char *error_msg; ++ reiser4_tree *tree; ++ ++ /* ++ * This operation is called to update key of internal item. This is ++ * necessary when carry shifted of cut data on the child ++ * level. Arguments of this operation are: ++ * ++ * @right --- child node. Operation should update key of internal ++ * item pointing to @right. ++ * ++ * @left --- left neighbor of @right. This parameter is optional. ++ */ ++ ++ assert("nikita-902", op != NULL); ++ assert("nikita-903", todo != NULL); ++ assert("nikita-904", op->op == COP_UPDATE); ++ ++ lchild = op->u.update.left; ++ rchild = op->node; ++ ++ if (lchild != NULL) { ++ assert("nikita-1001", lchild->parent); ++ assert("nikita-1003", !lchild->left); ++ left = reiser4_carry_real(lchild); ++ } else ++ left = NULL; ++ ++ tree = znode_get_tree(rchild->node); ++ read_lock_tree(); ++ right = znode_parent(rchild->node); ++ read_unlock_tree(); ++ ++ if (right != NULL) { ++ result = update_delimiting_key(right, ++ lchild ? lchild->node : NULL, ++ rchild->node, ++ doing, todo, &error_msg); ++ } else { ++ error_msg = "Cannot find node to update key in"; ++ result = RETERR(-EIO); ++ } ++ /* operation will be reposted to the next level by the ++ ->update_item_key() method of node plugin, if necessary. */ ++ ++ if (result != 0) { ++ warning("nikita-999", "Error updating delimiting key: %s (%i)", ++ error_msg ? : "", result); ++ } ++ return result; ++} ++ ++/* move items from @node during carry */ ++static int carry_shift_data(sideof side /* in what direction to move data */ , ++ coord_t *insert_coord /* coord where new item ++ * is to be inserted */, ++ znode * node /* node which data are moved from */ , ++ carry_level * doing /* active carry queue */ , ++ carry_level * todo /* carry queue where new ++ * operations are to be put ++ * in */ , ++ unsigned int including_insert_coord_p ++ /* true if @insertion_coord can be moved */ ) ++{ ++ int result; ++ znode *source; ++ carry_plugin_info info; ++ node_plugin *nplug; ++ ++ source = insert_coord->node; ++ ++ info.doing = doing; ++ info.todo = todo; ++ ++ nplug = node_plugin_by_node(node); ++ result = nplug->shift(insert_coord, node, ++ (side == LEFT_SIDE) ? SHIFT_LEFT : SHIFT_RIGHT, 0, ++ (int)including_insert_coord_p, &info); ++ /* the only error ->shift() method of node plugin can return is ++ -ENOMEM due to carry node/operation allocation. */ ++ assert("nikita-915", result >= 0 || result == -ENOMEM); ++ if (result > 0) { ++ /* ++ * if some number of bytes was actually shifted, mark nodes ++ * dirty, and carry level as non-restartable. ++ */ ++ doing->restartable = 0; ++ znode_make_dirty(source); ++ znode_make_dirty(node); ++ } ++ ++ assert("nikita-2077", coord_check(insert_coord)); ++ return 0; ++} ++ ++typedef carry_node *(*carry_iterator) (carry_node * node); ++static carry_node *find_dir_carry(carry_node * node, carry_level * level, ++ carry_iterator iterator); ++ ++static carry_node *pool_level_list_prev(carry_node *node) ++{ ++ return list_entry(node->header.level_linkage.prev, carry_node, header.level_linkage); ++} ++ ++/* look for the left neighbor of given carry node in a carry queue. ++ ++ This is used by find_left_neighbor(), but I am not sure that this ++ really gives any advantage. More statistics required. ++ ++*/ ++carry_node *find_left_carry(carry_node * node /* node to find left neighbor ++ * of */ , ++ carry_level * level/* level to scan */) ++{ ++ return find_dir_carry(node, level, ++ (carry_iterator) pool_level_list_prev); ++} ++ ++static carry_node *pool_level_list_next(carry_node *node) ++{ ++ return list_entry(node->header.level_linkage.next, carry_node, header.level_linkage); ++} ++ ++/* look for the right neighbor of given carry node in a ++ carry queue. ++ ++ This is used by find_right_neighbor(), but I am not sure that this ++ really gives any advantage. More statistics required. ++ ++*/ ++carry_node *find_right_carry(carry_node * node /* node to find right neighbor ++ * of */ , ++ carry_level * level/* level to scan */) ++{ ++ return find_dir_carry(node, level, ++ (carry_iterator) pool_level_list_next); ++} ++ ++/* look for the left or right neighbor of given carry node in a carry ++ queue. ++ ++ Helper function used by find_{left|right}_carry(). ++*/ ++static carry_node *find_dir_carry(carry_node * node /* node to start ++ * scanning from */ , ++ carry_level * level /* level to scan */ , ++ carry_iterator iterator /* operation to ++ * move to the ++ * next node */) ++{ ++ carry_node *neighbor; ++ ++ assert("nikita-1059", node != NULL); ++ assert("nikita-1060", level != NULL); ++ ++ /* scan list of carry nodes on this list dir-ward, skipping all ++ carry nodes referencing the same znode. */ ++ neighbor = node; ++ while (1) { ++ neighbor = iterator(neighbor); ++ if (carry_node_end(level, neighbor)) ++ /* list head is reached */ ++ return NULL; ++ if (reiser4_carry_real(neighbor) != reiser4_carry_real(node)) ++ return neighbor; ++ } ++} ++ ++/* ++ * Memory reservation estimation. ++ * ++ * Carry process proceeds through tree levels upwards. Carry assumes that it ++ * takes tree in consistent state (e.g., that search tree invariants hold), ++ * and leaves tree consistent after it finishes. This means that when some ++ * error occurs carry cannot simply return if there are pending carry ++ * operations. Generic solution for this problem is carry-undo either as ++ * transaction manager feature (requiring checkpoints and isolation), or ++ * through some carry specific mechanism. ++ * ++ * Our current approach is to panic if carry hits an error while tree is ++ * inconsistent. Unfortunately -ENOMEM can easily be triggered. To work around ++ * this "memory reservation" mechanism was added. ++ * ++ * Memory reservation is implemented by perthread-pages.diff patch from ++ * core-patches. Its API is defined in ++ * ++ * int perthread_pages_reserve(int nrpages, gfp_t gfp); ++ * void perthread_pages_release(int nrpages); ++ * int perthread_pages_count(void); ++ * ++ * carry estimates its worst case memory requirements at the entry, reserved ++ * enough memory, and released unused pages before returning. ++ * ++ * Code below estimates worst case memory requirements for a given carry ++ * queue. This is dome by summing worst case memory requirements for each ++ * operation in the queue. ++ * ++ */ ++ ++/* ++ * Memory memory requirements of many operations depends on the tree ++ * height. For example, item insertion requires new node to be inserted at ++ * each tree level in the worst case. What tree height should be used for ++ * estimation? Current tree height is wrong, because tree height can change ++ * between the time when estimation was done and the time when operation is ++ * actually performed. Maximal possible tree height (REISER4_MAX_ZTREE_HEIGHT) ++ * is also not desirable, because it would lead to the huge over-estimation ++ * all the time. Plausible solution is "capped tree height": if current tree ++ * height is less than some TREE_HEIGHT_CAP constant, capped tree height is ++ * TREE_HEIGHT_CAP, otherwise it's current tree height. Idea behind this is ++ * that if tree height is TREE_HEIGHT_CAP or larger, it's extremely unlikely ++ * to be increased even more during short interval of time. ++ */ ++#define TREE_HEIGHT_CAP (5) ++ ++/* return capped tree height for the @tree. See comment above. */ ++static int cap_tree_height(reiser4_tree * tree) ++{ ++ return max_t(int, tree->height, TREE_HEIGHT_CAP); ++} ++ ++/* return capped tree height for the current tree. */ ++static int capped_height(reiser4_tree *tree) ++{ ++ return cap_tree_height(tree); ++} ++ ++/* return number of pages required to store given number of bytes */ ++static int bytes_to_pages(int bytes) ++{ ++ return (bytes + PAGE_SIZE - 1) >> PAGE_SHIFT; ++} ++ ++/* how many pages are required to allocate znodes during item insertion. */ ++static int carry_estimate_znodes(reiser4_tree *tree) ++{ ++ /* ++ * Note, that there we have some problem here: there is no way to ++ * reserve pages specifically for the given slab. This means that ++ * these pages can be hijacked for some other end. ++ */ ++ ++ /* in the worst case we need 3 new znode on each tree level */ ++ return bytes_to_pages(capped_height(tree) * sizeof(znode) * 3); ++} ++ ++/* ++ * how many pages are required to load bitmaps. One bitmap per level. ++ */ ++static int carry_estimate_bitmaps(reiser4_tree *tree) ++{ ++ if (reiser4_is_set(reiser4_get_current_sb(), REISER4_DONT_LOAD_BITMAP)) { ++ int bytes; ++ ++ bytes = capped_height(tree) * (0 + /* bnode should be added, but ++ * it is private to bitmap.c, ++ * skip for now. */ ++ 2 * sizeof(jnode)); ++ /* working and commit jnodes */ ++ return bytes_to_pages(bytes) + 2; /* and their contents */ ++ } else ++ /* bitmaps were pre-loaded during mount */ ++ return 0; ++} ++ ++/* worst case item insertion memory requirements */ ++static int carry_estimate_insert(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ return carry_estimate_bitmaps(tree) ++ + carry_estimate_znodes(tree) ++ + 1 /* new atom */ ++ + capped_height(tree) /* new block on each level */ ++ + 1 /* possibly extra new block at the leaf level */ ++ + 3; /* loading of leaves into memory */ ++} ++ ++/* worst case item deletion memory requirements */ ++static int carry_estimate_delete(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ return carry_estimate_bitmaps(tree) ++ + carry_estimate_znodes(tree) ++ + 1 /* new atom */ ++ + 3; /* loading of leaves into memory */ ++} ++ ++/* worst case tree cut memory requirements */ ++static int carry_estimate_cut(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ return carry_estimate_bitmaps(tree) ++ + carry_estimate_znodes(tree) ++ + 1 /* new atom */ ++ + 3;/* loading of leaves into memory */ ++} ++ ++/* worst case memory requirements of pasting into item */ ++static int carry_estimate_paste(carry_op * op, carry_level * level, ++ reiser4_tree *tree) ++{ ++ return carry_estimate_bitmaps(tree) ++ + carry_estimate_znodes(tree) ++ + 1 /* new atom */ ++ + capped_height(tree) /* new block on each level */ ++ + 1 /* possibly extra new block at the leaf level */ ++ + 3; /* loading of leaves into memory */ ++} ++ ++/* worst case memory requirements of extent insertion */ ++static int carry_estimate_extent(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ return carry_estimate_insert(op, level, tree) /* insert extent */ ++ + carry_estimate_delete(op, level, tree); /* kill leaf */ ++} ++ ++/* worst case memory requirements of key update */ ++static int carry_estimate_update(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ return 0; ++} ++ ++/* worst case memory requirements of flow insertion */ ++static int carry_estimate_insert_flow(carry_op *op, carry_level *level, ++ reiser4_tree *tree) ++{ ++ int newnodes; ++ ++ newnodes = min(bytes_to_pages(op->u.insert_flow.flow->length), ++ CARRY_FLOW_NEW_NODES_LIMIT); ++ /* ++ * roughly estimate insert_flow as a sequence of insertions. ++ */ ++ return newnodes * carry_estimate_insert(op, level, tree); ++} ++ ++/* This is dispatch table for carry operations. It can be trivially ++ abstracted into useful plugin: tunable balancing policy is a good ++ thing. */ ++carry_op_handler op_dispatch_table[COP_LAST_OP] = { ++ [COP_INSERT] = { ++ .cop_handler = carry_insert, ++ .cop_estimate = carry_estimate_insert} ++ , ++ [COP_DELETE] = { ++ .cop_handler = carry_delete, ++ .cop_estimate = carry_estimate_delete} ++ , ++ [COP_CUT] = { ++ .cop_handler = carry_cut, ++ .cop_estimate = carry_estimate_cut} ++ , ++ [COP_PASTE] = { ++ .cop_handler = carry_paste, ++ .cop_estimate = carry_estimate_paste} ++ , ++ [COP_EXTENT] = { ++ .cop_handler = carry_extent, ++ .cop_estimate = carry_estimate_extent} ++ , ++ [COP_UPDATE] = { ++ .cop_handler = carry_update, ++ .cop_estimate = carry_estimate_update} ++ , ++ [COP_INSERT_FLOW] = { ++ .cop_handler = carry_insert_flow, ++ .cop_estimate = carry_estimate_insert_flow} ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/carry_ops.h linux-5.10.2/fs/reiser4/carry_ops.h +--- linux-5.10.2.orig/fs/reiser4/carry_ops.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/carry_ops.h 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,45 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* implementation of carry operations. See carry_ops.c for details. */ ++ ++#if !defined(__CARRY_OPS_H__) ++#define __CARRY_OPS_H__ ++ ++#include "forward.h" ++#include "znode.h" ++#include "carry.h" ++ ++/* carry operation handlers */ ++typedef struct carry_op_handler { ++ /* perform operation */ ++ int (*cop_handler)(carry_op *op, carry_level *doing, ++ carry_level *todo); ++ /* estimate memory requirements for @op */ ++ int (*cop_estimate)(carry_op *op, carry_level *level, ++ reiser4_tree *tree); ++} carry_op_handler; ++ ++/* This is dispatch table for carry operations. It can be trivially ++ abstracted into useful plugin: tunable balancing policy is a good ++ thing. */ ++extern carry_op_handler op_dispatch_table[COP_LAST_OP]; ++ ++unsigned int space_needed(const znode * node, const coord_t *coord, ++ const reiser4_item_data * data, int inserting); ++extern carry_node *find_left_carry(carry_node * node, carry_level * level); ++extern carry_node *find_right_carry(carry_node * node, carry_level * level); ++ ++/* __CARRY_OPS_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/checksum.c linux-5.10.2/fs/reiser4/checksum.c +--- linux-5.10.2.orig/fs/reiser4/checksum.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/checksum.c 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,33 @@ ++#include ++#include "debug.h" ++#include "checksum.h" ++ ++int reiser4_init_csum_tfm(struct crypto_shash **tfm) ++{ ++ struct crypto_shash *new_tfm; ++ ++ new_tfm = crypto_alloc_shash("crc32c", 0, 0); ++ if (IS_ERR(new_tfm)) { ++ warning("intelfx-81", "Could not load crc32c driver"); ++ return PTR_ERR(new_tfm); ++ } ++ ++ *tfm = new_tfm; ++ return 0; ++} ++ ++void reiser4_done_csum_tfm(struct crypto_shash *tfm) ++{ ++ crypto_free_shash(tfm); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/checksum.h linux-5.10.2/fs/reiser4/checksum.h +--- linux-5.10.2.orig/fs/reiser4/checksum.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/checksum.h 2020-12-23 16:07:46.114813070 +0100 +@@ -0,0 +1,38 @@ ++#ifndef __CHECKSUM__ ++#define __CHECKSUM__ ++ ++#include ++ ++int reiser4_init_csum_tfm(struct crypto_shash **tfm); ++void reiser4_done_csum_tfm(struct crypto_shash *tfm); ++u32 static inline reiser4_crc32c(struct crypto_shash *tfm, ++ u32 crc, const void *address, ++ unsigned int length) ++{ ++ struct { ++ struct shash_desc shash; ++ char ctx[4]; ++ } desc; ++ int err; ++ ++ desc.shash.tfm = tfm; ++ *(u32 *)desc.ctx = crc; ++ ++ err = crypto_shash_update(&desc.shash, address, length); ++ BUG_ON(err); ++ return *(u32 *)desc.ctx; ++} ++ ++#endif /* __CHECKSUM__ */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ ++ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/context.c linux-5.10.2/fs/reiser4/context.c +--- linux-5.10.2.orig/fs/reiser4/context.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/context.c 2020-12-23 16:08:55.164816614 +0100 +@@ -0,0 +1,403 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Manipulation of reiser4_context */ ++ ++/* ++ * global context used during system call. Variable of this type is allocated ++ * on the stack at the beginning of the reiser4 part of the system call and ++ * pointer to it is stored in the current->fs_context. This allows us to avoid ++ * passing pointer to current transaction and current lockstack (both in ++ * one-to-one mapping with threads) all over the call chain. ++ * ++ * It's kind of like those global variables the prof used to tell you not to ++ * use in CS1, except thread specific.;-) Nikita, this was a good idea. ++ * ++ * In some situations it is desirable to have ability to enter reiser4_context ++ * more than once for the same thread (nested contexts). For example, there ++ * are some functions that can be called either directly from VFS/VM or from ++ * already active reiser4 context (->writepage, for example). ++ * ++ * In such situations "child" context acts like dummy: all activity is ++ * actually performed in the top level context, and get_current_context() ++ * always returns top level context. ++ * Of course, reiser4_init_context()/reiser4_done_context() have to be properly ++ * nested any way. ++ * Note that there is an important difference between reiser4 uses ++ * ->fs_context and the way other file systems use it. Other file systems ++ * (ext3 and reiserfs) use ->fs_context only for the duration of _transaction_ ++ * (this is why ->fs_context was initially called ->journal_info). This means, ++ * that when ext3 or reiserfs finds that ->fs_context is not NULL on the entry ++ * to the file system, they assume that some transaction is already underway, ++ * and usually bail out, because starting nested transaction would most likely ++ * lead to the deadlock. This gives false positives with reiser4, because we ++ * set ->fs_context before starting transaction. ++ */ ++ ++#include "debug.h" ++#include "super.h" ++#include "context.h" ++#include "vfs_ops.h" /* for reiser4_throttle_write() */ ++#include "plugin/volume/volume.h" /* for METADATA_SUBVOL_ID */ ++ ++#include /* for current_is_pdflush() */ ++#include ++ ++/************************ context brick info ************************/ ++ ++static struct kmem_cache *cbi_slab = NULL; ++ ++int ctx_brick_info_init_static(void) ++{ ++ assert("edward-1978", cbi_slab == NULL); ++ ++ cbi_slab = kmem_cache_create("ctx_brick_info", ++ sizeof(struct ctx_brick_info), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, ++ NULL); ++ if (cbi_slab == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++void ctx_brick_info_done_static(void) ++{ ++ destroy_reiser4_cache(&cbi_slab); ++} ++ ++struct ctx_brick_info *alloc_context_brick_info(void) ++{ ++ return kmem_cache_alloc(cbi_slab, reiser4_ctx_gfp_mask_get()); ++} ++ ++void free_context_brick_info(struct ctx_brick_info *cbi) ++{ ++ assert("edward-1979", cbi != NULL); ++ ++ kmem_cache_free(cbi_slab, cbi); ++} ++ ++struct ctx_brick_info *find_context_brick_info(reiser4_context *ctx, ++ u32 brick_id) ++{ ++ struct rb_root *root = &ctx->bricks_info; ++ struct rb_node *node = root->rb_node; ++ ++ while (node) { ++ struct ctx_brick_info *cbi = ++ rb_entry(node, struct ctx_brick_info, node); ++ ++ if (cbi->brick_id > brick_id) ++ node = node->rb_left; ++ else if (cbi->brick_id < brick_id) ++ node = node->rb_right; ++ else ++ return cbi; ++ } ++ return NULL; ++} ++ ++int insert_context_brick_info(reiser4_context *ctx, ++ struct ctx_brick_info *this) ++{ ++ struct rb_root *root = &ctx->bricks_info; ++ struct rb_node *parent = NULL; ++ struct rb_node **new = &(root->rb_node); ++ ++ while (*new) { ++ struct ctx_brick_info *cbi; ++ ++ cbi = rb_entry(*new, struct ctx_brick_info, node); ++ parent = *new; ++ ++ if (this->brick_id < cbi->brick_id) ++ new = &((*new)->rb_left); ++ else if (this->brick_id > cbi->brick_id) ++ new = &((*new)->rb_right); ++ else ++ return -EEXIST; ++ } ++ rb_link_node(&this->node, parent, new); ++ rb_insert_color(&this->node, root); ++ ++ return 0; ++} ++ ++static void done_bricks_info(reiser4_context *ctx) ++{ ++ struct rb_root *root; ++ ++ root = &ctx->bricks_info; ++ ++ /* ++ * remove pre-allocated info ++ */ ++ rb_erase(&ctx->mcbi.node, root); ++ RB_CLEAR_NODE(&ctx->mcbi.node); ++ ++ while (!RB_EMPTY_ROOT(root)) { ++ struct rb_node *node; ++ struct ctx_brick_info *cbi; ++ ++ node = rb_first(root); ++ cbi = rb_entry(node, struct ctx_brick_info, node); ++ ++ assert("edward-1980", cbi->grabbed_blocks == 0); ++ ++ rb_erase(&cbi->node, root); ++ RB_CLEAR_NODE(&cbi->node); ++ free_context_brick_info(cbi); ++ } ++} ++ ++static void _reiser4_init_context(reiser4_context *context, ++ struct super_block *super) ++{ ++ context->super = super; ++ context->magic = context_magic; ++ context->outer = current->journal_info; ++ current->journal_info = (void *)context; ++ context->nr_children = 0; ++ context->gfp_mask = GFP_KERNEL; ++ /* ++ * init set of per-brick info and populate it ++ * with pree-allocated item for meta-data brick ++ */ ++ context->bricks_info = RB_ROOT; ++ init_context_brick_info(&context->mcbi, METADATA_SUBVOL_ID); ++ insert_context_brick_info(context, &context->mcbi); ++ ++ init_lock_stack(&context->stack); ++ ++ reiser4_txn_begin(context); ++ ++ /* initialize head of tap list */ ++ INIT_LIST_HEAD(&context->taps); ++#if REISER4_DEBUG ++ context->task = current; ++#endif ++ grab_space_enable(); ++} ++ ++/** ++ * initialize context and bind it to the current thread ++ * This function should be called at the beginning of reiser4 part of syscall. ++ */ ++reiser4_context *reiser4_init_context(struct super_block *super) ++{ ++ reiser4_context *context; ++ ++ assert("nikita-2662", !in_interrupt() && !in_irq()); ++ assert("nikita-3357", super != NULL); ++ assert("nikita-3358", super->s_op == NULL || is_reiser4_super(super)); ++ ++ context = get_current_context_check(); ++ if (context && context->super == super) { ++ context = (reiser4_context *) current->journal_info; ++ context->nr_children++; ++ return context; ++ } ++ context = kzalloc(sizeof(*context), GFP_KERNEL); ++ if (context == NULL) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ _reiser4_init_context(context, super); ++ return context; ++} ++ ++/** ++ * This is used in scan_mgr which is called with spinlock held and in ++ * reiser4_fill_super magic. ++ */ ++void init_stack_context(reiser4_context *context, struct super_block *super) ++{ ++ assert("nikita-2662", !in_interrupt() && !in_irq()); ++ assert("nikita-3357", super != NULL); ++ assert("nikita-3358", super->s_op == NULL || is_reiser4_super(super)); ++ assert("vs-12", !is_in_reiser4_context()); ++ ++ memset(context, 0, sizeof(*context)); ++ context->on_stack = 1; ++ _reiser4_init_context(context, super); ++} ++ ++/* cast lock stack embedded into reiser4 context up to its container */ ++reiser4_context *get_context_by_lock_stack(lock_stack * owner) ++{ ++ return container_of(owner, reiser4_context, stack); ++} ++ ++/* true if there is already _any_ reiser4 context for the current thread */ ++int is_in_reiser4_context(void) ++{ ++ reiser4_context *ctx; ++ ++ ctx = current->journal_info; ++ return ctx != NULL && ((unsigned long)ctx->magic) == context_magic; ++} ++ ++/* ++ * call balance dirty pages for the current context. ++ * ++ * File system is expected to call balance_dirty_pages_ratelimited() whenever ++ * it dirties a page. reiser4 does this for unformatted nodes (that is, during ++ * write---this covers vast majority of all dirty traffic), but we cannot do ++ * this immediately when formatted node is dirtied, because long term lock is ++ * usually held at that time. To work around this, dirtying of formatted node ++ * simply increases ->nr_marked_dirty counter in the current reiser4 ++ * context. When we are about to leave this context, ++ * balance_dirty_pages_ratelimited() is called, if necessary. ++ * ++ * This introduces another problem: sometimes we do not want to run ++ * balance_dirty_pages_ratelimited() when leaving a context, for example ++ * because some important lock (like ->i_mutex on the parent directory) is ++ * held. To achieve this, ->nobalance flag can be set in the current context. ++ */ ++static void reiser4_throttle_write_at(reiser4_context *context) ++{ ++ reiser4_super_info_data *sbinfo = get_super_private(context->super); ++ ++ /* ++ * call balance_dirty_pages_ratelimited() to process formatted nodes ++ * dirtied during this system call. Do that only if we are not in mount ++ * and there were nodes dirtied in this context and we are not in ++ * writepage (to avoid deadlock) and not in pdflush ++ */ ++ if (sbinfo != NULL && sbinfo->fake != NULL && ++ context->nr_marked_dirty != 0 && ++ !(current->flags & PF_MEMALLOC) && ++ !context->flush_bd_task) ++ reiser4_throttle_write(sbinfo->fake); ++} ++ ++/* release resources associated with context. ++ ++ This function should be called at the end of "session" with reiser4, ++ typically just before leaving reiser4 driver back to VFS. ++ ++ This is good place to put some degugging consistency checks, like that ++ thread released all locks and closed transcrash etc. ++ ++*/ ++static void reiser4_done_context(reiser4_context * context) ++ /* context being released */ ++{ ++ assert("nikita-860", context != NULL); ++ assert("nikita-859", context->magic == context_magic); ++ assert("vs-646", (reiser4_context *) current->journal_info == context); ++ assert("zam-686", !in_interrupt() && !in_irq()); ++ ++ /* only do anything when leaving top-level reiser4 context. All nested ++ * contexts are just dummies. */ ++ if (context->nr_children == 0) { ++ assert("jmacd-673", context->trans == NULL); ++ assert("jmacd-1002", lock_stack_isclean(&context->stack)); ++ assert("nikita-1936", reiser4_no_counters_are_held()); ++ assert("nikita-2626", list_empty_careful(reiser4_taps_list())); ++ assert("zam-1004", ergo(get_super_private(context->super), ++ get_super_private(context->super)->delete_mutex_owner != ++ current)); ++ /* ++ * release all grabbed but as yet unused blocks ++ */ ++ all_grabbed2free(); ++ /* ++ * synchronize against longterm_unlock_znode(): ++ * wake_up_requestor() wakes up requestors without holding ++ * zlock (otherwise they will immediately bump into that lock ++ * after wake up on another CPU). To work around (rare) ++ * situation where requestor has been woken up asynchronously ++ * and managed to run until completion (and destroy its ++ * context and lock stack) before wake_up_requestor() called ++ * wake_up() on it, wake_up_requestor() synchronize on lock ++ * stack spin lock. It has actually been observed that spin ++ * lock _was_ locked at this point, because ++ * wake_up_requestor() took interrupt. ++ */ ++ spin_lock_stack(&context->stack); ++ spin_unlock_stack(&context->stack); ++ ++ assert("zam-684", context->nr_children == 0); ++ /* ++ * restore original ->fs_context value ++ */ ++ current->journal_info = context->outer; ++ done_bricks_info(context); ++ if (context->on_stack == 0) ++ kfree(context); ++ } else { ++ context->nr_children--; ++#if REISER4_DEBUG ++ assert("zam-685", context->nr_children >= 0); ++#endif ++ } ++} ++ ++/* ++ * exit reiser4 context. Call balance_dirty_pages_at() if necessary. Close ++ * transaction. Call done_context() to do context related book-keeping. ++ */ ++void reiser4_exit_context(reiser4_context * context) ++{ ++ assert("nikita-3021", reiser4_schedulable()); ++ ++ if (context->nr_children == 0) { ++ if (!context->nobalance) ++ reiser4_throttle_write_at(context); ++ ++ /* if filesystem is mounted with -o sync or -o dirsync - commit ++ transaction. FIXME: TXNH_DONT_COMMIT is used to avoid ++ commiting on exit_context when inode semaphore is held and ++ to have ktxnmgrd to do commit instead to get better ++ concurrent filesystem accesses. But, when one mounts with -o ++ sync, he cares more about reliability than about ++ performance. So, for now we have this simple mount -o sync ++ support. */ ++ if (context->super->s_flags & (SB_SYNCHRONOUS | SB_DIRSYNC)) { ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked_nocheck(); ++ if (atom) { ++ atom->flags |= ATOM_FORCE_COMMIT; ++ context->trans->flags &= ~TXNH_DONT_COMMIT; ++ spin_unlock_atom(atom); ++ } ++ } ++ reiser4_txn_end(context); ++ } ++ reiser4_done_context(context); ++} ++ ++void reiser4_ctx_gfp_mask_set(void) ++{ ++ reiser4_context *ctx; ++ ++ ctx = get_current_context(); ++ if (ctx->entd == 0 && ++ list_empty(&ctx->stack.locks) && ++ ctx->trans->atom == NULL) ++ ctx->gfp_mask = GFP_KERNEL; ++ else ++ ctx->gfp_mask = GFP_NOFS; ++} ++ ++void reiser4_ctx_gfp_mask_force(gfp_t mask) ++{ ++ reiser4_context *ctx; ++ ctx = get_current_context(); ++ ++ assert("edward-1454", ctx != NULL); ++ ++ ctx->gfp_mask = mask; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/context.h linux-5.10.2/fs/reiser4/context.h +--- linux-5.10.2.orig/fs/reiser4/context.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/context.h 2020-12-23 16:08:55.164816614 +0100 +@@ -0,0 +1,277 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Reiser4 context. See context.c for details. */ ++ ++#if !defined( __REISER4_CONTEXT_H__ ) ++#define __REISER4_CONTEXT_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "tap.h" ++#include "lock.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block */ ++#include ++#include /* for struct task_struct */ ++#include ++ ++/* ++ * Info specific for a child (stack element) ++ */ ++struct ctx_stack_info { ++ struct ctx_stack_info *next; /* pointer to the next element ++ in the stack */ ++ reiser4_subvol *data_subv; /* This is a hint for update_extents(s). ++ Set by set_current_data_subvol(). ++ Check by validate_data_reservation(). ++ Unset by clear_current_data_subvol() ++ as soon as it is not needed. ++ */ ++ /* put here other info specific for reiser4 context nesting level */ ++}; ++ ++/* ++ * Brick-specific part of context ++ */ ++struct ctx_brick_info { ++ struct rb_node node; ++ u32 brick_id; /* key */ ++ reiser4_block_nr grabbed_blocks; ++}; ++ ++/* reiser4 per-thread context */ ++struct reiser4_context { ++ /* magic constant. For identification of reiser4 contexts. */ ++ __u32 magic; ++ ++ /* current lock stack. See lock.[ch]. This is where list of all ++ locks taken by current thread is kept. This is also used in ++ deadlock detection. */ ++ lock_stack stack; ++ ++ /* current transcrash. */ ++ txn_handle *trans; ++ /* transaction handle embedded into reiser4_context. ->trans points ++ * here by default. */ ++ txn_handle trans_in_ctx; ++ ++ /* super block we are working with */ ++ struct super_block *super; ++ ++ /* parent fs activation */ ++ struct fs_activation *outer; ++ ++ /* brick-specific parts of the context for all the bricks which ++ participate in the transaction. Sorted by internal brick ID */ ++ struct rb_root bricks_info; ++ struct ctx_brick_info mcbi; /* pre-allocated meta-brick info */ ++ ++ /* list of taps currently monitored. See tap.c */ ++ struct list_head taps; ++ ++ /* grabbing space is enabled */ ++ unsigned int grab_enabled:1; ++ /* should be set when we are write dirty nodes to disk in jnode_flush or ++ * reiser4_write_logs() */ ++ unsigned int writeout_mode:1; ++ /* true, if current thread is an ent thread */ ++ unsigned int entd:1; ++ /* true, if balance_dirty_pages() should not be run when leaving this ++ * context. This is used to avoid lengthly balance_dirty_pages() ++ * operation when holding some important resource, like directory ++ * ->i_mutex */ ++ unsigned int nobalance:1; ++ /* this bit is used on reiser4_done_context to decide whether context is ++ kmalloc-ed and has to be kfree-ed */ ++ unsigned int on_stack:1; ++ /* file system is read-only */ ++ unsigned int ro:1; ++ /* replacement of PF_FLUSHER */ ++ unsigned int flush_bd_task:1; ++ ++ /* count non-trivial jnode_set_dirty() calls */ ++ unsigned long nr_marked_dirty; ++ /* ++ * reiser4_writeback_inodes calls (via generic_writeback_sb_inodes) ++ * reiser4_writepages_dispatch for each of dirty inodes. ++ * Reiser4_writepages_dispatch captures pages. When number of pages ++ * captured in one reiser4_writeback_inodes reaches some threshold - ++ * some atoms get flushed ++ */ ++ int nr_captured; ++ int nr_children; /* number of child contexts */ ++ struct page *locked_page; /* page that should be unlocked in ++ * reiser4_dirty_inode() before taking ++ * a longterm lock (to not violate ++ * reiser4 lock ordering) */ ++#if REISER4_DEBUG ++ reiser4_lock_cnt_info locks; /* debugging information about reiser4 ++ locks held by the current thread */ ++ struct task_struct *task; /* so we can easily find owner of the stack */ ++ struct list_head flushers_link; /* list of all threads doing ++ flush currently */ ++ err_site err; /* information about last error encountered by reiser4 */ ++#endif ++ void *vp; ++ gfp_t gfp_mask; ++}; ++ ++extern reiser4_context *get_context_by_lock_stack(lock_stack *); ++extern int ctx_brick_info_init_static(void); ++extern void ctx_brick_info_done_static(void); ++extern int ctx_stack_info_init_static(void); ++extern void ctx_stack_info_done_static(void); ++extern reiser4_subvol *get_current_data_subvol(void); ++extern void set_current_data_subvol(reiser4_subvol *subv); ++extern void clear_current_data_subvol(void); ++extern struct ctx_brick_info *find_context_brick_info(reiser4_context *ctx, ++ u32 brick_id); ++extern int insert_context_brick_info(reiser4_context *ctx, ++ struct ctx_brick_info *data); ++extern struct ctx_brick_info *alloc_context_brick_info(void); ++extern void free_context_brick_info(struct ctx_brick_info *cbi); ++static inline ctx_brick_info *context_meta_brick_info(reiser4_context *ctx) ++{ ++ return &ctx->mcbi; ++} ++ ++static inline void init_context_brick_info(struct ctx_brick_info *cbi, ++ u32 brick_id) ++{ ++ memset(cbi, 0, sizeof(*cbi)); ++ RB_CLEAR_NODE(&cbi->node); ++ cbi->brick_id = brick_id; ++} ++ ++/* Debugging helps. */ ++#if REISER4_DEBUG ++extern void print_contexts(void); ++#endif ++ ++#define current_blocksize reiser4_get_current_sb()->s_blocksize ++#define current_blocksize_bits reiser4_get_current_sb()->s_blocksize_bits ++#define current_tree(subvol_id) (&(current_origin(subvol_id)->tree)) ++ ++extern reiser4_context *reiser4_init_context(struct super_block *); ++extern void init_stack_context(reiser4_context *, struct super_block *); ++extern void reiser4_exit_context(reiser4_context *); ++ ++/* magic constant we store in reiser4_context allocated at the stack. Used to ++ catch accesses to staled or uninitialized contexts. */ ++#define context_magic ((__u32) 0x4b1b5d0b) ++ ++extern int is_in_reiser4_context(void); ++ ++/* ++ * return reiser4_context for the thread @tsk ++ */ ++static inline reiser4_context *get_context(const struct task_struct *tsk) ++{ ++ assert("vs-1682", ++ ((reiser4_context *) tsk->journal_info)->magic == context_magic); ++ return (reiser4_context *) tsk->journal_info; ++} ++ ++/* ++ * return reiser4 context of the current thread, or NULL if there is none. ++ */ ++static inline reiser4_context *get_current_context_check(void) ++{ ++ if (is_in_reiser4_context()) ++ return get_context(current); ++ else ++ return NULL; ++} ++ ++static inline reiser4_context *get_current_context(void); /* __attribute__((const)); */ ++ ++/* return context associated with current thread */ ++static inline reiser4_context *get_current_context(void) ++{ ++ return get_context(current); ++} ++ ++static inline gfp_t reiser4_ctx_gfp_mask_get(void) ++{ ++ reiser4_context *ctx; ++ ++ ctx = get_current_context_check(); ++ return (ctx == NULL) ? GFP_KERNEL : ctx->gfp_mask; ++} ++ ++void reiser4_ctx_gfp_mask_set(void); ++void reiser4_ctx_gfp_mask_force (gfp_t mask); ++ ++/* ++ * true if current thread is in the write-out mode. Thread enters write-out ++ * mode during jnode_flush and reiser4_write_logs(). ++ */ ++static inline int is_writeout_mode(void) ++{ ++ return get_current_context()->writeout_mode; ++} ++ ++/* ++ * enter write-out mode ++ */ ++static inline void writeout_mode_enable(void) ++{ ++ assert("zam-941", !get_current_context()->writeout_mode); ++ get_current_context()->writeout_mode = 1; ++} ++ ++/* ++ * leave write-out mode ++ */ ++static inline void writeout_mode_disable(void) ++{ ++ assert("zam-942", get_current_context()->writeout_mode); ++ get_current_context()->writeout_mode = 0; ++} ++ ++static inline void grab_space_enable(void) ++{ ++ get_current_context()->grab_enabled = 1; ++} ++ ++static inline void grab_space_disable(void) ++{ ++ get_current_context()->grab_enabled = 0; ++} ++ ++static inline void grab_space_set_enabled(int enabled) ++{ ++ get_current_context()->grab_enabled = enabled; ++} ++ ++static inline int is_grab_enabled(reiser4_context * ctx) ++{ ++ return ctx->grab_enabled; ++} ++ ++/* mark transaction handle in @ctx as TXNH_DONT_COMMIT, so that no commit or ++ * flush would be performed when it is closed. This is necessary when handle ++ * has to be closed under some coarse semaphore, like i_mutex of ++ * directory. Commit will be performed by ktxnmgrd. */ ++static inline void context_set_commit_async(reiser4_context * context) ++{ ++ context->nobalance = 1; ++ context->trans->flags |= TXNH_DONT_COMMIT; ++} ++ ++/* __REISER4_CONTEXT_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/coord.c linux-5.10.2/fs/reiser4/coord.c +--- linux-5.10.2.orig/fs/reiser4/coord.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/coord.c 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,931 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "tree.h" ++#include "plugin/item/item.h" ++#include "znode.h" ++#include "coord.h" ++ ++/* Internal constructor. */ ++static inline void ++coord_init_values(coord_t *coord, const znode * node, pos_in_node_t item_pos, ++ pos_in_node_t unit_pos, between_enum between) ++{ ++ coord->node = (znode *) node; ++ coord_set_item_pos(coord, item_pos); ++ coord->unit_pos = unit_pos; ++ coord->between = between; ++ ON_DEBUG(coord->plug_v = 0); ++ ON_DEBUG(coord->body_v = 0); ++ ++ /*ON_TRACE (TRACE_COORDS, "init coord %p node %p: %u %u %s\n", coord, ++ node, item_pos, unit_pos, coord_tween_tostring (between)); */ ++} ++ ++/* after shifting of node content, coord previously set properly may become ++ invalid, try to "normalize" it. */ ++void coord_normalize(coord_t *coord) ++{ ++ znode *node; ++ ++ node = coord->node; ++ assert("vs-683", node); ++ ++ coord_clear_iplug(coord); ++ ++ if (node_is_empty(node)) { ++ coord_init_first_unit(coord, node); ++ } else if ((coord->between == AFTER_ITEM) ++ || (coord->between == AFTER_UNIT)) { ++ return; ++ } else if (coord->item_pos == coord_num_items(coord) ++ && coord->between == BEFORE_ITEM) { ++ coord_dec_item_pos(coord); ++ coord->between = AFTER_ITEM; ++ } else if (coord->unit_pos == coord_num_units(coord) ++ && coord->between == BEFORE_UNIT) { ++ coord->unit_pos--; ++ coord->between = AFTER_UNIT; ++ } else if (coord->item_pos == coord_num_items(coord) ++ && coord->unit_pos == 0 && coord->between == BEFORE_UNIT) { ++ coord_dec_item_pos(coord); ++ coord->unit_pos = 0; ++ coord->between = AFTER_ITEM; ++ } ++} ++ ++/* Copy a coordinate. */ ++void coord_dup(coord_t *coord, const coord_t *old_coord) ++{ ++ assert("jmacd-9800", coord_check(old_coord)); ++ coord_dup_nocheck(coord, old_coord); ++} ++ ++/* Copy a coordinate without check. Useful when old_coord->node is not ++ loaded. As in cbk_tree_lookup -> connect_znode -> connect_one_side */ ++void coord_dup_nocheck(coord_t *coord, const coord_t *old_coord) ++{ ++ coord->node = old_coord->node; ++ coord_set_item_pos(coord, old_coord->item_pos); ++ coord->unit_pos = old_coord->unit_pos; ++ coord->between = old_coord->between; ++ coord->iplugid = old_coord->iplugid; ++ ON_DEBUG(coord->plug_v = old_coord->plug_v); ++ ON_DEBUG(coord->body_v = old_coord->body_v); ++} ++ ++/* Initialize an invalid coordinate. */ ++void coord_init_invalid(coord_t *coord, const znode * node) ++{ ++ coord_init_values(coord, node, 0, 0, INVALID_COORD); ++} ++ ++void coord_init_first_unit_nocheck(coord_t *coord, const znode * node) ++{ ++ coord_init_values(coord, node, 0, 0, AT_UNIT); ++} ++ ++/* Initialize a coordinate to point at the first unit of the first item. If the ++ node is empty, it is positioned at the EMPTY_NODE. */ ++void coord_init_first_unit(coord_t *coord, const znode * node) ++{ ++ int is_empty = node_is_empty(node); ++ ++ coord_init_values(coord, node, 0, 0, (is_empty ? EMPTY_NODE : AT_UNIT)); ++ ++ assert("jmacd-9801", coord_check(coord)); ++} ++ ++/* Initialize a coordinate to point at the last unit of the last item. If the ++ node is empty, it is positioned at the EMPTY_NODE. */ ++void coord_init_last_unit(coord_t *coord, const znode * node) ++{ ++ int is_empty = node_is_empty(node); ++ ++ coord_init_values(coord, node, ++ (is_empty ? 0 : node_num_items(node) - 1), 0, ++ (is_empty ? EMPTY_NODE : AT_UNIT)); ++ if (!is_empty) ++ coord->unit_pos = coord_last_unit_pos(coord); ++ assert("jmacd-9802", coord_check(coord)); ++} ++ ++/* Initialize a coordinate to before the first item. If the node is empty, it is ++ positioned at the EMPTY_NODE. */ ++void coord_init_before_first_item(coord_t *coord, const znode * node) ++{ ++ int is_empty = node_is_empty(node); ++ ++ coord_init_values(coord, node, 0, 0, ++ (is_empty ? EMPTY_NODE : BEFORE_UNIT)); ++ ++ assert("jmacd-9803", coord_check(coord)); ++} ++ ++/* Initialize a coordinate to after the last item. If the node is empty, it is ++ positioned at the EMPTY_NODE. */ ++void coord_init_after_last_item(coord_t *coord, const znode * node) ++{ ++ int is_empty = node_is_empty(node); ++ ++ coord_init_values(coord, node, ++ (is_empty ? 0 : node_num_items(node) - 1), 0, ++ (is_empty ? EMPTY_NODE : AFTER_ITEM)); ++ ++ assert("jmacd-9804", coord_check(coord)); ++} ++ ++/* Initialize a coordinate to after last unit in the item. Coord must be set ++ already to existing item */ ++void coord_init_after_item_end(coord_t *coord) ++{ ++ coord->between = AFTER_UNIT; ++ coord->unit_pos = coord_last_unit_pos(coord); ++} ++ ++/* Initialize a coordinate to before the item. Coord must be set already to ++ existing item */ ++void coord_init_before_item(coord_t *coord) ++{ ++ coord->unit_pos = 0; ++ coord->between = BEFORE_ITEM; ++} ++ ++/* Initialize a coordinate to after the item. Coord must be set already to ++ existing item */ ++void coord_init_after_item(coord_t *coord) ++{ ++ coord->unit_pos = 0; ++ coord->between = AFTER_ITEM; ++} ++ ++/* Initialize a coordinate by 0s. Used in places where init_coord was used and ++ it was not clear how actually */ ++void coord_init_zero(coord_t *coord) ++{ ++ memset(coord, 0, sizeof(*coord)); ++} ++ ++/* Return the number of units at the present item. ++ Asserts coord_is_existing_item(). */ ++unsigned coord_num_units(const coord_t *coord) ++{ ++ assert("jmacd-9806", coord_is_existing_item(coord)); ++ ++ return item_plugin_by_coord(coord)->b.nr_units(coord); ++} ++ ++/* Returns true if the coord was initializewd by coord_init_invalid (). */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_invalid(const coord_t *coord) ++{ ++ return coord->between == INVALID_COORD; ++} ++ ++/* Returns true if the coordinate is positioned at an existing item, not before ++ or after an item. It may be placed at, before, or after any unit within the ++ item, whether existing or not. */ ++int coord_is_existing_item(const coord_t *coord) ++{ ++ switch (coord->between) { ++ case EMPTY_NODE: ++ case BEFORE_ITEM: ++ case AFTER_ITEM: ++ case INVALID_COORD: ++ return 0; ++ ++ case BEFORE_UNIT: ++ case AT_UNIT: ++ case AFTER_UNIT: ++ return coord->item_pos < coord_num_items(coord); ++ } ++ ++ impossible("jmacd-9900", "unreachable coord: %p", coord); ++ return 0; ++} ++ ++/* Returns true if the coordinate is positioned at an existing unit, not before ++ or after a unit. */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_existing_unit(const coord_t *coord) ++{ ++ switch (coord->between) { ++ case EMPTY_NODE: ++ case BEFORE_UNIT: ++ case AFTER_UNIT: ++ case BEFORE_ITEM: ++ case AFTER_ITEM: ++ case INVALID_COORD: ++ return 0; ++ ++ case AT_UNIT: ++ return (coord->item_pos < coord_num_items(coord) ++ && coord->unit_pos < coord_num_units(coord)); ++ } ++ ++ impossible("jmacd-9902", "unreachable"); ++ return 0; ++} ++ ++/* Returns true if the coordinate is positioned at the first unit of the first ++ item. Not true for empty nodes nor coordinates positioned before the first ++ item. */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_leftmost_unit(const coord_t *coord) ++{ ++ return (coord->between == AT_UNIT && coord->item_pos == 0 ++ && coord->unit_pos == 0); ++} ++ ++#if REISER4_DEBUG ++/* For assertions only, checks for a valid coordinate. */ ++int coord_check(const coord_t *coord) ++{ ++ if (coord->node == NULL) ++ return 0; ++ if (znode_above_root(coord->node)) ++ return 1; ++ ++ switch (coord->between) { ++ default: ++ case INVALID_COORD: ++ return 0; ++ case EMPTY_NODE: ++ if (!node_is_empty(coord->node)) ++ return 0; ++ return coord->item_pos == 0 && coord->unit_pos == 0; ++ ++ case BEFORE_UNIT: ++ case AFTER_UNIT: ++ if (node_is_empty(coord->node) && (coord->item_pos == 0) ++ && (coord->unit_pos == 0)) ++ return 1; ++ case AT_UNIT: ++ break; ++ case AFTER_ITEM: ++ case BEFORE_ITEM: ++ /* before/after item should not set unit_pos. */ ++ if (coord->unit_pos != 0) ++ return 0; ++ break; ++ } ++ ++ if (coord->item_pos >= node_num_items(coord->node)) ++ return 0; ++ ++ /* FIXME-VS: we are going to check unit_pos. This makes no sense when ++ between is set either AFTER_ITEM or BEFORE_ITEM */ ++ if (coord->between == AFTER_ITEM || coord->between == BEFORE_ITEM) ++ return 1; ++ ++ if (coord_is_iplug_set(coord) && ++ coord->unit_pos > ++ item_plugin_by_coord(coord)->b.nr_units(coord) - 1) ++ return 0; ++ return 1; ++} ++#endif ++ ++/* Adjust coordinate boundaries based on the number of items prior to ++ coord_next/prev. Returns 1 if the new position is does not exist. */ ++static int coord_adjust_items(coord_t *coord, unsigned items, int is_next) ++{ ++ /* If the node is invalid, leave it. */ ++ if (coord->between == INVALID_COORD) ++ return 1; ++ ++ /* If the node is empty, set it appropriately. */ ++ if (items == 0) { ++ coord->between = EMPTY_NODE; ++ coord_set_item_pos(coord, 0); ++ coord->unit_pos = 0; ++ return 1; ++ } ++ ++ /* If it was empty and it no longer is, set to BEFORE/AFTER_ITEM. */ ++ if (coord->between == EMPTY_NODE) { ++ coord->between = (is_next ? BEFORE_ITEM : AFTER_ITEM); ++ coord_set_item_pos(coord, 0); ++ coord->unit_pos = 0; ++ return 0; ++ } ++ ++ /* If the item_pos is out-of-range, set it appropriatly. */ ++ if (coord->item_pos >= items) { ++ coord->between = AFTER_ITEM; ++ coord_set_item_pos(coord, items - 1); ++ coord->unit_pos = 0; ++ /* If is_next, return 1 (can't go any further). */ ++ return is_next; ++ } ++ ++ return 0; ++} ++ ++/** ++ * Advances the coordinate by one unit to the right in a node. ++ * If node is empty, no change. If @coord is the rightmost unit ++ * in the node, advances to AFTER THE LAST ITEM. Returns 0 if ++ * new position is an existing unit ++ */ ++int coord_next_unit(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 1) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case BEFORE_UNIT: ++ /* Now it is positioned at the same unit. */ ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case AFTER_UNIT: ++ case AT_UNIT: ++ /* If it was at or after a unit and there are more units in this ++ item, advance to the next one. */ ++ if (coord->unit_pos < coord_last_unit_pos(coord)) { ++ coord->unit_pos += 1; ++ coord->between = AT_UNIT; ++ return 0; ++ } ++ ++ /* Otherwise, it is crossing an item boundary and treated as if ++ it was after the current item. */ ++ coord->between = AFTER_ITEM; ++ coord->unit_pos = 0; ++ /* FALLTHROUGH */ ++ ++ case AFTER_ITEM: ++ /* Check for end-of-node. */ ++ if (coord->item_pos == items - 1) ++ return 1; ++ ++ coord_inc_item_pos(coord); ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case BEFORE_ITEM: ++ /* The adjust_items checks ensure that we are valid here. */ ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case INVALID_COORD: ++ case EMPTY_NODE: ++ /* Handled in coord_adjust_items(). */ ++ break; ++ } ++ ++ impossible("jmacd-9902", "unreachable"); ++ return 0; ++} ++ ++/* Advances the coordinate by one item to the right. If empty, no change. If ++ coord_is_rightmost_unit, advances to AFTER THE LAST ITEM. Returns 0 if new ++ position is an existing item. */ ++int coord_next_item(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 1) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case AFTER_UNIT: ++ case AT_UNIT: ++ case BEFORE_UNIT: ++ case AFTER_ITEM: ++ /* Check for end-of-node. */ ++ if (coord->item_pos == items - 1) { ++ coord->between = AFTER_ITEM; ++ coord->unit_pos = 0; ++ coord_clear_iplug(coord); ++ return 1; ++ } ++ ++ /* Anywhere in an item, go to the next one. */ ++ coord->between = AT_UNIT; ++ coord_inc_item_pos(coord); ++ coord->unit_pos = 0; ++ return 0; ++ ++ case BEFORE_ITEM: ++ /* The out-of-range check ensures that we are valid here. */ ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ return 0; ++ case INVALID_COORD: ++ case EMPTY_NODE: ++ /* Handled in coord_adjust_items(). */ ++ break; ++ } ++ ++ impossible("jmacd-9903", "unreachable"); ++ return 0; ++} ++ ++/* Advances the coordinate by one unit to the left. If empty, no change. If ++ coord_is_leftmost_unit, advances to BEFORE THE FIRST ITEM. Returns 0 if new ++ position is an existing unit. */ ++int coord_prev_unit(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 0) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case AT_UNIT: ++ case BEFORE_UNIT: ++ if (coord->unit_pos > 0) { ++ coord->unit_pos -= 1; ++ coord->between = AT_UNIT; ++ return 0; ++ } ++ ++ if (coord->item_pos == 0) { ++ coord->between = BEFORE_ITEM; ++ return 1; ++ } ++ ++ coord_dec_item_pos(coord); ++ coord->unit_pos = coord_last_unit_pos(coord); ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case AFTER_UNIT: ++ /* What if unit_pos is out-of-range? */ ++ assert("jmacd-5442", ++ coord->unit_pos <= coord_last_unit_pos(coord)); ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case BEFORE_ITEM: ++ if (coord->item_pos == 0) ++ return 1; ++ ++ coord_dec_item_pos(coord); ++ /* FALLTHROUGH */ ++ ++ case AFTER_ITEM: ++ coord->between = AT_UNIT; ++ coord->unit_pos = coord_last_unit_pos(coord); ++ return 0; ++ ++ case INVALID_COORD: ++ case EMPTY_NODE: ++ break; ++ } ++ ++ impossible("jmacd-9904", "unreachable"); ++ return 0; ++} ++ ++/* Advances the coordinate by one item to the left. If empty, no change. If ++ coord_is_leftmost_unit, advances to BEFORE THE FIRST ITEM. Returns 0 if new ++ position is an existing item. */ ++int coord_prev_item(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 0) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case AT_UNIT: ++ case AFTER_UNIT: ++ case BEFORE_UNIT: ++ case BEFORE_ITEM: ++ ++ if (coord->item_pos == 0) { ++ coord->between = BEFORE_ITEM; ++ coord->unit_pos = 0; ++ return 1; ++ } ++ ++ coord_dec_item_pos(coord); ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case AFTER_ITEM: ++ coord->between = AT_UNIT; ++ coord->unit_pos = 0; ++ return 0; ++ ++ case INVALID_COORD: ++ case EMPTY_NODE: ++ break; ++ } ++ ++ impossible("jmacd-9905", "unreachable"); ++ return 0; ++} ++ ++/* Calls either coord_init_first_unit or coord_init_last_unit depending on ++ sideof argument. */ ++void coord_init_sideof_unit(coord_t *coord, const znode * node, sideof dir) ++{ ++ assert("jmacd-9821", dir == LEFT_SIDE || dir == RIGHT_SIDE); ++ if (dir == LEFT_SIDE) { ++ coord_init_first_unit(coord, node); ++ } else { ++ coord_init_last_unit(coord, node); ++ } ++} ++ ++/* Calls either coord_is_before_leftmost or coord_is_after_rightmost depending ++ on sideof argument. */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_after_sideof_unit(coord_t *coord, sideof dir) ++{ ++ assert("jmacd-9822", dir == LEFT_SIDE || dir == RIGHT_SIDE); ++ if (dir == LEFT_SIDE) { ++ return coord_is_before_leftmost(coord); ++ } else { ++ return coord_is_after_rightmost(coord); ++ } ++} ++ ++/* Calls either coord_next_unit or coord_prev_unit depending on sideof argument. ++ */ ++/* Audited by: green(2002.06.15) */ ++int coord_sideof_unit(coord_t *coord, sideof dir) ++{ ++ assert("jmacd-9823", dir == LEFT_SIDE || dir == RIGHT_SIDE); ++ if (dir == LEFT_SIDE) { ++ return coord_prev_unit(coord); ++ } else { ++ return coord_next_unit(coord); ++ } ++} ++ ++#if REISER4_DEBUG ++int coords_equal(const coord_t *c1, const coord_t *c2) ++{ ++ assert("nikita-2840", c1 != NULL); ++ assert("nikita-2841", c2 != NULL); ++ ++ return ++ c1->node == c2->node && ++ c1->item_pos == c2->item_pos && ++ c1->unit_pos == c2->unit_pos && c1->between == c2->between; ++} ++#endif /* REISER4_DEBUG */ ++ ++/* If coord_is_after_rightmost return NCOORD_ON_THE_RIGHT, if ++ coord_is_after_leftmost return NCOORD_ON_THE_LEFT, otherwise return ++ NCOORD_INSIDE. */ ++/* Audited by: green(2002.06.15) */ ++coord_wrt_node coord_wrt(const coord_t *coord) ++{ ++ if (coord_is_before_leftmost(coord)) ++ return COORD_ON_THE_LEFT; ++ ++ if (coord_is_after_rightmost(coord)) ++ return COORD_ON_THE_RIGHT; ++ ++ return COORD_INSIDE; ++} ++ ++/* Returns true if the coordinate is positioned after the last item or after the ++ last unit of the last item or it is an empty node. */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_after_rightmost(const coord_t *coord) ++{ ++ assert("jmacd-7313", coord_check(coord)); ++ ++ switch (coord->between) { ++ case INVALID_COORD: ++ case AT_UNIT: ++ case BEFORE_UNIT: ++ case BEFORE_ITEM: ++ return 0; ++ ++ case EMPTY_NODE: ++ return 1; ++ ++ case AFTER_ITEM: ++ return (coord->item_pos == node_num_items(coord->node) - 1); ++ ++ case AFTER_UNIT: ++ return ((coord->item_pos == node_num_items(coord->node) - 1) && ++ coord->unit_pos == coord_last_unit_pos(coord)); ++ } ++ ++ impossible("jmacd-9908", "unreachable"); ++ return 0; ++} ++ ++/* Returns true if the coordinate is positioned before the first item or it is ++ an empty node. */ ++int coord_is_before_leftmost(const coord_t *coord) ++{ ++ /* FIXME-VS: coord_check requires node to be loaded whereas it is not ++ necessary to check if coord is set before leftmost ++ assert ("jmacd-7313", coord_check (coord)); */ ++ switch (coord->between) { ++ case INVALID_COORD: ++ case AT_UNIT: ++ case AFTER_ITEM: ++ case AFTER_UNIT: ++ return 0; ++ ++ case EMPTY_NODE: ++ return 1; ++ ++ case BEFORE_ITEM: ++ case BEFORE_UNIT: ++ return (coord->item_pos == 0) && (coord->unit_pos == 0); ++ } ++ ++ impossible("jmacd-9908", "unreachable"); ++ return 0; ++} ++ ++/* Returns true if the coordinate is positioned after a item, before a item, ++ after the last unit of an item, before the first unit of an item, or at an ++ empty node. */ ++/* Audited by: green(2002.06.15) */ ++int coord_is_between_items(const coord_t *coord) ++{ ++ assert("jmacd-7313", coord_check(coord)); ++ ++ switch (coord->between) { ++ case INVALID_COORD: ++ case AT_UNIT: ++ return 0; ++ ++ case AFTER_ITEM: ++ case BEFORE_ITEM: ++ case EMPTY_NODE: ++ return 1; ++ ++ case BEFORE_UNIT: ++ return coord->unit_pos == 0; ++ ++ case AFTER_UNIT: ++ return coord->unit_pos == coord_last_unit_pos(coord); ++ } ++ ++ impossible("jmacd-9908", "unreachable"); ++ return 0; ++} ++ ++#if REISER4_DEBUG ++/* Returns true if the coordinates are positioned at adjacent units, regardless ++ of before-after or item boundaries. */ ++int coord_are_neighbors(coord_t *c1, coord_t *c2) ++{ ++ coord_t *left; ++ coord_t *right; ++ ++ assert("nikita-1241", c1 != NULL); ++ assert("nikita-1242", c2 != NULL); ++ assert("nikita-1243", c1->node == c2->node); ++ assert("nikita-1244", coord_is_existing_unit(c1)); ++ assert("nikita-1245", coord_is_existing_unit(c2)); ++ ++ left = right = NULL; ++ switch (coord_compare(c1, c2)) { ++ case COORD_CMP_ON_LEFT: ++ left = c1; ++ right = c2; ++ break; ++ case COORD_CMP_ON_RIGHT: ++ left = c2; ++ right = c1; ++ break; ++ case COORD_CMP_SAME: ++ return 0; ++ default: ++ wrong_return_value("nikita-1246", "compare_coords()"); ++ } ++ assert("vs-731", left && right); ++ if (left->item_pos == right->item_pos) { ++ return left->unit_pos + 1 == right->unit_pos; ++ } else if (left->item_pos + 1 == right->item_pos) { ++ return (left->unit_pos == coord_last_unit_pos(left)) ++ && (right->unit_pos == 0); ++ } else { ++ return 0; ++ } ++} ++#endif /* REISER4_DEBUG */ ++ ++/* Assuming two coordinates are positioned in the same node, return ++ COORD_CMP_ON_RIGHT, COORD_CMP_ON_LEFT, or COORD_CMP_SAME depending on c1's ++ position relative to c2. */ ++/* Audited by: green(2002.06.15) */ ++coord_cmp coord_compare(coord_t *c1, coord_t *c2) ++{ ++ assert("vs-209", c1->node == c2->node); ++ assert("vs-194", coord_is_existing_unit(c1) ++ && coord_is_existing_unit(c2)); ++ ++ if (c1->item_pos > c2->item_pos) ++ return COORD_CMP_ON_RIGHT; ++ if (c1->item_pos < c2->item_pos) ++ return COORD_CMP_ON_LEFT; ++ if (c1->unit_pos > c2->unit_pos) ++ return COORD_CMP_ON_RIGHT; ++ if (c1->unit_pos < c2->unit_pos) ++ return COORD_CMP_ON_LEFT; ++ return COORD_CMP_SAME; ++} ++ ++/* If the coordinate is between items, shifts it to the right. Returns 0 on ++ success and non-zero if there is no position to the right. */ ++int coord_set_to_right(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 1) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case AT_UNIT: ++ return 0; ++ ++ case BEFORE_ITEM: ++ case BEFORE_UNIT: ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case AFTER_UNIT: ++ if (coord->unit_pos < coord_last_unit_pos(coord)) { ++ coord->unit_pos += 1; ++ coord->between = AT_UNIT; ++ return 0; ++ } else { ++ ++ coord->unit_pos = 0; ++ ++ if (coord->item_pos == items - 1) { ++ coord->between = AFTER_ITEM; ++ return 1; ++ } ++ ++ coord_inc_item_pos(coord); ++ coord->between = AT_UNIT; ++ return 0; ++ } ++ ++ case AFTER_ITEM: ++ if (coord->item_pos == items - 1) ++ return 1; ++ ++ coord_inc_item_pos(coord); ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case EMPTY_NODE: ++ return 1; ++ ++ case INVALID_COORD: ++ break; ++ } ++ ++ impossible("jmacd-9920", "unreachable"); ++ return 0; ++} ++ ++/* If the coordinate is between items, shifts it to the left. Returns 0 on ++ success and non-zero if there is no position to the left. */ ++int coord_set_to_left(coord_t *coord) ++{ ++ unsigned items = coord_num_items(coord); ++ ++ if (coord_adjust_items(coord, items, 0) == 1) ++ return 1; ++ ++ switch (coord->between) { ++ case AT_UNIT: ++ return 0; ++ ++ case AFTER_UNIT: ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case AFTER_ITEM: ++ coord->between = AT_UNIT; ++ coord->unit_pos = coord_last_unit_pos(coord); ++ return 0; ++ ++ case BEFORE_UNIT: ++ if (coord->unit_pos > 0) { ++ coord->unit_pos -= 1; ++ coord->between = AT_UNIT; ++ return 0; ++ } else { ++ ++ if (coord->item_pos == 0) { ++ coord->between = BEFORE_ITEM; ++ return 1; ++ } ++ ++ coord->unit_pos = coord_last_unit_pos(coord); ++ coord_dec_item_pos(coord); ++ coord->between = AT_UNIT; ++ return 0; ++ } ++ ++ case BEFORE_ITEM: ++ if (coord->item_pos == 0) ++ return 1; ++ ++ coord_dec_item_pos(coord); ++ coord->unit_pos = coord_last_unit_pos(coord); ++ coord->between = AT_UNIT; ++ return 0; ++ ++ case EMPTY_NODE: ++ return 1; ++ ++ case INVALID_COORD: ++ break; ++ } ++ ++ impossible("jmacd-9920", "unreachable"); ++ return 0; ++} ++ ++static const char *coord_tween_tostring(between_enum n) ++{ ++ switch (n) { ++ case BEFORE_UNIT: ++ return "before unit"; ++ case BEFORE_ITEM: ++ return "before item"; ++ case AT_UNIT: ++ return "at unit"; ++ case AFTER_UNIT: ++ return "after unit"; ++ case AFTER_ITEM: ++ return "after item"; ++ case EMPTY_NODE: ++ return "empty node"; ++ case INVALID_COORD: ++ return "invalid"; ++ default: ++ { ++ static char buf[30]; ++ ++ sprintf(buf, "unknown: %i", n); ++ return buf; ++ } ++ } ++} ++ ++void print_coord(const char *mes, const coord_t *coord, int node) ++{ ++ if (coord == NULL) { ++ printk("%s: null\n", mes); ++ return; ++ } ++ printk("%s: item_pos = %d, unit_pos %d, tween=%s, iplug=%d\n", ++ mes, coord->item_pos, coord->unit_pos, ++ coord_tween_tostring(coord->between), coord->iplugid); ++} ++ ++int ++item_utmost_child_real_block(const coord_t *coord, sideof side, ++ reiser4_block_nr * blk) ++{ ++ return item_plugin_by_coord(coord)->f.utmost_child_real_block(coord, ++ side, ++ blk); ++} ++ ++int item_utmost_child(const coord_t *coord, sideof side, jnode ** child) ++{ ++ return item_plugin_by_coord(coord)->f.utmost_child(coord, side, child); ++} ++ ++/* @count bytes of flow @f got written, update correspondingly f->length, ++ f->data and f->key */ ++void move_flow_forward(flow_t *f, unsigned count) ++{ ++ if (f->data) ++ f->data += count; ++ f->length -= count; ++ set_key_offset(&f->key, get_key_offset(&f->key) + count); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/coord.h linux-5.10.2/fs/reiser4/coord.h +--- linux-5.10.2.orig/fs/reiser4/coord.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/coord.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,399 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Coords */ ++ ++#if !defined(__REISER4_COORD_H__) ++#define __REISER4_COORD_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++ ++/* insertions happen between coords in the tree, so we need some means ++ of specifying the sense of betweenness. */ ++typedef enum { ++ BEFORE_UNIT, /* Note: we/init_coord depends on this value being zero. */ ++ AT_UNIT, ++ AFTER_UNIT, ++ BEFORE_ITEM, ++ AFTER_ITEM, ++ INVALID_COORD, ++ EMPTY_NODE, ++} between_enum; ++ ++/* location of coord w.r.t. its node */ ++typedef enum { ++ COORD_ON_THE_LEFT = -1, ++ COORD_ON_THE_RIGHT = +1, ++ COORD_INSIDE = 0 ++} coord_wrt_node; ++ ++typedef enum { ++ COORD_CMP_SAME = 0, COORD_CMP_ON_LEFT = -1, COORD_CMP_ON_RIGHT = +1 ++} coord_cmp; ++ ++struct coord { ++ /* node in a tree */ ++ /* 0 */ znode *node; ++ ++ /* position of item within node */ ++ /* 4 */ pos_in_node_t item_pos; ++ /* position of unit within item */ ++ /* 6 */ pos_in_node_t unit_pos; ++ /* optimization: plugin of item is stored in coord_t. Until this was ++ implemented, item_plugin_by_coord() was major CPU consumer. ->iplugid ++ is invalidated (set to 0xff) on each modification of ->item_pos, ++ and all such modifications are funneled through coord_*_item_pos() ++ functions below. ++ */ ++ /* 8 */ char iplugid; ++ /* position of coord w.r.t. to neighboring items and/or units. ++ Values are taken from &between_enum above. ++ */ ++ /* 9 */ char between; ++ /* padding. It will be added by the compiler anyway to conform to the ++ * C language alignment requirements. We keep it here to be on the ++ * safe side and to have a clear picture of the memory layout of this ++ * structure. */ ++ /* 10 */ __u16 pad; ++ /* 12 */ int offset; ++#if REISER4_DEBUG ++ unsigned long plug_v; ++ unsigned long body_v; ++#endif ++}; ++ ++#define INVALID_PLUGID ((char)((1 << 8) - 1)) ++#define INVALID_OFFSET -1 ++ ++static inline void coord_clear_iplug(coord_t *coord) ++{ ++ assert("nikita-2835", coord != NULL); ++ coord->iplugid = INVALID_PLUGID; ++ coord->offset = INVALID_OFFSET; ++} ++ ++static inline int coord_is_iplug_set(const coord_t *coord) ++{ ++ assert("nikita-2836", coord != NULL); ++ return coord->iplugid != INVALID_PLUGID; ++} ++ ++static inline void coord_set_item_pos(coord_t *coord, pos_in_node_t pos) ++{ ++ assert("nikita-2478", coord != NULL); ++ coord->item_pos = pos; ++ coord_clear_iplug(coord); ++} ++ ++static inline void coord_dec_item_pos(coord_t *coord) ++{ ++ assert("nikita-2480", coord != NULL); ++ --coord->item_pos; ++ coord_clear_iplug(coord); ++} ++ ++static inline void coord_inc_item_pos(coord_t *coord) ++{ ++ assert("nikita-2481", coord != NULL); ++ ++coord->item_pos; ++ coord_clear_iplug(coord); ++} ++ ++static inline void coord_add_item_pos(coord_t *coord, int delta) ++{ ++ assert("nikita-2482", coord != NULL); ++ coord->item_pos += delta; ++ coord_clear_iplug(coord); ++} ++ ++static inline void coord_invalid_item_pos(coord_t *coord) ++{ ++ assert("nikita-2832", coord != NULL); ++ coord->item_pos = (unsigned short)~0; ++ coord_clear_iplug(coord); ++} ++ ++/* Reverse a direction. */ ++static inline sideof sideof_reverse(sideof side) ++{ ++ return side == LEFT_SIDE ? RIGHT_SIDE : LEFT_SIDE; ++} ++ ++/* NOTE: There is a somewhat odd mixture of the following opposed terms: ++ ++ "first" and "last" ++ "next" and "prev" ++ "before" and "after" ++ "leftmost" and "rightmost" ++ ++ But I think the chosen names are decent the way they are. ++*/ ++ ++/* COORD INITIALIZERS */ ++ ++/* Initialize an invalid coordinate. */ ++extern void coord_init_invalid(coord_t *coord, const znode * node); ++ ++extern void coord_init_first_unit_nocheck(coord_t *coord, const znode * node); ++ ++/* Initialize a coordinate to point at the first unit of the first item. If the ++ node is empty, it is positioned at the EMPTY_NODE. */ ++extern void coord_init_first_unit(coord_t *coord, const znode * node); ++ ++/* Initialize a coordinate to point at the last unit of the last item. If the ++ node is empty, it is positioned at the EMPTY_NODE. */ ++extern void coord_init_last_unit(coord_t *coord, const znode * node); ++ ++/* Initialize a coordinate to before the first item. If the node is empty, it is ++ positioned at the EMPTY_NODE. */ ++extern void coord_init_before_first_item(coord_t *coord, const znode * node); ++ ++/* Initialize a coordinate to after the last item. If the node is empty, it is ++ positioned at the EMPTY_NODE. */ ++extern void coord_init_after_last_item(coord_t *coord, const znode * node); ++ ++/* Initialize a coordinate to after last unit in the item. Coord must be set ++ already to existing item */ ++void coord_init_after_item_end(coord_t *coord); ++ ++/* Initialize a coordinate to before the item. Coord must be set already to ++ existing item */ ++void coord_init_before_item(coord_t *); ++/* Initialize a coordinate to after the item. Coord must be set already to ++ existing item */ ++void coord_init_after_item(coord_t *); ++ ++/* Calls either coord_init_first_unit or coord_init_last_unit depending on ++ sideof argument. */ ++extern void coord_init_sideof_unit(coord_t *coord, const znode * node, ++ sideof dir); ++ ++/* Initialize a coordinate by 0s. Used in places where init_coord was used and ++ it was not clear how actually ++ FIXME-VS: added by vs (2002, june, 8) */ ++extern void coord_init_zero(coord_t *coord); ++ ++/* COORD METHODS */ ++ ++/* after shifting of node content, coord previously set properly may become ++ invalid, try to "normalize" it. */ ++void coord_normalize(coord_t *coord); ++ ++/* Copy a coordinate. */ ++extern void coord_dup(coord_t *coord, const coord_t *old_coord); ++ ++/* Copy a coordinate without check. */ ++void coord_dup_nocheck(coord_t *coord, const coord_t *old_coord); ++ ++unsigned coord_num_units(const coord_t *coord); ++ ++/* Return the last valid unit number at the present item (i.e., ++ coord_num_units() - 1). */ ++static inline unsigned coord_last_unit_pos(const coord_t *coord) ++{ ++ return coord_num_units(coord) - 1; ++} ++ ++#if REISER4_DEBUG ++/* For assertions only, checks for a valid coordinate. */ ++extern int coord_check(const coord_t *coord); ++ ++extern unsigned long znode_times_locked(const znode * z); ++ ++static inline void coord_update_v(coord_t *coord) ++{ ++ coord->plug_v = coord->body_v = znode_times_locked(coord->node); ++} ++#endif ++ ++extern int coords_equal(const coord_t *c1, const coord_t *c2); ++ ++extern void print_coord(const char *mes, const coord_t *coord, int print_node); ++ ++/* If coord_is_after_rightmost return NCOORD_ON_THE_RIGHT, if ++ coord_is_after_leftmost return NCOORD_ON_THE_LEFT, otherwise return ++ NCOORD_INSIDE. */ ++extern coord_wrt_node coord_wrt(const coord_t *coord); ++ ++/* Returns true if the coordinates are positioned at adjacent units, regardless ++ of before-after or item boundaries. */ ++extern int coord_are_neighbors(coord_t *c1, coord_t *c2); ++ ++/* Assuming two coordinates are positioned in the same node, return ++ NCOORD_CMP_ON_RIGHT, NCOORD_CMP_ON_LEFT, or NCOORD_CMP_SAME depending on c1's ++ position relative to c2. */ ++extern coord_cmp coord_compare(coord_t *c1, coord_t *c2); ++ ++/* COORD PREDICATES */ ++ ++/* Returns true if the coord was initializewd by coord_init_invalid (). */ ++extern int coord_is_invalid(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned at an existing item, not before ++ or after an item. It may be placed at, before, or after any unit within the ++ item, whether existing or not. If this is true you can call methods of the ++ item plugin. */ ++extern int coord_is_existing_item(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned after a item, before a item, ++ after the last unit of an item, before the first unit of an item, or at an ++ empty node. */ ++extern int coord_is_between_items(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned at an existing unit, not before ++ or after a unit. */ ++extern int coord_is_existing_unit(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned at an empty node. */ ++extern int coord_is_empty(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned at the first unit of the first ++ item. Not true for empty nodes nor coordinates positioned before the first ++ item. */ ++extern int coord_is_leftmost_unit(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned after the last item or after the ++ last unit of the last item or it is an empty node. */ ++extern int coord_is_after_rightmost(const coord_t *coord); ++ ++/* Returns true if the coordinate is positioned before the first item or it is ++ an empty node. */ ++extern int coord_is_before_leftmost(const coord_t *coord); ++ ++/* Calls either coord_is_before_leftmost or coord_is_after_rightmost depending ++ on sideof argument. */ ++extern int coord_is_after_sideof_unit(coord_t *coord, sideof dir); ++ ++/* COORD MODIFIERS */ ++ ++/* Advances the coordinate by one unit to the right. If empty, no change. If ++ coord_is_rightmost_unit, advances to AFTER THE LAST ITEM. Returns 0 if new ++ position is an existing unit. */ ++extern int coord_next_unit(coord_t *coord); ++ ++/* Advances the coordinate by one item to the right. If empty, no change. If ++ coord_is_rightmost_unit, advances to AFTER THE LAST ITEM. Returns 0 if new ++ position is an existing item. */ ++extern int coord_next_item(coord_t *coord); ++ ++/* Advances the coordinate by one unit to the left. If empty, no change. If ++ coord_is_leftmost_unit, advances to BEFORE THE FIRST ITEM. Returns 0 if new ++ position is an existing unit. */ ++extern int coord_prev_unit(coord_t *coord); ++ ++/* Advances the coordinate by one item to the left. If empty, no change. If ++ coord_is_leftmost_unit, advances to BEFORE THE FIRST ITEM. Returns 0 if new ++ position is an existing item. */ ++extern int coord_prev_item(coord_t *coord); ++ ++/* If the coordinate is between items, shifts it to the right. Returns 0 on ++ success and non-zero if there is no position to the right. */ ++extern int coord_set_to_right(coord_t *coord); ++ ++/* If the coordinate is between items, shifts it to the left. Returns 0 on ++ success and non-zero if there is no position to the left. */ ++extern int coord_set_to_left(coord_t *coord); ++ ++/* If the coordinate is at an existing unit, set to after that unit. Returns 0 ++ on success and non-zero if the unit did not exist. */ ++extern int coord_set_after_unit(coord_t *coord); ++ ++/* Calls either coord_next_unit or coord_prev_unit depending on sideof ++ argument. */ ++extern int coord_sideof_unit(coord_t *coord, sideof dir); ++ ++/* iterate over all units in @node */ ++#define for_all_units(coord, node) \ ++ for (coord_init_before_first_item((coord), (node)) ; \ ++ coord_next_unit(coord) == 0 ;) ++ ++/* iterate over all items in @node */ ++#define for_all_items(coord, node) \ ++ for (coord_init_before_first_item((coord), (node)) ; \ ++ coord_next_item(coord) == 0 ;) ++ ++/* COORD/ITEM METHODS */ ++ ++extern int item_utmost_child_real_block(const coord_t *coord, sideof side, ++ reiser4_block_nr * blk); ++extern int item_utmost_child(const coord_t *coord, sideof side, ++ jnode ** child); ++ ++/* a flow is a sequence of bytes being written to or read from the tree. The ++ tree will slice the flow into items while storing it into nodes, but all of ++ that is hidden from anything outside the tree. */ ++ ++struct flow { ++ reiser4_key key; /* key of start of flow's sequence of bytes */ ++ loff_t length; /* length of flow's sequence of bytes */ ++ char *data; /* start of flow's sequence of bytes */ ++ int user; /* if 1 data is user space, 0 - kernel space */ ++ rw_op op; /* NIKITA-FIXME-HANS: comment is where? */ ++}; ++ ++void move_flow_forward(flow_t *f, unsigned count); ++ ++/* &reiser4_item_data - description of data to be inserted or pasted ++ ++ Q: articulate the reasons for the difference between this and flow. ++ ++ A: Becides flow we insert into tree other things: stat data, directory ++ entry, etc. To insert them into tree one has to provide this structure. If ++ one is going to insert flow - he can use insert_flow, where this structure ++ does not have to be created ++*/ ++struct reiser4_item_data { ++ /* actual data to be inserted. If NULL, ->create_item() will not ++ do xmemcpy itself, leaving this up to the caller. This can ++ save some amount of unnecessary memory copying, for example, ++ during insertion of stat data. ++ ++ */ ++ char *data; ++ /* 1 if 'char * data' contains pointer to user space and 0 if it is ++ kernel space */ ++ int user; ++ /* amount of data we are going to insert or paste */ ++ int length; ++ /* "Arg" is opaque data that is passed down to the ++ ->create_item() method of node layout, which in turn ++ hands it to the ->create_hook() of item being created. This ++ arg is currently used by: ++ ++ . ->create_hook() of internal item ++ (fs/reiser4/plugin/item/internal.c:internal_create_hook()), ++ . ->paste() method of directory item. ++ . ->create_hook() of extent item ++ ++ For internal item, this is left "brother" of new node being ++ inserted and it is used to add new node into sibling list ++ after parent to it was just inserted into parent. ++ ++ While ->arg does look somewhat of unnecessary compication, ++ it actually saves a lot of headache in many places, because ++ all data necessary to insert or paste new data into tree are ++ collected in one place, and this eliminates a lot of extra ++ argument passing and storing everywhere. ++ ++ */ ++ void *arg; ++ /* plugin of item we are inserting */ ++ item_plugin *iplug; ++}; ++ ++/* __REISER4_COORD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/debug.c linux-5.10.2/fs/reiser4/debug.c +--- linux-5.10.2.orig/fs/reiser4/debug.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/debug.c 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,310 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Debugging facilities. */ ++ ++/* ++ * This file contains generic debugging functions used by reiser4. Roughly ++ * following: ++ * ++ * panicking: reiser4_do_panic(), reiser4_print_prefix(). ++ * ++ * locking: ++ * reiser4_schedulable(), reiser4_lock_counters(), print_lock_counters(), ++ * reiser4_no_counters_are_held(), reiser4_commit_check_locks() ++ * ++ * error code monitoring (see comment before RETERR macro): ++ * reiser4_return_err(), reiser4_report_err(). ++ * ++ * stack back-tracing: fill_backtrace() ++ * ++ * miscellaneous: reiser4_preempt_point(), call_on_each_assert(), ++ * reiser4_debugtrap(). ++ * ++ */ ++ ++#include "reiser4.h" ++#include "context.h" ++#include "super.h" ++#include "txnmgr.h" ++#include "znode.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include /* signal_pending() */ ++ ++#if 0 ++#if REISER4_DEBUG ++static void reiser4_report_err(void); ++#else ++#define reiser4_report_err() noop ++#endif ++#endif /* 0 */ ++ ++/* ++ * global buffer where message given to reiser4_panic is formatted. ++ */ ++static char panic_buf[REISER4_PANIC_MSG_BUFFER_SIZE]; ++ ++/* ++ * lock protecting consistency of panic_buf under concurrent panics ++ */ ++static DEFINE_SPINLOCK(panic_guard); ++ ++/* Your best friend. Call it on each occasion. This is called by ++ fs/reiser4/debug.h:reiser4_panic(). */ ++void reiser4_do_panic(const char *format/* format string */ , ... /* rest */) ++{ ++ static int in_panic = 0; ++ va_list args; ++ ++ /* ++ * check for recursive panic. ++ */ ++ if (in_panic == 0) { ++ in_panic = 1; ++ ++ spin_lock(&panic_guard); ++ va_start(args, format); ++ vsnprintf(panic_buf, sizeof(panic_buf), format, args); ++ va_end(args); ++ printk(KERN_EMERG "reiser4 panicked cowardly: %s", panic_buf); ++ spin_unlock(&panic_guard); ++ ++ /* ++ * if kernel debugger is configured---drop in. Early dropping ++ * into kgdb is not always convenient, because panic message ++ * is not yet printed most of the times. But: ++ * ++ * (1) message can be extracted from printk_buf[] ++ * (declared static inside of printk()), and ++ * ++ * (2) sometimes serial/kgdb combo dies while printing ++ * long panic message, so it's more prudent to break into ++ * debugger earlier. ++ * ++ */ ++ DEBUGON(1); ++ } ++ /* to make gcc happy about noreturn attribute */ ++ panic("%s", panic_buf); ++} ++ ++#if 0 ++void ++reiser4_print_prefix(const char *level, int reperr, const char *mid, ++ const char *function, const char *file, int lineno) ++{ ++ const char *comm; ++ int pid; ++ ++ if (unlikely(in_interrupt() || in_irq())) { ++ comm = "interrupt"; ++ pid = 0; ++ } else { ++ comm = current->comm; ++ pid = current->pid; ++ } ++ printk("%sreiser4[%.16s(%i)]: %s (%s:%i)[%s]:\n", ++ level, comm, pid, function, file, lineno, mid); ++ if (reperr) ++ reiser4_report_err(); ++} ++#endif /* 0 */ ++ ++/* Preemption point: this should be called periodically during long running ++ operations (carry, allocate, and squeeze are best examples) */ ++int reiser4_preempt_point(void) ++{ ++ assert("nikita-3008", reiser4_schedulable()); ++ cond_resched(); ++ return signal_pending(current); ++} ++ ++#if REISER4_DEBUG ++/* Debugging aid: return struct where information about locks taken by current ++ thread is accumulated. This can be used to formulate lock ordering ++ constraints and various assertions. ++ ++*/ ++reiser4_lock_cnt_info *reiser4_lock_counters(void) ++{ ++ reiser4_context *ctx = get_current_context(); ++ assert("jmacd-1123", ctx != NULL); ++ return &ctx->locks; ++} ++ ++/* ++ * print human readable information about locks held by the reiser4 context. ++ */ ++static void print_lock_counters(const char *prefix, ++ const reiser4_lock_cnt_info * info) ++{ ++ printk("%s: jnode: %i, tree: %i (r:%i,w:%i), dk: %i (r:%i,w:%i)\n" ++ "jload: %i, " ++ "txnh: %i, atom: %i, stack: %i, txnmgr: %i, " ++ "ktxnmgrd: %i, fq: %i\n" ++ "inode: %i, " ++ "cbk_cache: %i (r:%i,w%i), " ++ "eflush: %i, " ++ "zlock: %i,\n" ++ "spin: %i, long: %i inode_sem: (r:%i,w:%i)\n" ++ "d: %i, x: %i, t: %i\n", prefix, ++ info->spin_locked_jnode, ++ info->rw_locked_tree, info->read_locked_tree, ++ info->write_locked_tree, ++ info->rw_locked_dk, info->read_locked_dk, info->write_locked_dk, ++ info->spin_locked_jload, ++ info->spin_locked_txnh, ++ info->spin_locked_atom, info->spin_locked_stack, ++ info->spin_locked_txnmgr, info->spin_locked_ktxnmgrd, ++ info->spin_locked_fq, ++ info->spin_locked_inode, ++ info->rw_locked_cbk_cache, ++ info->read_locked_cbk_cache, ++ info->write_locked_cbk_cache, ++ info->spin_locked_super_eflush, ++ info->spin_locked_zlock, ++ info->spin_locked, ++ info->long_term_locked_znode, ++ info->inode_sem_r, info->inode_sem_w, ++ info->d_refs, info->x_refs, info->t_refs); ++} ++ ++/* check that no spinlocks are held */ ++int reiser4_schedulable(void) ++{ ++ if (get_current_context_check() != NULL) { ++ if (!LOCK_CNT_NIL(spin_locked)) { ++ print_lock_counters("in atomic", reiser4_lock_counters()); ++ return 0; ++ } ++ } ++ might_sleep(); ++ return 1; ++} ++/* ++ * return true, iff no locks are held. ++ */ ++int reiser4_no_counters_are_held(void) ++{ ++ reiser4_lock_cnt_info *counters; ++ ++ counters = reiser4_lock_counters(); ++ return ++ (counters->spin_locked_zlock == 0) && ++ (counters->spin_locked_jnode == 0) && ++ (counters->rw_locked_tree == 0) && ++ (counters->read_locked_tree == 0) && ++ (counters->write_locked_tree == 0) && ++ (counters->rw_locked_dk == 0) && ++ (counters->read_locked_dk == 0) && ++ (counters->write_locked_dk == 0) && ++ (counters->spin_locked_txnh == 0) && ++ (counters->spin_locked_atom == 0) && ++ (counters->spin_locked_stack == 0) && ++ (counters->spin_locked_txnmgr == 0) && ++ (counters->spin_locked_inode == 0) && ++ (counters->spin_locked == 0) && ++ (counters->long_term_locked_znode == 0) && ++ (counters->inode_sem_r == 0) && ++ (counters->inode_sem_w == 0) && (counters->d_refs == 0); ++} ++ ++/* ++ * return true, iff transaction commit can be done under locks held by the ++ * current thread. ++ */ ++int reiser4_commit_check_locks(void) ++{ ++ reiser4_lock_cnt_info *counters; ++ int inode_sem_r; ++ int inode_sem_w; ++ int result; ++ ++ /* ++ * inode's read/write semaphore is the only reiser4 lock that can be ++ * held during commit. ++ */ ++ ++ counters = reiser4_lock_counters(); ++ inode_sem_r = counters->inode_sem_r; ++ inode_sem_w = counters->inode_sem_w; ++ ++ counters->inode_sem_r = counters->inode_sem_w = 0; ++ result = reiser4_no_counters_are_held(); ++ counters->inode_sem_r = inode_sem_r; ++ counters->inode_sem_w = inode_sem_w; ++ return result; ++} ++ ++/* ++ * fill "error site" in the current reiser4 context. See comment before RETERR ++ * macro for more details. ++ */ ++void reiser4_return_err(int code, const char *file, int line) ++{ ++ if (code < 0 && is_in_reiser4_context()) { ++ reiser4_context *ctx = get_current_context(); ++ ++ if (ctx != NULL) { ++ ctx->err.code = code; ++ ctx->err.file = file; ++ ctx->err.line = line; ++ } ++ } ++} ++ ++#if 0 ++/* ++ * report error information recorder by reiser4_return_err(). ++ */ ++static void reiser4_report_err(void) ++{ ++ reiser4_context *ctx = get_current_context_check(); ++ ++ if (ctx != NULL) { ++ if (ctx->err.code != 0) { ++ printk("code: %i at %s:%i\n", ++ ctx->err.code, ctx->err.file, ctx->err.line); ++ } ++ } ++} ++#endif /* 0 */ ++ ++#endif /* REISER4_DEBUG */ ++ ++#if KERNEL_DEBUGGER ++ ++/* ++ * this functions just drops into kernel debugger. It is a convenient place to ++ * put breakpoint in. ++ */ ++void reiser4_debugtrap(void) ++{ ++ /* do nothing. Put break point here. */ ++#if defined(CONFIG_KGDB) && !defined(CONFIG_REISER4_FS_MODULE) ++ extern void kgdb_breakpoint(void); ++ //kgdb_breakpoint(); ++ ; ++#endif ++} ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/debug.h linux-5.10.2/fs/reiser4/debug.h +--- linux-5.10.2.orig/fs/reiser4/debug.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/debug.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,344 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Declarations of debug macros. */ ++ ++#if !defined(__FS_REISER4_DEBUG_H__) ++#define __FS_REISER4_DEBUG_H__ ++ ++#include "forward.h" ++#include "reiser4.h" ++ ++/** ++ * generic function to produce formatted output, decorating it with ++ * whatever standard prefixes/postfixes we want. "Fun" is a function ++ * that will be actually called, can be printk, panic etc. ++ * This is for use by other debugging macros, not by users. ++ */ ++#define DCALL(lev, fun, reperr, label, format, ...) \ ++({ \ ++ fun(lev "reiser4[%.16s(%i)]: %s (%s:%i)[%s]:\n" format "\n" , \ ++ current->comm, current->pid, __FUNCTION__, \ ++ __FILE__, __LINE__, label, ## __VA_ARGS__); \ ++}) ++ ++/* ++ * cause kernel to crash ++ */ ++#define reiser4_panic(mid, format, ...) \ ++ DCALL("", reiser4_do_panic, 1, mid, format , ## __VA_ARGS__) ++ ++/* print message with indication of current process, file, line and ++ function */ ++#define reiser4_log(label, format, ...) \ ++ DCALL(KERN_DEBUG, printk, 0, label, format , ## __VA_ARGS__) ++ ++#define noop do {; } while (0) ++ ++#if REISER4_DEBUG ++/* version of info that only actually prints anything when _d_ebugging ++ is on */ ++#define dinfo(format, ...) printk(format , ## __VA_ARGS__) ++/* macro to catch logical errors. Put it into `default' clause of ++ switch() statement. */ ++#define impossible(label, format, ...) \ ++ reiser4_panic(label, "impossible: " format , ## __VA_ARGS__) ++/* assert assures that @cond is true. If it is not, reiser4_panic() is ++ called. Use this for checking logical consistency and _never_ call ++ this to check correctness of external data: disk blocks and user-input . */ ++#define assert(label, cond) \ ++({ \ ++ /* call_on_each_assert(); */ \ ++ if (cond) { \ ++ /* put negated check to avoid using !(cond) that would lose \ ++ * warnings for things like assert(a = b); */ \ ++ ; \ ++ } else { \ ++ DEBUGON(1); \ ++ reiser4_panic(label, "assertion failed: %s", #cond); \ ++ } \ ++}) ++ ++/* like assertion, but @expr is evaluated even if REISER4_DEBUG is off. */ ++#define check_me(label, expr) assert(label, (expr)) ++ ++#define ON_DEBUG(exp) exp ++ ++extern int reiser4_schedulable(void); ++extern void call_on_each_assert(void); ++ ++#else ++ ++#define dinfo(format, args...) noop ++#define impossible(label, format, args...) noop ++#define assert(label, cond) noop ++#define check_me(label, expr) ((void) (expr)) ++#define ON_DEBUG(exp) ++#define reiser4_schedulable() might_sleep() ++ ++/* REISER4_DEBUG */ ++#endif ++ ++#if REISER4_DEBUG ++/* per-thread information about lock acquired by this thread. Used by lock ++ * ordering checking in spin_macros.h */ ++typedef struct reiser4_lock_cnt_info { ++ int rw_locked_tree; ++ int read_locked_tree; ++ int write_locked_tree; ++ ++ int rw_locked_dk; ++ int read_locked_dk; ++ int write_locked_dk; ++ ++ int rw_locked_cbk_cache; ++ int read_locked_cbk_cache; ++ int write_locked_cbk_cache; ++ ++ int spin_locked_zlock; ++ int spin_locked_jnode; ++ int spin_locked_jload; ++ int spin_locked_txnh; ++ int spin_locked_atom; ++ int spin_locked_stack; ++ int spin_locked_txnmgr; ++ int spin_locked_ktxnmgrd; ++ int spin_locked_fq; ++ int spin_locked_inode; ++ int spin_locked_super_eflush; ++ int spin_locked; ++ int long_term_locked_znode; ++ ++ int inode_sem_r; ++ int inode_sem_w; ++ ++ int d_refs; ++ int x_refs; ++ int t_refs; ++} reiser4_lock_cnt_info; ++ ++extern struct reiser4_lock_cnt_info *reiser4_lock_counters(void); ++#define IN_CONTEXT(a, b) (is_in_reiser4_context() ? (a) : (b)) ++ ++/* increment lock-counter @counter, if present */ ++#define LOCK_CNT_INC(counter) \ ++ IN_CONTEXT(++(reiser4_lock_counters()->counter), 0) ++ ++/* decrement lock-counter @counter, if present */ ++#define LOCK_CNT_DEC(counter) \ ++ IN_CONTEXT(--(reiser4_lock_counters()->counter), 0) ++ ++/* check that lock-counter is zero. This is for use in assertions */ ++#define LOCK_CNT_NIL(counter) \ ++ IN_CONTEXT(reiser4_lock_counters()->counter == 0, 1) ++ ++/* check that lock-counter is greater than zero. This is for use in ++ * assertions */ ++#define LOCK_CNT_GTZ(counter) \ ++ IN_CONTEXT(reiser4_lock_counters()->counter > 0, 1) ++#define LOCK_CNT_LT(counter,n) \ ++ IN_CONTEXT(reiser4_lock_counters()->counter < n, 1) ++ ++#else /* REISER4_DEBUG */ ++ ++/* no-op versions on the above */ ++ ++typedef struct reiser4_lock_cnt_info { ++} reiser4_lock_cnt_info; ++ ++#define reiser4_lock_counters() ((reiser4_lock_cnt_info *)NULL) ++#define LOCK_CNT_INC(counter) noop ++#define LOCK_CNT_DEC(counter) noop ++#define LOCK_CNT_NIL(counter) (1) ++#define LOCK_CNT_GTZ(counter) (1) ++#define LOCK_CNT_LT(counter, n) (1) ++ ++#endif /* REISER4_DEBUG */ ++ ++#define assert_spin_not_locked(lock) BUG_ON(0) ++#define assert_rw_write_locked(lock) BUG_ON(0) ++#define assert_rw_read_locked(lock) BUG_ON(0) ++#define assert_rw_locked(lock) BUG_ON(0) ++#define assert_rw_not_write_locked(lock) BUG_ON(0) ++#define assert_rw_not_read_locked(lock) BUG_ON(0) ++#define assert_rw_not_locked(lock) BUG_ON(0) ++ ++/* flags controlling debugging behavior. Are set through debug_flags=N mount ++ option. */ ++typedef enum { ++ /* print a lot of information during panic. When this is on all jnodes ++ * are listed. This can be *very* large output. Usually you don't want ++ * this. Especially over serial line. */ ++ REISER4_VERBOSE_PANIC = 0x00000001, ++ /* print a lot of information during umount */ ++ REISER4_VERBOSE_UMOUNT = 0x00000002, ++ /* print gathered statistics on umount */ ++ REISER4_STATS_ON_UMOUNT = 0x00000004, ++ /* check node consistency */ ++ REISER4_CHECK_NODE = 0x00000008 ++} reiser4_debug_flags; ++ ++extern int is_in_reiser4_context(void); ++ ++/* ++ * evaluate expression @e only if with reiser4 context ++ */ ++#define ON_CONTEXT(e) do { \ ++ if (is_in_reiser4_context()) { \ ++ e; \ ++ } } while (0) ++ ++/* ++ * evaluate expression @e only when within reiser4_context and debugging is ++ * on. ++ */ ++#define ON_DEBUG_CONTEXT(e) ON_DEBUG(ON_CONTEXT(e)) ++ ++/* ++ * complain about unexpected function result and crash. Used in "default" ++ * branches of switch statements and alike to assert that invalid results are ++ * not silently ignored. ++ */ ++#define wrong_return_value(label, function) \ ++ impossible(label, "wrong return value from " function) ++ ++/* Issue different types of reiser4 messages to the console */ ++#define warning(label, format, ...) \ ++ DCALL(KERN_WARNING, \ ++ printk, 1, label, "WARNING: " format , ## __VA_ARGS__) ++#define notice(label, format, ...) \ ++ DCALL(KERN_NOTICE, \ ++ printk, 1, label, "NOTICE: " format , ## __VA_ARGS__) ++ ++/* mark not yet implemented functionality */ ++#define not_yet(label, format, ...) \ ++ reiser4_panic(label, "NOT YET IMPLEMENTED: " format , ## __VA_ARGS__) ++ ++extern void reiser4_do_panic(const char *format, ...) ++ __attribute__ ((noreturn, format(printf, 1, 2))); ++ ++extern int reiser4_preempt_point(void); ++extern void reiser4_print_stats(void); ++ ++#if REISER4_DEBUG ++extern int reiser4_no_counters_are_held(void); ++extern int reiser4_commit_check_locks(void); ++#else ++#define reiser4_no_counters_are_held() (1) ++#define reiser4_commit_check_locks() (1) ++#endif ++ ++/* true if @i is power-of-two. Useful for rate-limited warnings, etc. */ ++#define IS_POW(i) \ ++({ \ ++ typeof(i) __i; \ ++ \ ++ __i = (i); \ ++ !(__i & (__i - 1)); \ ++}) ++ ++#define KERNEL_DEBUGGER (1) ++ ++#if KERNEL_DEBUGGER ++ ++extern void reiser4_debugtrap(void); ++ ++/* ++ * Check condition @cond and drop into kernel debugger (kgdb) if it's true. If ++ * kgdb is not compiled in, do nothing. ++ */ ++#define DEBUGON(cond) \ ++({ \ ++ if (unlikely(cond)) \ ++ reiser4_debugtrap(); \ ++}) ++#else ++#define DEBUGON(cond) noop ++#endif ++ ++/* ++ * Error code tracing facility. (Idea is borrowed from XFS code.) ++ * ++ * Suppose some strange and/or unexpected code is returned from some function ++ * (for example, write(2) returns -EEXIST). It is possible to place a ++ * breakpoint in the reiser4_write(), but it is too late here. How to find out ++ * in what particular place -EEXIST was generated first? ++ * ++ * In reiser4 all places where actual error codes are produced (that is, ++ * statements of the form ++ * ++ * return -EFOO; // (1), or ++ * ++ * result = -EFOO; // (2) ++ * ++ * are replaced with ++ * ++ * return RETERR(-EFOO); // (1a), and ++ * ++ * result = RETERR(-EFOO); // (2a) respectively ++ * ++ * RETERR() macro fills a backtrace in reiser4_context. This back-trace is ++ * printed in error and warning messages. Moreover, it's possible to put a ++ * conditional breakpoint in reiser4_return_err (low-level function called ++ * by RETERR() to do the actual work) to break into debugger immediately ++ * when particular error happens. ++ * ++ */ ++ ++#if REISER4_DEBUG ++ ++/* ++ * data-type to store information about where error happened ("error site"). ++ */ ++typedef struct err_site { ++ int code; /* error code */ ++ const char *file; /* source file, filled by __FILE__ */ ++ int line; /* source file line, filled by __LINE__ */ ++} err_site; ++ ++extern void reiser4_return_err(int code, const char *file, int line); ++ ++/* ++ * fill &get_current_context()->err_site with error information. ++ */ ++#define RETERR(code) \ ++({ \ ++ typeof(code) __code; \ ++ \ ++ __code = (code); \ ++ reiser4_return_err(__code, __FILE__, __LINE__); \ ++ __code; \ ++}) ++ ++#else ++ ++/* ++ * no-op versions of the above ++ */ ++ ++typedef struct err_site { ++} err_site; ++#define RETERR(code) code ++#endif ++ ++#if REISER4_LARGE_KEY ++/* ++ * conditionally compile arguments only if REISER4_LARGE_KEY is on. ++ */ ++#define ON_LARGE_KEY(...) __VA_ARGS__ ++#else ++#define ON_LARGE_KEY(...) ++#endif ++ ++/* __FS_REISER4_DEBUG_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/dformat.h linux-5.10.2/fs/reiser4/dformat.h +--- linux-5.10.2.orig/fs/reiser4/dformat.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/dformat.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,124 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Formats of on-disk data and conversion functions. */ ++ ++/* put all item formats in the files describing the particular items, ++ our model is, everything you need to do to add an item to reiser4, ++ (excepting the changes to the plugin that uses the item which go ++ into the file defining that plugin), you put into one file. */ ++/* Data on disk are stored in little-endian format. ++ To declare fields of on-disk structures, use d8, d16, d32 and d64. ++ d??tocpu() and cputod??() to convert. */ ++ ++#if !defined(__FS_REISER4_DFORMAT_H__) ++#define __FS_REISER4_DFORMAT_H__ ++ ++#include "debug.h" ++ ++#include ++#include ++#include ++ ++typedef __u8 d8; ++typedef __le16 d16; ++typedef __le32 d32; ++typedef __le64 d64; ++ ++#define PACKED __attribute__((packed)) ++ ++/* data-type for block number */ ++typedef __u64 reiser4_block_nr; ++ ++static_assert(sizeof(reiser4_block_nr) == 8); ++ ++/* data-type for block number on disk, disk format */ ++typedef __le64 reiser4_dblock_nr; ++ ++/** ++ * disk_addr_eq - compare disk addresses ++ * @b1: pointer to block number ot compare ++ * @b2: pointer to block number ot compare ++ * ++ * Returns true if if disk addresses are the same ++ */ ++static inline int disk_addr_eq(const reiser4_block_nr * b1, ++ const reiser4_block_nr * b2) ++{ ++ assert("nikita-1033", b1 != NULL); ++ assert("nikita-1266", b2 != NULL); ++ ++ return !memcmp(b1, b2, sizeof *b1); ++} ++ ++/* ++ * Structure of master super block. ++ * Having been set by mkfs utility, master super block never ++ * get changed in its life long and doesn't participate in ++ * transactions. ++ */ ++typedef struct reiser4_master_sb { ++ char magic[16]; /* "ReIsEr4" */ ++ d16 dformat_pid; /* disk format plugin id (per subvolume) */ ++ d16 blocksize; /* block size (per-volume) */ ++ char uuid[16]; /* volume id (per volume) */ ++ char label[16]; /* filesystem label (per volume) */ ++ /* Reiser5 */ ++ char sub_uuid[16]; /* subvolume's external id (per subolvume) */ ++ d16 volume_pid; /* volume plugin id (per volume) */ ++ d16 distrib_pid; /* distribution plugin id (per volume) */ ++ d16 mirror_id; /* serial (ordered) number of the mirror ++ (0 for original subvolumes) */ ++ d16 num_replicas; /* number of replicas of an original subvolume. ++ Original is a mirror with id=0, other mirrors ++ (if any) are called replicas */ ++ char stripe_bits; /* logarithm of stripe size (per volume) */ ++} reiser4_master_sb; ++ ++static inline u16 master_get_block_size(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->blocksize)); ++} ++ ++static inline u16 master_get_dformat_pid(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->dformat_pid)); ++} ++ ++static inline u16 master_get_volume_pid(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->volume_pid)); ++} ++ ++static inline u16 master_get_distrib_pid(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->distrib_pid)); ++} ++ ++static inline u16 master_get_mirror_id(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->mirror_id)); ++} ++ ++static inline u16 master_get_num_replicas(reiser4_master_sb *master) ++{ ++ return le16_to_cpu(get_unaligned(&master->num_replicas)); ++} ++ ++static inline char master_get_stripe_bits(reiser4_master_sb *master) ++{ ++ return master->stripe_bits; ++} ++ ++/* __FS_REISER4_DFORMAT_H__ */ ++#endif ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/discard.c linux-5.10.2/fs/reiser4/discard.c +--- linux-5.10.2.orig/fs/reiser4/discard.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/discard.c 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,182 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* TRIM/discard interoperation subsystem for reiser4. */ ++ ++/* ++ * This subsystem is responsible for populating an atom's ->discard_set and ++ * (later) converting it into a series of discard calls to the kernel. ++ * ++ * The discard is an in-kernel interface for notifying the storage ++ * hardware about blocks that are being logically freed by the filesystem. ++ * This is done via calling the blkdev_issue_discard() function. There are ++ * restrictions on block ranges: they should constitute at least one erase unit ++ * in length and be correspondingly aligned. Otherwise a discard request will ++ * be ignored. ++ * ++ * The erase unit size is kept in struct queue_limits as discard_granularity. ++ * The offset from the partition start to the first erase unit is kept in ++ * struct queue_limits as discard_alignment. ++ * ++ * At atom level, we record numbers of all blocks that happen to be deallocated ++ * during the transaction. Then we read the generated set, filter out any blocks ++ * that have since been allocated again and issue discards for everything still ++ * valid. This is what discard.[ch] is here for. ++ * ++ * However, simply iterating through the recorded extents is not enough: ++ * - if a single extent is smaller than the erase unit, then this particular ++ * extent won't be discarded even if it is surrounded by enough free blocks ++ * to constitute a whole erase unit; ++ * - we won't be able to merge small adjacent extents forming an extent long ++ * enough to be discarded. ++ * ++ * MECHANISM: ++ * ++ * During the transaction deallocated extents are recorded in atom's delete ++ * set. In reiser4, there are two methods to deallocate a block: ++ * 1. deferred deallocation, enabled by BA_DEFER flag to reiser4_dealloc_block(). ++ * In this mode, blocks are stored to delete set instead of being marked free ++ * immediately. After committing the transaction, the delete set is "applied" ++ * by the block allocator and all these blocks are marked free in memory ++ * (see reiser4_post_write_back_hook()). ++ * Space management plugins also read the delete set to update on-disk ++ * allocation records (see reiser4_pre_commit_hook()). ++ * 2. immediate deallocation (the opposite). ++ * In this mode, blocks are marked free immediately. This is used by the ++ * journal subsystem to manage space used by the journal records, so these ++ * allocations are not visible to the space management plugins and never hit ++ * the disk. ++ * ++ * When discard is enabled, all immediate deallocations become deferred. This ++ * is OK because journal's allocations happen after reiser4_pre_commit_hook() ++ * where the on-disk space allocation records are updated. So, in this mode ++ * the atom's delete set becomes "the discard set" -- list of blocks that have ++ * to be considered for discarding. ++ * ++ * Discarding is performed before completing deferred deallocations, hence all ++ * extents in the discard set are still marked as allocated and cannot contain ++ * any data. Thus we can avoid any checks for blocks directly present in the ++ * discard set. ++ * ++ * For now, we don't perform "padding" of extents to erase unit boundaries. ++ * This means if extents are not aligned with the device's erase unit lattice, ++ * the partial erase units at head and tail of extents are truncated by kernel ++ * (in blkdev_issue_discard()). ++ * ++ * So, at commit time the following actions take place: ++ * - delete sets are merged to form the discard set; ++ * - elements of the discard set are sorted; ++ * - the discard set is iterated, joining any adjacent extents; ++ * - for each extent, a single call to blkdev_issue_discard() is done. ++ */ ++ ++#include "discard.h" ++#include "context.h" ++#include "debug.h" ++#include "txnmgr.h" ++#include "super.h" ++ ++#include ++#include ++#include ++ ++static int __discard_extent(struct block_device *bdev, sector_t start, ++ sector_t len) ++{ ++ assert("intelfx-21", bdev != NULL); ++ ++ return blkdev_issue_discard(bdev, start, len, reiser4_ctx_gfp_mask_get(), ++ 0); ++} ++ ++static int discard_extent(txn_atom *atom UNUSED_ARG, ++ const reiser4_block_nr* start, ++ const reiser4_block_nr* len, ++ __u32 subvol_id, ++ void *data UNUSED_ARG) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ reiser4_subvol *subv = super_origin(sb, subvol_id); ++ struct block_device *bdev = subv->bdev; ++ sector_t extent_start_sec, extent_len_sec; ++ const int sec_per_blk = sb->s_blocksize >> 9; ++ ++ if (!subvol_is_set(subv, SUBVOL_IS_NONROT_DEVICE)) ++ return 0; ++ ++ /* we assume block = N * sector */ ++ assert("intelfx-7", sec_per_blk > 0); ++ ++ /* convert extent to sectors */ ++ extent_start_sec = *start * sec_per_blk; ++ extent_len_sec = *len * sec_per_blk; ++ ++ /* discard the extent, don't pad it to erase unit boundaries for now */ ++ return __discard_extent(bdev, extent_start_sec, extent_len_sec); ++} ++ ++int discard_atom(txn_atom *atom, struct list_head *processed_set) ++{ ++ int ret; ++ struct list_head discard_set; ++ ++ if (!reiser4_is_set(reiser4_get_current_sb(), REISER4_DISCARD)) { ++ spin_unlock_atom(atom); ++ return 0; ++ } ++ ++ assert("intelfx-28", atom != NULL); ++ assert("intelfx-59", processed_set != NULL); ++ ++ if (list_empty(&atom->discard.delete_set)) { ++ /* Nothing left to discard. */ ++ spin_unlock_atom(atom); ++ return 0; ++ } ++ ++ /* Take the delete sets from the atom in order to release atom spinlock. */ ++ blocknr_list_init(&discard_set); ++ blocknr_list_merge(&atom->discard.delete_set, &discard_set); ++ spin_unlock_atom(atom); ++ ++ /* Sort the discard list, joining adjacent and overlapping extents. */ ++ blocknr_list_sort_and_join(&discard_set); ++ ++ /* Perform actual dirty work. */ ++ ret = blocknr_list_iterator(NULL, &discard_set, &discard_extent, NULL, 0); ++ ++ /* Add processed extents to the temporary list. */ ++ blocknr_list_merge(&discard_set, processed_set); ++ ++ if (ret != 0) { ++ return ret; ++ } ++ ++ /* Let's do this again for any new extents in the atom's discard set. */ ++ return -E_REPEAT; ++} ++ ++void discard_atom_post(txn_atom *atom, struct list_head *processed_set) ++{ ++ assert("intelfx-60", atom != NULL); ++ assert("intelfx-61", processed_set != NULL); ++ ++ if (!reiser4_is_set(reiser4_get_current_sb(), REISER4_DISCARD)) { ++ spin_unlock_atom(atom); ++ return; ++ } ++ ++ blocknr_list_merge(processed_set, &atom->discard.delete_set); ++ spin_unlock_atom(atom); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/discard.h linux-5.10.2/fs/reiser4/discard.h +--- linux-5.10.2.orig/fs/reiser4/discard.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/discard.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,42 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* TRIM/discard interoperation subsystem for reiser4. */ ++ ++#if !defined(__FS_REISER4_DISCARD_H__) ++#define __FS_REISER4_DISCARD_H__ ++ ++#include "forward.h" ++#include "dformat.h" ++ ++/** ++ * Issue discard requests for all block extents recorded in @atom's delete sets, ++ * if discard is enabled. The extents processed are removed from the @atom's ++ * delete sets and stored in @processed_set. ++ * ++ * @atom must be locked on entry and is unlocked on exit. ++ * @processed_set must be initialized with blocknr_list_init(). ++ */ ++extern int discard_atom(txn_atom *atom, struct list_head *processed_set); ++ ++/** ++ * Splices @processed_set back to @atom's delete set. ++ * Must be called after discard_atom() loop, using the same @processed_set. ++ * ++ * @atom must be locked on entry and is unlocked on exit. ++ * @processed_set must be the same as passed to discard_atom(). ++ */ ++extern void discard_atom_post(txn_atom *atom, struct list_head *processed_set); ++ ++/* __FS_REISER4_DISCARD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/dscale.c linux-5.10.2/fs/reiser4/dscale.c +--- linux-5.10.2.orig/fs/reiser4/dscale.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/dscale.c 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,192 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Scalable on-disk integers */ ++ ++/* ++ * Various on-disk structures contain integer-like structures. Stat-data ++ * contain [yes, "data" is plural, check the dictionary] file size, link ++ * count; extent unit contains extent width etc. To accommodate for general ++ * case enough space is reserved to keep largest possible value. 64 bits in ++ * all cases above. But in overwhelming majority of cases numbers actually ++ * stored in these fields will be comparatively small and reserving 8 bytes is ++ * a waste of precious disk bandwidth. ++ * ++ * Scalable integers are one way to solve this problem. dscale_write() ++ * function stores __u64 value in the given area consuming from 1 to 9 bytes, ++ * depending on the magnitude of the value supplied. dscale_read() reads value ++ * previously stored by dscale_write(). ++ * ++ * dscale_write() produces format not completely unlike of UTF: two highest ++ * bits of the first byte are used to store "tag". One of 4 possible tag ++ * values is chosen depending on the number being encoded: ++ * ++ * 0 ... 0x3f => 0 [table 1] ++ * 0x40 ... 0x3fff => 1 ++ * 0x4000 ... 0x3fffffff => 2 ++ * 0x40000000 ... 0xffffffffffffffff => 3 ++ * ++ * (see dscale_range() function) ++ * ++ * Values in the range 0x40000000 ... 0xffffffffffffffff require 8 full bytes ++ * to be stored, so in this case there is no place in the first byte to store ++ * tag. For such values tag is stored in an extra 9th byte. ++ * ++ * As _highest_ bits are used for the test (which is natural) scaled integers ++ * are stored in BIG-ENDIAN format in contrast with the rest of reiser4 which ++ * uses LITTLE-ENDIAN. ++ * ++ */ ++ ++#include "debug.h" ++#include "dscale.h" ++ ++/* return tag of scaled integer stored at @address */ ++static int gettag(const unsigned char *address) ++{ ++ /* tag is stored in two highest bits */ ++ return (*address) >> 6; ++} ++ ++/* clear tag from value. Clear tag embedded into @value. */ ++static void cleartag(__u64 *value, int tag) ++{ ++ /* ++ * W-w-what ?! ++ * ++ * Actually, this is rather simple: @value passed here was read by ++ * dscale_read(), converted from BIG-ENDIAN, and padded to __u64 by ++ * zeroes. Tag is still stored in the highest (arithmetically) ++ * non-zero bits of @value, but relative position of tag within __u64 ++ * depends on @tag. ++ * ++ * For example if @tag is 0, it's stored 2 highest bits of lowest ++ * byte, and its offset (counting from lowest bit) is 8 - 2 == 6 bits. ++ * ++ * If tag is 1, it's stored in two highest bits of 2nd lowest byte, ++ * and it's offset if (2 * 8) - 2 == 14 bits. ++ * ++ * See table 1 above for details. ++ * ++ * All these cases are captured by the formula: ++ */ ++ *value &= ~(3 << (((1 << tag) << 3) - 2)); ++ /* ++ * That is, clear two (3 == 0t11) bits at the offset ++ * ++ * 8 * (2 ^ tag) - 2, ++ * ++ * that is, two highest bits of (2 ^ tag)-th byte of @value. ++ */ ++} ++ ++/* return tag for @value. See table 1 above for details. */ ++static int dscale_range(__u64 value) ++{ ++ if (value > 0x3fffffff) ++ return 3; ++ if (value > 0x3fff) ++ return 2; ++ if (value > 0x3f) ++ return 1; ++ return 0; ++} ++ ++/* restore value stored at @adderss by dscale_write() and return number of ++ * bytes consumed */ ++int dscale_read(unsigned char *address, __u64 *value) ++{ ++ int tag; ++ ++ /* read tag */ ++ tag = gettag(address); ++ switch (tag) { ++ case 3: ++ /* In this case tag is stored in an extra byte, skip this byte ++ * and decode value stored in the next 8 bytes.*/ ++ *value = __be64_to_cpu(get_unaligned((__be64 *)(address + 1))); ++ /* worst case: 8 bytes for value itself plus one byte for ++ * tag. */ ++ return 9; ++ case 0: ++ *value = get_unaligned(address); ++ break; ++ case 1: ++ *value = __be16_to_cpu(get_unaligned((__be16 *)address)); ++ break; ++ case 2: ++ *value = __be32_to_cpu(get_unaligned((__be32 *)address)); ++ break; ++ default: ++ return RETERR(-EIO); ++ } ++ /* clear tag embedded into @value */ ++ cleartag(value, tag); ++ /* number of bytes consumed is (2 ^ tag)---see table 1. */ ++ return 1 << tag; ++} ++ ++/* number of bytes consumed */ ++int dscale_bytes_to_read(unsigned char *address) ++{ ++ int tag; ++ ++ tag = gettag(address); ++ switch (tag) { ++ case 0: ++ case 1: ++ case 2: ++ return 1 << tag; ++ case 3: ++ return 9; ++ default: ++ return RETERR(-EIO); ++ } ++} ++ ++/* store @value at @address and return number of bytes consumed */ ++int dscale_write(unsigned char *address, __u64 value) ++{ ++ int tag; ++ int shift; ++ __be64 v; ++ unsigned char *valarr; ++ ++ tag = dscale_range(value); ++ v = __cpu_to_be64(value); ++ valarr = (unsigned char *)&v; ++ shift = (tag == 3) ? 1 : 0; ++ memcpy(address + shift, valarr + sizeof v - (1 << tag), 1 << tag); ++ *address |= (tag << 6); ++ return shift + (1 << tag); ++} ++ ++/* number of bytes required to store @value */ ++int dscale_bytes_to_write(__u64 value) ++{ ++ int bytes; ++ ++ bytes = 1 << dscale_range(value); ++ if (bytes == 8) ++ ++bytes; ++ return bytes; ++} ++ ++/* returns true if @value and @other require the same number of bytes to be ++ * stored. Used by detect when data structure (like stat-data) has to be ++ * expanded or contracted. */ ++int dscale_fit(__u64 value, __u64 other) ++{ ++ return dscale_range(value) == dscale_range(other); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/dscale.h linux-5.10.2/fs/reiser4/dscale.h +--- linux-5.10.2.orig/fs/reiser4/dscale.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/dscale.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,28 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Scalable on-disk integers. See dscale.h for details. */ ++ ++#if !defined(__FS_REISER4_DSCALE_H__) ++#define __FS_REISER4_DSCALE_H__ ++ ++#include "dformat.h" ++ ++extern int dscale_read(unsigned char *address, __u64 *value); ++extern int dscale_write(unsigned char *address, __u64 value); ++extern int dscale_bytes_to_read(unsigned char *address); ++extern int dscale_bytes_to_write(__u64 value); ++extern int dscale_fit(__u64 value, __u64 other); ++ ++/* __FS_REISER4_DSCALE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/entd.c linux-5.10.2/fs/reiser4/entd.c +--- linux-5.10.2.orig/fs/reiser4/entd.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/entd.c 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,361 @@ ++/* Copyright 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Ent daemon. */ ++ ++#include "debug.h" ++#include "txnmgr.h" ++#include "tree.h" ++#include "entd.h" ++#include "super.h" ++#include "context.h" ++#include "reiser4.h" ++#include "vfs_ops.h" ++#include "page_cache.h" ++#include "inode.h" ++ ++#include /* struct task_struct */ ++#include ++#include ++#include ++#include /* INITIAL_JIFFIES */ ++#include /* bdi_write_congested */ ++#include ++#include ++#include ++ ++#define DEF_PRIORITY 12 ++#define MAX_ENTD_ITERS 10 ++ ++static void entd_flush(struct super_block *, struct wbq *); ++static int entd(void *arg); ++ ++/* ++ * set ->comm field of end thread to make its state visible to the user level ++ */ ++#define entd_set_comm(state) \ ++ snprintf(current->comm, sizeof(current->comm), \ ++ "ent:%s%s", super->s_id, (state)) ++ ++/** ++ * reiser4_init_entd - initialize entd context and start kernel daemon ++ * @super: super block to start ent thread for ++ * ++ * Creates entd contexts, starts kernel thread and waits until it ++ * initializes. ++ */ ++int reiser4_init_entd(struct super_block *super) ++{ ++ entd_context *ctx; ++ ++ assert("nikita-3104", super != NULL); ++ ++ ctx = get_entd_context(super); ++ ++ memset(ctx, 0, sizeof *ctx); ++ spin_lock_init(&ctx->guard); ++ init_waitqueue_head(&ctx->wait); ++#if REISER4_DEBUG ++ INIT_LIST_HEAD(&ctx->flushers_list); ++#endif ++ /* lists of writepage requests */ ++ INIT_LIST_HEAD(&ctx->todo_list); ++ INIT_LIST_HEAD(&ctx->done_list); ++ /* start entd */ ++ ctx->tsk = kthread_run(entd, super, "ent:%s", super->s_id); ++ if (IS_ERR(ctx->tsk)) ++ return PTR_ERR(ctx->tsk); ++ return 0; ++} ++ ++static void put_wbq(struct wbq *rq) ++{ ++ iput(rq->mapping->host); ++ complete(&rq->completion); ++} ++ ++/* ent should be locked */ ++static struct wbq *__get_wbq(entd_context * ent) ++{ ++ struct wbq *wbq; ++ ++ if (list_empty(&ent->todo_list)) ++ return NULL; ++ ++ ent->nr_todo_reqs--; ++ wbq = list_entry(ent->todo_list.next, struct wbq, link); ++ list_del_init(&wbq->link); ++ return wbq; ++} ++ ++/* ent thread function */ ++static int entd(void *arg) ++{ ++ struct super_block *super; ++ entd_context *ent; ++ int done = 0; ++ ++ super = arg; ++ /* do_fork() just copies task_struct into the new ++ thread. ->fs_context shouldn't be copied of course. This shouldn't ++ be a problem for the rest of the code though. ++ */ ++ current->journal_info = NULL; ++ ++ ent = get_entd_context(super); ++ ++ while (!done) { ++ try_to_freeze(); ++ ++ spin_lock(&ent->guard); ++ while (ent->nr_todo_reqs != 0) { ++ struct wbq *rq; ++ ++ assert("", list_empty(&ent->done_list)); ++ ++ /* take request from the queue head */ ++ rq = __get_wbq(ent); ++ assert("", rq != NULL); ++ ent->cur_request = rq; ++ spin_unlock(&ent->guard); ++ ++ entd_set_comm("!"); ++ entd_flush(super, rq); ++ ++ put_wbq(rq); ++ ++ /* ++ * wakeup all requestors and iput their inodes ++ */ ++ spin_lock(&ent->guard); ++ while (!list_empty(&ent->done_list)) { ++ rq = list_entry(ent->done_list.next, struct wbq, link); ++ list_del_init(&rq->link); ++ ent->nr_done_reqs--; ++ spin_unlock(&ent->guard); ++ assert("", rq->written == 1); ++ put_wbq(rq); ++ spin_lock(&ent->guard); ++ } ++ } ++ spin_unlock(&ent->guard); ++ ++ entd_set_comm("."); ++ ++ { ++ DEFINE_WAIT(__wait); ++ ++ do { ++ prepare_to_wait(&ent->wait, &__wait, TASK_INTERRUPTIBLE); ++ if (kthread_should_stop()) { ++ done = 1; ++ break; ++ } ++ if (ent->nr_todo_reqs != 0) ++ break; ++ schedule(); ++ } while (0); ++ finish_wait(&ent->wait, &__wait); ++ } ++ } ++ BUG_ON(ent->nr_todo_reqs != 0); ++ return 0; ++} ++ ++/** ++ * reiser4_done_entd - stop entd kernel thread ++ * @super: super block to stop ent thread for ++ * ++ * It is called on umount. Sends stop signal to entd and wait until it handles ++ * it. ++ */ ++void reiser4_done_entd(struct super_block *super) ++{ ++ entd_context *ent; ++ ++ assert("nikita-3103", super != NULL); ++ ++ ent = get_entd_context(super); ++ assert("zam-1055", ent->tsk != NULL); ++ kthread_stop(ent->tsk); ++} ++ ++/* called at the beginning of jnode_flush to register flusher thread with ent ++ * daemon */ ++void reiser4_enter_flush(struct super_block *super) ++{ ++ entd_context *ent; ++ ++ assert("zam-1029", super != NULL); ++ ent = get_entd_context(super); ++ ++ assert("zam-1030", ent != NULL); ++ ++ spin_lock(&ent->guard); ++ ent->flushers++; ++#if REISER4_DEBUG ++ list_add(&get_current_context()->flushers_link, &ent->flushers_list); ++#endif ++ spin_unlock(&ent->guard); ++} ++ ++/* called at the end of jnode_flush */ ++void reiser4_leave_flush(struct super_block *super) ++{ ++ entd_context *ent; ++ int wake_up_ent; ++ ++ assert("zam-1027", super != NULL); ++ ent = get_entd_context(super); ++ ++ assert("zam-1028", ent != NULL); ++ ++ spin_lock(&ent->guard); ++ ent->flushers--; ++ wake_up_ent = (ent->flushers == 0 && ent->nr_todo_reqs != 0); ++#if REISER4_DEBUG ++ list_del_init(&get_current_context()->flushers_link); ++#endif ++ spin_unlock(&ent->guard); ++ if (wake_up_ent) ++ wake_up_process(ent->tsk); ++} ++ ++#define ENTD_CAPTURE_APAGE_BURST SWAP_CLUSTER_MAX ++ ++static void entd_flush(struct super_block *super, struct wbq *rq) ++{ ++ reiser4_context ctx; ++ ++ init_stack_context(&ctx, super); ++ ctx.entd = 1; ++ ctx.gfp_mask = GFP_NOFS; ++ ++ rq->wbc->range_start = page_offset(rq->page); ++ rq->wbc->range_end = rq->wbc->range_start + ++ (ENTD_CAPTURE_APAGE_BURST << PAGE_SHIFT); ++ ++ ++ rq->mapping->a_ops->writepages(rq->mapping, rq->wbc); ++ ++ if (rq->wbc->nr_to_write > 0) { ++ long result; ++ struct bdi_writeback *wb; ++ struct wb_writeback_work work = { ++ .sb = super, ++ .sync_mode = WB_SYNC_NONE, ++ .nr_pages = LONG_MAX, ++ .range_cyclic = 0, ++ .reason = WB_REASON_VMSCAN, ++ }; ++ rq->wbc->sync_mode = work.sync_mode, ++ rq->wbc->range_cyclic = work.range_cyclic, ++ rq->wbc->range_start = 0; ++ rq->wbc->range_end = LLONG_MAX; ++ /* ++ * we don't need to pin superblock for writeback: ++ * this is implicitly pinned by write_page_by_ent ++ * (via igrab), so that shutdown_super() will wait ++ * (on reiser4_put_super) for entd completion. ++ */ ++ wb = &inode_to_bdi(rq->mapping->host)->wb; ++ ++ spin_lock(&wb->list_lock); ++ result = generic_writeback_sb_inodes(super, ++ wb, ++ rq->wbc, ++ &work, ++ true); ++ spin_unlock(&wb->list_lock); ++ } ++ rq->wbc->nr_to_write = ENTD_CAPTURE_APAGE_BURST; ++ ++ reiser4_writeout(super, rq->wbc); ++ context_set_commit_async(&ctx); ++ reiser4_exit_context(&ctx); ++} ++ ++/** ++ * write_page_by_ent - ask entd thread to flush this page as part of slum ++ * @page: page to be written ++ * @wbc: writeback control passed to reiser4_writepage ++ * ++ * Creates a request, puts it on entd list of requests, wakeups entd if ++ * necessary, waits until entd completes with the request. ++ */ ++int write_page_by_ent(struct page *page, struct writeback_control *wbc) ++{ ++ struct super_block *sb; ++ struct inode *inode; ++ entd_context *ent; ++ struct wbq rq; ++ ++ assert("", PageLocked(page)); ++ assert("", page->mapping != NULL); ++ ++ sb = page->mapping->host->i_sb; ++ ent = get_entd_context(sb); ++ assert("", ent && ent->done == 0); ++ ++ /* ++ * we are going to unlock page and ask ent thread to write the ++ * page. Re-dirty page before unlocking so that if ent thread fails to ++ * write it - it will remain dirty ++ */ ++ set_page_dirty_notag(page); ++ account_page_redirty(page); ++ ++ /* ++ * pin inode in memory, unlock page, entd_flush will iput. We can not ++ * iput here becasue we can not allow delete_inode to be called here ++ */ ++ inode = igrab(page->mapping->host); ++ unlock_page(page); ++ if (inode == NULL) ++ /* inode is getting freed */ ++ return 0; ++ ++ /* init wbq */ ++ INIT_LIST_HEAD(&rq.link); ++ rq.magic = WBQ_MAGIC; ++ rq.wbc = wbc; ++ rq.page = page; ++ rq.mapping = inode->i_mapping; ++ rq.node = NULL; ++ rq.written = 0; ++ init_completion(&rq.completion); ++ ++ /* add request to entd's list of writepage requests */ ++ spin_lock(&ent->guard); ++ ent->nr_todo_reqs++; ++ list_add_tail(&rq.link, &ent->todo_list); ++ if (ent->nr_todo_reqs == 1) ++ wake_up_process(ent->tsk); ++ ++ spin_unlock(&ent->guard); ++ ++ /* wait until entd finishes */ ++ wait_for_completion(&rq.completion); ++ ++ if (rq.written) ++ /* Eventually ENTD has written the page to disk. */ ++ return 0; ++ return 0; ++} ++ ++int wbq_available(void) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ entd_context *ent = get_entd_context(sb); ++ return ent->nr_todo_reqs; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/entd.h linux-5.10.2/fs/reiser4/entd.h +--- linux-5.10.2.orig/fs/reiser4/entd.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/entd.h 2020-12-23 16:07:46.115813085 +0100 +@@ -0,0 +1,90 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Ent daemon. */ ++ ++#ifndef __ENTD_H__ ++#define __ENTD_H__ ++ ++#include "context.h" ++ ++#include ++#include ++#include ++#include ++#include /* for struct task_struct */ ++ ++#define WBQ_MAGIC 0x7876dc76 ++ ++/* write-back request. */ ++struct wbq { ++ int magic; ++ struct list_head link; /* list head of this list is in entd context */ ++ struct writeback_control *wbc; ++ struct page *page; ++ struct address_space *mapping; ++ struct completion completion; ++ jnode *node; /* set if ent thread captured requested page */ ++ int written; /* set if ent thread wrote requested page */ ++}; ++ ++/* ent-thread context. This is used to synchronize starting/stopping ent ++ * threads. */ ++typedef struct entd_context { ++ /* wait queue that ent thread waits on for more work. It's ++ * signaled by write_page_by_ent(). */ ++ wait_queue_head_t wait; ++ /* spinlock protecting other fields */ ++ spinlock_t guard; ++ /* ent thread */ ++ struct task_struct *tsk; ++ /* set to indicate that ent thread should leave. */ ++ int done; ++ /* counter of active flushers */ ++ int flushers; ++ /* ++ * when reiser4_writepage asks entd to write a page - it adds struct ++ * wbq to this list ++ */ ++ struct list_head todo_list; ++ /* number of elements on the above list */ ++ int nr_todo_reqs; ++ ++ struct wbq *cur_request; ++ /* ++ * when entd writes a page it moves write-back request from todo_list ++ * to done_list. This list is used at the end of entd iteration to ++ * wakeup requestors and iput inodes. ++ */ ++ struct list_head done_list; ++ /* number of elements on the above list */ ++ int nr_done_reqs; ++ ++#if REISER4_DEBUG ++ /* list of all active flushers */ ++ struct list_head flushers_list; ++#endif ++} entd_context; ++ ++extern int reiser4_init_entd(struct super_block *); ++extern void reiser4_done_entd(struct super_block *); ++ ++extern void reiser4_enter_flush(struct super_block *); ++extern void reiser4_leave_flush(struct super_block *); ++ ++extern int write_page_by_ent(struct page *, struct writeback_control *); ++extern int wbq_available(void); ++extern void ent_writes_page(struct super_block *, struct page *); ++ ++extern jnode *get_jnode_by_wbq(struct super_block *, struct wbq *); ++/* __ENTD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/eottl.c linux-5.10.2/fs/reiser4/eottl.c +--- linux-5.10.2.orig/fs/reiser4/eottl.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/eottl.c 2020-12-23 16:07:46.116813099 +0100 +@@ -0,0 +1,514 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/node/node.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "tree_mod.h" ++#include "carry.h" ++#include "tree.h" ++#include "super.h" ++ ++#include /* for __u?? */ ++ ++/* ++ * Extents on the twig level (EOTTL) handling. ++ * ++ * EOTTL poses some problems to the tree traversal, that are better explained ++ * by example. ++ * ++ * Suppose we have block B1 on the twig level with the following items: ++ * ++ * 0. internal item I0 with key (0:0:0:0) (locality, key-type, object-id, ++ * offset) ++ * 1. extent item E1 with key (1:4:100:0), having 10 blocks of 4k each ++ * 2. internal item I2 with key (10:0:0:0) ++ * ++ * We are trying to insert item with key (5:0:0:0). Lookup finds node B1, and ++ * then intra-node lookup is done. This lookup finished on the E1, because the ++ * key we are looking for is larger than the key of E1 and is smaller than key ++ * the of I2. ++ * ++ * Here search is stuck. ++ * ++ * After some thought it is clear what is wrong here: extents on the twig level ++ * break some basic property of the *search* tree (on the pretext, that they ++ * restore property of balanced tree). ++ * ++ * Said property is the following: if in the internal node of the search tree ++ * we have [ ... Key1 Pointer Key2 ... ] then, all data that are or will be ++ * keyed in the tree with the Key such that Key1 <= Key < Key2 are accessible ++ * through the Pointer. ++ * ++ * This is not true, when Pointer is Extent-Pointer, simply because extent ++ * cannot expand indefinitely to the right to include any item with ++ * ++ * Key1 <= Key <= Key2. ++ * ++ * For example, our E1 extent is only responsible for the data with keys ++ * ++ * (1:4:100:0) <= key <= (1:4:100:0xffffffffffffffff), and ++ * ++ * so, key range ++ * ++ * ( (1:4:100:0xffffffffffffffff), (10:0:0:0) ) ++ * ++ * is orphaned: there is no way to get there from the tree root. ++ * ++ * In other words, extent pointers are different than normal child pointers as ++ * far as search tree is concerned, and this creates such problems. ++ * ++ * Possible solution for this problem is to insert our item into node pointed ++ * to by I2. There are some problems through: ++ * ++ * (1) I2 can be in a different node. ++ * (2) E1 can be immediately followed by another extent E2. ++ * ++ * (1) is solved by calling reiser4_get_right_neighbor() and accounting ++ * for locks/coords as necessary. ++ * ++ * (2) is more complex. Solution here is to insert new empty leaf node and ++ * insert internal item between E1 and E2 pointing to said leaf node. This is ++ * further complicated by possibility that E2 is in a different node, etc. ++ * ++ * Problems: ++ * ++ * (1) if there was internal item I2 immediately on the right of an extent E1 ++ * we and we decided to insert new item S1 into node N2 pointed to by I2, then ++ * key of S1 will be less than smallest key in the N2. Normally, search key ++ * checks that key we are looking for is in the range of keys covered by the ++ * node key is being looked in. To work around of this situation, while ++ * preserving useful consistency check new flag CBK_TRUST_DK was added to the ++ * cbk falgs bitmask. This flag is automatically set on entrance to the ++ * coord_by_key() and is only cleared when we are about to enter situation ++ * described above. ++ * ++ * (2) If extent E1 is immediately followed by another extent E2 and we are ++ * searching for the key that is between E1 and E2 we only have to insert new ++ * empty leaf node when coord_by_key was called for insertion, rather than just ++ * for lookup. To distinguish these cases, new flag CBK_FOR_INSERT was added to ++ * the cbk falgs bitmask. This flag is automatically set by coord_by_key calls ++ * performed by insert_by_key() and friends. ++ * ++ * (3) Insertion of new empty leaf node (possibly) requires balancing. In any ++ * case it requires modification of node content which is only possible under ++ * write lock. It may well happen that we only have read lock on the node where ++ * new internal pointer is to be inserted (common case: lookup of non-existent ++ * stat-data that fells between two extents). If only read lock is held, tree ++ * traversal is restarted with lock_level modified so that next time we hit ++ * this problem, write lock will be held. Once we have write lock, balancing ++ * will be performed. ++ */ ++ ++/** ++ * is_next_item_internal - check whether next item is internal ++ * @coord: coordinate of extent item in twig node ++ * @key: search key ++ * @lh: twig node lock handle ++ * ++ * Looks at the unit next to @coord. If it is an internal one - 1 is returned, ++ * @coord is set to that unit. If that unit is in right neighbor, @lh is moved ++ * to that node, @coord is set to its first unit. If next item is not internal ++ * or does not exist then 0 is returned, @coord and @lh are left unchanged. 2 ++ * is returned if search restart has to be done. ++ */ ++static int ++is_next_item_internal(coord_t *coord, const reiser4_key * key, ++ lock_handle * lh) ++{ ++ coord_t next; ++ lock_handle rn; ++ int result; ++ reiser4_tree *tree = znode_get_tree(coord->node); ++ ++ coord_dup(&next, coord); ++ if (coord_next_unit(&next) == 0) { ++ /* next unit is in this node */ ++ if (item_is_internal(&next)) { ++ coord_dup(coord, &next); ++ return 1; ++ } ++ assert("vs-3", item_is_extent(&next)); ++ return 0; ++ } ++ ++ /* ++ * next unit either does not exist or is in right neighbor. If it is in ++ * right neighbor we have to check right delimiting key because ++ * concurrent thread could get their first and insert item with a key ++ * smaller than @key ++ */ ++ read_lock_dk(tree); ++ result = keycmp(key, znode_get_rd_key(coord->node)); ++ read_unlock_dk(tree); ++ assert("vs-6", result != EQUAL_TO); ++ if (result == GREATER_THAN) ++ return 2; ++ ++ /* lock right neighbor */ ++ init_lh(&rn); ++ result = reiser4_get_right_neighbor(&rn, coord->node, ++ znode_is_wlocked(coord->node) ? ++ ZNODE_WRITE_LOCK : ZNODE_READ_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result == -E_NO_NEIGHBOR) { ++ /* we are on the rightmost edge of the tree */ ++ done_lh(&rn); ++ return 0; ++ } ++ ++ if (result) { ++ assert("vs-4", result < 0); ++ done_lh(&rn); ++ return result; ++ } ++ ++ /* ++ * check whether concurrent thread managed to insert item with a key ++ * smaller than @key ++ */ ++ read_lock_dk(tree); ++ result = keycmp(key, znode_get_ld_key(rn.node)); ++ read_unlock_dk(tree); ++ assert("vs-6", result != EQUAL_TO); ++ if (result == GREATER_THAN) { ++ done_lh(&rn); ++ return 2; ++ } ++ ++ result = zload(rn.node); ++ if (result) { ++ assert("vs-5", result < 0); ++ done_lh(&rn); ++ return result; ++ } ++ ++ coord_init_first_unit(&next, rn.node); ++ if (item_is_internal(&next)) { ++ /* ++ * next unit is in right neighbor and it is an unit of internal ++ * item. Unlock coord->node. Move @lh to right neighbor. @coord ++ * is set to the first unit of right neighbor. ++ */ ++ coord_dup(coord, &next); ++ zrelse(rn.node); ++ done_lh(lh); ++ move_lh(lh, &rn); ++ return 1; ++ } ++ ++ /* ++ * next unit is unit of extent item. Return without chaning @lh and ++ * @coord. ++ */ ++ assert("vs-6", item_is_extent(&next)); ++ zrelse(rn.node); ++ done_lh(&rn); ++ return 0; ++} ++ ++/** ++ * rd_key - calculate key of an item next to the given one ++ * @coord: position in a node ++ * @key: storage for result key ++ * ++ * @coord is set between items or after the last item in a node. Calculate key ++ * of item to the right of @coord. ++ */ ++static reiser4_key *rd_key(const coord_t *coord, reiser4_key *key) ++{ ++ coord_t dup; ++ reiser4_tree *tree; ++ ++ assert("nikita-2281", coord_is_between_items(coord)); ++ ++ tree = znode_get_tree(coord->node); ++ coord_dup(&dup, coord); ++ ++ if (coord_set_to_right(&dup) == 0) ++ /* next item is in this node. Return its key. */ ++ unit_key_by_coord(&dup, key); ++ else { ++ /* ++ * next item either does not exist or is in right ++ * neighbor. Return znode's right delimiting key. ++ */ ++ read_lock_dk(tree); ++ *key = *znode_get_rd_key(coord->node); ++ read_unlock_dk(tree); ++ } ++ return key; ++} ++ ++/** ++ * add_empty_leaf - insert empty leaf between two extents ++ * @insert_coord: position in twig node between two extents ++ * @lh: twig node lock handle ++ * @key: left delimiting key of new node ++ * @rdkey: right delimiting key of new node ++ * ++ * Inserts empty leaf node between two extent items. It is necessary when we ++ * have to insert an item on leaf level between two extents (items on the twig ++ * level). ++ */ ++static int ++add_empty_leaf(coord_t *insert_coord, lock_handle *lh, ++ const reiser4_key *key, const reiser4_key *rdkey) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *todo; ++ reiser4_item_data *item; ++ carry_insert_data *cdata; ++ carry_op *op; ++ znode *node; ++ reiser4_tree *tree; ++ ++ assert("vs-49827", znode_contains_key_lock(insert_coord->node, key)); ++ tree = znode_get_tree(insert_coord->node); ++ node = reiser4_new_node(insert_coord->node, LEAF_LEVEL); ++ if (IS_ERR(node)) ++ return PTR_ERR(node); ++ ++ /* setup delimiting keys for node being inserted */ ++ write_lock_dk(tree); ++ znode_set_ld_key(node, key); ++ znode_set_rd_key(node, rdkey); ++ ON_DEBUG(node->creator = current); ++ ON_DEBUG(node->first_key = *key); ++ write_unlock_dk(tree); ++ ++ ZF_SET(node, JNODE_ORPHAN); ++ ++ /* ++ * allocate carry_pool, 3 carry_level-s, reiser4_item_data and ++ * carry_insert_data ++ */ ++ pool = init_carry_pool(sizeof(*pool) + 3 * sizeof(*todo) + ++ sizeof(*item) + sizeof(*cdata)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ todo = (carry_level *) (pool + 1); ++ init_carry_level(todo, pool); ++ ++ item = (reiser4_item_data *) (todo + 3); ++ cdata = (carry_insert_data *) (item + 1); ++ ++ op = reiser4_post_carry(todo, COP_INSERT, insert_coord->node, 0); ++ if (!IS_ERR(op)) { ++ cdata->coord = insert_coord; ++ cdata->key = key; ++ cdata->data = item; ++ op->u.insert.d = cdata; ++ op->u.insert.type = COPT_ITEM_DATA; ++ build_child_ptr_data(node, item); ++ item->arg = NULL; ++ /* have @insert_coord to be set at inserted item after ++ insertion is done */ ++ todo->track_type = CARRY_TRACK_CHANGE; ++ todo->tracked = lh; ++ ++ result = reiser4_carry(todo, NULL); ++ if (result == 0) { ++ /* ++ * pin node in memory. This is necessary for ++ * znode_make_dirty() below. ++ */ ++ result = zload(node); ++ if (result == 0) { ++ lock_handle local_lh; ++ ++ /* ++ * if we inserted new child into tree we have ++ * to mark it dirty so that flush will be able ++ * to process it. ++ */ ++ init_lh(&local_lh); ++ result = longterm_lock_znode(&local_lh, node, ++ ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_LOPRI); ++ if (result == 0) { ++ znode_make_dirty(node); ++ ++ /* ++ * when internal item pointing to @node ++ * was inserted into twig node ++ * create_hook_internal did not connect ++ * it properly because its right ++ * neighbor was not known. Do it ++ * here ++ */ ++ write_lock_tree(); ++ assert("nikita-3312", ++ znode_is_right_connected(node)); ++ assert("nikita-2984", ++ node->right == NULL); ++ ZF_CLR(node, JNODE_RIGHT_CONNECTED); ++ write_unlock_tree(); ++ result = ++ connect_znode(insert_coord, node); ++ ON_DEBUG(if (result == 0) check_dkeys(node);); ++ ++ done_lh(lh); ++ move_lh(lh, &local_lh); ++ assert("vs-1676", node_is_empty(node)); ++ coord_init_first_unit(insert_coord, ++ node); ++ } else { ++ warning("nikita-3136", ++ "Cannot lock child"); ++ } ++ done_lh(&local_lh); ++ zrelse(node); ++ } ++ } ++ } else ++ result = PTR_ERR(op); ++ zput(node); ++ done_carry_pool(pool); ++ return result; ++} ++ ++/** ++ * handle_eottl - handle extent-on-the-twig-level cases in tree traversal ++ * @h: search handle ++ * @outcome: flag saying whether search has to restart or is done ++ * ++ * Handles search on twig level. If this function completes search itself then ++ * it returns 1. If search has to go one level down then 0 is returned. If ++ * error happens then LOOKUP_DONE is returned via @outcome and error code is ++ * saved in @h->result. ++ */ ++int handle_eottl(cbk_handle *h, int *outcome) ++{ ++ int result; ++ reiser4_key key; ++ coord_t *coord; ++ ++ coord = h->coord; ++ ++ if (h->level != TWIG_LEVEL || ++ (coord_is_existing_item(coord) && item_is_internal(coord))) { ++ /* Continue to traverse tree downward. */ ++ return 0; ++ } ++ ++ /* ++ * make sure that @h->coord is set to twig node and that it is either ++ * set to extent item or after extent item ++ */ ++ assert("vs-356", h->level == TWIG_LEVEL); ++ assert("vs-357", ({ ++ coord_t lcoord; ++ coord_dup(&lcoord, coord); ++ check_me("vs-733", coord_set_to_left(&lcoord) == 0); ++ item_is_extent(&lcoord); ++ } ++ )); ++ ++ if (*outcome == NS_FOUND) { ++ /* we have found desired key on twig level in extent item */ ++ h->result = CBK_COORD_FOUND; ++ *outcome = LOOKUP_DONE; ++ return 1; ++ } ++ ++ if (!(h->flags & CBK_FOR_INSERT)) { ++ /* tree traversal is not for insertion. Just return ++ CBK_COORD_NOTFOUND. */ ++ h->result = CBK_COORD_NOTFOUND; ++ *outcome = LOOKUP_DONE; ++ return 1; ++ } ++ ++ /* take a look at the item to the right of h -> coord */ ++ result = is_next_item_internal(coord, h->key, h->active_lh); ++ if (unlikely(result < 0)) { ++ h->error = "get_right_neighbor failed"; ++ h->result = result; ++ *outcome = LOOKUP_DONE; ++ return 1; ++ } ++ if (result == 0) { ++ /* ++ * item to the right is also an extent one. Allocate a new node ++ * and insert pointer to it after item h -> coord. ++ * ++ * This is a result of extents being located at the twig ++ * level. For explanation, see comment just above ++ * is_next_item_internal(). ++ */ ++ znode *loaded; ++ ++ if (cbk_lock_mode(h->level, h) != ZNODE_WRITE_LOCK) { ++ /* ++ * we got node read locked, restart coord_by_key to ++ * have write lock on twig level ++ */ ++ h->lock_level = TWIG_LEVEL; ++ h->lock_mode = ZNODE_WRITE_LOCK; ++ *outcome = LOOKUP_REST; ++ return 1; ++ } ++ ++ loaded = coord->node; ++ result = ++ add_empty_leaf(coord, h->active_lh, h->key, ++ rd_key(coord, &key)); ++ if (result) { ++ h->error = "could not add empty leaf"; ++ h->result = result; ++ *outcome = LOOKUP_DONE; ++ return 1; ++ } ++ /* added empty leaf is locked (h->active_lh), its parent node ++ is unlocked, h->coord is set as EMPTY */ ++ assert("vs-13", coord->between == EMPTY_NODE); ++ assert("vs-14", znode_is_write_locked(coord->node)); ++ assert("vs-15", ++ WITH_DATA(coord->node, node_is_empty(coord->node))); ++ assert("vs-16", jnode_is_leaf(ZJNODE(coord->node))); ++ assert("vs-17", coord->node == h->active_lh->node); ++ *outcome = LOOKUP_DONE; ++ h->result = CBK_COORD_NOTFOUND; ++ return 1; ++ } else if (result == 1) { ++ /* ++ * this is special case mentioned in the comment on ++ * tree.h:cbk_flags. We have found internal item immediately on ++ * the right of extent, and we are going to insert new item ++ * there. Key of item we are going to insert is smaller than ++ * leftmost key in the node pointed to by said internal item ++ * (otherwise search wouldn't come to the extent in the first ++ * place). ++ * ++ * This is a result of extents being located at the twig ++ * level. For explanation, see comment just above ++ * is_next_item_internal(). ++ */ ++ h->flags &= ~CBK_TRUST_DK; ++ } else { ++ assert("vs-8", result == 2); ++ *outcome = LOOKUP_REST; ++ return 1; ++ } ++ assert("vs-362", WITH_DATA(coord->node, item_is_internal(coord))); ++ return 0; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/estimate.c linux-5.10.2/fs/reiser4/estimate.c +--- linux-5.10.2.orig/fs/reiser4/estimate.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/estimate.c 2020-12-23 16:07:46.116813099 +0100 +@@ -0,0 +1,172 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "tree.h" ++#include "carry.h" ++#include "inode.h" ++#include "plugin/cluster.h" ++#include "plugin/item/ctail.h" ++ ++/* This returns how many nodes might get dirty and added nodes if @children ++ nodes are dirtied ++ ++ Amount of internals which will get dirty or get allocated we estimate as 5% ++ of the childs + 1 balancing. 1 balancing is 2 neighbours, 2 new blocks and ++ the current block on the leaf level, 2 neighbour nodes + the current (or 1 ++ neighbour and 1 new and the current) on twig level, 2 neighbour nodes on ++ upper levels and 1 for a new root. So 5 for leaf level, 3 for twig level, ++ 2 on upper + 1 for root. ++ ++ Do not calculate the current node of the lowest level here - this is overhead ++ only. ++ ++ children is almost always 1 here. Exception is flow insertion ++*/ ++static reiser4_block_nr ++max_balance_overhead(reiser4_block_nr childen, tree_level tree_height) ++{ ++ reiser4_block_nr ten_percent; ++ ++ ten_percent = ((103 * childen) >> 10); ++ ++ /* If we have too many balancings at the time, tree height can raise on ++ more then 1. Assume that if tree_height is 5, it can raise on 1 only. ++ */ ++ return ((tree_height < 5 ? 5 : tree_height) * 2 + (4 + ten_percent)); ++} ++ ++/* this returns maximal possible number of nodes which can be modified plus ++ number of new nodes which can be required to perform insertion of one item ++ into the tree */ ++/* it is only called when tree height changes, or gets initialized */ ++reiser4_block_nr calc_estimate_one_insert(tree_level height) ++{ ++ return 1 + max_balance_overhead(1, height); ++} ++ ++reiser4_block_nr estimate_one_insert_item(reiser4_tree * tree) ++{ ++ return tree->estimate_one_insert; ++} ++ ++/* this returns maximal possible number of nodes which can be modified plus ++ number of new nodes which can be required to perform insertion of one unit ++ into an item in the tree */ ++reiser4_block_nr estimate_one_insert_into_item(reiser4_tree * tree) ++{ ++ /* estimate insert into item just like item insertion */ ++ return tree->estimate_one_insert; ++} ++ ++reiser4_block_nr estimate_one_item_removal(reiser4_tree * tree) ++{ ++ /* on item removal reiser4 does not try to pack nodes more complact, so, ++ only one node may be dirtied on leaf level */ ++ return tree->estimate_one_insert; ++} ++ ++/* on leaf level insert_flow may add CARRY_FLOW_NEW_NODES_LIMIT new nodes and ++ dirty 3 existing nodes (insert point and both its neighbors). ++ Max_balance_overhead should estimate number of blocks which may change/get ++ added on internal levels */ ++reiser4_block_nr estimate_insert_flow(tree_level height) ++{ ++ return 3 + CARRY_FLOW_NEW_NODES_LIMIT + max_balance_overhead(3 + ++ CARRY_FLOW_NEW_NODES_LIMIT, ++ height); ++} ++ ++/* returnes max number of nodes can be occupied by disk cluster */ ++static reiser4_block_nr estimate_cluster(struct inode *inode, int unprepped) ++{ ++ int per_cluster; ++ per_cluster = (unprepped ? 1 : cluster_nrpages(inode)); ++ return 3 + per_cluster + ++ max_balance_overhead(3 + per_cluster, ++ REISER4_MAX_ZTREE_HEIGHT); ++} ++ ++/* how many nodes might get dirty and added ++ during insertion of a disk cluster */ ++reiser4_block_nr estimate_insert_cluster(struct inode *inode) ++{ ++ return estimate_cluster(inode, 1); /* 24 */ ++} ++ ++/* how many nodes might get dirty and added ++ during update of a (prepped or unprepped) disk cluster */ ++reiser4_block_nr estimate_update_cluster(struct inode *inode) ++{ ++ return estimate_cluster(inode, 0); /* 44, for 64K-cluster */ ++} ++ ++/* How many nodes occupied by a disk cluster might get dirty. ++ Note that this estimation is not precise (i.e. disk cluster ++ can occupy more nodes). ++ Q: Why we don't use precise estimation? ++ A: 1.Because precise estimation is fairly bad: 65536 nodes ++ for 64K logical cluster, it means 256M of dead space on ++ a partition ++ 2.It is a very rare case when disk cluster occupies more ++ nodes then this estimation returns. ++*/ ++reiser4_block_nr estimate_dirty_cluster(struct inode *inode) ++{ ++ return cluster_nrpages(inode) + 4; ++} ++ ++/** ++ * How many meta-data blocks are needed to write @count ++ * data pages to a striped file by extents. ++ */ ++reiser4_block_nr estimate_write_stripe_meta(int count) ++{ ++ reiser4_tree *tree = meta_subvol_tree(); ++/* ++ * to write @count data pages to a file by extents we have to ++ * reserve disk space for: ++ * ++ * 1. find_file_item() may have to insert empty node to the tree ++ * (empty leaf node between two extent items). This requires: ++ * (a) 1 block for the leaf node; ++ * (b) number of formatted blocks which are necessary to perform ++ * insertion of an internal item into twig level. ++ * ++ * 2. for each of written pages there might be needed: ++ * number of blocks which might be necessary to insert or ++ * paste to an extent item. ++ * ++ * 3. stat data update. ++ */ ++ return 1 /* (1a) */ + ++ 2 * estimate_one_insert_item(tree) /* (1b) + (3) */ + ++ count * estimate_one_insert_into_item(tree) /* (2) */; ++} ++ ++/** ++ * How many meta-data blocks are needed to perform one iteration ++ * by migrate_extent() ++ */ ++reiser4_block_nr estimate_migration_iter(void) ++{ ++ reiser4_tree *tree = meta_subvol_tree(); ++ /* ++ * 1 + estimate_one_insert_item(tree) for do_split_extent(), ++ * other is estimation above without stat-data update - for ++ * do_migrate_extent() ++ */ ++ return 2 + 3 * estimate_one_insert_item(tree); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/export_ops.c linux-5.10.2/fs/reiser4/export_ops.c +--- linux-5.10.2.orig/fs/reiser4/export_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/export_ops.c 2020-12-23 16:07:46.116813099 +0100 +@@ -0,0 +1,325 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "inode.h" ++#include "plugin/plugin.h" ++ ++/* ++ * Supported file-handle types ++ */ ++typedef enum { ++ FH_WITH_PARENT = 0x10, /* file handle with parent */ ++ FH_WITHOUT_PARENT = 0x11 /* file handle without parent */ ++} reiser4_fhtype; ++ ++#define NFSERROR (255) ++ ++/* initialize place-holder for object */ ++static void object_on_wire_init(reiser4_object_on_wire *o) ++{ ++ o->plugin = NULL; ++} ++ ++/* finish with @o */ ++static void object_on_wire_done(reiser4_object_on_wire *o) ++{ ++ if (o->plugin != NULL) ++ o->plugin->wire.done(o); ++} ++ ++/* ++ * read serialized object identity from @addr and store information about ++ * object in @obj. This is dual to encode_inode(). ++ */ ++static char *decode_inode(struct super_block *s, char *addr, ++ reiser4_object_on_wire * obj) ++{ ++ file_plugin *fplug; ++ ++ /* identifier of object plugin is stored in the first two bytes, ++ * followed by... */ ++ fplug = file_plugin_by_disk_id((d16 *) addr); ++ if (fplug != NULL) { ++ addr += sizeof(d16); ++ obj->plugin = fplug; ++ assert("nikita-3520", fplug->wire.read != NULL); ++ /* plugin specific encoding of object identity. */ ++ addr = fplug->wire.read(addr, obj); ++ } else ++ addr = ERR_PTR(RETERR(-EINVAL)); ++ return addr; ++} ++ ++static struct dentry *reiser4_get_dentry(struct super_block *super, ++ void *data); ++/** ++ * reiser4_decode_fh: decode on-wire object - helper function ++ * for fh_to_dentry, fh_to_parent export operations; ++ * @super: super block; ++ * @addr: onwire object to be decoded; ++ * ++ * Returns dentry referring to the object being decoded. ++ */ ++static struct dentry *reiser4_decode_fh(struct super_block * super, ++ char * addr) ++{ ++ reiser4_object_on_wire object; ++ ++ object_on_wire_init(&object); ++ ++ addr = decode_inode(super, addr, &object); ++ if (!IS_ERR(addr)) { ++ struct dentry *d; ++ d = reiser4_get_dentry(super, &object); ++ if (d != NULL && !IS_ERR(d)) ++ /* FIXME check for -ENOMEM */ ++ reiser4_get_dentry_fsdata(d)->stateless = 1; ++ addr = (char *)d; ++ } ++ object_on_wire_done(&object); ++ return (void *)addr; ++} ++ ++static struct dentry *reiser4_fh_to_dentry(struct super_block *sb, ++ struct fid *fid, ++ int fh_len, int fh_type) ++{ ++ reiser4_context *ctx; ++ struct dentry *d; ++ ++ assert("edward-1536", ++ fh_type == FH_WITH_PARENT || fh_type == FH_WITHOUT_PARENT); ++ ++ ctx = reiser4_init_context(sb); ++ if (IS_ERR(ctx)) ++ return (struct dentry *)ctx; ++ ++ d = reiser4_decode_fh(sb, (char *)fid->raw); ++ ++ reiser4_exit_context(ctx); ++ return d; ++} ++ ++static struct dentry *reiser4_fh_to_parent(struct super_block *sb, ++ struct fid *fid, ++ int fh_len, int fh_type) ++{ ++ char * addr; ++ struct dentry * d; ++ reiser4_context *ctx; ++ file_plugin *fplug; ++ ++ if (fh_type == FH_WITHOUT_PARENT) ++ return NULL; ++ assert("edward-1537", fh_type == FH_WITH_PARENT); ++ ++ ctx = reiser4_init_context(sb); ++ if (IS_ERR(ctx)) ++ return (struct dentry *)ctx; ++ addr = (char *)fid->raw; ++ /* extract 2-bytes file plugin id */ ++ fplug = file_plugin_by_disk_id((d16 *)addr); ++ if (fplug == NULL) { ++ d = ERR_PTR(RETERR(-EINVAL)); ++ goto exit; ++ } ++ addr += sizeof(d16); ++ /* skip previously encoded object */ ++ addr = fplug->wire.read(addr, NULL /* skip */); ++ if (IS_ERR(addr)) { ++ d = (struct dentry *)addr; ++ goto exit; ++ } ++ /* @extract and decode parent object */ ++ d = reiser4_decode_fh(sb, addr); ++ exit: ++ reiser4_exit_context(ctx); ++ return d; ++} ++ ++/* ++ * Object serialization support. ++ * ++ * To support knfsd file system provides export_operations that are used to ++ * construct and interpret NFS file handles. As a generalization of this, ++ * reiser4 object plugins have serialization support: it provides methods to ++ * create on-wire representation of identity of reiser4 object, and ++ * re-create/locate object given its on-wire identity. ++ * ++ */ ++ ++/* ++ * return number of bytes that on-wire representation of @inode's identity ++ * consumes. ++ */ ++static int encode_inode_size(struct inode *inode) ++{ ++ assert("nikita-3514", inode != NULL); ++ assert("nikita-3515", inode_file_plugin(inode) != NULL); ++ assert("nikita-3516", inode_file_plugin(inode)->wire.size != NULL); ++ ++ return inode_file_plugin(inode)->wire.size(inode) + sizeof(d16); ++} ++ ++/* ++ * store on-wire representation of @inode's identity at the area beginning at ++ * @start. ++ */ ++static char *encode_inode(struct inode *inode, char *start) ++{ ++ assert("nikita-3517", inode != NULL); ++ assert("nikita-3518", inode_file_plugin(inode) != NULL); ++ assert("nikita-3519", inode_file_plugin(inode)->wire.write != NULL); ++ ++ /* ++ * first, store two-byte identifier of object plugin, then ++ */ ++ save_plugin_id(file_plugin_to_plugin(inode_file_plugin(inode)), ++ (d16 *) start); ++ start += sizeof(d16); ++ /* ++ * call plugin to serialize object's identity ++ */ ++ return inode_file_plugin(inode)->wire.write(inode, start); ++} ++ ++/* this returns number of 32 bit long numbers encoded in @lenp. 255 is ++ * returned if file handle can not be stored */ ++/** ++ * reiser4_encode_fh - encode_fh of export operations ++ * @dentry: ++ * @fh: ++ * @lenp: ++ * @need_parent: ++ * ++ */ ++static int ++reiser4_encode_fh(struct inode *inode, __u32 *fh, int *lenp, ++ struct inode *parent) ++{ ++ char *addr; ++ int need; ++ int delta; ++ int result; ++ bool need_parent; ++ reiser4_context *ctx; ++ ++ /* ++ * knfsd asks as to serialize @inode, and, optionally its ++ * parent @parent (if it is non-NULL). ++ * ++ * encode_inode() and encode_inode_size() is used to build ++ * representation of object and its parent. All hard work is done by ++ * object plugins. ++ */ ++ need_parent = (parent != NULL); ++ addr = (char *)fh; ++ ++ need = encode_inode_size(inode); ++ if (need < 0) ++ return NFSERROR; ++ if (need_parent) { ++ delta = encode_inode_size(parent); ++ if (delta < 0) ++ return NFSERROR; ++ need += delta; ++ } ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ if (need <= sizeof(__u32) * (*lenp)) { ++ addr = encode_inode(inode, addr); ++ if (need_parent) ++ addr = encode_inode(parent, addr); ++ ++ /* store in lenp number of 32bit words required for file ++ * handle. */ ++ *lenp = (need + sizeof(__u32) - 1) >> 2; ++ result = need_parent ? FH_WITH_PARENT : FH_WITHOUT_PARENT; ++ } else ++ /* no enough space in file handle */ ++ result = NFSERROR; ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/** ++ * reiser4_get_dentry_parent - get_parent of export operations ++ * @child: ++ * ++ */ ++static struct dentry *reiser4_get_dentry_parent(struct dentry *child) ++{ ++ struct inode *dir; ++ dir_plugin *dplug; ++ struct dentry *result; ++ reiser4_context *ctx; ++ ++ assert("nikita-3527", child != NULL); ++ ++ dir = child->d_inode; ++ assert("nikita-3529", dir != NULL); ++ ++ ctx = reiser4_init_context(dir->i_sb); ++ if (IS_ERR(ctx)) ++ return (void *)ctx; ++ ++ dplug = inode_dir_plugin(dir); ++ assert("nikita-3531", ergo(dplug != NULL, dplug->get_parent != NULL)); ++ ++ if (unlikely(dplug == NULL)) { ++ reiser4_exit_context(ctx); ++ return ERR_PTR(RETERR(-ENOTDIR)); ++ } ++ result = dplug->get_parent(dir); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/** ++ * reiser4_get_dentry - get_dentry of export operations ++ * @super: ++ * @data: ++ * ++ * ++ */ ++static struct dentry *reiser4_get_dentry(struct super_block *super, void *data) ++{ ++ reiser4_object_on_wire *o; ++ ++ assert("nikita-3522", super != NULL); ++ assert("nikita-3523", data != NULL); ++ /* ++ * this is only supposed to be called by ++ * ++ * reiser4_decode_fh->find_exported_dentry ++ * ++ * so, reiser4_context should be here already. ++ */ ++ assert("nikita-3526", is_in_reiser4_context()); ++ ++ o = (reiser4_object_on_wire *)data; ++ assert("nikita-3524", o->plugin != NULL); ++ assert("nikita-3525", o->plugin->wire.get != NULL); ++ ++ return o->plugin->wire.get(super, o); ++} ++ ++struct export_operations reiser4_export_operations = { ++ .encode_fh = reiser4_encode_fh, ++ .fh_to_dentry = reiser4_fh_to_dentry, ++ .fh_to_parent = reiser4_fh_to_parent, ++ .get_parent = reiser4_get_dentry_parent, ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/flush.c linux-5.10.2/fs/reiser4/flush.c +--- linux-5.10.2.orig/fs/reiser4/flush.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/flush.c 2020-12-23 16:07:46.116813099 +0100 +@@ -0,0 +1,3794 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* The design document for this file is at http://www.namesys.com/v4/v4.html. */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/plugin.h" ++#include "plugin/object.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "carry.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "page_cache.h" ++#include "wander.h" ++#include "super.h" ++#include "entd.h" ++#include "reiser4.h" ++#include "flush.h" ++#include "writeout.h" ++ ++#include ++#include /* for struct super_block */ ++#include /* for struct page */ ++#include /* for struct bio */ ++#include ++#include ++ ++/* IMPLEMENTATION NOTES */ ++ ++/* PARENT-FIRST: Some terminology: A parent-first traversal is a way of ++ assigning a total order to the nodes of the tree in which the parent is ++ placed before its children, which are ordered (recursively) in left-to-right ++ order. When we speak of a "parent-first preceder", it describes the node that ++ "came before in forward parent-first order". When we speak of a "parent-first ++ follower", it describes the node that "comes next in parent-first order" ++ (alternatively the node that "came before in reverse parent-first order"). ++ ++ The following pseudo-code prints the nodes of a tree in forward parent-first ++ order: ++ ++ void parent_first (node) ++ { ++ print_node (node); ++ if (node->level > leaf) { ++ for (i = 0; i < num_children; i += 1) { ++ parent_first (node->child[i]); ++ } ++ } ++ } ++*/ ++ ++/* JUST WHAT ARE WE TRYING TO OPTIMIZE, HERE? The idea is to optimize block ++ allocation so that a left-to-right scan of the tree's data (i.e., the leaves ++ in left-to-right order) can be accomplished with sequential reads, which ++ results in reading nodes in their parent-first order. This is a ++ read-optimization aspect of the flush algorithm, and there is also a ++ write-optimization aspect, which is that we wish to make large sequential ++ writes to the disk by allocating or reallocating blocks so that they can be ++ written in sequence. Sometimes the read-optimization and write-optimization ++ goals conflict with each other, as we discuss in more detail below. ++*/ ++ ++/* STATE BITS: The flush code revolves around the state of the jnodes it covers. ++ Here are the relevant jnode->state bits and their relevence to flush: ++ ++ JNODE_DIRTY: If a node is dirty, it must be flushed. But in order to be ++ written it must be allocated first. In order to be considered allocated, ++ the jnode must have exactly one of { JNODE_OVRWR, JNODE_RELOC } set. These ++ two bits are exclusive, and all dirtied jnodes eventually have one of these ++ bits set during each transaction. ++ ++ JNODE_CREATED: The node was freshly created in its transaction and has no ++ previous block address, so it is unconditionally assigned to be relocated, ++ although this is mainly for code-convenience. It is not being 'relocated' ++ from anything, but in almost every regard it is treated as part of the ++ relocate set. The JNODE_CREATED bit remains set even after JNODE_RELOC is ++ set, so the actual relocate can be distinguished from the ++ created-and-allocated set easily: relocate-set members (belonging to the ++ preserve-set) have (JNODE_RELOC) set and created-set members which have no ++ previous location to preserve have (JNODE_RELOC | JNODE_CREATED) set. ++ ++ JNODE_OVRWR: The node belongs to atom's overwrite set. The flush algorithm ++ made the decision to maintain the pre-existing location for this node and ++ it will be written to the wandered-log. ++ ++ JNODE_RELOC: The flush algorithm made the decision to relocate this block ++ (if it was not created, see note above). A block with JNODE_RELOC set is ++ eligible for early-flushing and may be submitted during flush_empty_queues. ++ When the JNODE_RELOC bit is set on a znode, the parent node's internal item ++ is modified and the znode is rehashed. ++ ++ JNODE_SQUEEZABLE: Before shifting everything left, the flush algorithm ++ scans the node and calls plugin->f.squeeze() method for its items. By this ++ technology we update disk clusters of cryptcompress objects. Also if ++ leftmost point that was found by flush scan has this flag (races with ++ write(), rare case) the flush algorythm makes the decision to pass it to ++ squalloc() in spite of its flushprepped status for squeezing, not for ++ repeated allocation. ++ ++ JNODE_FLUSH_QUEUED: This bit is set when a call to flush enters the jnode ++ into its flush queue. This means the jnode is not on any clean or dirty ++ list, instead it is moved to one of the flush queue (see flush_queue.h) ++ object private list. This prevents multiple concurrent flushes from ++ attempting to start flushing from the same node. ++ ++ (DEAD STATE BIT) JNODE_FLUSH_BUSY: This bit was set during the bottom-up ++ squeeze-and-allocate on a node while its children are actively being ++ squeezed and allocated. This flag was created to avoid submitting a write ++ request for a node while its children are still being allocated and ++ squeezed. Then flush queue was re-implemented to allow unlimited number of ++ nodes be queued. This flag support was commented out in source code because ++ we decided that there was no reason to submit queued nodes before ++ jnode_flush() finishes. However, current code calls fq_write() during a ++ slum traversal and may submit "busy nodes" to disk. Probably we can ++ re-enable the JNODE_FLUSH_BUSY bit support in future. ++ ++ With these state bits, we describe a test used frequently in the code below, ++ jnode_is_flushprepped()(and the spin-lock-taking jnode_check_flushprepped()). ++ The test for "flushprepped" returns true if any of the following are true: ++ ++ - The node is not dirty ++ - The node has JNODE_RELOC set ++ - The node has JNODE_OVRWR set ++ ++ If either the node is not dirty or it has already been processed by flush ++ (and assigned JNODE_OVRWR or JNODE_RELOC), then it is prepped. If ++ jnode_is_flushprepped() returns true then flush has work to do on that node. ++*/ ++ ++/* FLUSH_PREP_ONCE_PER_TRANSACTION: Within a single transaction a node is never ++ flushprepped twice (unless an explicit call to flush_unprep is made as ++ described in detail below). For example a node is dirtied, allocated, and ++ then early-flushed to disk and set clean. Before the transaction commits, the ++ page is dirtied again and, due to memory pressure, the node is flushed again. ++ The flush algorithm will not relocate the node to a new disk location, it ++ will simply write it to the same, previously relocated position again. ++*/ ++ ++/* THE BOTTOM-UP VS. TOP-DOWN ISSUE: This code implements a bottom-up algorithm ++ where we start at a leaf node and allocate in parent-first order by iterating ++ to the right. At each step of the iteration, we check for the right neighbor. ++ Before advancing to the right neighbor, we check if the current position and ++ the right neighbor share the same parent. If they do not share the same ++ parent, the parent is allocated before the right neighbor. ++ ++ This process goes recursively up the tree and squeeze nodes level by level as ++ long as the right neighbor and the current position have different parents, ++ then it allocates the right-neighbors-with-different-parents on the way back ++ down. This process is described in more detail in ++ flush_squalloc_changed_ancestor and the recursive function ++ squalloc_one_changed_ancestor. But the purpose here is not to discuss the ++ specifics of the bottom-up approach as it is to contrast the bottom-up and ++ top-down approaches. ++ ++ The top-down algorithm was implemented earlier (April-May 2002). In the ++ top-down approach, we find a starting point by scanning left along each level ++ past dirty nodes, then going up and repeating the process until the left node ++ and the parent node are clean. We then perform a parent-first traversal from ++ the starting point, which makes allocating in parent-first order trivial. ++ After one subtree has been allocated in this manner, we move to the right, ++ try moving upward, then repeat the parent-first traversal. ++ ++ Both approaches have problems that need to be addressed. Both are ++ approximately the same amount of code, but the bottom-up approach has ++ advantages in the order it acquires locks which, at the very least, make it ++ the better approach. At first glance each one makes the other one look ++ simpler, so it is important to remember a few of the problems with each one. ++ ++ Main problem with the top-down approach: When you encounter a clean child ++ during the parent-first traversal, what do you do? You would like to avoid ++ searching through a large tree of nodes just to find a few dirty leaves at ++ the bottom, and there is not an obvious solution. One of the advantages of ++ the top-down approach is that during the parent-first traversal you check ++ every child of a parent to see if it is dirty. In this way, the top-down ++ approach easily handles the main problem of the bottom-up approach: ++ unallocated children. ++ ++ The unallocated children problem is that before writing a node to disk we ++ must make sure that all of its children are allocated. Otherwise, the writing ++ the node means extra I/O because the node will have to be written again when ++ the child is finally allocated. ++ ++ WE HAVE NOT YET ELIMINATED THE UNALLOCATED CHILDREN PROBLEM. Except for bugs, ++ this should not cause any file system corruption, it only degrades I/O ++ performance because a node may be written when it is sure to be written at ++ least one more time in the same transaction when the remaining children are ++ allocated. What follows is a description of how we will solve the problem. ++*/ ++ ++/* HANDLING UNALLOCATED CHILDREN: During flush we may allocate a parent node, ++ then proceeding in parent first order, allocate some of its left-children, ++ then encounter a clean child in the middle of the parent. We do not allocate ++ the clean child, but there may remain unallocated (dirty) children to the ++ right of the clean child. If we were to stop flushing at this moment and ++ write everything to disk, the parent might still contain unallocated ++ children. ++ ++ We could try to allocate all the descendents of every node that we allocate, ++ but this is not necessary. Doing so could result in allocating the entire ++ tree: if the root node is allocated then every unallocated node would have to ++ be allocated before flushing. Actually, we do not have to write a node just ++ because we allocate it. It is possible to allocate but not write a node ++ during flush, when it still has unallocated children. However, this approach ++ is probably not optimal for the following reason. ++ ++ The flush algorithm is designed to allocate nodes in parent-first order in an ++ attempt to optimize reads that occur in the same order. Thus we are ++ read-optimizing for a left-to-right scan through all the leaves in the ++ system, and we are hoping to write-optimize at the same time because those ++ nodes will be written together in batch. What happens, however, if we assign ++ a block number to a node in its read-optimized order but then avoid writing ++ it because it has unallocated children? In that situation, we lose out on the ++ write-optimization aspect because a node will have to be written again to the ++ its location on the device, later, which likely means seeking back to that ++ location. ++ ++ So there are tradeoffs. We can choose either: ++ ++ A. Allocate all unallocated children to preserve both write-optimization and ++ read-optimization, but this is not always desirable because it may mean ++ having to allocate and flush very many nodes at once. ++ ++ B. Defer writing nodes with unallocated children, keep their read-optimized ++ locations, but sacrifice write-optimization because those nodes will be ++ written again. ++ ++ C. Defer writing nodes with unallocated children, but do not keep their ++ read-optimized locations. Instead, choose to write-optimize them later, when ++ they are written. To facilitate this, we "undo" the read-optimized allocation ++ that was given to the node so that later it can be write-optimized, thus ++ "unpreparing" the flush decision. This is a case where we disturb the ++ FLUSH_PREP_ONCE_PER_TRANSACTION rule described above. By a call to ++ flush_unprep() we will: if the node was wandered, unset the JNODE_OVRWR bit; ++ if the node was relocated, unset the JNODE_RELOC bit, non-deferred-deallocate ++ its block location, and set the JNODE_CREATED bit, effectively setting the ++ node back to an unallocated state. ++ ++ We will take the following approach in v4.0: for twig nodes we will always ++ finish allocating unallocated children (A). For nodes with (level > TWIG) ++ we will defer writing and choose write-optimization (C). ++ ++ To summarize, there are several parts to a solution that avoids the problem ++ with unallocated children: ++ ++ FIXME-ZAM: Still no one approach is implemented to eliminate the ++ "UNALLOCATED CHILDREN" problem because there was an experiment which was done ++ showed that we have 1-2 nodes with unallocated children for thousands of ++ written nodes. The experiment was simple like coping/deletion of linux kernel ++ sources. However the problem can arise in more complex tests. I think we have ++ jnode_io_hook to insert a check for unallocated children and see what kind of ++ problem we have. ++ ++ 1. When flush reaches a stopping point (e.g. a clean node) it should continue ++ calling squeeze-and-allocate on any remaining unallocated children. ++ FIXME: Difficulty to implement: should be simple -- amounts to adding a while ++ loop to jnode_flush, see comments in that function. ++ ++ 2. When flush reaches flush_empty_queue(), some of the (level > TWIG) nodes ++ may still have unallocated children. If the twig level has unallocated ++ children it is an assertion failure. If a higher-level node has unallocated ++ children, then it should be explicitly de-allocated by a call to ++ flush_unprep(). ++ FIXME: Difficulty to implement: should be simple. ++ ++ 3. (CPU-Optimization) Checking whether a node has unallocated children may ++ consume more CPU cycles than we would like, and it is possible (but medium ++ complexity) to optimize this somewhat in the case where large sub-trees are ++ flushed. The following observation helps: if both the left- and ++ right-neighbor of a node are processed by the flush algorithm then the node ++ itself is guaranteed to have all of its children allocated. However, the cost ++ of this check may not be so expensive after all: it is not needed for leaves ++ and flush can guarantee this property for twigs. That leaves only (level > ++ TWIG) nodes that have to be checked, so this optimization only helps if at ++ least three (level > TWIG) nodes are flushed in one pass, and the savings ++ will be very small unless there are many more (level > TWIG) nodes. But if ++ there are many (level > TWIG) nodes then the number of blocks being written ++ will be very large, so the savings may be insignificant. That said, the idea ++ is to maintain both the left and right edges of nodes that are processed in ++ flush. When flush_empty_queue() is called, a relatively simple test will ++ tell whether the (level > TWIG) node is on the edge. If it is on the edge, ++ the slow check is necessary, but if it is in the interior then it can be ++ assumed to have all of its children allocated. FIXME: medium complexity to ++ implement, but simple to verify given that we must have a slow check anyway. ++ ++ 4. (Optional) This part is optional, not for v4.0--flush should work ++ independently of whether this option is used or not. Called RAPID_SCAN, the ++ idea is to amend the left-scan operation to take unallocated children into ++ account. Normally, the left-scan operation goes left as long as adjacent ++ nodes are dirty up until some large maximum value (FLUSH_SCAN_MAXNODES) at ++ which point it stops and begins flushing. But scan-left may stop at a ++ position where there are unallocated children to the left with the same ++ parent. When RAPID_SCAN is enabled, the ordinary scan-left operation stops ++ after FLUSH_RELOCATE_THRESHOLD, which is much smaller than ++ FLUSH_SCAN_MAXNODES, then procedes with a rapid scan. The rapid scan skips ++ all the interior children of a node--if the leftmost child of a twig is ++ dirty, check its left neighbor (the rightmost child of the twig to the left). ++ If the left neighbor of the leftmost child is also dirty, then continue the ++ scan at the left twig and repeat. This option will cause flush to allocate ++ more twigs in a single pass, but it also has the potential to write many more ++ nodes than would otherwise be written without the RAPID_SCAN option. ++ RAPID_SCAN was partially implemented, code removed August 12, 2002 by JMACD. ++*/ ++ ++/* FLUSH CALLED ON NON-LEAF LEVEL. Most of our design considerations assume that ++ the starting point for flush is a leaf node, but actually the flush code ++ cares very little about whether or not this is true. It is possible that all ++ the leaf nodes are flushed and dirty parent nodes still remain, in which case ++ jnode_flush() is called on a non-leaf argument. Flush doesn't care--it treats ++ the argument node as if it were a leaf, even when it is not. This is a simple ++ approach, and there may be a more optimal policy but until a problem with ++ this approach is discovered, simplest is probably best. ++ ++ NOTE: In this case, the ordering produced by flush is parent-first only if ++ you ignore the leaves. This is done as a matter of simplicity and there is ++ only one (shaky) justification. When an atom commits, it flushes all leaf ++ level nodes first, followed by twigs, and so on. With flushing done in this ++ order, if flush is eventually called on a non-leaf node it means that ++ (somehow) we reached a point where all leaves are clean and only internal ++ nodes need to be flushed. If that it the case, then it means there were no ++ leaves that were the parent-first preceder/follower of the parent. This is ++ expected to be a rare case, which is why we do nothing special about it. ++ However, memory pressure may pass an internal node to flush when there are ++ still dirty leaf nodes that need to be flushed, which could prove our ++ original assumptions "inoperative". If this needs to be fixed, then ++ scan_left/right should have special checks for the non-leaf levels. For ++ example, instead of passing from a node to the left neighbor, it should pass ++ from the node to the left neighbor's rightmost descendent (if dirty). ++ ++*/ ++ ++/* UNIMPLEMENTED AS YET: REPACKING AND RESIZING. We walk the tree in 4MB-16MB ++ chunks, dirtying everything and putting it into a transaction. We tell the ++ allocator to allocate the blocks as far as possible towards one end of the ++ logical device--the left (starting) end of the device if we are walking from ++ left to right, the right end of the device if we are walking from right to ++ left. We then make passes in alternating directions, and as we do this the ++ device becomes sorted such that tree order and block number order fully ++ correlate. ++ ++ Resizing is done by shifting everything either all the way to the left or all ++ the way to the right, and then reporting the last block. ++*/ ++ ++/* RELOCATE DECISIONS: The code makes a decision to relocate in several places. ++ This descibes the policy from the highest level: ++ ++ The FLUSH_RELOCATE_THRESHOLD parameter: If we count this many consecutive ++ nodes on the leaf level during flush-scan (right, left), then we ++ unconditionally decide to relocate leaf nodes. ++ ++ Otherwise, there are two contexts in which we make a decision to relocate: ++ ++ 1. The REVERSE PARENT-FIRST context: Implemented in reverse_allocate ++ During the initial stages of flush, after scan-right completes, we want to ++ ask the question: should we relocate this leaf node and thus dirty the parent ++ node. Then if the node is a leftmost child its parent is its own parent-first ++ preceder, thus we repeat the question at the next level up, and so on. In ++ these cases we are moving in the reverse-parent first direction. ++ ++ There is another case which is considered the reverse direction, which comes ++ at the end of a twig in reverse_relocate_end_of_twig(). As we finish ++ processing a twig we may reach a point where there is a clean twig to the ++ right with a dirty leftmost child. In this case, we may wish to relocate the ++ child by testing if it should be relocated relative to its parent. ++ ++ 2. The FORWARD PARENT-FIRST context: Testing for forward relocation is done ++ in allocate_znode. What distinguishes the forward parent-first case from the ++ reverse-parent first case is that the preceder has already been allocated in ++ the forward case, whereas in the reverse case we don't know what the preceder ++ is until we finish "going in reverse". That simplifies the forward case ++ considerably, and there we actually use the block allocator to determine ++ whether, e.g., a block closer to the preceder is available. ++*/ ++ ++/* SQUEEZE_LEFT_EDGE: Unimplemented idea for future consideration. The idea is, ++ once we finish scan-left and find a starting point, if the parent's left ++ neighbor is dirty then squeeze the parent's left neighbor and the parent. ++ This may change the flush-starting-node's parent. Repeat until the child's ++ parent is stable. If the child is a leftmost child, repeat this left-edge ++ squeezing operation at the next level up. Note that we cannot allocate ++ extents during this or they will be out of parent-first order. There is also ++ some difficult coordinate maintenence issues. We can't do a tree search to ++ find coordinates again (because we hold locks), we have to determine them ++ from the two nodes being squeezed. Looks difficult, but has potential to ++ increase space utilization. */ ++ ++static struct kmem_cache *_fbi_slab = NULL; ++ ++/* Flush-scan helper functions. */ ++static void scan_init(flush_scan * scan, flush_pos_t *pos); ++static void scan_done(flush_scan * scan); ++ ++/* Flush-scan algorithm. */ ++static int scan_left(flush_scan *scan, flush_scan *right, jnode *node); ++static int scan_right(flush_scan *scan, jnode *node); ++static int do_scan(flush_scan * scan, flush_scan * other); ++static int scan_formatted(flush_scan * scan); ++static int lock_parent_and_scan_upper_level(flush_scan * scan, flush_scan * other); ++static int scan_by_coord(flush_scan * scan); ++ ++/* Initial flush-point ancestor allocation. */ ++static int alloc_pos_and_ancestors(flush_pos_t *pos); ++static int alloc_one_ancestor(const coord_t *coord, flush_pos_t *pos); ++static int find_preceder(const coord_t *coord_in, flush_brick_info *fbi); ++static struct flush_brick_info *find_fbi(const struct rb_root *root, ++ u32 brick_id); ++static void insert_fbi(struct rb_root *root, flush_brick_info *this); ++static flush_brick_info *grab_fbi(struct rb_root *infos, ++ flush_brick_info *mfbi, u32 brick_id); ++static void init_fbi(flush_brick_info *fbi, u32 subv_id); ++static void done_all_fbi(struct rb_root *infos, struct flush_brick_info *mfbi); ++ ++/* Main flush algorithm. ++ Note on abbreviation: "squeeze and allocate" == "squalloc". */ ++static int squalloc(flush_pos_t *pos); ++static int squalloc_upper_levels(flush_pos_t *, znode *, znode *); ++ ++/* Flush squeeze implementation. */ ++static int squeeze_right_non_twig(znode * left, znode * right); ++static int shift_one_internal_unit(znode * left, znode * right); ++ ++/* Parent re-allocation policy */ ++static int check_parent_for_realloc(jnode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos); ++ ++/* Flush allocate write-queueing functions: */ ++static int allocate_znode(znode * node, const coord_t *parent_coord, ++ flush_pos_t *pos); ++static int lock_parent_and_allocate_znode(znode *, flush_pos_t *); ++ ++/* Flush helper functions: */ ++static int jnode_lock_parent_coord(jnode * node, ++ coord_t *coord, ++ lock_handle * parent_lh, ++ load_count * parent_zh, ++ znode_lock_mode mode, int try); ++static int neighbor_in_slum(znode * node, lock_handle * right_lock, sideof side, ++ znode_lock_mode mode, int check_dirty, int expected); ++static int znode_same_parents(znode * a, znode * b); ++ ++static int znode_check_flushprepped(znode * node) ++{ ++ return jnode_check_flushprepped(ZJNODE(node)); ++} ++static void update_znode_dkeys(znode * left, znode * right); ++ ++/* Flush position functions */ ++static void pos_init(flush_pos_t *pos); ++static int pos_valid(flush_pos_t *pos); ++static void pos_done(flush_pos_t *pos); ++static int pos_stop(flush_pos_t *pos); ++ ++/* check that @org is first jnode extent unit, if extent is unallocated, ++ * because all jnodes of unallocated extent are dirty and of the same atom. */ ++#define checkchild(scan) \ ++assert("nikita-3435", \ ++ ergo(scan->direction == LEFT_SIDE && \ ++ (scan->parent_coord.node->level == TWIG_LEVEL) && \ ++ jnode_is_unformatted(scan->node) && \ ++ extent_is_unallocated(&scan->parent_coord), \ ++ extent_unit_index(&scan->parent_coord) == index_jnode(scan->node))) ++ ++/* This flush_cnt variable is used to track the number of concurrent flush ++ operations, useful for debugging. It is initialized in txnmgr.c out of ++ laziness (because flush has no static initializer function...) */ ++ON_DEBUG(atomic_t flush_cnt;) ++ ++/* check fs backing device for write congestion */ ++static int check_write_congestion(void) ++{ ++ struct super_block *sb; ++ struct backing_dev_info *bdi; ++ ++ sb = reiser4_get_current_sb(); ++ bdi = inode_to_bdi(reiser4_get_super_fake(sb)); ++ return bdi_write_congested(bdi); ++} ++ ++/* conditionally write flush queue */ ++static int write_prepped_nodes(flush_pos_t *pos) ++{ ++ int ret; ++ ++ assert("zam-831", pos); ++ assert("zam-832", pos->fq); ++ ++ if (!(pos->flags & JNODE_FLUSH_WRITE_BLOCKS)) ++ return 0; ++ ++ if (check_write_congestion()) ++ return 0; ++ ++ ret = reiser4_write_fq(pos->fq, pos->nr_written, ++ WRITEOUT_SINGLE_STREAM | WRITEOUT_FOR_PAGE_RECLAIM); ++ return ret; ++} ++ ++/* Proper release all flush pos. resources then move flush position to new ++ locked node */ ++static void move_flush_pos(flush_pos_t *pos, lock_handle * new_lock, ++ load_count * new_load, const coord_t *new_coord) ++{ ++ assert("zam-857", new_lock->node == new_load->node); ++ ++ if (new_coord) { ++ assert("zam-858", new_coord->node == new_lock->node); ++ coord_dup(&pos->coord, new_coord); ++ } else { ++ coord_init_first_unit(&pos->coord, new_lock->node); ++ } ++ ++ if (pos->child) { ++ jput(pos->child); ++ pos->child = NULL; ++ } ++ ++ move_load_count(&pos->load, new_load); ++ done_lh(&pos->lock); ++ move_lh(&pos->lock, new_lock); ++} ++ ++/* delete empty node which link from the parent still exists. */ ++static inline int delete_empty_node(znode *node) ++{ ++ reiser4_key smallest_removed; ++ ++ assert("zam-1019", node != NULL); ++ assert("zam-1020", node_is_empty(node)); ++ assert("zam-1023", znode_is_wlocked(node)); ++ ++ return reiser4_delete_node(node, &smallest_removed, NULL, 1); ++} ++ ++/* Prepare flush position for alloc_pos_and_ancestors() and squalloc() */ ++static int prepare_flush_pos(flush_pos_t *pos, jnode *leftmost) ++{ ++ int ret; ++ load_count load; ++ lock_handle lock; ++ ++ init_lh(&lock); ++ init_load_count(&load); ++ ++ if (jnode_is_znode(leftmost)) { ++ ret = longterm_lock_znode(&lock, JZNODE(leftmost), ++ ZNODE_WRITE_LOCK, ZNODE_LOCK_HIPRI); ++ if (ret) ++ return ret; ++ ++ ret = incr_load_count_znode(&load, JZNODE(leftmost)); ++ if (ret) ++ return ret; ++ ++ pos->state = ++ (jnode_get_level(leftmost) == ++ LEAF_LEVEL) ? POS_ON_LEAF : POS_ON_INTERNAL; ++ move_flush_pos(pos, &lock, &load, NULL); ++ } else { ++ coord_t parent_coord; ++ ret = jnode_lock_parent_coord(leftmost, &parent_coord, &lock, ++ &load, ZNODE_WRITE_LOCK, 0); ++ if (ret) ++ goto done; ++ if (!item_is_extent(&parent_coord)) { ++ /* ++ * file was converted to tail, ++ * @leftmost became HEARD_BANSHEE, ++ * we found internal item ++ */ ++ ret = -EAGAIN; ++ goto done; ++ } ++ pos->state = POS_ON_EPOINT; ++ move_flush_pos(pos, &lock, &load, &parent_coord); ++ pos->child = jref(leftmost); ++ ++ if (extent_is_unallocated(&parent_coord) && ++ extent_unit_index(&parent_coord) != index_jnode(leftmost)) { ++ /* @leftmost is not first child of its parent unit. ++ This may happen because longerm lock of its parent ++ node was released between scan_left and scan_right. ++ For now work around this having flush to repeat */ ++ ret = -EAGAIN; ++ } ++ } ++ ++done: ++ done_load_count(&load); ++ done_lh(&lock); ++ return ret; ++} ++ ++/** ++ * Make relocation decision on a brick basing on statictics accumulated ++ * by flush scan for that brick ++ */ ++int leaf_should_relocate(flush_pos_t *pos, u32 subv_id) ++{ ++ flush_brick_info *fbi; ++ ++ fbi = find_fbi(&pos->bricks_info, subv_id); ++ return fbi == NULL ? 0 : __leaf_should_relocate(fbi); ++} ++ ++/* TODO LIST (no particular order): */ ++/* I have labelled most of the legitimate FIXME comments in this file with ++ letters to indicate which issue they relate to. There are a few miscellaneous ++ FIXMEs with specific names mentioned instead that need to be ++ inspected/resolved. */ ++/* B. There is an issue described in reverse_allocate having to do with an ++ imprecise is_preceder? check having to do with partially-dirty extents. The ++ code that sets preceder hints and computes the preceder is basically ++ untested. Careful testing needs to be done that preceder calculations are ++ done correctly, since if it doesn't affect correctness we will not catch this ++ stuff during regular testing. */ ++/* C. EINVAL, E_DEADLOCK, E_NO_NEIGHBOR, ENOENT handling. It is unclear which of ++ these are considered expected but unlikely conditions. Flush currently ++ returns 0 (i.e., success but no progress, i.e., restart) whenever it receives ++ any of these in jnode_flush(). Many of the calls that may produce one of ++ these return values (i.e., longterm_lock_znode, reiser4_get_parent, ++ reiser4_get_neighbor, ...) check some of these values themselves and, for ++ instance, stop flushing instead of resulting in a restart. If any of these ++ results are true error conditions then flush will go into a busy-loop, as we ++ noticed during testing when a corrupt tree caused find_child_ptr to return ++ ENOENT. It needs careful thought and testing of corner conditions. ++*/ ++/* D. Atomicity of flush_prep against deletion and flush concurrency. Suppose a ++ created block is assigned a block number then early-flushed to disk. It is ++ dirtied again and flush is called again. Concurrently, that block is deleted, ++ and the de-allocation of its block number does not need to be deferred, since ++ it is not part of the preserve set (i.e., it didn't exist before the ++ transaction). I think there may be a race condition where flush writes the ++ dirty, created block after the non-deferred deallocated block number is ++ re-allocated, making it possible to write deleted data on top of non-deleted ++ data. Its just a theory, but it needs to be thought out. */ ++/* F. bio_alloc() failure is not handled gracefully. */ ++/* G. Unallocated children. */ ++/* H. Add a WANDERED_LIST to the atom to clarify the placement of wandered ++ blocks. */ ++/* I. Rename flush-scan to scan-point, (flush-pos to flush-point?) */ ++ ++/* JNODE_FLUSH: MAIN ENTRY POINT */ ++/* This is the main entry point for flushing a jnode and its dirty neighborhood ++ (dirty neighborhood is named "slum"). Jnode_flush() is called if reiser4 has ++ to write dirty blocks to disk, it happens when Linux VM decides to reduce ++ number of dirty pages or as a part of transaction commit. ++ ++ Our objective here is to prep and flush the slum the jnode belongs to. We ++ want to squish the slum together, and allocate the nodes in it as we squish ++ because allocation of children affects squishing of parents. ++ ++ The "argument" @node tells flush where to start. From there, flush finds the ++ left edge of the slum, and calls squalloc (in which nodes are squeezed and ++ allocated). To find a "better place" to start squalloc first we perform a ++ flush_scan. ++ ++ Flush-scanning may be performed in both left and right directions, but for ++ different purposes. When scanning to the left, we are searching for a node ++ that precedes a sequence of parent-first-ordered nodes which we will then ++ flush in parent-first order. During flush-scanning, we also take the ++ opportunity to count the number of consecutive leaf nodes. If this number is ++ past some threshold (FLUSH_RELOCATE_THRESHOLD), then we make a decision to ++ reallocate leaf nodes (thus favoring write-optimization). ++ ++ Since the flush argument node can be anywhere in a sequence of dirty leaves, ++ there may also be dirty nodes to the right of the argument. If the scan-left ++ operation does not count at least FLUSH_RELOCATE_THRESHOLD nodes then we ++ follow it with a right-scan operation to see whether there is, in fact, ++ enough nodes to meet the relocate threshold. Each right- and left-scan ++ operation uses a single flush_scan object. ++ ++ After left-scan and possibly right-scan, we prepare a flush_position object ++ with the starting flush point or parent coordinate, which was determined ++ using scan-left. ++ ++ Next we call the main flush routine, squalloc, which iterates along the leaf ++ level, squeezing and allocating nodes (and placing them into the flush ++ queue). ++ ++ After squalloc returns we take extra steps to ensure that all the children ++ of the final twig node are allocated--this involves repeating squalloc ++ until we finish at a twig with no unallocated children. ++ ++ Finally, we call flush_empty_queue to submit write-requests to disk. If we ++ encounter any above-twig nodes during flush_empty_queue that still have ++ unallocated children, we flush_unprep them. ++ ++ Flush treats several "failure" cases as non-failures, essentially causing ++ them to start over. E_DEADLOCK is one example. ++ FIXME:(C) EINVAL, E_NO_NEIGHBOR, ENOENT: these should probably be handled ++ properly rather than restarting, but there are a bunch of cases to audit. ++ ++ We process not more than one meta-data and one data subvolume in one ++ jnode_flush() call. This is optimal, because file bodies in the tree are ++ sorted by subvolume IDs due to special key assignment policy (see method ++ ->build_body_key() of file plugin). We store pointer to the data subvolume ++ in flush position (field data_subv). We don't keep a track of meta-data ++ subvolume, as there is only single one per asymmetric LV (other LV types ++ are not supported for now). ++*/ ++ ++static int jnode_flush(jnode *node, long nr_to_write, long *nr_written, ++ flush_queue_t *fq, int flags) ++{ ++ long ret = 0; ++ flush_scan *right_scan; ++ flush_scan *left_scan; ++ flush_pos_t *flush_pos; ++ struct super_block *sb; ++ reiser4_super_info_data *sbinfo; ++ jnode *leftmost_in_slum = NULL; ++ ++ assert("jmacd-76619", lock_stack_isclean(get_current_lock_stack())); ++ assert("nikita-3022", reiser4_schedulable()); ++ assert("nikita-3185", ++ get_current_super_private()->delete_mutex_owner != current); ++ ++ /* allocate right_scan, left_scan and flush_pos */ ++ right_scan = ++ kmalloc(2 * sizeof(*right_scan) + sizeof(*flush_pos), ++ reiser4_ctx_gfp_mask_get()); ++ if (right_scan == NULL) ++ return RETERR(-ENOMEM); ++ left_scan = right_scan + 1; ++ flush_pos = (flush_pos_t *) (left_scan + 1); ++ ++ sb = reiser4_get_current_sb(); ++ sbinfo = get_super_private(sb); ++ ++ /* Flush-concurrency debug code */ ++#if REISER4_DEBUG ++ atomic_inc(&flush_cnt); ++#endif ++ ++ reiser4_enter_flush(sb); ++ ++ /* Initialize a flush position. */ ++ pos_init(flush_pos); ++ ++ flush_pos->nr_written = nr_written; ++ flush_pos->fq = fq; ++ flush_pos->flags = flags; ++ flush_pos->nr_to_write = nr_to_write; ++ ++ scan_init(right_scan, flush_pos); ++ scan_init(left_scan, flush_pos); ++ ++ /* First scan left and remember the leftmost scan position. If the ++ leftmost position is unformatted we remember its parent_coord. We ++ scan until counting FLUSH_SCAN_MAXNODES. ++ ++ If starting @node is unformatted, at the beginning of left scan its ++ parent (twig level node, containing extent item) will be long term ++ locked and lock handle will be stored in the ++ @right_scan->parent_lock. This lock is used to start the rightward ++ scan without redoing the tree traversal (necessary to find parent) ++ and, hence, is kept during leftward scan. As a result, we have to ++ use try-lock when taking long term locks during the leftward scan. ++ */ ++ ret = scan_left(left_scan, right_scan, node); ++ if (ret != 0) ++ goto failed; ++ leftmost_in_slum = jref(left_scan->node); ++ scan_done(left_scan); ++ ++ /* Then possibly go right to decide if we will use a policy of ++ relocating leaves. This is only done if we did not scan past (and ++ count) enough nodes during the leftward scan. If we do scan right, ++ we only care to go far enough to establish that at least ++ FLUSH_RELOCATE_THRESHOLD number of nodes are being flushed. The scan ++ limit is the difference between left_scan.count and the threshold. */ ++ ++ right_scan->max_count = left_scan->max_count - left_scan->count; ++ /* ++ * scan right is inherently deadlock prone, because we are ++ * (potentially) holding a lock on the twig node at this moment. ++ * FIXME: this is incorrect comment: lock is not held ++ */ ++ if (right_scan->max_count > 0) { ++ ret = scan_right(right_scan, node); ++ if (ret != 0) ++ goto failed; ++ } ++ /* ++ * Only the right-scan count is needed, release any rightward locks ++ * right away ++ */ ++ scan_done(right_scan); ++ ++ /* Funny business here. We set the 'point' in the flush_position at ++ prior to starting squalloc regardless of whether the first point is ++ formatted or unformatted. Without this there would be an invariant, ++ in the rest of the code, that if the flush_position is unformatted ++ then flush_position->point is NULL and ++ flush_position->parent_{lock,coord} is set, and if the flush_position ++ is formatted then flush_position->point is non-NULL and no parent ++ info is set. ++ ++ This seems lazy, but it makes the initial calls to ++ reverse_allocate (which ask "is it the pos->point the leftmost ++ child of its parent") much easier because we know the first child ++ already. Nothing is broken by this, but the reasoning is subtle. ++ Holding an extra reference on a jnode during flush can cause us to ++ see nodes with HEARD_BANSHEE during squalloc, because nodes are not ++ removed from sibling lists until they have zero reference count. ++ Flush would never observe a HEARD_BANSHEE node on the left-edge of ++ flush, nodes are only deleted to the right. So if nothing is broken, ++ why fix it? ++ ++ NOTE-NIKITA actually, flush can meet HEARD_BANSHEE node at any ++ point and in any moment, because of the concurrent file system ++ activity (for example, truncate). */ ++ ++ /* Check jnode state after flush_scan completed. Having a lock on this ++ node or its parent (in case of unformatted) helps us in case of ++ concurrent flushing. */ ++ if (jnode_check_flushprepped(leftmost_in_slum) ++ && !jnode_convertible(leftmost_in_slum)) { ++ ret = 0; ++ goto failed; ++ } ++ ++ /* Now setup flush_pos using scan_left's endpoint. */ ++ ret = prepare_flush_pos(flush_pos, leftmost_in_slum); ++ if (ret) ++ goto failed; ++ ++ if (znode_get_level(flush_pos->coord.node) == LEAF_LEVEL ++ && node_is_empty(flush_pos->coord.node)) { ++ znode *empty = flush_pos->coord.node; ++ ++ assert("zam-1022", !ZF_ISSET(empty, JNODE_HEARD_BANSHEE)); ++ ret = delete_empty_node(empty); ++ goto failed; ++ } ++ ++ if (jnode_check_flushprepped(leftmost_in_slum) ++ && !jnode_convertible(leftmost_in_slum)) { ++ ret = 0; ++ goto failed; ++ } ++ ++ /* Set pos->preceder and (re)allocate pos and its ancestors if it is ++ needed */ ++ ret = alloc_pos_and_ancestors(flush_pos); ++ if (ret) ++ goto failed; ++ ++ /* Do the main rightward-bottom-up squeeze and allocate loop. */ ++ ret = squalloc(flush_pos); ++ ++ pos_stop(flush_pos); ++ if (ret) ++ goto failed; ++ ++ /* FIXME_NFQUCMPD: Here, handle the twig-special case for unallocated ++ children. First, the pos_stop() and pos_valid() routines should be ++ modified so that pos_stop() sets a flush_position->stop flag to 1 ++ without releasing the current position immediately--instead release ++ it in pos_done(). This is a better implementation than the current ++ one anyway. ++ ++ It is not clear that all fields of the flush_position should not be ++ released, but at the very least the parent_lock, parent_coord, and ++ parent_load should remain held because they are hold the last twig ++ when pos_stop() is called. ++ ++ When we reach this point in the code, if the parent_coord is set to ++ after the last item then we know that flush reached the end of a twig ++ (and according to the new flush queueing design, we will return now). ++ If parent_coord is not past the last item, we should check if the ++ current twig has any unallocated children to the right (we are not ++ concerned with unallocated children to the left--in that case the ++ twig itself should not have been allocated). If the twig has ++ unallocated children to the right, set the parent_coord to that ++ position and then repeat the call to squalloc. ++ ++ Testing for unallocated children may be defined in two ways: if any ++ internal item has a fake block number, it is unallocated; if any ++ extent item is unallocated then all of its children are unallocated. ++ But there is a more aggressive approach: if there are any dirty ++ children of the twig to the right of the current position, we may ++ wish to relocate those nodes now. Checking for potential relocation ++ is more expensive as it requires knowing whether there are any dirty ++ children that are not unallocated. The extent_needs_allocation should ++ be used after setting the correct preceder. ++ ++ When we reach the end of a twig at this point in the code, if the ++ flush can continue (when the queue is ready) it will need some ++ information on the future starting point. That should be stored away ++ in the flush_handle using a seal, I believe. Holding a jref() on the ++ future starting point may break other code that deletes that node. ++ */ ++ ++ /* FIXME_NFQUCMPD: Also, we don't want to do any flushing when flush is ++ called above the twig level. If the VM calls flush above the twig ++ level, do nothing and return (but figure out why this happens). The ++ txnmgr should be modified to only flush its leaf-level dirty list. ++ This will do all the necessary squeeze and allocate steps but leave ++ unallocated branches and possibly unallocated twigs (when the twig's ++ leftmost child is not dirty). After flushing the leaf level, the ++ remaining unallocated nodes should be given write-optimized ++ locations. (Possibly, the remaining unallocated twigs should be ++ allocated just before their leftmost child.) ++ */ ++ ++ /* Any failure reaches this point. */ ++failed: ++ ++ switch (ret) { ++ case -E_REPEAT: ++ case -EINVAL: ++ case -E_DEADLOCK: ++ case -E_NO_NEIGHBOR: ++ case -ENOENT: ++ /* FIXME(C): Except for E_DEADLOCK, these should probably be ++ handled properly in each case. They already are handled in ++ many cases. */ ++ /* Something bad happened, but difficult to avoid... Try again! ++ */ ++ ret = 0; ++ } ++ ++ if (leftmost_in_slum) ++ jput(leftmost_in_slum); ++ ++ pos_done(flush_pos); ++ scan_done(left_scan); ++ scan_done(right_scan); ++ kfree(right_scan); ++ ++ ON_DEBUG(atomic_dec(&flush_cnt)); ++ ++ reiser4_leave_flush(sb); ++ ++ return ret; ++} ++ ++/* ++ * Reiser4 flush subsystem can be turned into "rapid flush mode" means that ++ * flusher should submit all prepped nodes immediately without keeping them in ++ * flush queues for long time. The reason for rapid flush mode is to free ++ * memory as fast as possible. ++ */ ++ ++#if REISER4_USE_RAPID_FLUSH ++/** ++ * submit all prepped nodes if rapid flush mode is set, ++ * turn rapid flush mode off. ++ */ ++static int rapid_flush(flush_pos_t *pos) ++{ ++ if (!wbq_available()) ++ return 0; ++ ++ return write_prepped_nodes(pos); ++} ++#else ++#define rapid_flush(pos) (0) ++#endif /* REISER4_USE_RAPID_FLUSH */ ++ ++static jnode *find_flush_start_jnode(jnode *start, txn_atom * atom, ++ flush_queue_t *fq, int *nr_queued, ++ int flags) ++{ ++ jnode * node; ++ ++ if (start != NULL) { ++ spin_lock_jnode(start); ++ if (!jnode_is_flushprepped(start)) { ++ assert("zam-1056", start->atom == atom); ++ node = start; ++ goto enter; ++ } ++ spin_unlock_jnode(start); ++ } ++ /* ++ * In this loop we process all already prepped (RELOC or OVRWR) and ++ * dirtied again nodes. The atom spin lock is not released until all ++ * dirty nodes processed or not prepped node found in the atom dirty ++ * lists. ++ */ ++ while ((node = find_first_dirty_jnode(atom, flags))) { ++ spin_lock_jnode(node); ++enter: ++ assert("zam-881", JF_ISSET(node, JNODE_DIRTY)); ++ assert("zam-898", !JF_ISSET(node, JNODE_OVRWR)); ++ ++ if (JF_ISSET(node, JNODE_WRITEBACK)) { ++ /* move node to the end of atom's writeback list */ ++ list_move_tail(&node->capture_link, ATOM_WB_LIST(atom)); ++ ++ /* ++ * jnode is not necessarily on dirty list: if it was ++ * dirtied when it was on flush queue - it does not get ++ * moved to dirty list ++ */ ++ ON_DEBUG(count_jnode(atom, node, NODE_LIST(node), ++ WB_LIST, 1)); ++ ++ } else if (jnode_is_znode(node) ++ && znode_above_root(JZNODE(node))) { ++ /* ++ * A special case for znode-above-root. The above-root ++ * (fake) znode is captured and dirtied when the tree ++ * height changes or when the root node is relocated. ++ * This causes atoms to fuse so that changes at the root ++ * are serialized. However, this node is never flushed. ++ * This special case used to be in lock.c to prevent the ++ * above-root node from ever being captured, but now ++ * that it is captured we simply prevent it from ++ * flushing. The log-writer code relies on this to ++ * properly log superblock modifications of the tree ++ * height. ++ */ ++ jnode_make_wander_nolock(node); ++ } else if (JF_ISSET(node, JNODE_RELOC)) { ++ queue_jnode(fq, node); ++ ++(*nr_queued); ++ } else ++ break; ++ ++ spin_unlock_jnode(node); ++ } ++ return node; ++} ++ ++/** ++ * Flush some nodes of current atom, usually slum, return -E_REPEAT if there are ++ * more nodes to flush, return 0 if atom's dirty lists empty and keep current ++ * atom locked, return other errors as they are. ++ */ ++int flush_current_atom(int flags, long nr_to_write, long *nr_submitted, ++ txn_atom ** atom, jnode *start) ++{ ++ reiser4_super_info_data *sinfo = get_current_super_private(); ++ flush_queue_t *fq = NULL; ++ jnode *node; ++ int nr_queued; ++ int ret; ++ ++ assert("zam-889", atom != NULL && *atom != NULL); ++ assert_spin_locked(&((*atom)->alock)); ++ assert("zam-892", get_current_context()->trans->atom == *atom); ++ ++ BUG_ON(sb_rdonly(get_current_context()->super)); ++ ++ nr_to_write = LONG_MAX; ++ while (1) { ++ ret = reiser4_fq_by_atom(*atom, &fq); ++ if (ret != -E_REPEAT) ++ break; ++ *atom = get_current_atom_locked(); ++ } ++ if (ret) ++ return ret; ++ ++ assert_spin_locked(&((*atom)->alock)); ++ /* ++ * parallel flushers limit ++ */ ++ if (sinfo->tmgr.atom_max_flushers != 0) { ++ while ((*atom)->nr_flushers >= sinfo->tmgr.atom_max_flushers) { ++ /* ++ * An reiser4_atom_send_event() call is inside ++ * reiser4_fq_put_nolock() which is called when ++ * flush is finished and nr_flushers is decremented. ++ */ ++ reiser4_atom_wait_event(*atom); ++ *atom = get_current_atom_locked(); ++ } ++ } ++ /* ++ * count ourself as a flusher ++ */ ++ (*atom)->nr_flushers++; ++ ++ writeout_mode_enable(); ++ ++ nr_queued = 0; ++ node = find_flush_start_jnode(start, *atom, fq, &nr_queued, flags); ++ ++ if (node == NULL) { ++ if (nr_queued == 0) { ++ (*atom)->nr_flushers--; ++ reiser4_fq_put_nolock(fq); ++ reiser4_atom_send_event(*atom); ++ /* current atom remains locked */ ++ writeout_mode_disable(); ++ return 0; ++ } ++ spin_unlock_atom(*atom); ++ } else { ++ jref(node); ++ assert("edward-2138", jnode_get_super(node) != NULL); ++ BUG_ON((*atom)->super != jnode_get_super(node)); ++ spin_unlock_atom(*atom); ++ spin_unlock_jnode(node); ++ BUG_ON(nr_to_write == 0); ++ ret = jnode_flush(node, nr_to_write, nr_submitted, fq, flags); ++ jput(node); ++ } ++ ret = reiser4_write_fq(fq, nr_submitted, ++ WRITEOUT_SINGLE_STREAM | WRITEOUT_FOR_PAGE_RECLAIM); ++ ++ *atom = get_current_atom_locked(); ++ (*atom)->nr_flushers--; ++ reiser4_fq_put_nolock(fq); ++ reiser4_atom_send_event(*atom); ++ spin_unlock_atom(*atom); ++ ++ writeout_mode_disable(); ++ ++ if (ret == 0) ++ ret = -E_REPEAT; ++ ++ return ret; ++} ++ ++/** ++ * This function calls txmod->reverse_should_realloc_formatted() to make ++ * a reverse-parent-first relocation decision and then, if yes, it marks ++ * the parent dirty. ++ */ ++static int check_parent_for_realloc(jnode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ int ret; ++ reiser4_subvol *subv = node->subvol; ++ ++ if (!JF_ISSET(ZJNODE(parent_coord->node), JNODE_DIRTY)) { ++ txmod_plugin *txmod_plug = txmod_plugin_by_id(subv->txmod); ++ ++ if (!txmod_plug->reverse_should_realloc_formatted) ++ return 0; ++ ret = txmod_plug->reverse_should_realloc_formatted(node, ++ parent_coord, ++ pos); ++ if (ret < 0) ++ return ret; ++ /* ++ * FIXME-ZAM: if parent is already relocated - ++ * we do not want to grab space, right? ++ */ ++ if (ret == 1) { ++ int grabbed; ++ ++ grabbed = ctx_subvol_grabbed(get_current_context(), ++ subv->id); ++ if (reiser4_grab_space_force((__u64) 1, ++ BA_RESERVED, subv) != 0) ++ reiser4_panic("umka-1250", ++ "No space left during flush."); ++ assert("jmacd-18923", ++ znode_is_write_locked(parent_coord->node)); ++ znode_make_dirty(parent_coord->node); ++ grabbed2free_mark(grabbed, subv); ++ } ++ } ++ return 0; ++} ++ ++/* INITIAL ALLOCATE ANCESTORS STEP (REVERSE PARENT-FIRST ALLOCATION BEFORE ++ FORWARD PARENT-FIRST LOOP BEGINS) */ ++ ++/* Get the leftmost child for given coord. */ ++static int get_leftmost_child_of_unit(const coord_t *coord, jnode ** child) ++{ ++ int ret; ++ ++ ret = item_utmost_child(coord, LEFT_SIDE, child); ++ ++ if (ret) ++ return ret; ++ ++ if (IS_ERR(*child)) ++ return PTR_ERR(*child); ++ ++ return 0; ++} ++ ++/* This step occurs after the left- and right-scans are completed, before ++ starting the forward parent-first traversal. Here we attempt to allocate ++ ancestors of the starting flush point, which means continuing in the reverse ++ parent-first direction to the parent, grandparent, and so on (as long as the ++ child is a leftmost child). This routine calls a recursive process, ++ alloc_one_ancestor, which does the real work, except there is special-case ++ handling here for the first ancestor, which may be a twig. At each level ++ (here and alloc_one_ancestor), we check for relocation and then, if the child ++ is a leftmost child, repeat at the next level. On the way back down (the ++ recursion), we allocate the ancestors in parent-first order. */ ++static int alloc_pos_and_ancestors(flush_pos_t *pos) ++{ ++ int ret = 0; ++ lock_handle plock; ++ load_count pload; ++ coord_t pcoord; ++ ++ if (znode_check_flushprepped(pos->lock.node)) ++ return 0; ++ ++ coord_init_invalid(&pcoord, NULL); ++ init_lh(&plock); ++ init_load_count(&pload); ++ ++ if (pos->state == POS_ON_EPOINT) { ++ /* a special case for pos on twig level, where we already have ++ a lock on parent node. */ ++ /* The parent may not be dirty, in which case we should decide ++ whether to relocate the child now. If decision is made to ++ relocate the child, the parent is marked dirty. */ ++ ret = check_parent_for_realloc(pos->child, &pos->coord, pos); ++ if (ret) ++ goto exit; ++ ++ /* FIXME_NFQUCMPD: We only need to allocate the twig (if child ++ is leftmost) and the leaf/child, so recursion is not needed. ++ Levels above the twig will be allocated for ++ write-optimization before the transaction commits. */ ++ ++ /* Do the recursive step, allocating zero or more of our ++ * ancestors. */ ++ ret = alloc_one_ancestor(&pos->coord, pos); ++ } else { ++ if (!znode_is_root(pos->lock.node)) { ++ /* ++ * all formatted nodes except tree root ++ */ ++ ret = reiser4_get_parent(&plock, pos->lock.node, ++ ZNODE_WRITE_LOCK); ++ if (ret) ++ goto exit; ++ ++ ret = incr_load_count_znode(&pload, plock.node); ++ if (ret) ++ goto exit; ++ ++ ret = find_child_ptr(plock.node, pos->lock.node, &pcoord); ++ if (ret) ++ goto exit; ++ ++ ret = check_parent_for_realloc(ZJNODE(pos->lock.node), ++ &pcoord, ++ pos); ++ if (ret) ++ goto exit; ++ ++ ret = alloc_one_ancestor(&pcoord, pos); ++ if (ret) ++ goto exit; ++ } ++ ret = allocate_znode(pos->lock.node, &pcoord, pos); ++ } ++exit: ++ done_load_count(&pload); ++ done_lh(&plock); ++ return ret; ++} ++ ++/* This is the recursive step described in alloc_pos_and_ancestors, above. ++ Ignoring the call to find_preceder, which is the next function described, this ++ checks if the child is a leftmost child and returns if it is not. If the ++ child is a leftmost child it checks for relocation, possibly dirtying the ++ parent. Then it performs the recursive step. */ ++static int alloc_one_ancestor(const coord_t *coord, flush_pos_t *pos) ++{ ++ int ret = 0; ++ lock_handle alock; ++ load_count aload; ++ coord_t acoord; ++ /* ++ * As we ascend at the left-edge of the region to flush, take this ++ * opportunity at the twig level to find our parent-first preceder. ++ * This precider will be used to allocate the formatted node we will ++ * start descending from. Other nodes on the way back will be allocated ++ * by using the updated preceder. ++ */ ++ if (pos->mfbi.preceder.blk == 0) { ++ ret = find_preceder(coord, &pos->mfbi); ++ if (ret != 0) ++ return ret; ++ } ++ /* ++ * If the ancestor is clean or already allocated, or ++ * if the child is not a leftmost child, stop going up, ++ * even leaving coord->node not flushprepped ++ */ ++ if (znode_check_flushprepped(coord->node) || ++ !coord_is_leftmost_unit(coord)) ++ return 0; ++ ++ init_lh(&alock); ++ init_load_count(&aload); ++ coord_init_invalid(&acoord, NULL); ++ ++ /* Only ascend to the next level if it is a leftmost child, but ++ write-lock the parent in case we will relocate the child. */ ++ if (!znode_is_root(coord->node)) { ++ ++ ret = ++ jnode_lock_parent_coord(ZJNODE(coord->node), &acoord, ++ &alock, &aload, ZNODE_WRITE_LOCK, ++ 0); ++ if (ret != 0) { ++ /* FIXME(C): check EINVAL, E_DEADLOCK */ ++ goto exit; ++ } ++ ++ ret = check_parent_for_realloc(ZJNODE(coord->node), ++ &acoord, pos); ++ if (ret != 0) ++ goto exit; ++ ++ /* Recursive call. */ ++ if (!znode_check_flushprepped(acoord.node)) { ++ ret = alloc_one_ancestor(&acoord, pos); ++ if (ret) ++ goto exit; ++ } ++ } ++ ++ /* Note: we call allocate with the parent write-locked (except at the ++ root) in case we relocate the child, in which case it will modify the ++ parent during this call. */ ++ ret = allocate_znode(coord->node, &acoord, pos); ++ ++exit: ++ done_load_count(&aload); ++ done_lh(&alock); ++ return ret; ++} ++ ++/* During the reverse parent-first alloc_pos_and_ancestors process described ++ above there is a call to this function at the twig level. During ++ alloc_pos_and_ancestors we may ask: should this node be relocated (in reverse ++ parent-first context)? We repeat this process as long as the child is the ++ leftmost child, eventually reaching an ancestor of the flush point that is ++ not a leftmost child. The preceder of that ancestors, which is not a leftmost ++ child, is actually on the leaf level. The preceder of that block is the ++ left-neighbor of the flush point. The preceder of that block is the rightmost ++ child of the twig on the left. So, when alloc_pos_and_ancestors passes upward ++ through the twig level, it stops momentarily to remember the block of the ++ rightmost child of the twig on the left and sets it to the flush_position's ++ preceder_hint. ++ ++ There is one other place where we may set the flush_position's preceder hint, ++ which is during scan-left. ++*/ ++static int find_preceder(const coord_t *coord_in, flush_brick_info *fbi) ++{ ++ int ret; ++ coord_t coord; ++ lock_handle left_lock; ++ load_count left_load; ++ reiser4_block_nr blk; ++ ++ coord_dup(&coord, coord_in); ++ ++ init_lh(&left_lock); ++ init_load_count(&left_load); ++ /* ++ * FIXME(B): Same FIXME as in "Find the preceder" in ++ * reverse_allocate. coord_is_leftmost_unit is not the ++ * right test if the unformatted child is in the middle ++ * of the first extent unit ++ */ ++ if (!coord_is_leftmost_unit(&coord)) ++ coord_prev_unit(&coord); ++ else { ++ ret = reiser4_get_left_neighbor(&left_lock, coord.node, ++ ZNODE_READ_LOCK, ++ GN_SAME_ATOM); ++ if (ret) { ++ /* ++ * If we fail for any reason it doesn't matter because ++ * the preceder is only a hint. We are low-priority at ++ * this point, so this must be the case ++ */ ++ if (ret == -E_REPEAT || ++ ret == -E_NO_NEIGHBOR || ++ ret == -ENOENT || ++ ret == -EINVAL || ++ ret == -E_DEADLOCK) ++ ret = 0; ++ goto exit; ++ } ++ ret = incr_load_count_znode(&left_load, left_lock.node); ++ if (ret) ++ goto exit; ++ ++ coord_init_last_unit(&coord, left_lock.node); ++ } ++ assert("edward-1849", ++ item_is_extent(&coord) || item_is_internal(&coord)); ++ ++ ret = item_utmost_child_real_block(&coord, RIGHT_SIDE, &blk); ++ if (ret) ++ goto exit; ++ if (find_data_subvol(&coord) != get_meta_subvol()) ++ /* ++ * We are looking for a preceder for a formatted node ++ * on the twig level (that is in meta-data brick), whereas ++ * previous extent at @coord points out to different brick, ++ * so preceder not found. ++ */ ++ goto exit; ++ fbi->preceder.blk = blk; ++ check_preceder(blk, get_meta_subvol()); ++ exit: ++ done_load_count(&left_load); ++ done_lh(&left_lock); ++ return ret; ++} ++ ++int shift_extent_left_complete(coord_t *to, reiser4_key *to_key, znode *left); ++ ++/* MAIN SQUEEZE AND ALLOCATE LOOP (THREE BIG FUNCTIONS) */ ++ ++/* This procedure implements the outer loop of the flush algorithm. To put this ++ in context, here is the general list of steps taken by the flush routine as a ++ whole: ++ ++ 1. Scan-left ++ 2. Scan-right (maybe) ++ 3. Allocate initial flush position and its ancestors ++ 4. ++ 5. ++ 6. ++ ++ This procedure implements the loop in steps 4 through 6 in the above listing. ++ ++ Step 4: if the current flush position is an extent item (position on the twig ++ level), it allocates the extent (allocate_extent_item_in_place) then shifts ++ to the next coordinate. If the next coordinate's leftmost child needs ++ flushprep, we will continue. If the next coordinate is an internal item, we ++ descend back to the leaf level, otherwise we repeat a step #4 (labeled ++ ALLOC_EXTENTS below). If the "next coordinate" brings us past the end of the ++ twig level, then we call reverse_relocate_end_of_twig to possibly dirty the ++ next (right) twig, prior to step #5 which moves to the right. ++ ++ Step 5: calls squalloc_changed_ancestors, which initiates a recursive call up ++ the tree to allocate any ancestors of the next-right flush position that are ++ not also ancestors of the current position. Those ancestors (in top-down ++ order) are the next in parent-first order. We squeeze adjacent nodes on the ++ way up until the right node and current node share the same parent, then ++ allocate on the way back down. Finally, this step sets the flush position to ++ the next-right node. Then repeat steps 4 and 5. ++*/ ++ ++/* SQUEEZE CODE */ ++ ++/* Copy as much of the leading extents from @right to @left, allocating ++ unallocated extents as they are copied. Returns SQUEEZE_TARGET_FULL or ++ SQUEEZE_SOURCE_EMPTY when no more can be shifted. If the next item is an ++ internal item it calls shift_one_internal_unit and may then return ++ SUBTREE_MOVED. */ ++ ++static int squeeze_right_twig(znode * left, znode * right, flush_pos_t *pos) ++{ ++ int ret = SUBTREE_MOVED; ++ coord_t coord; /* used to iterate over items */ ++ reiser4_key stop_key; ++ reiser4_tree *tree; ++ reiser4_subvol *subv; ++ txmod_plugin *txmod_plug; ++ ++ assert("jmacd-2008", !node_is_empty(right)); ++ assert("edward-1728", ZJNODE(right)->subvol == ZJNODE(left)->subvol); ++ ++ subv = get_meta_subvol(); ++ txmod_plug = txmod_plugin_by_id(subv->txmod); ++ coord_init_first_unit(&coord, right); ++ /* ++ * FIXME: can be optimized to cut once ++ */ ++ while (!node_is_empty(coord.node) && item_is_extent(&coord)) { ++ /* ++ * ON_DEBUG(void *vp); FIXME-EDWARD: that shift check ++ * leads to false positives ++ */ ++ assert("vs-1468", coord_is_leftmost_unit(&coord)); ++ //ON_DEBUG(vp = shift_check_prepare(left, coord.node)); ++ /* ++ * Allocate one extent (a unit of reiser4 extent item) ++ * in "squeeze context" and append it to the @left. ++ * stop_key is used to find what was copied and what ++ * to cut ++ */ ++ stop_key = *reiser4_min_key(); ++ ret = txmod_plug->squeeze_alloc_unformatted(left, ++ &coord, pos, ++ &stop_key); ++ if (ret != SQUEEZE_CONTINUE) { ++ //ON_DEBUG(kfree(vp)); ++ break; ++ } ++ assert("vs-1465", !keyeq(&stop_key, reiser4_min_key())); ++ /* ++ * cut the original units from @right (to complete shifting) ++ */ ++ set_key_offset(&stop_key, get_key_offset(&stop_key) - 1); ++ check_me("vs-1466", ++ shift_extent_left_complete(&coord, &stop_key, left) == 0); ++ ++ //ON_DEBUG(shift_check(vp, left, coord.node)); ++ } ++ /* ++ * @left and @right nodes participated in the ++ * implicit shift, determined by the pair of ++ * functions: ++ * . squeeze_alloc_unformatted() - copy unit from @right to @left ++ * . shift_extent_left_complete() - cut the original unit from @right ++ * so update their delimiting keys ++ */ ++ tree = znode_get_tree(left); ++ write_lock_dk(tree); ++ update_znode_dkeys(left, right); ++ write_unlock_dk(tree); ++ ++ if (node_is_empty(coord.node)) ++ ret = SQUEEZE_SOURCE_EMPTY; ++ ++ if (ret == SQUEEZE_TARGET_FULL) ++ goto out; ++ ++ if (node_is_empty(right)) { ++ /* The whole right node was copied into @left. */ ++ assert("vs-464", ret == SQUEEZE_SOURCE_EMPTY); ++ goto out; ++ } ++ ++ coord_init_first_unit(&coord, right); ++ ++ if (!item_is_internal(&coord)) { ++ /* we do not want to squeeze anything else to left neighbor ++ because "slum" is over */ ++ ret = SQUEEZE_TARGET_FULL; ++ goto out; ++ } ++ assert("jmacd-433", item_is_internal(&coord)); ++ ++ /* Shift an internal unit. The child must be allocated before shifting ++ any more extents, so we stop here. */ ++ ret = shift_one_internal_unit(left, right); ++ ++out: ++ assert("jmacd-8612", ret < 0 || ret == SQUEEZE_TARGET_FULL ++ || ret == SUBTREE_MOVED || ret == SQUEEZE_SOURCE_EMPTY); ++ ++ if (ret == SQUEEZE_TARGET_FULL) { ++ /* We submit prepped nodes here and expect that this @left twig ++ * will not be modified again during this jnode_flush() call. */ ++ int ret1; ++ ++ /* NOTE: seems like io is done under long term locks. */ ++ ret1 = write_prepped_nodes(pos); ++ if (ret1 < 0) ++ return ret1; ++ } ++ ++ return ret; ++} ++ ++#if REISER4_DEBUG ++static void item_convert_invariant(flush_pos_t *pos) ++{ ++ assert("edward-1225", coord_is_existing_item(&pos->coord)); ++ if (convert_data_attached(pos)) { ++ item_plugin *iplug = item_convert_plug(pos); ++ ++ assert("edward-1000", ++ iplug == item_plugin_by_coord(&pos->coord)); ++ assert("edward-1001", iplug->f.convert != NULL); ++ } else ++ assert("edward-1226", pos->child == NULL); ++} ++#else ++ ++#define item_convert_invariant(pos) noop ++ ++#endif ++ ++/* ++ * Scan all node's items and apply for each one ++ * its ->convert() method. This method may: ++ * . resize the item; ++ * . kill the item; ++ * . insert a group of items/nodes on the right, ++ * which possess the following properties: ++ * . all new nodes are dirty and not convertible; ++ * . for all new items ->convert() method is a noop. ++ * ++ * NOTE: this function makes the tree unbalanced! ++ * This intended to be used by flush squalloc() in a ++ * combination with squeeze procedure. ++ * ++ * GLOSSARY ++ * ++ * Chained nodes and items. ++ * Two neighboring nodes @left and @right are chained, ++ * iff the last item of @left and the first item of @right ++ * belong to the same item cluster. In this case those ++ * items are called chained. ++ */ ++static int convert_node(flush_pos_t *pos, znode * node) ++{ ++ int ret = 0; ++ item_plugin *iplug; ++ assert("edward-304", pos != NULL); ++ assert("edward-305", pos->child == NULL); ++ assert("edward-475", znode_convertible(node)); ++ assert("edward-669", znode_is_wlocked(node)); ++ assert("edward-1210", !node_is_empty(node)); ++ ++ if (znode_get_level(node) != LEAF_LEVEL) ++ /* unsupported */ ++ goto exit; ++ ++ coord_init_first_unit(&pos->coord, node); ++ ++ while (1) { ++ ret = 0; ++ coord_set_to_left(&pos->coord); ++ item_convert_invariant(pos); ++ ++ iplug = item_plugin_by_coord(&pos->coord); ++ assert("edward-844", iplug != NULL); ++ ++ if (iplug->f.convert) { ++ ret = iplug->f.convert(pos); ++ if (ret) ++ goto exit; ++ } ++ assert("edward-307", pos->child == NULL); ++ ++ if (coord_next_item(&pos->coord)) { ++ /* ++ * node is over ++ */ ++ if (convert_data_attached(pos)) ++ /* ++ * the last item was convertible and ++ * there still is an unprocesssed flow ++ */ ++ if (next_node_is_chained(pos)) { ++ /* ++ * next node contains items of ++ * the same disk cluster, ++ * so finish with this node ++ */ ++ update_chaining_state(pos, 0/* move ++ to next ++ node */); ++ break; ++ } ++ else { ++ /* ++ * perform one more iteration ++ * for the same item and the ++ * rest of flow ++ */ ++ update_chaining_state(pos, 1/* this ++ node */); ++ } ++ else ++ /* ++ * the last item wasn't convertible, or ++ * convert date was detached in the last ++ * iteration, ++ * go to next node ++ */ ++ break; ++ } else { ++ /* ++ * Node is not over, item position got decremented. ++ */ ++ if (convert_data_attached(pos)) { ++ /* ++ * disk cluster should be increased, so roll ++ * one item position back and perform the ++ * iteration with the previous item and the ++ * rest of attached data ++ */ ++ if (iplug != item_plugin_by_coord(&pos->coord)) ++ set_item_convert_count(pos, 0); ++ ++ ret = coord_prev_item(&pos->coord); ++ assert("edward-1003", !ret); ++ ++ update_chaining_state(pos, 1/* this node */); ++ } ++ else ++ /* ++ * previous item was't convertible, or ++ * convert date was detached in the last ++ * iteration, go to next item ++ */ ++ ; ++ } ++ } ++ JF_CLR(ZJNODE(node), JNODE_CONVERTIBLE); ++ znode_make_dirty(node); ++exit: ++ assert("edward-1004", !ret); ++ return ret; ++} ++ ++/* Squeeze and allocate the right neighbor. This is called after @left and ++ its current children have been squeezed and allocated already. This ++ procedure's job is to squeeze and items from @right to @left. ++ ++ If at the leaf level, use the shift_everything_left memcpy-optimized ++ version of shifting (squeeze_right_leaf). ++ ++ If at the twig level, extents are allocated as they are shifted from @right ++ to @left (squalloc_right_twig). ++ ++ At any other level, shift one internal item and return to the caller ++ (squalloc_parent_first) so that the shifted-subtree can be processed in ++ parent-first order. ++ ++ When unit of internal item is moved, squeezing stops and SUBTREE_MOVED is ++ returned. When all content of @right is squeezed, SQUEEZE_SOURCE_EMPTY is ++ returned. If nothing can be moved into @left anymore, SQUEEZE_TARGET_FULL ++ is returned. ++*/ ++ ++static int squeeze_right_neighbor(flush_pos_t *pos, znode * left, ++ znode * right) ++{ ++ int ret; ++ ++ /* FIXME it is possible to see empty hasn't-heard-banshee node in a ++ * tree owing to error (for example, ENOSPC) in write */ ++ /* assert("jmacd-9321", !node_is_empty(left)); */ ++ assert("jmacd-9322", !node_is_empty(right)); ++ assert("jmacd-9323", znode_get_level(left) == znode_get_level(right)); ++ ++ switch (znode_get_level(left)) { ++ case TWIG_LEVEL: ++ /* Shift with extent allocating until either an internal item ++ is encountered or everything is shifted or no free space ++ left in @left */ ++ ret = squeeze_right_twig(left, right, pos); ++ break; ++ ++ default: ++ /* All other levels can use shift_everything until we implement ++ per-item flush plugins. */ ++ ret = squeeze_right_non_twig(left, right); ++ break; ++ } ++ ++ assert("jmacd-2011", (ret < 0 || ++ ret == SQUEEZE_SOURCE_EMPTY ++ || ret == SQUEEZE_TARGET_FULL ++ || ret == SUBTREE_MOVED)); ++ return ret; ++} ++ ++static int squeeze_right_twig_and_advance_coord(flush_pos_t *pos, ++ znode * right) ++{ ++ int ret; ++ ++ ret = squeeze_right_twig(pos->lock.node, right, pos); ++ if (ret < 0) ++ return ret; ++ if (ret > 0) { ++ coord_init_after_last_item(&pos->coord, pos->lock.node); ++ return ret; ++ } ++ ++ coord_init_last_unit(&pos->coord, pos->lock.node); ++ return 0; ++} ++ ++/* do a fast check for "same parents" condition before calling ++ * squalloc_upper_levels() */ ++static inline int check_parents_and_squalloc_upper_levels(flush_pos_t *pos, ++ znode * left, ++ znode * right) ++{ ++ if (znode_same_parents(left, right)) ++ return 0; ++ ++ return squalloc_upper_levels(pos, left, right); ++} ++ ++/* Check whether the parent of given @right node needs to be processes ++ ((re)allocated) prior to processing of the child. If @left and @right do not ++ share at least the parent of the @right is after the @left but before the ++ @right in parent-first order, we have to (re)allocate it before the @right ++ gets (re)allocated. */ ++static int squalloc_upper_levels(flush_pos_t *pos, znode * left, znode * right) ++{ ++ int ret; ++ ++ lock_handle left_parent_lock; ++ lock_handle right_parent_lock; ++ ++ load_count left_parent_load; ++ load_count right_parent_load; ++ ++ init_lh(&left_parent_lock); ++ init_lh(&right_parent_lock); ++ ++ init_load_count(&left_parent_load); ++ init_load_count(&right_parent_load); ++ ++ ret = reiser4_get_parent(&left_parent_lock, left, ZNODE_WRITE_LOCK); ++ if (ret) ++ goto out; ++ ++ ret = reiser4_get_parent(&right_parent_lock, right, ZNODE_WRITE_LOCK); ++ if (ret) ++ goto out; ++ ++ /* Check for same parents */ ++ if (left_parent_lock.node == right_parent_lock.node) ++ goto out; ++ ++ if (znode_check_flushprepped(right_parent_lock.node)) { ++ /* ++ * Keep parent-first order. In the order, the right parent node ++ * stands before the @right node. If it is already allocated, ++ * we set the preceder (next block search start point) to its ++ * block number, @right node should be allocated after it. ++ * ++ * However, preceder is set only if the right parent is on twig ++ * level. The explanation is the following: new branch nodes are ++ * allocated over already allocated children while the tree ++ * grows, it is difficult to keep tree ordered, we assume that ++ * only leaves and twings are correctly allocated. So, only ++ * twigs are used as a preceder for allocating of the rest of ++ * the slum ++ */ ++ if (znode_get_level(right_parent_lock.node) == TWIG_LEVEL) ++ fbi_update_preceder(&pos->mfbi, ++ *znode_get_block(right_parent_lock.node)); ++ goto out; ++ } ++ ret = incr_load_count_znode(&left_parent_load, left_parent_lock.node); ++ if (ret) ++ goto out; ++ ++ ret = incr_load_count_znode(&right_parent_load, right_parent_lock.node); ++ if (ret) ++ goto out; ++ ++ ret = squeeze_right_neighbor(pos, left_parent_lock.node, ++ right_parent_lock.node); ++ /* ++ * We stop if error. We stop if some items/units were shifted (ret == 0) ++ * and thus @right changed its parent. It means we have not process ++ * right_parent node prior to processing of @right. Positive return ++ * values say that shifting items was not happen because of "empty ++ * source" or "target full" conditions. ++ */ ++ if (ret <= 0) ++ goto out; ++ ++ /* parent(@left) and parent(@right) may have different parents also. We ++ * do a recursive call for checking that. */ ++ ++ ret = check_parents_and_squalloc_upper_levels(pos, left_parent_lock.node, ++ right_parent_lock.node); ++ if (ret) ++ goto out; ++ ++ /* allocate znode when going down */ ++ ret = lock_parent_and_allocate_znode(right_parent_lock.node, pos); ++ ++out: ++ done_load_count(&left_parent_load); ++ done_load_count(&right_parent_load); ++ ++ done_lh(&left_parent_lock); ++ done_lh(&right_parent_lock); ++ ++ return ret; ++} ++ ++/* Check the leftmost child "flushprepped" status, also returns true if child ++ * node was not found in cache. */ ++static int leftmost_child_of_unit_check_flushprepped(const coord_t *coord) ++{ ++ int ret; ++ int prepped; ++ ++ jnode *child; ++ ++ ret = get_leftmost_child_of_unit(coord, &child); ++ ++ if (ret) ++ return ret; ++ ++ if (child) { ++ prepped = jnode_check_flushprepped(child); ++ jput(child); ++ } else { ++ /* We consider not existing child as a node which slum ++ processing should not continue to. Not cached node is clean, ++ so it is flushprepped. */ ++ prepped = 1; ++ } ++ ++ return prepped; ++} ++ ++/* (re)allocate znode with automated getting parent node */ ++static int lock_parent_and_allocate_znode(znode * node, flush_pos_t *pos) ++{ ++ int ret; ++ lock_handle parent_lock; ++ load_count parent_load; ++ coord_t pcoord; ++ ++ assert("zam-851", znode_is_write_locked(node)); ++ ++ init_lh(&parent_lock); ++ init_load_count(&parent_load); ++ ++ ret = reiser4_get_parent(&parent_lock, node, ZNODE_WRITE_LOCK); ++ if (ret) ++ goto out; ++ ++ ret = incr_load_count_znode(&parent_load, parent_lock.node); ++ if (ret) ++ goto out; ++ ++ ret = find_child_ptr(parent_lock.node, node, &pcoord); ++ if (ret) ++ goto out; ++ ++ ret = allocate_znode(node, &pcoord, pos); ++ ++out: ++ done_load_count(&parent_load); ++ done_lh(&parent_lock); ++ return ret; ++} ++ ++/* ++ * Process nodes on the leaf level until unformatted node or ++ * rightmost node in the slum reached. ++ * ++ * This function is a complicated beast, because it calls a ++ * static machine ->convert_node() for every node, which, in ++ * turn, scans node's items and does something for each of them. ++ */ ++static int handle_pos_on_formatted(flush_pos_t *pos) ++{ ++ int ret; ++ lock_handle right_lock; ++ load_count right_load; ++ ++ init_lh(&right_lock); ++ init_load_count(&right_load); ++ ++ if (znode_convertible(pos->lock.node)) { ++ ret = convert_node(pos, pos->lock.node); ++ if (ret) ++ return ret; ++ } ++ while (1) { ++ assert("edward-1635", ++ ergo(node_is_empty(pos->lock.node), ++ ZF_ISSET(pos->lock.node, JNODE_HEARD_BANSHEE))); ++ /* ++ * First of all, grab a right neighbor ++ */ ++ if (convert_data(pos) && convert_data(pos)->right_locked) { ++ /* ++ * the right neighbor was locked by convert_node() ++ * transfer the lock from the "cache". ++ */ ++ move_lh(&right_lock, &convert_data(pos)->right_lock); ++ done_lh(&convert_data(pos)->right_lock); ++ convert_data(pos)->right_locked = 0; ++ } ++ else { ++ ret = neighbor_in_slum(pos->lock.node, &right_lock, ++ RIGHT_SIDE, ZNODE_WRITE_LOCK, ++ 1, 0); ++ if (ret) { ++ /* ++ * There is no right neighbor for some reasons, ++ * so finish with this level. ++ */ ++ assert("edward-1636", ++ !should_convert_right_neighbor(pos)); ++ break; ++ } ++ } ++ /* ++ * Check "flushprepped" status of the right neighbor. ++ * ++ * We don't prep(allocate) nodes for flushing twice. This can be ++ * suboptimal, or it can be optimal. For now we choose to live ++ * with the risk that it will be suboptimal because it would be ++ * quite complex to code it to be smarter. ++ */ ++ if (znode_check_flushprepped(right_lock.node) ++ && !znode_convertible(right_lock.node)) { ++ assert("edward-1005", ++ !should_convert_right_neighbor(pos)); ++ pos_stop(pos); ++ break; ++ } ++ ret = incr_load_count_znode(&right_load, right_lock.node); ++ if (ret) ++ break; ++ if (znode_convertible(right_lock.node)) { ++ assert("edward-1643", ++ ergo(convert_data(pos), ++ convert_data(pos)->right_locked == 0)); ++ ++ ret = convert_node(pos, right_lock.node); ++ if (ret) ++ break; ++ } ++ else ++ assert("edward-1637", ++ !should_convert_right_neighbor(pos)); ++ ++ if (node_is_empty(pos->lock.node)) { ++ /* ++ * Current node became empty after conversion ++ * and, hence, was removed from the tree; ++ * Advance the current position to the right neighbor. ++ */ ++ assert("edward-1638", ++ ZF_ISSET(pos->lock.node, JNODE_HEARD_BANSHEE)); ++ move_flush_pos(pos, &right_lock, &right_load, NULL); ++ continue; ++ } ++ if (node_is_empty(right_lock.node)) { ++ assert("edward-1639", ++ ZF_ISSET(right_lock.node, JNODE_HEARD_BANSHEE)); ++ /* ++ * The right neighbor became empty after ++ * convertion, and hence it was deleted ++ * from the tree - skip this. ++ * Since current node is not empty, ++ * we'll obtain a correct pointer to ++ * the next right neighbor ++ */ ++ done_load_count(&right_load); ++ done_lh(&right_lock); ++ continue; ++ } ++ /* ++ * At this point both, current node and its right ++ * neigbor are converted and not empty. ++ * Squeeze them _before_ going upward. ++ */ ++ ret = squeeze_right_neighbor(pos, pos->lock.node, ++ right_lock.node); ++ if (ret < 0) ++ break; ++ if (node_is_empty(right_lock.node)) { ++ assert("edward-1640", ++ ZF_ISSET(right_lock.node, JNODE_HEARD_BANSHEE)); ++ /* ++ * right neighbor was squeezed completely, ++ * and hence has been deleted from the tree. ++ * Skip this. ++ */ ++ done_load_count(&right_load); ++ done_lh(&right_lock); ++ continue; ++ } ++ if (znode_check_flushprepped(right_lock.node)) { ++ if (should_convert_right_neighbor(pos)) { ++ /* ++ * in spite of flushprepped status of the node, ++ * its right slum neighbor should be converted ++ */ ++ assert("edward-953", convert_data(pos)); ++ assert("edward-954", item_convert_data(pos)); ++ ++ move_flush_pos(pos, &right_lock, &right_load, NULL); ++ continue; ++ } else { ++ pos_stop(pos); ++ break; ++ } ++ } ++ /* ++ * parent(right_lock.node) has to be processed before ++ * (right_lock.node) due to "parent-first" allocation ++ * order ++ */ ++ ret = check_parents_and_squalloc_upper_levels(pos, ++ pos->lock.node, ++ right_lock.node); ++ if (ret) ++ break; ++ /* ++ * (re)allocate _after_ going upward ++ */ ++ ret = lock_parent_and_allocate_znode(right_lock.node, pos); ++ if (ret) ++ break; ++ if (should_terminate_squalloc(pos)) { ++ set_item_convert_count(pos, 0); ++ break; ++ } ++ /* ++ * advance the flush position to the right neighbor ++ */ ++ move_flush_pos(pos, &right_lock, &right_load, NULL); ++ ++ ret = rapid_flush(pos); ++ if (ret) ++ break; ++ } ++ check_convert_info(pos); ++ done_load_count(&right_load); ++ done_lh(&right_lock); ++ /* ++ * This function indicates via pos whether to stop or go to twig or ++ * continue on current level ++ */ ++ return ret; ++ ++} ++ ++/* Process nodes on leaf level until unformatted node or rightmost node in the ++ * slum reached. */ ++static int handle_pos_on_leaf(flush_pos_t *pos) ++{ ++ int ret; ++ ++ assert("zam-845", pos->state == POS_ON_LEAF); ++ ++ ret = handle_pos_on_formatted(pos); ++ ++ if (ret == -E_NO_NEIGHBOR) { ++ /* cannot get right neighbor, go process extents. */ ++ pos->state = POS_TO_TWIG; ++ return 0; ++ } ++ ++ return ret; ++} ++ ++/* Process slum on level > 1 */ ++static int handle_pos_on_internal(flush_pos_t *pos) ++{ ++ assert("zam-850", pos->state == POS_ON_INTERNAL); ++ return handle_pos_on_formatted(pos); ++} ++ ++/* check whether squalloc should stop before processing given extent */ ++static int squalloc_extent_should_stop(flush_pos_t *pos) ++{ ++ assert("zam-869", item_is_extent(&pos->coord)); ++ ++ /* pos->child is a jnode handle_pos_on_extent() should start with in ++ * stead of the first child of the first extent unit. */ ++ if (pos->child) { ++ int prepped; ++ ++ assert("vs-1383", jnode_is_unformatted(pos->child)); ++ prepped = jnode_check_flushprepped(pos->child); ++ pos->pos_in_unit = ++ jnode_get_index(pos->child) - ++ extent_unit_index(&pos->coord); ++ assert("vs-1470", ++ pos->pos_in_unit < extent_unit_width(&pos->coord)); ++ assert("nikita-3434", ++ ergo(extent_is_unallocated(&pos->coord), ++ pos->pos_in_unit == 0)); ++ jput(pos->child); ++ pos->child = NULL; ++ ++ return prepped; ++ } ++ ++ pos->pos_in_unit = 0; ++ if (extent_is_unallocated(&pos->coord)) ++ return 0; ++ ++ return leftmost_child_of_unit_check_flushprepped(&pos->coord); ++} ++ ++/* Handle the case when regular reiser4 tree (znodes connected one to its ++ * neighbors by sibling pointers) is interrupted on leaf level by one or more ++ * unformatted nodes. By having a lock on twig level and use extent code ++ * routines to process unformatted nodes we swim around an irregular part of ++ * reiser4 tree. */ ++static int handle_pos_on_twig(flush_pos_t *pos) ++{ ++ int ret; ++ reiser4_subvol *subv; ++ txmod_plugin *txmod_plug; ++ ++ assert("zam-844", pos->state == POS_ON_EPOINT); ++ assert("zam-843", item_is_extent(&pos->coord)); ++ ++ subv = find_data_subvol(&pos->coord); ++ txmod_plug = txmod_plugin_by_id(subv->txmod); ++ ++ /* We decide should we continue slum processing with current extent ++ unit: if leftmost child of current extent unit is flushprepped ++ (i.e. clean or already processed by flush) we stop squalloc(). There ++ is a fast check for unallocated extents which we assume contain all ++ not flushprepped nodes. */ ++ /* FIXME: Here we implement simple check, we are only looking on the ++ leftmost child. */ ++ ret = squalloc_extent_should_stop(pos); ++ if (ret != 0) { ++ pos_stop(pos); ++ return ret; ++ } ++ /* ++ * loop on the whole connected set of extents ++ */ ++ while (pos_valid(pos) && coord_is_existing_unit(&pos->coord) && ++ item_is_extent(&pos->coord)) { ++ ret = txmod_plug->forward_alloc_unformatted(pos); ++ if (ret) ++ break; ++ coord_next_unit(&pos->coord); ++ } ++ if (coord_is_after_rightmost(&pos->coord)) { ++ pos->state = POS_END_OF_TWIG; ++ return 0; ++ } ++ if (item_is_internal(&pos->coord)) { ++ pos->state = POS_TO_LEAF; ++ return 0; ++ } ++ ++ assert("zam-860", item_is_extent(&pos->coord)); ++ ++ /* "slum" is over */ ++ pos->state = POS_INVALID; ++ return 0; ++} ++ ++/** ++ * When we about to return flush position from twig to leaf level ++ * we can process the right twig node or move position to the leaf. ++ * This function processes right twig if it is possible and jumps ++ * to leaf level if not ++ */ ++static int handle_pos_end_of_twig(flush_pos_t *pos) ++{ ++ int ret; ++ lock_handle right_lock; ++ load_count right_load; ++ coord_t at_right; ++ jnode *child = NULL; ++ ++ assert("zam-848", pos->state == POS_END_OF_TWIG); ++ assert("zam-849", coord_is_after_rightmost(&pos->coord)); ++ ++ init_lh(&right_lock); ++ init_load_count(&right_load); ++ /* ++ * We get a lock on the right twig node even it is not dirty because ++ * slum continues or discontinues on leaf level not on next twig. This ++ * lock on the right twig is needed for getting its leftmost child ++ */ ++ ret = reiser4_get_right_neighbor(&right_lock, pos->lock.node, ++ ZNODE_WRITE_LOCK, GN_SAME_ATOM); ++ if (ret) ++ goto out; ++ ++ ret = incr_load_count_znode(&right_load, right_lock.node); ++ if (ret) ++ goto out; ++ ++ coord_init_first_unit(&at_right, right_lock.node); ++ ++ if (JF_ISSET(ZJNODE(right_lock.node), JNODE_DIRTY)) { ++ /* ++ * If right twig node is dirty we always attempt to squeeze it ++ * content to the left... ++ */ ++ became_dirty: ++ ret = squeeze_right_twig_and_advance_coord(pos, right_lock.node); ++ if (ret <= 0) { ++ /* ++ * pos->coord is on internal item, go to leaf level, or ++ * we have an error which will be caught in squalloc() ++ */ ++ pos->state = POS_TO_LEAF; ++ goto out; ++ } ++ /* ++ * If right twig was squeezed completely we have to re-lock ++ * right twig. Now it is done through the top-level squalloc ++ * routine ++ */ ++ if (node_is_empty(right_lock.node)) ++ goto out; ++ /* ++ * ... and prep it if it is not yet prepped ++ */ ++ if (!znode_check_flushprepped(right_lock.node)) { ++ /* ++ * As usual, process parent before ... ++ */ ++ ret = check_parents_and_squalloc_upper_levels(pos, ++ pos->lock. ++ node, ++ right_lock.node); ++ if (ret) ++ goto out; ++ /* ++ * ... processing the child ++ */ ++ ret = lock_parent_and_allocate_znode(right_lock.node, ++ pos); ++ if (ret) ++ goto out; ++ } ++ } else { ++ /* ++ * right twig node is not dirty ++ */ ++ coord_init_first_unit(&at_right, right_lock.node); ++ /* ++ * check first child of next twig, should we continue there ? ++ */ ++ ret = get_leftmost_child_of_unit(&at_right, &child); ++ if (ret || child == NULL || jnode_check_flushprepped(child)) { ++ pos_stop(pos); ++ goto out; ++ } ++ /* ++ * check clean twig for possible relocation ++ */ ++ if (!znode_check_flushprepped(right_lock.node)) { ++ ret = check_parent_for_realloc(child, &at_right, pos); ++ if (ret) ++ goto out; ++ if (JF_ISSET(ZJNODE(right_lock.node), JNODE_DIRTY)) ++ goto became_dirty; ++ } ++ } ++ assert("zam-875", znode_check_flushprepped(right_lock.node)); ++ /* ++ * Update the preceder by a block number of just processed right ++ * twig node. The code above could miss the preceder updating ++ * because allocate_znode() could not be called for this node ++ */ ++ fbi_update_preceder(&pos->mfbi, *znode_get_block(right_lock.node)); ++ ++ coord_init_first_unit(&at_right, right_lock.node); ++ assert("zam-868", coord_is_existing_unit(&at_right)); ++ ++ pos->state = item_is_extent(&at_right) ? POS_ON_EPOINT : POS_TO_LEAF; ++ move_flush_pos(pos, &right_lock, &right_load, &at_right); ++ out: ++ done_load_count(&right_load); ++ done_lh(&right_lock); ++ ++ if (child) ++ jput(child); ++ return ret; ++} ++ ++/* Move the pos->lock to leaf node pointed by pos->coord, check should we ++ * continue there. */ ++static int handle_pos_to_leaf(flush_pos_t *pos) ++{ ++ int ret; ++ lock_handle child_lock; ++ load_count child_load; ++ jnode *child; ++ ++ assert("zam-846", pos->state == POS_TO_LEAF); ++ assert("zam-847", item_is_internal(&pos->coord)); ++ ++ init_lh(&child_lock); ++ init_load_count(&child_load); ++ ++ ret = get_leftmost_child_of_unit(&pos->coord, &child); ++ if (ret) ++ return ret; ++ if (child == NULL) { ++ pos_stop(pos); ++ return 0; ++ } ++ ++ if (jnode_check_flushprepped(child)) { ++ pos->state = POS_INVALID; ++ goto out; ++ } ++ ++ ret = ++ longterm_lock_znode(&child_lock, JZNODE(child), ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_LOPRI); ++ if (ret) ++ goto out; ++ ++ ret = incr_load_count_znode(&child_load, JZNODE(child)); ++ if (ret) ++ goto out; ++ ++ ret = allocate_znode(JZNODE(child), &pos->coord, pos); ++ if (ret) ++ goto out; ++ ++ /* move flush position to leaf level */ ++ pos->state = POS_ON_LEAF; ++ move_flush_pos(pos, &child_lock, &child_load, NULL); ++ ++ if (node_is_empty(JZNODE(child))) { ++ ret = delete_empty_node(JZNODE(child)); ++ pos->state = POS_INVALID; ++ } ++out: ++ done_load_count(&child_load); ++ done_lh(&child_lock); ++ jput(child); ++ ++ return ret; ++} ++ ++/* move pos from leaf to twig, and move lock from leaf to twig. */ ++/* Move pos->lock to upper (twig) level */ ++static int handle_pos_to_twig(flush_pos_t *pos) ++{ ++ int ret; ++ ++ lock_handle parent_lock; ++ load_count parent_load; ++ coord_t pcoord; ++ ++ assert("zam-852", pos->state == POS_TO_TWIG); ++ ++ init_lh(&parent_lock); ++ init_load_count(&parent_load); ++ ++ ret = reiser4_get_parent(&parent_lock, ++ pos->lock.node, ZNODE_WRITE_LOCK); ++ if (ret) ++ goto out; ++ ++ ret = incr_load_count_znode(&parent_load, parent_lock.node); ++ if (ret) ++ goto out; ++ ++ ret = find_child_ptr(parent_lock.node, pos->lock.node, &pcoord); ++ if (ret) ++ goto out; ++ ++ assert("zam-870", item_is_internal(&pcoord)); ++ coord_next_item(&pcoord); ++ ++ if (coord_is_after_rightmost(&pcoord)) ++ pos->state = POS_END_OF_TWIG; ++ else if (item_is_extent(&pcoord)) { ++ pos->state = POS_ON_EPOINT; ++ } else { ++ /* ++ * Here we understand that getting -E_NO_NEIGHBOR in ++ * handle_pos_on_leaf() was because of just a reaching ++ * edge of slum ++ */ ++ pos_stop(pos); ++ goto out; ++ } ++ move_flush_pos(pos, &parent_lock, &parent_load, &pcoord); ++out: ++ done_load_count(&parent_load); ++ done_lh(&parent_lock); ++ return ret; ++} ++ ++typedef int (*pos_state_handle_t) (flush_pos_t *); ++static pos_state_handle_t flush_pos_handlers[] = { ++ /* process formatted nodes on leaf level, keep lock on a leaf node */ ++ [POS_ON_LEAF] = handle_pos_on_leaf, ++ /* process unformatted nodes, keep lock on twig node, pos->coord points ++ * to extent currently being processed */ ++ [POS_ON_EPOINT] = handle_pos_on_twig, ++ /* move a lock from leaf node to its parent for further processing of ++ unformatted nodes */ ++ [POS_TO_TWIG] = handle_pos_to_twig, ++ /* move a lock from twig to leaf level when a processing of unformatted ++ * nodes finishes, pos->coord points to the leaf node we jump to */ ++ [POS_TO_LEAF] = handle_pos_to_leaf, ++ /* this is called after processing last extent in the twig node. ++ * This handler attempts to shift items from the right neighbor (on the ++ * twig level) and process them while shifting. Specifically, for extent ++ * items extent allocation in the "squeeze context" is performed */ ++ [POS_END_OF_TWIG] = handle_pos_end_of_twig, ++ /* process formatted nodes on internal level, keep lock on an internal ++ node */ ++ [POS_ON_INTERNAL] = handle_pos_on_internal ++}; ++ ++/* Advance flush position horizontally, prepare for flushing ((re)allocate, ++ * squeeze, encrypt) nodes and their ancestors in "parent-first" order */ ++static int squalloc(flush_pos_t *pos) ++{ ++ int ret = 0; ++ ++ /* maybe needs to be made a case statement with handle_pos_on_leaf as ++ * first case, for greater CPU efficiency? Measure and see.... -Hans */ ++ while (pos_valid(pos)) { ++ ret = flush_pos_handlers[pos->state] (pos); ++ if (ret < 0) ++ break; ++ ++ ret = rapid_flush(pos); ++ if (ret) ++ break; ++ } ++ ++ /* any positive value or -E_NO_NEIGHBOR are legal return codes for ++ handle_pos* routines, -E_NO_NEIGHBOR means that slum edge was ++ reached */ ++ if (ret > 0 || ret == -E_NO_NEIGHBOR) ++ ret = 0; ++ ++ return ret; ++} ++ ++static void update_ldkey(znode * node) ++{ ++ reiser4_key ldkey; ++ ++ assert_rw_write_locked(&(znode_get_tree(node)->dk_lock)); ++ if (node_is_empty(node)) ++ return; ++ ++ znode_set_ld_key(node, leftmost_key_in_node(node, &ldkey)); ++} ++ ++/* this is to be called after calling of shift node's method to shift data from ++ @right to @left. It sets left delimiting keys of @left and @right to keys of ++ first items of @left and @right correspondingly and sets right delimiting key ++ of @left to first key of @right */ ++static void update_znode_dkeys(znode * left, znode * right) ++{ ++ assert_rw_write_locked(&(znode_get_tree(right)->dk_lock)); ++ assert("vs-1629", (znode_is_write_locked(left) && ++ znode_is_write_locked(right))); ++ ++ /* we need to update left delimiting of left if it was empty before ++ shift */ ++ update_ldkey(left); ++ update_ldkey(right); ++ if (node_is_empty(right)) ++ znode_set_rd_key(left, znode_get_rd_key(right)); ++ else ++ znode_set_rd_key(left, znode_get_ld_key(right)); ++} ++ ++/* ++ * try to shift everything from @right to @left. If everything was shifted - ++ * @right is removed from the tree. Result is the number of bytes shifted ++ */ ++static int shift_everything_left(znode *right, znode *left, carry_level *todo) ++{ ++ coord_t from; ++ node_plugin *nplug; ++ carry_plugin_info info; ++ ++ coord_init_after_last_item(&from, right); ++ ++ nplug = node_plugin_by_node(right); ++ info.doing = NULL; ++ info.todo = todo; ++ return nplug->shift(&from, left, SHIFT_LEFT, ++ 1, /* delete @right if it becomes empty */ ++ 1, /* move coord @from to node @left if ++ everything will be shifted */ ++ &info); ++} ++ ++/* Shift as much as possible from @right to @left using the memcpy-optimized ++ shift_everything_left. @left and @right are formatted neighboring nodes on ++ leaf level. */ ++static int squeeze_right_non_twig(znode * left, znode * right) ++{ ++ int ret; ++ carry_pool *pool; ++ carry_level *todo; ++ reiser4_subvol *subv = znode_get_subvol(left); ++ ++ assert("edward-1729", subv != NULL); ++ assert("nikita-2246", znode_get_level(left) == znode_get_level(right)); ++ assert("edward-1730", znode_get_subvol(left) == znode_get_subvol(right)); ++ ++ if (!JF_ISSET(ZJNODE(left), JNODE_DIRTY) || ++ !JF_ISSET(ZJNODE(right), JNODE_DIRTY)) ++ return SQUEEZE_TARGET_FULL; ++ ++ pool = init_carry_pool(sizeof(*pool) + 3 * sizeof(*todo)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ todo = (carry_level *) (pool + 1); ++ init_carry_level(todo, pool); ++ ++ ret = shift_everything_left(right, left, todo); ++ if (ret > 0) { ++ /* something was shifted */ ++ reiser4_tree *tree; ++ __u64 grabbed; ++ ++ znode_make_dirty(left); ++ znode_make_dirty(right); ++ /* ++ * update delimiting keys of nodes which participated in ++ * shift. FIXME: it would be better to have this in shift ++ * node's operation. But it can not be done there. Nobody ++ * remembers why, though ++ */ ++ tree = znode_get_tree(left); ++ write_lock_dk(tree); ++ update_znode_dkeys(left, right); ++ write_unlock_dk(tree); ++ /* ++ * Carry is called to update delimiting key and, maybe, ++ * to remove empty node ++ */ ++ grabbed = ctx_subvol_grabbed(get_current_context(), subv->id); ++ ret = reiser4_grab_space_force(tree->height, BA_RESERVED, subv); ++ assert("nikita-3003", ret == 0); /* reserved space is ++ exhausted. Ask Hans */ ++ ret = reiser4_carry(todo, NULL/* previous level */); ++ grabbed2free_mark(grabbed, subv); ++ } else { ++ /* ++ * Shifting impossible, we return appropriate result code ++ */ ++ ret = node_is_empty(right) ? SQUEEZE_SOURCE_EMPTY : ++ SQUEEZE_TARGET_FULL; ++ } ++ done_carry_pool(pool); ++ return ret; ++} ++ ++#if REISER4_DEBUG ++static int sibling_link_is_ok(const znode *left, const znode *right) ++{ ++ int result; ++ ++ read_lock_tree(); ++ result = (left->right == right && left == right->left); ++ read_unlock_tree(); ++ return result; ++} ++#endif ++ ++/* Shift first unit of first item if it is an internal one. Return ++ SQUEEZE_TARGET_FULL if it fails to shift an item, otherwise return ++ SUBTREE_MOVED. */ ++static int shift_one_internal_unit(znode * left, znode * right) ++{ ++ int ret; ++ carry_pool *pool; ++ carry_level *todo; ++ coord_t *coord; ++ carry_plugin_info *info; ++ int size, moved; ++ ++ assert("nikita-2247", znode_get_level(left) == znode_get_level(right)); ++ assert("nikita-2435", znode_is_write_locked(left)); ++ assert("nikita-2436", znode_is_write_locked(right)); ++ assert("nikita-2434", sibling_link_is_ok(left, right)); ++ ++ pool = init_carry_pool(sizeof(*pool) + 3 * sizeof(*todo) + ++ sizeof(*coord) + sizeof(*info) ++#if REISER4_DEBUG ++ + sizeof(*coord) + 2 * sizeof(reiser4_key) ++#endif ++ ); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ todo = (carry_level *) (pool + 1); ++ init_carry_level(todo, pool); ++ ++ coord = (coord_t *) (todo + 3); ++ coord_init_first_unit(coord, right); ++ info = (carry_plugin_info *) (coord + 1); ++ ++#if REISER4_DEBUG ++ if (!node_is_empty(left)) { ++ coord_t *last; ++ reiser4_key *right_key; ++ reiser4_key *left_key; ++ ++ last = (coord_t *) (info + 1); ++ right_key = (reiser4_key *) (last + 1); ++ left_key = right_key + 1; ++ coord_init_last_unit(last, left); ++ ++ assert("nikita-2463", ++ keyle(item_key_by_coord(last, left_key), ++ item_key_by_coord(coord, right_key))); ++ } ++#endif ++ ++ assert("jmacd-2007", item_is_internal(coord)); ++ ++ size = item_length_by_coord(coord); ++ info->todo = todo; ++ info->doing = NULL; ++ ++ ret = node_plugin_by_node(left)->shift(coord, left, SHIFT_LEFT, ++ 1 ++ /* delete @right if it becomes ++ empty */ ++ , ++ 0 ++ /* do not move coord @coord to ++ node @left */ ++ , ++ info); ++ ++ /* If shift returns positive, then we shifted the item. */ ++ assert("vs-423", ret <= 0 || size == ret); ++ moved = (ret > 0); ++ ++ if (moved) { ++ /* something was moved */ ++ reiser4_tree *tree; ++ int grabbed; ++ reiser4_subvol *subv = znode_get_subvol(left); ++ ++ znode_make_dirty(left); ++ znode_make_dirty(right); ++ tree = znode_get_tree(left); ++ write_lock_dk(tree); ++ update_znode_dkeys(left, right); ++ write_unlock_dk(tree); ++ /* ++ * reserve space for delimiting keys after shifting ++ */ ++ grabbed = ctx_subvol_grabbed(get_current_context(), subv->id); ++ ret = reiser4_grab_space_force(tree->height, BA_RESERVED, subv); ++ assert("nikita-3003", ret == 0); /* reserved space is ++ exhausted. Ask Hans. */ ++ ret = reiser4_carry(todo, NULL/* previous level */); ++ grabbed2free_mark(grabbed, subv); ++ } ++ done_carry_pool(pool); ++ ++ if (ret != 0) { ++ /* Shift or carry operation failed. */ ++ assert("jmacd-7325", ret < 0); ++ return ret; ++ } ++ return moved ? SUBTREE_MOVED : SQUEEZE_TARGET_FULL; ++} ++ ++static int allocate_znode(znode *node, ++ const coord_t *parent_coord, flush_pos_t *pos) ++{ ++ txmod_plugin *plug; ++ ++ plug = txmod_plugin_by_id(get_meta_subvol()->txmod); ++ /* ++ * perform znode allocation with znode pinned in memory to avoid races ++ * with asynchronous emergency flush (which plays with ++ * JNODE_FLUSH_RESERVED bit). ++ */ ++ return WITH_DATA(node, plug->forward_alloc_formatted(node, ++ parent_coord, ++ pos)); ++} ++ ++ ++/* JNODE INTERFACE */ ++ ++/* Lock a node (if formatted) and then get its parent locked, set the child's ++ coordinate in the parent. If the child is the root node, the above_root ++ znode is returned but the coord is not set. This function may cause atom ++ fusion, but it is only used for read locks (at this point) and therefore ++ fusion only occurs when the parent is already dirty. */ ++/* Hans adds this note: remember to ask how expensive this operation is vs. ++ storing parent pointer in jnodes. */ ++static int ++jnode_lock_parent_coord(jnode * node, ++ coord_t *coord, ++ lock_handle * parent_lh, ++ load_count * parent_zh, ++ znode_lock_mode parent_mode, int try) ++{ ++ int ret; ++ ++ assert("edward-53", jnode_is_unformatted(node) || jnode_is_znode(node)); ++ assert("edward-54", jnode_is_unformatted(node) ++ || znode_is_any_locked(JZNODE(node))); ++ ++ if (!jnode_is_znode(node)) { ++ reiser4_key key; ++ tree_level stop_level = TWIG_LEVEL; ++ lookup_bias bias = FIND_EXACT; ++ ++ assert("edward-168", !(jnode_get_type(node) == JNODE_BITMAP)); ++ assert("edward-2163", !jnode_is_volinfo_head(node)); ++ ++ /* The case when node is not znode, but can have parent coord ++ (unformatted node, node which represents cluster page, ++ etc..). Generate a key for the appropriate entry, search ++ in the tree using coord_by_key, which handles locking for ++ us. */ ++ ++ /* ++ * nothing is locked at this moment, so, nothing prevents ++ * concurrent truncate from removing jnode from inode. To ++ * prevent this spin-lock jnode. jnode can be truncated just ++ * after call to the jnode_build_key(), but this is ok, ++ * because coord_by_key() will just fail to find appropriate ++ * extent. ++ */ ++ spin_lock_jnode(node); ++ if (!JF_ISSET(node, JNODE_HEARD_BANSHEE)) { ++ jnode_build_key(node, &key); ++ ret = 0; ++ } else ++ ret = RETERR(-ENOENT); ++ spin_unlock_jnode(node); ++ ++ if (ret != 0) ++ return ret; ++ ++ if (jnode_is_cluster_page(node)) ++ stop_level = LEAF_LEVEL; ++ ++ assert("jmacd-1812", coord != NULL); ++ ++ ret = coord_by_key(meta_subvol_tree(), &key, coord, parent_lh, ++ parent_mode, bias, stop_level, stop_level, ++ CBK_UNIQUE, NULL/*ra_info */); ++ switch (ret) { ++ case CBK_COORD_NOTFOUND: ++ assert("edward-1038", ++ ergo(jnode_is_cluster_page(node), ++ JF_ISSET(node, JNODE_HEARD_BANSHEE))); ++ if (!JF_ISSET(node, JNODE_HEARD_BANSHEE)) { ++ assert("edward-2164", 0); ++ warning("nikita-3177", "Parent not found"); ++ } ++ return ret; ++ case CBK_COORD_FOUND: ++ if (coord->between != AT_UNIT) { ++ /* FIXME: comment needed */ ++ done_lh(parent_lh); ++ if (!JF_ISSET(node, JNODE_HEARD_BANSHEE)) { ++ assert("edward-2366", 0); ++ warning("nikita-3178", ++ "Found but not happy: %i", ++ coord->between); ++ } ++ return RETERR(-ENOENT); ++ } ++ ret = incr_load_count_znode(parent_zh, parent_lh->node); ++ if (ret != 0) ++ return ret; ++ /* if (jnode_is_cluster_page(node)) { ++ races with write() are possible ++ check_child_cluster (parent_lh->node); ++ } ++ */ ++ break; ++ default: ++ return ret; ++ } ++ ++ } else { ++ int flags; ++ znode *z; ++ ++ z = JZNODE(node); ++ /* Formatted node case: */ ++ assert("jmacd-2061", !znode_is_root(z)); ++ ++ flags = GN_ALLOW_NOT_CONNECTED; ++ if (try) ++ flags |= GN_TRY_LOCK; ++ ++ ret = ++ reiser4_get_parent_flags(parent_lh, z, parent_mode, flags); ++ if (ret != 0) ++ /* -E_REPEAT is ok here, it is handled by the caller. */ ++ return ret; ++ ++ /* Make the child's position "hint" up-to-date. (Unless above ++ root, which caller must check.) */ ++ if (coord != NULL) { ++ ++ ret = incr_load_count_znode(parent_zh, parent_lh->node); ++ if (ret != 0) { ++ warning("jmacd-976812386", ++ "incr_load_count_znode failed: %d", ++ ret); ++ return ret; ++ } ++ ++ ret = find_child_ptr(parent_lh->node, z, coord); ++ if (ret != 0) { ++ warning("jmacd-976812", ++ "find_child_ptr failed: %d", ret); ++ return ret; ++ } ++ } ++ } ++ ++ return 0; ++} ++ ++/* Get the (locked) next neighbor of a znode which is dirty and a member of the ++ same atom. If there is no next neighbor or the neighbor is not in memory or ++ if there is a neighbor but it is not dirty or not in the same atom, ++ -E_NO_NEIGHBOR is returned. In some cases the slum may include nodes which ++ are not dirty, if so @check_dirty should be 0 */ ++static int neighbor_in_slum(znode * node, /* starting point */ ++ lock_handle * lock, /* lock on starting point */ ++ sideof side, /* left or right direction we ++ seek the next node in */ ++ znode_lock_mode mode, /* kind of lock we want */ ++ int check_dirty, /* true if the neighbor should ++ be dirty */ ++ int use_upper_levels /* get neighbor by going though ++ upper levels */) ++{ ++ int ret; ++ int flags; ++ ++ assert("jmacd-6334", znode_is_connected(node)); ++ ++ flags = GN_SAME_ATOM | (side == LEFT_SIDE ? GN_GO_LEFT : 0); ++ if (use_upper_levels) ++ flags |= GN_CAN_USE_UPPER_LEVELS; ++ ++ ret = reiser4_get_neighbor(lock, node, mode, flags); ++ if (ret) { ++ /* May return -ENOENT or -E_NO_NEIGHBOR. */ ++ /* FIXME(C): check EINVAL, E_DEADLOCK */ ++ if (ret == -ENOENT) ++ ret = RETERR(-E_NO_NEIGHBOR); ++ return ret; ++ } ++ if (!check_dirty) ++ return 0; ++ /* Check dirty bit of locked znode, no races here */ ++ if (JF_ISSET(ZJNODE(lock->node), JNODE_DIRTY)) ++ return 0; ++ ++ done_lh(lock); ++ return RETERR(-E_NO_NEIGHBOR); ++} ++ ++/* Return true if two znodes have the same parent. This is called with both ++ nodes write-locked (for squeezing) so no tree lock is needed. */ ++static int znode_same_parents(znode * a, znode * b) ++{ ++ int result; ++ ++ assert("jmacd-7011", znode_is_write_locked(a)); ++ assert("jmacd-7012", znode_is_write_locked(b)); ++ ++ /* We lock the whole tree for this check.... I really don't like whole ++ * tree locks... -Hans */ ++ read_lock_tree(); ++ result = (znode_parent(a) == znode_parent(b)); ++ read_unlock_tree(); ++ return result; ++} ++ ++/* FLUSH SCAN */ ++ ++/* Initialize the flush_scan data structure. */ ++static void scan_init(flush_scan * scan, flush_pos_t *pos) ++{ ++ memset(scan, 0, sizeof(*scan)); ++ init_lh(&scan->node_lock); ++ init_lh(&scan->parent_lock); ++ init_load_count(&scan->parent_load); ++ init_load_count(&scan->node_load); ++ coord_init_invalid(&scan->parent_coord, NULL); ++ scan->bricks_info = &pos->bricks_info; ++ scan->mfbi = &pos->mfbi; ++} ++ ++/* Release any resources held by the flush scan, e.g. release locks, ++ free memory, etc. */ ++static void scan_done(flush_scan * scan) ++{ ++ done_load_count(&scan->node_load); ++ if (scan->node != NULL) { ++ jput(scan->node); ++ scan->node = NULL; ++ } ++ done_load_count(&scan->parent_load); ++ done_lh(&scan->parent_lock); ++ done_lh(&scan->node_lock); ++} ++ ++/** ++ * Returns true if flush scanning has to be finished ++ */ ++int reiser4_scan_finished(flush_scan *scan) ++{ ++ return scan->stop || (scan->direction == RIGHT_SIDE && ++ scan->count >= scan->max_count); ++} ++ ++/** ++ * Return true if the scan should continue to the @tonode. ++ * True if the node meets the same_slum_check condition. ++ * If not, deref the "left" node and stop the scan ++ */ ++int reiser4_scan_goto(flush_scan *scan, jnode *tonode) ++{ ++ int go = same_slum_check(scan->node, tonode, 1, 0); ++ ++ if (!go) { ++ scan->stop = 1; ++ jput(tonode); ++ } ++ return go; ++} ++ ++/** ++ * Move scan position to @node: ++ * set scan->node to @node, refcount it, deref node at previous position, ++ * optionally copy the parent coordinate, increment count by the @add_count, ++ * which indicates number of processed nodes ++ */ ++int move_scan_pos(flush_scan *scan, jnode *node, ++ unsigned add_count, const coord_t *parent) ++{ ++ struct flush_brick_info *fbi = NULL; ++ /* ++ * Release the old references, take the new reference ++ */ ++ done_load_count(&scan->node_load); ++ ++ if (scan->node != NULL) ++ jput(scan->node); ++ ++ fbi = grab_fbi(scan->bricks_info, scan->mfbi, node->subvol->id); ++ if (fbi == NULL) ++ return RETERR(-ENOMEM); ++ ++ scan->node = node; ++ ++ fbi->count += add_count; ++ scan->count += add_count; ++ ++ /* This next stmt is somewhat inefficient. The reiser4_scan_extent() ++ code could delay this update step until it finishes and update the ++ parent_coord only once. It did that before, but there was a bug and ++ this was the easiest way to make it correct ++ */ ++ if (parent != NULL) ++ coord_dup(&scan->parent_coord, parent); ++ /* ++ * Failure may happen at the incr_load_count call, but the caller can ++ * assume the reference is safely taken ++ */ ++ return incr_load_count_jnode(&scan->node_load, node); ++} ++ ++/* Return true if scanning in the leftward direction. */ ++int reiser4_scanning_left(flush_scan * scan) ++{ ++ return scan->direction == LEFT_SIDE; ++} ++ ++/* Performs leftward scanning starting from either kind of node. Counts the ++ starting node. The right-scan object is passed in for the left-scan in order ++ to copy the parent of an unformatted starting position. This way we avoid ++ searching for the unformatted node's parent when scanning in each direction. ++ If we search for the parent once it is set in both scan objects. The limit ++ parameter tells flush-scan when to stop. ++ ++ Rapid scanning is used only during scan_left, where we are interested in ++ finding the 'leftpoint' where we begin flushing. We are interested in ++ stopping at the left child of a twig that does not have a dirty left ++ neighbour. THIS IS A SPECIAL CASE. The problem is finding a way to flush only ++ those nodes without unallocated children, and it is difficult to solve in the ++ bottom-up flushing algorithm we are currently using. The problem can be ++ solved by scanning left at every level as we go upward, but this would ++ basically bring us back to using a top-down allocation strategy, which we ++ already tried (see BK history from May 2002), and has a different set of ++ problems. The top-down strategy makes avoiding unallocated children easier, ++ but makes it difficult to propertly flush dirty children with clean parents ++ that would otherwise stop the top-down flush, only later to dirty the parent ++ once the children are flushed. So we solve the problem in the bottom-up ++ algorithm with a special case for twigs and leaves only. ++ ++ The first step in solving the problem is this rapid leftward scan. After we ++ determine that there are at least enough nodes counted to qualify for ++ FLUSH_RELOCATE_THRESHOLD we are no longer interested in the exact count, we ++ are only interested in finding the best place to start the flush. ++ ++ We could choose one of two possibilities: ++ ++ 1. Stop at the leftmost child (of a twig) that does not have a dirty left ++ neighbor. This requires checking one leaf per rapid-scan twig ++ ++ 2. Stop at the leftmost child (of a twig) where there are no dirty children ++ of the twig to the left. This requires checking possibly all of the in-memory ++ children of each twig during the rapid scan. ++ ++ For now we implement the first policy. ++*/ ++static int scan_left(flush_scan *scan, flush_scan *right, jnode *node) ++{ ++ int ret = 0; ++ ++ scan->direction = LEFT_SIDE; ++ ++ ret = move_scan_pos(scan, jref(node), 1, NULL); ++ if (ret != 0) ++ return ret; ++ ++ ret = do_scan(scan, right); ++ if (ret != 0) ++ return ret; ++ ++ /* Before rapid scanning, we need a lock on scan->node so that we can ++ get its parent, only if formatted. */ ++ if (jnode_is_znode(scan->node)) { ++ ret = longterm_lock_znode(&scan->node_lock, JZNODE(scan->node), ++ ZNODE_WRITE_LOCK, ZNODE_LOCK_LOPRI); ++ } ++ ++ /* Rapid_scan would go here (with limit set to FLUSH_RELOCATE_THRESHOLD) ++ */ ++ return ret; ++} ++ ++/* Performs rightward scanning... Does not count the starting node. The limit ++ parameter is described in scan_left. If the starting node is unformatted then ++ the parent_coord was already set during scan_left. The rapid_after parameter ++ is not used during right-scanning. ++ ++ scan_right is only called if the scan_left operation does not count at least ++ FLUSH_RELOCATE_THRESHOLD nodes for flushing. Otherwise, the limit parameter ++ is set to the difference between scan-left's count and ++ FLUSH_RELOCATE_THRESHOLD, meaning scan-right counts as high as ++ FLUSH_RELOCATE_THRESHOLD and then stops ++*/ ++static int scan_right(flush_scan *scan, jnode *node) ++{ ++ int ret; ++ ++ scan->direction = RIGHT_SIDE; ++ ++ ret = move_scan_pos(scan, jref(node), 0, NULL); ++ if (ret != 0) ++ return ret; ++ ++ return do_scan(scan, NULL); ++} ++ ++/** ++ * Perform scan in a given direction ++ */ ++static int do_scan(flush_scan *scan, flush_scan *other) ++{ ++ int ret; ++ ++ assert("nikita-2376", scan->node != NULL); ++ assert("edward-54", ++ jnode_is_unformatted(scan->node) || jnode_is_znode(scan->node)); ++ /* ++ * Special case for starting at an unformatted node. Optimization: we ++ * only want to search for the parent (which requires a tree traversal) ++ * once. Obviously, we shouldn't have to call it once for the left scan ++ * and once for the right scan. For this reason, if we search for the ++ * parent during scan-left we then duplicate the coord/lock/load into ++ * the scan-right object ++ */ ++ if (jnode_is_unformatted(scan->node)) { ++ ret = lock_parent_and_scan_upper_level(scan, other); ++ if (ret != 0) ++ return ret; ++ } ++ /* ++ * scan formatted nodes starting at current position ++ */ ++ while (!reiser4_scan_finished(scan)) { ++ ++ ret = scan_formatted(scan); ++ if (ret != 0) ++ return ret; ++ } ++ return 0; ++} ++ ++/* ++ * Set up parent coord (if needed), jump one level up ++ * and scan formatted nodes on the upper level ++ */ ++static int lock_parent_and_scan_upper_level(flush_scan *scan, flush_scan *other) ++{ ++ int ret = 0; ++ int try = 0; ++ ++ if (!coord_is_invalid(&scan->parent_coord)) ++ /* ++ * parent has been set already by ++ * previous scan session (scan_left) ++ */ ++ goto scan; ++ /* ++ * set parent coord ++ */ ++ if (!jnode_is_unformatted(scan->node)) { ++ /* formatted position */ ++ ++ lock_handle lock; ++ assert("edward-301", jnode_is_znode(scan->node)); ++ init_lh(&lock); ++ ++ /* ++ * when flush starts from unformatted node, first thing it ++ * does is tree traversal to find formatted parent of starting ++ * node. This parent is then kept lock across scans to the ++ * left and to the right. This means that during scan to the ++ * left we cannot take left-ward lock, because this is ++ * dead-lock prone. So, if we are scanning to the left and ++ * there is already lock held by this thread, ++ * jnode_lock_parent_coord() should use try-lock. ++ */ ++ try = reiser4_scanning_left(scan) ++ && !lock_stack_isclean(get_current_lock_stack()); ++ /* Need the node locked to get the parent lock, We have to ++ take write lock since there is at least one call path ++ where this znode is already write-locked by us. */ ++ ret = ++ longterm_lock_znode(&lock, JZNODE(scan->node), ++ ZNODE_WRITE_LOCK, ++ reiser4_scanning_left(scan) ? ++ ZNODE_LOCK_LOPRI : ++ ZNODE_LOCK_HIPRI); ++ if (ret != 0) ++ /* EINVAL or E_DEADLOCK here mean... try again! At this ++ point we've scanned too far and can't back out, just ++ start over. */ ++ return ret; ++ ++ ret = jnode_lock_parent_coord(scan->node, ++ &scan->parent_coord, ++ &scan->parent_lock, ++ &scan->parent_load, ++ ZNODE_WRITE_LOCK, try); ++ ++ /* FIXME(C): check EINVAL, E_DEADLOCK */ ++ done_lh(&lock); ++ if (ret == -E_REPEAT) { ++ scan->stop = 1; ++ return 0; ++ } ++ if (ret) ++ return ret; ++ ++ } else { ++ /* unformatted position */ ++ ++ ret = ++ jnode_lock_parent_coord(scan->node, &scan->parent_coord, ++ &scan->parent_lock, ++ &scan->parent_load, ++ ZNODE_WRITE_LOCK, try); ++ ++ if (IS_CBKERR(ret)) ++ return ret; ++ ++ if (ret == CBK_COORD_NOTFOUND) ++ /* FIXME(C): check EINVAL, E_DEADLOCK */ ++ return ret; ++ ++ /* parent was found */ ++ assert("jmacd-8661", other != NULL); ++ /* Duplicate the reference into the other flush_scan. */ ++ coord_dup(&other->parent_coord, &scan->parent_coord); ++ copy_lh(&other->parent_lock, &scan->parent_lock); ++ copy_load_count(&other->parent_load, &scan->parent_load); ++ } ++scan: ++ /* ++ * proceed with scanning formatted nodes on the upper level ++ */ ++ return scan_by_coord(scan); ++} ++ ++/* Performs left- or rightward scanning starting from a formatted node. Follow ++ left pointers under tree lock as long as: ++ ++ - node->left/right is non-NULL ++ - node->left/right is connected, dirty ++ - node->left/right belongs to the same atom ++ - scan has not reached maximum count ++*/ ++static int scan_formatted(flush_scan * scan) ++{ ++ int ret; ++ znode *neighbor = NULL; ++ ++ assert("jmacd-1401", !reiser4_scan_finished(scan)); ++ ++ do { ++ znode *node = JZNODE(scan->node); ++ /* ++ * node should be connected, but if not stop the scan ++ */ ++ if (!znode_is_connected(node)) { ++ scan->stop = 1; ++ break; ++ } ++ /* Lock the tree, check-for and reference the next sibling. */ ++ read_lock_tree(); ++ ++ /* It may be that a node is inserted or removed between a node ++ and its left sibling while the tree lock is released, but the ++ flush-scan count does not need to be precise. Thus, we ++ release the tree lock as soon as we get the neighboring node. ++ */ ++ neighbor = ++ reiser4_scanning_left(scan) ? node->left : node->right; ++ if (neighbor != NULL) ++ zref(neighbor); ++ ++ read_unlock_tree(); ++ /* ++ * If neighbor is NULL at the leaf level, need to check for an ++ * unformatted sibling using the parent--break in any case ++ */ ++ if (neighbor == NULL) ++ break; ++ /* ++ * Check the condition for going left, break if it is not met. ++ * This also releases (jputs) the neighbor if false ++ */ ++ if (!reiser4_scan_goto(scan, ZJNODE(neighbor))) ++ break; ++ /* ++ * Advance the flush_scan state to the left, repeat ++ */ ++ ret = move_scan_pos(scan, ZJNODE(neighbor), 1, NULL); ++ if (ret != 0) ++ return ret; ++ ++ } while (!reiser4_scan_finished(scan)); ++ /* ++ * If neighbor is NULL then we reached the end of a formatted region, ++ * or else the sibling is out of memory, now check for an extent to the ++ * left (as long as LEAF_LEVEL) ++ */ ++ if (neighbor != NULL || ++ jnode_get_level(scan->node) != LEAF_LEVEL || ++ reiser4_scan_finished(scan)) { ++ ++ scan->stop = 1; ++ return 0; ++ } ++ /* ++ * otherwise, calls scan_by_coord for the right(left)most item of the ++ * left(right) neighbor on the parent level, then possibly continue ++ */ ++ coord_init_invalid(&scan->parent_coord, NULL); ++ return lock_parent_and_scan_upper_level(scan, NULL); ++} ++ ++/** ++ * This scans adjacent items of the same type and calls scan flush plugin for ++ * each one. Performs left(right)ward scanning starting from a (possibly) ++ * unformatted node. If we start from unformatted node, then we continue only if ++ * the next neighbor is also unformatted. When called from scan_formatted, we ++ * skip first iteration (to make sure that right(left)most item of the ++ * left(right) neighbor on the parent level is of the same type and set ++ * appropriate coord) ++ */ ++static int scan_by_coord(flush_scan * scan) ++{ ++ int ret = 0; ++ int scan_this_coord; ++ lock_handle next_lock; ++ load_count next_load; ++ coord_t next_coord; ++ jnode *child; ++ item_plugin *iplug; ++ ++ init_lh(&next_lock); ++ init_load_count(&next_load); ++ scan_this_coord = (jnode_is_unformatted(scan->node) ? 1 : 0); ++ ++ /* set initial item id */ ++ iplug = item_plugin_by_coord(&scan->parent_coord); ++ ++ for (; !reiser4_scan_finished(scan); scan_this_coord = 1) { ++ if (scan_this_coord) { ++ /* ++ * Here we expect that unit is scannable. ++ * It would not be so due to race with extent->tail ++ * conversion ++ */ ++ if (iplug->f.scan == NULL) { ++ scan->stop = 1; ++ ret = -E_REPEAT; ++ /* skip the check at the end. */ ++ goto race; ++ } ++ ret = iplug->f.scan(scan); ++ if (ret != 0) ++ goto exit; ++ ++ if (reiser4_scan_finished(scan)) { ++ checkchild(scan); ++ break; ++ } ++ } else { ++ /* ++ * the same race against truncate as above is possible ++ * here, it seems. ++ * ++ * NOTE-JMACD: In this case, apply the same end-of-node ++ * logic but don't scan the first coordinate ++ */ ++ assert("jmacd-1231", ++ item_is_internal(&scan->parent_coord)); ++ } ++ if (iplug->f.utmost_child == NULL || ++ znode_get_level(scan->parent_coord.node) != TWIG_LEVEL) { ++ /* ++ * stop this coord and continue on parrent level ++ * (see the function do_scan) ++ */ ++ ret = move_scan_pos(scan, ++ ZJNODE(zref(scan->parent_coord.node)), ++ 1, NULL); ++ if (ret != 0) ++ goto exit; ++ break; ++ } ++ /* ++ * Either way, the invariant is that scan->parent_coord is set ++ * to the parent of scan->node. Now get the next unit ++ */ ++ coord_dup(&next_coord, &scan->parent_coord); ++ coord_sideof_unit(&next_coord, scan->direction); ++ /* ++ * If off-the-end of the twig, try the next twig ++ */ ++ if (coord_is_after_sideof_unit(&next_coord, scan->direction)) { ++ /* ++ * We take the write lock because we may start ++ * flushing from this coordinate ++ */ ++ ret = neighbor_in_slum(next_coord.node, ++ &next_lock, ++ scan->direction, ++ ZNODE_WRITE_LOCK, ++ 1 /* check dirty */, ++ 0 /* don't go though upper ++ levels */); ++ if (ret == -E_NO_NEIGHBOR) { ++ scan->stop = 1; ++ ret = 0; ++ break; ++ } ++ if (ret != 0) ++ goto exit; ++ ret = incr_load_count_znode(&next_load, next_lock.node); ++ if (ret != 0) ++ goto exit; ++ coord_init_sideof_unit(&next_coord, next_lock.node, ++ sideof_reverse(scan->direction)); ++ } ++ iplug = item_plugin_by_coord(&next_coord); ++ /* ++ * Get the next child ++ */ ++ ret = iplug->f.utmost_child(&next_coord, ++ sideof_reverse(scan->direction), ++ &child); ++ if (ret != 0) ++ goto exit; ++ /* ++ * If the next child is not in memory, or, item_utmost_child ++ * failed (due to race with unlink, most probably), stop here ++ */ ++ if (child == NULL || IS_ERR(child)) { ++ scan->stop = 1; ++ checkchild(scan); ++ break; ++ } ++ assert("nikita-2374", ++ jnode_is_unformatted(child) || jnode_is_znode(child)); ++ /* ++ * See if it is dirty, part of the same atom ++ */ ++ if (!reiser4_scan_goto(scan, child)) { ++ checkchild(scan); ++ break; ++ } ++ /* ++ * If so, make this child current ++ */ ++ ret = move_scan_pos(scan, child, 1, &next_coord); ++ if (ret != 0) ++ goto exit; ++ /* ++ * Now continue. ++ * If formatted we release the parent lock and return, ++ * then proceed ++ */ ++ if (jnode_is_znode(child)) ++ break; ++ /* ++ * Otherwise, repeat the above loop with next_coord ++ */ ++ if (next_load.node != NULL) { ++ done_lh(&scan->parent_lock); ++ move_lh(&scan->parent_lock, &next_lock); ++ move_load_count(&scan->parent_load, &next_load); ++ } ++ } ++ assert("jmacd-6233", ++ reiser4_scan_finished(scan) || jnode_is_znode(scan->node)); ++ exit: ++ checkchild(scan); ++ race: ++ if (jnode_is_znode(scan->node)) { ++ done_lh(&scan->parent_lock); ++ done_load_count(&scan->parent_load); ++ } ++ done_load_count(&next_load); ++ done_lh(&next_lock); ++ return ret; ++} ++ ++/* FLUSH POS HELPERS */ ++ ++/* Initialize the fields of a flush_position. */ ++static void pos_init(flush_pos_t *pos) ++{ ++ memset(pos, 0, sizeof *pos); ++ ++ pos->state = POS_INVALID; ++ coord_init_invalid(&pos->coord, NULL); ++ init_lh(&pos->lock); ++ init_load_count(&pos->load); ++ /* ++ * init set of per-brick infos and populate it ++ * with pre-allocated item for meta-data brick ++ */ ++ pos->bricks_info = RB_ROOT; ++ /* ++ * populate the rb-tree with pre-allocated info ++ * for meta-data brick ++ */ ++ init_fbi(&pos->mfbi, METADATA_SUBVOL_ID); ++ insert_fbi(&pos->bricks_info, &pos->mfbi); ++} ++ ++/* The flush loop inside squalloc periodically checks pos_valid to determine ++ when "enough flushing" has been performed. This will return true until one ++ of the following conditions is met: ++ ++ 1. the number of flush-queued nodes has reached the kernel-supplied ++ "int *nr_to_flush" parameter, meaning we have flushed as many blocks as the ++ kernel requested. When flushing to commit, this parameter is NULL. ++ ++ 2. pos_stop() is called because squalloc discovers that the "next" node in ++ the flush order is either non-existant, not dirty, or not in the same atom. ++*/ ++ ++static int pos_valid(flush_pos_t *pos) ++{ ++ return pos->state != POS_INVALID; ++} ++ ++/* Release any resources of a flush_position. Called when jnode_flush ++ finishes. */ ++static void pos_done(flush_pos_t *pos) ++{ ++ pos_stop(pos); ++ if (convert_data(pos)) ++ free_convert_data(pos); ++ done_all_fbi(&pos->bricks_info, &pos->mfbi); ++} ++ ++/* Reset the point and parent. Called during flush subroutines to terminate the ++ squalloc loop. */ ++static int pos_stop(flush_pos_t *pos) ++{ ++ pos->state = POS_INVALID; ++ done_lh(&pos->lock); ++ done_load_count(&pos->load); ++ coord_init_invalid(&pos->coord, NULL); ++ ++ if (pos->child) { ++ jput(pos->child); ++ pos->child = NULL; ++ } ++ ++ return 0; ++} ++ ++flush_queue_t *reiser4_pos_fq(flush_pos_t *pos) ++{ ++ return pos->fq; ++} ++ ++/********************** flush brick info ops ************************/ ++ ++int flush_init_static(void) ++{ ++ assert("edward-2397", _fbi_slab == NULL); ++ ++ _fbi_slab = kmem_cache_create("flush_brick_info", ++ sizeof(flush_brick_info), 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ return _fbi_slab == NULL ? RETERR(-ENOMEM) : 0; ++} ++ ++/** ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void done_flush_static(void) ++{ ++ destroy_reiser4_cache(&_fbi_slab); ++} ++ ++struct flush_brick_info *alloc_fbi(void) ++{ ++ return kmem_cache_alloc(_fbi_slab, reiser4_ctx_gfp_mask_get()); ++} ++ ++static void init_fbi(flush_brick_info *fbi, u32 subv_id) ++{ ++ memset(fbi, 0, sizeof(*fbi)); ++ RB_CLEAR_NODE(&fbi->node); ++ fbi->brick_id = subv_id; ++} ++ ++static void free_fbi(struct flush_brick_info *fbi) ++{ ++ kmem_cache_free(_fbi_slab, fbi); ++} ++ ++static struct flush_brick_info *find_fbi(const struct rb_root *root, ++ u32 brick_id) ++{ ++ struct rb_node *node = root->rb_node; ++ ++ while (node) { ++ struct flush_brick_info *fbi = ++ rb_entry(node, struct flush_brick_info, node); ++ ++ if (fbi->brick_id > brick_id) ++ node = node->rb_left; ++ else if (fbi->brick_id < brick_id) ++ node = node->rb_right; ++ else ++ return fbi; ++ } ++ return NULL; ++} ++ ++/** ++ * Try to insert item @this to rb-tree @root ++ * Return NULL on success. Otherwise, return node of existing item ++ */ ++static void insert_fbi(struct rb_root *root, struct flush_brick_info *this) ++{ ++ struct rb_node *parent = NULL; ++ struct rb_node **pos = &(root->rb_node); ++ ++ while (*pos) { ++ struct flush_brick_info *fbi; ++ ++ fbi = rb_entry(*pos, struct flush_brick_info, node); ++ parent = *pos; ++ ++ if (this->brick_id < fbi->brick_id) ++ pos = &((*pos)->rb_left); ++ else if (this->brick_id > fbi->brick_id) ++ pos = &((*pos)->rb_right); ++ else ++ BUG_ON(1); ++ } ++ rb_link_node(&this->node, parent, pos); ++ rb_insert_color(&this->node, root); ++} ++ ++/** ++ * On sucess return pointer to the flush brick info ++ * (existing or newly allocated). ++ * @mfbi: pre-allocated info for meta-data brick ++ */ ++static flush_brick_info *grab_fbi(struct rb_root *infos, ++ struct flush_brick_info *mfbi, u32 brick_id) ++{ ++ struct flush_brick_info *fbi; ++ ++ if (brick_id == METADATA_SUBVOL_ID) ++ /* ++ * It is known to be preallocated ++ */ ++ return mfbi; ++ fbi = find_fbi(infos, brick_id); ++ if (fbi) ++ return fbi; ++ /* ++ * Insert a new item to the rb-tree ++ */ ++ fbi = alloc_fbi(); ++ if (fbi) { ++ init_fbi(fbi, brick_id); ++ insert_fbi(infos, fbi); ++ } ++ return fbi; ++} ++ ++static void done_all_fbi(struct rb_root *infos, struct flush_brick_info *mfbi) ++{ ++ /* ++ * remove pre-allocated info ++ */ ++ rb_erase(&mfbi->node, infos); ++ RB_CLEAR_NODE(&mfbi->node); ++ ++ while (!RB_EMPTY_ROOT(infos)) { ++ struct rb_node *node; ++ struct flush_brick_info *fbi; ++ ++ node = rb_first(infos); ++ fbi = rb_entry(node, struct flush_brick_info, node); ++ ++ rb_erase(&fbi->node, infos); ++ RB_CLEAR_NODE(&fbi->node); ++ free_fbi(fbi); ++ } ++} ++ ++reiser4_blocknr_hint *flush_pos_get_hint(flush_pos_t *pos, u32 subv_id, ++ reiser4_blocknr_hint *ehint) ++{ ++ flush_brick_info *fbi = NULL; ++ ++ fbi = grab_fbi(&pos->bricks_info, &pos->mfbi, subv_id); ++ if (likely(fbi != NULL)) ++ return &fbi->preceder; ++ else { ++ /* use emergency hint */ ++ memset(ehint, 0, sizeof(*ehint)); ++ return ehint; ++ } ++} ++ ++void flush_pos_update_preceder(flush_pos_t *pos, u32 subv_id, ++ reiser4_block_nr blk) ++{ ++ flush_brick_info *fbi; ++ ++ fbi = grab_fbi(&pos->bricks_info, &pos->mfbi, subv_id); ++ if (!fbi) ++ return; ++ fbi_update_preceder(fbi, blk); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 90 ++ LocalWords: preceder ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/flush.h linux-5.10.2/fs/reiser4/flush.h +--- linux-5.10.2.orig/fs/reiser4/flush.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/flush.h 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,326 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* DECLARATIONS: */ ++ ++#if !defined(__REISER4_FLUSH_H__) ++#define __REISER4_FLUSH_H__ ++ ++#include "plugin/cluster.h" ++#include "plugin/volume/volume.h" ++ ++struct flush_brick_info { ++ struct rb_node node; ++ u32 brick_id; /* key */ ++ ++ /* scan info */ ++ int count; /* Number of scanned nodes which belong to this brick. ++ This is used to make relocation decisions */ ++ /* squalloc info */ ++ reiser4_blocknr_hint preceder; /* The flush 'hint' state */ ++}; ++ ++/* The flush_scan data structure maintains the state of an in-progress ++ flush-scan on a single level of the tree. A flush-scan is used for counting ++ the number of adjacent nodes to flush, which is used to determine whether we ++ should relocate, and it is also used to find a starting point for flush. A ++ flush-scan object can scan in both right and left directions via the ++ scan_left() and scan_right() interfaces. The right- and left-variations are ++ similar but perform different functions. When scanning left we (optionally ++ perform rapid scanning and then) longterm-lock the endpoint node. When ++ scanning right we are simply counting the number of adjacent, dirty nodes. */ ++struct flush_scan { ++ struct rb_root *bricks_info; ++ flush_brick_info *mfbi; /* pre-loaded info for meta-data brick */ ++ /* The following two fields are used to terminate scan */ ++ int count; /* total number of nodes scanned on this level */ ++ int max_count; /* maximal total number of nodes to scan on any ++ * single level. When going leftward, then both ++ * counts are restricted by FLUSH_SCAN_MAXNODES */ ++ /* ++ * One of the sideof enumeration: {LEFT_SIDE, RIGHT_SIDE} ++ */ ++ sideof direction; ++ /* ++ * Initially @stop is set to false then set true once some condition ++ * stops the search (e.g., we found a clean node before reaching ++ * max_count or we found a node belonging to another atom) ++ */ ++ int stop; ++ ++ /* The current scan position. If @node is non-NULL then its reference ++ count has been incremented to reflect this reference. */ ++ jnode *node; ++ ++ /* A handle for zload/zrelse of current scan position node. */ ++ load_count node_load; ++ ++ /* During left-scan, if the final position (a.k.a. endpoint node) is ++ formatted the node is locked using this lock handle. The endpoint ++ needs to be locked for transfer to the flush_position object after ++ scanning finishes. */ ++ lock_handle node_lock; ++ ++ /* When the position is unformatted, its parent, coordinate, and parent ++ zload/zrelse handle. */ ++ lock_handle parent_lock; ++ coord_t parent_coord; ++ load_count parent_load; ++}; ++ ++struct convert_item_info { ++ dc_item_stat d_cur; /* per-cluster status of the current item */ ++ dc_item_stat d_next; /* per-cluster status of the first item on ++ the right neighbor */ ++ int cluster_shift; /* disk cluster shift */ ++ flow_t flow; /* disk cluster data */ ++}; ++ ++struct convert_info { ++ int count; /* for squalloc terminating */ ++ item_plugin *iplug; /* current item plugin */ ++ struct convert_item_info *itm; /* current item info */ ++ struct cluster_handle clust; /* transform cluster */ ++ lock_handle right_lock; /* lock handle of the right neighbor */ ++ int right_locked; ++}; ++ ++typedef enum flush_position_state { ++ POS_INVALID, /* Invalid or stopped pos, do not continue slum ++ * processing */ ++ POS_ON_LEAF, /* pos points to already prepped, locked ++ * formatted node at leaf level */ ++ POS_ON_EPOINT, /* pos keeps a lock on twig level, "coord" field ++ * is used to traverse unformatted nodes */ ++ POS_TO_LEAF, /* pos is being moved to leaf level */ ++ POS_TO_TWIG, /* pos is being moved to twig level */ ++ POS_END_OF_TWIG, /* special case of POS_ON_TWIG, when coord is ++ * after rightmost unit of the current twig */ ++ POS_ON_INTERNAL /* same as POS_ON_LEAF, but points to internal ++ * node */ ++} flushpos_state_t; ++ ++/* An encapsulation of the current flush point and all the parameters that are ++ passed through the entire squeeze-and-allocate stage of the flush routine. ++ A single flush_position object is constructed after left- and right-scanning ++ finishes. */ ++struct flush_position { ++ struct rb_root bricks_info; ++ struct flush_brick_info mfbi; /* pre-allocated info for meta-data brick */ ++ ++ flushpos_state_t state; ++ coord_t coord; /* coord to traverse unformatted nodes */ ++ lock_handle lock; /* current lock we hold */ ++ load_count load; /* load status for current locked formatted node ++ */ ++ jnode *child; /* for passing a reference to unformatted child ++ * across pos state changes */ ++ ++ int alloc_cnt; /* The number of nodes allocated during squeeze ++ and allococate. */ ++ int prep_or_free_cnt; /* The number of nodes prepared for write ++ (allocate) or squeezed and freed. */ ++ flush_queue_t *fq; ++ long *nr_written; /* number of nodes submitted to disk */ ++ int flags; /* a copy of jnode_flush flags argument */ ++ ++ znode *prev_twig; /* previous parent pointer value, used to catch ++ * processing of new twig node */ ++ struct convert_info *sq; /* convert info */ ++ ++ unsigned long pos_in_unit; /* for extents only. Position ++ within an extent unit of first ++ jnode of slum */ ++ long nr_to_write; /* number of unformatted nodes to handle on ++ flush */ ++}; ++ ++static inline int item_convert_count(flush_pos_t *pos) ++{ ++ return pos->sq->count; ++} ++static inline void inc_item_convert_count(flush_pos_t *pos) ++{ ++ pos->sq->count++; ++} ++static inline void set_item_convert_count(flush_pos_t *pos, int count) ++{ ++ pos->sq->count = count; ++} ++static inline item_plugin *item_convert_plug(flush_pos_t *pos) ++{ ++ return pos->sq->iplug; ++} ++ ++static inline struct convert_info *convert_data(flush_pos_t *pos) ++{ ++ return pos->sq; ++} ++ ++static inline struct convert_item_info *item_convert_data(flush_pos_t *pos) ++{ ++ assert("edward-955", convert_data(pos)); ++ return pos->sq->itm; ++} ++ ++static inline struct tfm_cluster *tfm_cluster_sq(flush_pos_t *pos) ++{ ++ return &pos->sq->clust.tc; ++} ++ ++static inline struct tfm_stream *tfm_stream_sq(flush_pos_t *pos, ++ tfm_stream_id id) ++{ ++ assert("edward-854", pos->sq != NULL); ++ return get_tfm_stream(tfm_cluster_sq(pos), id); ++} ++ ++static inline int convert_data_attached(flush_pos_t *pos) ++{ ++ return convert_data(pos) != NULL && item_convert_data(pos) != NULL; ++} ++ ++#define should_convert_right_neighbor(pos) convert_data_attached(pos) ++ ++/* Returns true if next node contains next item of the disk cluster ++ so item convert data should be moved to the right slum neighbor. ++*/ ++static inline int next_node_is_chained(flush_pos_t *pos) ++{ ++ return convert_data_attached(pos) && ++ item_convert_data(pos)->d_next == DC_CHAINED_ITEM; ++} ++ ++/* ++ * Update "twin state" (d_cur, d_next) to assign a proper ++ * conversion mode in the next iteration of convert_node() ++ */ ++static inline void update_chaining_state(flush_pos_t *pos, ++ int this_node /* where to proceed */) ++{ ++ ++ assert("edward-1010", convert_data_attached(pos)); ++ ++ if (this_node) { ++ /* ++ * we want to perform one more iteration with the same item ++ */ ++ assert("edward-1013", ++ item_convert_data(pos)->d_cur == DC_FIRST_ITEM || ++ item_convert_data(pos)->d_cur == DC_CHAINED_ITEM); ++ assert("edward-1227", ++ item_convert_data(pos)->d_next == DC_AFTER_CLUSTER || ++ item_convert_data(pos)->d_next == DC_INVALID_STATE); ++ ++ item_convert_data(pos)->d_cur = DC_AFTER_CLUSTER; ++ item_convert_data(pos)->d_next = DC_INVALID_STATE; ++ } ++ else { ++ /* ++ * we want to proceed on right neighbor, which is chained ++ */ ++ assert("edward-1011", ++ item_convert_data(pos)->d_cur == DC_FIRST_ITEM || ++ item_convert_data(pos)->d_cur == DC_CHAINED_ITEM); ++ assert("edward-1012", ++ item_convert_data(pos)->d_next == DC_CHAINED_ITEM); ++ ++ item_convert_data(pos)->d_cur = DC_CHAINED_ITEM; ++ item_convert_data(pos)->d_next = DC_INVALID_STATE; ++ } ++} ++ ++#define SQUALLOC_THRESHOLD 256 ++ ++static inline int should_terminate_squalloc(flush_pos_t *pos) ++{ ++ return convert_data(pos) && ++ !item_convert_data(pos) && ++ item_convert_count(pos) >= SQUALLOC_THRESHOLD; ++} ++ ++/** ++ * Make a decision about block relocation in a brick ++ */ ++static inline int __leaf_should_relocate(flush_brick_info *fbi) ++{ ++ /* ++ * relocate leaf nodes if at least FLUSH_RELOCATE_THRESHOLD ++ * nodes were found by left and right scan ++ */ ++ return fbi->count >= ++ current_origin(fbi->brick_id)->flush.relocate_threshold; ++} ++ ++#if REISER4_DEBUG ++#define check_convert_info(pos) \ ++do { \ ++ if (unlikely(should_convert_right_neighbor(pos))) { \ ++ warning("edward-1006", "unprocessed chained data"); \ ++ printk("d_cur = %d, d_next = %d, flow.len = %llu\n", \ ++ item_convert_data(pos)->d_cur, \ ++ item_convert_data(pos)->d_next, \ ++ item_convert_data(pos)->flow.length); \ ++ } \ ++} while (0) ++#else ++#define check_convert_info(pos) ++#endif /* REISER4_DEBUG */ ++ ++void free_convert_data(flush_pos_t *pos); ++/* used in extent.c */ ++int move_scan_pos(flush_scan *scan, jnode *node, unsigned add_size, ++ const coord_t *parent); ++int reiser4_scan_finished(flush_scan * scan); ++int reiser4_scanning_left(flush_scan * scan); ++int reiser4_scan_goto(flush_scan * scan, jnode * tonode); ++txn_atom *atom_locked_by_fq(flush_queue_t *fq); ++int reiser4_alloc_extent(flush_pos_t *flush_pos); ++squeeze_result squalloc_extent(znode *left, const coord_t *, flush_pos_t *, ++ reiser4_key *stop_key); ++extern int reiser4_init_fqs(void); ++extern void reiser4_done_fqs(void); ++extern reiser4_blocknr_hint *flush_pos_get_hint(flush_pos_t *pos, u32 subv_id, ++ reiser4_blocknr_hint *ehint); ++extern int leaf_should_relocate(flush_pos_t *pos, u32 subv_id); ++extern void flush_pos_update_preceder(flush_pos_t *pos, u32 subv_id, ++ reiser4_block_nr blk); ++extern int flush_init_static(void); ++extern void done_flush_static(void); ++ ++#if REISER4_DEBUG ++extern void reiser4_check_fq(const txn_atom *atom); ++extern atomic_t flush_cnt; ++ ++#define check_preceder(blk, subv) \ ++assert("nikita-2588", blk < reiser4_subvol_block_count(subv)); ++extern void check_pos(flush_pos_t *pos); ++#else ++#define check_preceder(blk, subv) noop ++#define check_pos(pos) noop ++#endif ++ ++static inline void fbi_update_preceder(flush_brick_info *fbi, ++ reiser4_block_nr blk) ++{ ++ if (unlikely(blk == current_origin(fbi->brick_id)->block_count)) ++ /* ++ * we reached end of device, reset preceder ++ */ ++ blk = 0; ++ fbi->preceder.blk = blk; ++ check_preceder(blk, current_origin(fbi->brick_id)); ++} ++ ++/* __REISER4_FLUSH_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 90 ++ LocalWords: preceder ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/flush_queue.c linux-5.10.2/fs/reiser4/flush_queue.c +--- linux-5.10.2.orig/fs/reiser4/flush_queue.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/flush_queue.c 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,735 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++#include "debug.h" ++#include "super.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "page_cache.h" ++#include "wander.h" ++#include "vfs_ops.h" ++#include "writeout.h" ++#include "flush.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* A flush queue object is an accumulator for keeping jnodes prepared ++ by the jnode_flush() function for writing to disk. Those "queued" jnodes are ++ kept on the flush queue until memory pressure or atom commit asks ++ flush queues to write some or all from their jnodes. */ ++ ++/* ++ LOCKING: ++ ++ fq->guard spin lock protects fq->atom pointer and nothing else. fq->prepped ++ list protected by atom spin lock. fq->prepped list uses the following ++ locking: ++ ++ two ways to protect fq->prepped list for read-only list traversal: ++ ++ 1. atom spin-lock atom. ++ 2. fq is IN_USE, atom->nr_running_queues increased. ++ ++ and one for list modification: ++ ++ 1. atom is spin-locked and one condition is true: fq is IN_USE or ++ atom->nr_running_queues == 0. ++ ++ The deadlock-safe order for flush queues and atoms is: first lock atom, then ++ lock flush queue, then lock jnode. ++*/ ++ ++#define fq_in_use(fq) ((fq)->state & FQ_IN_USE) ++#define fq_ready(fq) (!fq_in_use(fq)) ++ ++#define mark_fq_in_use(fq) do { (fq)->state |= FQ_IN_USE; } while (0) ++#define mark_fq_ready(fq) do { (fq)->state &= ~FQ_IN_USE; } while (0) ++ ++/* get lock on atom from locked flush queue object */ ++static txn_atom *atom_locked_by_fq_nolock(flush_queue_t *fq) ++{ ++ /* This code is similar to jnode_get_atom(), look at it for the ++ * explanation. */ ++ txn_atom *atom; ++ ++ assert_spin_locked(&(fq->guard)); ++ ++ while (1) { ++ atom = fq->atom; ++ if (atom == NULL) ++ break; ++ ++ if (spin_trylock_atom(atom)) ++ break; ++ ++ atomic_inc(&atom->refcount); ++ spin_unlock(&(fq->guard)); ++ spin_lock_atom(atom); ++ spin_lock(&(fq->guard)); ++ ++ if (fq->atom == atom) { ++ atomic_dec(&atom->refcount); ++ break; ++ } ++ ++ spin_unlock(&(fq->guard)); ++ atom_dec_and_unlock(atom); ++ spin_lock(&(fq->guard)); ++ } ++ ++ return atom; ++} ++ ++txn_atom *atom_locked_by_fq(flush_queue_t *fq) ++{ ++ txn_atom *atom; ++ ++ spin_lock(&(fq->guard)); ++ atom = atom_locked_by_fq_nolock(fq); ++ spin_unlock(&(fq->guard)); ++ return atom; ++} ++ ++static void init_fq(flush_queue_t *fq) ++{ ++ memset(fq, 0, sizeof *fq); ++ ++ atomic_set(&fq->nr_submitted, 0); ++ ++ INIT_LIST_HEAD(ATOM_FQ_LIST(fq)); ++ ++ init_waitqueue_head(&fq->wait); ++ spin_lock_init(&fq->guard); ++} ++ ++/* slab for flush queues */ ++static struct kmem_cache *fq_slab; ++ ++/** ++ * reiser4_init_fqs - create flush queue cache ++ * ++ * Initializes slab cache of flush queues. It is part of reiser4 module ++ * initialization. ++ */ ++int reiser4_init_fqs(void) ++{ ++ fq_slab = kmem_cache_create("fq", ++ sizeof(flush_queue_t), ++ 0, SLAB_HWCACHE_ALIGN, NULL); ++ if (fq_slab == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++/** ++ * reiser4_done_fqs - delete flush queue cache ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void reiser4_done_fqs(void) ++{ ++ destroy_reiser4_cache(&fq_slab); ++} ++ ++/* create new flush queue object */ ++static flush_queue_t *create_fq(gfp_t gfp) ++{ ++ flush_queue_t *fq; ++ ++ fq = kmem_cache_alloc(fq_slab, gfp); ++ if (fq) ++ init_fq(fq); ++ ++ return fq; ++} ++ ++/* adjust atom's and flush queue's counters of queued nodes */ ++static void count_enqueued_node(flush_queue_t *fq) ++{ ++ ON_DEBUG(fq->atom->num_queued++); ++} ++ ++static void count_dequeued_node(flush_queue_t *fq) ++{ ++ assert("zam-993", fq->atom->num_queued > 0); ++ ON_DEBUG(fq->atom->num_queued--); ++} ++ ++/* attach flush queue object to the atom */ ++static void attach_fq(txn_atom *atom, flush_queue_t *fq) ++{ ++ assert_spin_locked(&(atom->alock)); ++ list_add(&fq->alink, &atom->flush_queues); ++ fq->atom = atom; ++ ON_DEBUG(atom->nr_flush_queues++); ++} ++ ++static void detach_fq(flush_queue_t *fq) ++{ ++ assert_spin_locked(&(fq->atom->alock)); ++ ++ spin_lock(&(fq->guard)); ++ list_del_init(&fq->alink); ++ assert("vs-1456", fq->atom->nr_flush_queues > 0); ++ ON_DEBUG(fq->atom->nr_flush_queues--); ++ fq->atom = NULL; ++ spin_unlock(&(fq->guard)); ++} ++ ++/* destroy flush queue object */ ++static void done_fq(flush_queue_t *fq) ++{ ++ assert("zam-763", list_empty_careful(ATOM_FQ_LIST(fq))); ++ assert("zam-766", atomic_read(&fq->nr_submitted) == 0); ++ ++ kmem_cache_free(fq_slab, fq); ++} ++ ++static void mark_jnode_queued(flush_queue_t *fq, jnode * node) ++{ ++ JF_SET(node, JNODE_FLUSH_QUEUED); ++ count_enqueued_node(fq); ++} ++ ++/** ++ * Move jnode to the flush queue. ++ * Both atom and jnode should be spin-locked ++ */ ++void queue_jnode(flush_queue_t *fq, jnode *node) ++{ ++ assert_spin_locked(&(node->guard)); ++ assert("zam-713", node->atom != NULL); ++ assert_spin_locked(&(node->atom->alock)); ++ assert("zam-716", fq->atom != NULL); ++ assert("zam-717", fq->atom == node->atom); ++ assert("zam-907", fq_in_use(fq)); ++ ++ assert("zam-714", JF_ISSET(node, JNODE_DIRTY)); ++ assert("zam-826", JF_ISSET(node, JNODE_RELOC)); ++ assert("vs-1481", !JF_ISSET(node, JNODE_FLUSH_QUEUED)); ++ assert("vs-1481", NODE_LIST(node) != FQ_LIST); ++ ++ assert("edward-2321", !reiser4_blocknr_is_fake(jnode_get_block(node))); ++ ++ mark_jnode_queued(fq, node); ++ list_move_tail(&node->capture_link, ATOM_FQ_LIST(fq)); ++ ++ ON_DEBUG(count_jnode(node->atom, node, NODE_LIST(node), ++ FQ_LIST, 1)); ++} ++ ++/** ++ * Repeatable process for waiting io completion on a flush queue object ++ */ ++static int wait_io(flush_queue_t *fq, int *nr_io_errors) ++{ ++ assert("zam-738", fq->atom != NULL); ++ assert_spin_locked(&(fq->atom->alock)); ++ assert("zam-736", fq_in_use(fq)); ++ assert("zam-911", list_empty_careful(ATOM_FQ_LIST(fq))); ++ ++ if (atomic_read(&fq->nr_submitted) != 0) { ++ struct super_block *super; ++ ++ spin_unlock_atom(fq->atom); ++ ++ assert("nikita-3013", reiser4_schedulable()); ++ ++ super = reiser4_get_current_sb(); ++ ++ //blk_run_queues(); ++ //blk_flush_plug(current); ++ ++ if (!sb_rdonly(super)) ++ wait_event(fq->wait, ++ atomic_read(&fq->nr_submitted) == 0); ++ /* ++ * Ask the caller to re-acquire the locks and call this ++ * function again. Note: this technique is commonly used ++ * in the txnmgr code ++ */ ++ return -E_REPEAT; ++ } ++ *nr_io_errors += atomic_read(&fq->nr_errors); ++ return 0; ++} ++ ++/** ++ * Wait on I/O completion, re-submit dirty nodes to write ++ */ ++static int finish_fq(flush_queue_t *fq, int *nr_io_errors) ++{ ++ int ret; ++ txn_atom *atom = fq->atom; ++ ++ assert("zam-801", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ assert("zam-762", fq_in_use(fq)); ++ ++ ret = wait_io(fq, nr_io_errors); ++ if (ret) ++ return ret; ++ ++ detach_fq(fq); ++ done_fq(fq); ++ ++ reiser4_atom_send_event(atom); ++ ++ return 0; ++} ++ ++/** ++ * Wait for all IOs for given atom to be completed. ++ * Actually do one iteration on that and return -E_REPEAT, ++ * if there more iterations needed ++ */ ++static int finish_all_fq(txn_atom * atom, int *nr_io_errors) ++{ ++ flush_queue_t *fq; ++ ++ assert_spin_locked(&(atom->alock)); ++ ++ if (list_empty_careful(&atom->flush_queues)) ++ return 0; ++ ++ list_for_each_entry(fq, &atom->flush_queues, alink) { ++ if (fq_ready(fq)) { ++ int ret; ++ ++ mark_fq_in_use(fq); ++ assert("vs-1247", fq->owner == NULL); ++ ON_DEBUG(fq->owner = current); ++ ret = finish_fq(fq, nr_io_errors); ++ ++ if (*nr_io_errors) ++ reiser4_handle_error(); ++ ++ if (ret) { ++ reiser4_fq_put(fq); ++ return ret; ++ } ++ spin_unlock_atom(atom); ++ ++ return -E_REPEAT; ++ } ++ } ++ /* ++ * All flush queues are in use; atom remains locked ++ */ ++ return -EBUSY; ++} ++ ++/** ++ * Wait all IOs for current atom ++ */ ++int current_atom_finish_all_fq(void) ++{ ++ txn_atom *atom; ++ int nr_io_errors = 0; ++ int ret = 0; ++ ++ do { ++ while (1) { ++ atom = get_current_atom_locked(); ++ ret = finish_all_fq(atom, &nr_io_errors); ++ if (ret != -EBUSY) ++ break; ++ reiser4_atom_wait_event(atom); ++ } ++ } while (ret == -E_REPEAT); ++ /* ++ * we do not need locked atom after this function finishes, ++ * SUCCESS or -EBUSY are two return codes when atom remains ++ * locked after finish_all_fq ++ */ ++ if (!ret) ++ spin_unlock_atom(atom); ++ ++ assert_spin_not_locked(&(atom->alock)); ++ ++ if (ret) ++ return ret; ++ ++ if (nr_io_errors) ++ return RETERR(-EIO); ++ ++ return 0; ++} ++ ++/** ++ * Change node->atom field for all jnode from given list ++ */ ++static void scan_fq_and_update_atom_ref(struct list_head *list, ++ txn_atom *atom) ++{ ++ jnode *cur; ++ ++ list_for_each_entry(cur, list, capture_link) { ++ spin_lock_jnode(cur); ++ cur->atom = atom; ++ spin_unlock_jnode(cur); ++ } ++} ++ ++/** ++ * Support for atom fusion operation ++ */ ++void reiser4_fuse_fq(txn_atom *to, txn_atom *from) ++{ ++ flush_queue_t *fq; ++ ++ assert_spin_locked(&(to->alock)); ++ assert_spin_locked(&(from->alock)); ++ ++ list_for_each_entry(fq, &from->flush_queues, alink) { ++ scan_fq_and_update_atom_ref(ATOM_FQ_LIST(fq), to); ++ spin_lock(&(fq->guard)); ++ fq->atom = to; ++ spin_unlock(&(fq->guard)); ++ } ++ ++ list_splice_init(&from->flush_queues, to->flush_queues.prev); ++ ++#if REISER4_DEBUG ++ to->num_queued += from->num_queued; ++ to->nr_flush_queues += from->nr_flush_queues; ++ from->nr_flush_queues = 0; ++#endif ++} ++ ++#if REISER4_DEBUG ++int atom_fq_parts_are_clean(txn_atom * atom) ++{ ++ assert("zam-915", atom != NULL); ++ return list_empty_careful(&atom->flush_queues); ++} ++#endif ++ ++/** ++ * Bio i/o completion routine for reiser4 write operations ++ */ ++static void end_io_handler(struct bio *bio) ++{ ++ int nr = 0; ++ int nr_errors = 0; ++ flush_queue_t *fq; ++ struct bio_vec *bvec; ++ struct bvec_iter_all iter_all; ++ ++ assert("zam-958", bio_op(bio) == WRITE); ++ /* ++ * We expect that bio->private is set to NULL, or ++ * to fq object which is used for synchronization ++ * and error counting ++ */ ++ fq = bio->bi_private; ++ /* ++ * Check all elements of io_vec for correct write completion ++ */ ++ bio_for_each_segment_all(bvec, bio, iter_all) { ++ struct page *pg = bvec->bv_page; ++ ++ if (bio->bi_status) { ++ SetPageError(pg); ++ nr_errors++; ++ } ++ ++ { ++ /* jnode WRITEBACK ("write is in progress bit") is ++ * atomically cleared here. */ ++ jnode *node; ++ ++ assert("zam-736", pg != NULL); ++ assert("zam-736", PagePrivate(pg)); ++ node = jprivate(pg); ++ ++ JF_CLR(node, JNODE_WRITEBACK); ++ } ++ nr ++; ++ end_page_writeback(pg); ++ put_page(pg); ++ } ++ if (fq) { ++ /* ++ * count i/o error in fq object ++ */ ++ atomic_add(nr_errors, &fq->nr_errors); ++ /* ++ * If all write requests registered in this "fq" are done ++ * we up the waiter ++ */ ++ if (atomic_sub_and_test(nr, &fq->nr_submitted)) ++ wake_up(&fq->wait); ++ } ++ bio_put(bio); ++} ++ ++/** ++ * Count I/O requests which will be submitted by @bio ++ * in the given flush queue @fq ++ */ ++void add_fq_to_bio(flush_queue_t *fq, struct bio *bio) ++{ ++ bio->bi_private = fq; ++ bio->bi_end_io = end_io_handler; ++ ++ if (fq) ++ atomic_add(bio->bi_iter.bi_size >> PAGE_SHIFT, ++ &fq->nr_submitted); ++} ++ ++/** ++ * Move all queued nodes out from @fq->prepped list ++ */ ++static void release_prepped_list(flush_queue_t *fq) ++{ ++ txn_atom *atom; ++ ++ assert("zam-904", fq_in_use(fq)); ++ atom = atom_locked_by_fq(fq); ++ ++ while (!list_empty(ATOM_FQ_LIST(fq))) { ++ jnode *cur; ++ ++ cur = list_entry(ATOM_FQ_LIST(fq)->next, jnode, capture_link); ++ list_del_init(&cur->capture_link); ++ ++ count_dequeued_node(fq); ++ spin_lock_jnode(cur); ++ assert("nikita-3154", !JF_ISSET(cur, JNODE_OVRWR)); ++ assert("nikita-3154", JF_ISSET(cur, JNODE_RELOC)); ++ assert("nikita-3154", JF_ISSET(cur, JNODE_FLUSH_QUEUED)); ++ JF_CLR(cur, JNODE_FLUSH_QUEUED); ++ ++ if (JF_ISSET(cur, JNODE_DIRTY)) { ++ list_add_tail(&cur->capture_link, ++ ATOM_DIRTY_LIST(atom, ++ jnode_get_level(cur))); ++ ON_DEBUG(count_jnode(atom, cur, FQ_LIST, ++ DIRTY_LIST, 1)); ++ } else { ++ list_add_tail(&cur->capture_link, ++ ATOM_CLEAN_LIST(atom)); ++ ON_DEBUG(count_jnode(atom, cur, FQ_LIST, ++ CLEAN_LIST, 1)); ++ } ++ ++ spin_unlock_jnode(cur); ++ } ++ ++ if (--atom->nr_running_queues == 0) ++ reiser4_atom_send_event(atom); ++ ++ spin_unlock_atom(atom); ++} ++ ++static int fq_compare_jnode(void* priv UNUSED_ARG, ++ struct list_head *a, struct list_head *b) ++{ ++ jnode *ja, *jb; ++ ++ assert("edward-1873", a != NULL); ++ assert("edward-1874", b != NULL); ++ ++ ja = jnode_by_link(a); ++ jb = jnode_by_link(b); ++ ++ if (jnode_get_subvol(ja)->id < jnode_get_subvol(jb)->id) ++ return -1; ++ if (jnode_get_subvol(ja)->id > jnode_get_subvol(jb)->id) ++ return 1; ++ if (jnode_get_block(ja) < jnode_get_block(jb)) ++ return -1; ++ return 1; ++} ++ ++/** ++ * Submit write requests for nodes on the already filled flush queue @fq. ++ * ++ * @fq: flush queue object which contains jnodes we can (and will) write. ++ * @return: number of submitted blocks (>=0) if success, otherwise -- an ++ * error code (<0) ++ */ ++int reiser4_write_fq(flush_queue_t *fq, long *nr_submitted, int flags) ++{ ++ int ret; ++ txn_atom *atom; ++ ++ while (1) { ++ atom = atom_locked_by_fq(fq); ++ assert("zam-924", atom); ++ /* ++ * do not write fq in parallel ++ */ ++ if (atom->nr_running_queues == 0 || ++ !(flags & WRITEOUT_SINGLE_STREAM)) ++ break; ++ reiser4_atom_wait_event(atom); ++ } ++ atom->nr_running_queues++; ++ spin_unlock_atom(atom); ++ ++ list_sort(NULL, ATOM_FQ_LIST(fq), fq_compare_jnode); ++ ret = write_jnode_list(ATOM_FQ_LIST(fq), fq, nr_submitted, flags); ++ release_prepped_list(fq); ++ return ret; ++} ++ ++/** ++ * Getting flush queue object for exclusive use by one thread. May require ++ * several iterations which is indicated by -E_REPEAT return code. ++ * ++ * This function does not contain code for obtaining an atom lock because an ++ * atom lock is obtained by different ways in different parts of reiser4, ++ * usually it is current atom, but we need a possibility for getting fq for ++ * the atom of given jnode. ++ */ ++static int fq_by_atom_gfp(txn_atom *atom, flush_queue_t **new_fq, gfp_t gfp) ++{ ++ flush_queue_t *fq; ++ ++ assert_spin_locked(&(atom->alock)); ++ ++ fq = list_entry(atom->flush_queues.next, flush_queue_t, alink); ++ while (&atom->flush_queues != &fq->alink) { ++ spin_lock(&(fq->guard)); ++ ++ if (fq_ready(fq)) { ++ mark_fq_in_use(fq); ++ assert("vs-1246", fq->owner == NULL); ++ ON_DEBUG(fq->owner = current); ++ spin_unlock(&(fq->guard)); ++ ++ if (*new_fq) ++ done_fq(*new_fq); ++ *new_fq = fq; ++ return 0; ++ } ++ spin_unlock(&(fq->guard)); ++ ++ fq = list_entry(fq->alink.next, flush_queue_t, alink); ++ } ++ /* ++ * Use previously allocated fq object ++ */ ++ if (*new_fq) { ++ mark_fq_in_use(*new_fq); ++ assert("vs-1248", (*new_fq)->owner == 0); ++ ON_DEBUG((*new_fq)->owner = current); ++ attach_fq(atom, *new_fq); ++ return 0; ++ } ++ spin_unlock_atom(atom); ++ ++ *new_fq = create_fq(gfp); ++ ++ if (*new_fq == NULL) ++ return RETERR(-ENOMEM); ++ /* ++ * caller should re-acquire atom lock and call this function again ++ */ ++ return RETERR(-E_REPEAT); ++} ++ ++int reiser4_fq_by_atom(txn_atom * atom, flush_queue_t **new_fq) ++{ ++ return fq_by_atom_gfp(atom, new_fq, reiser4_ctx_gfp_mask_get()); ++} ++ ++/** ++ * A wrapper around reiser4_fq_by_atom for getting a flush queue ++ * object for current atom, if success fq->atom remains locked ++ */ ++flush_queue_t *get_fq_for_current_atom(void) ++{ ++ flush_queue_t *fq = NULL; ++ txn_atom *atom; ++ int ret; ++ ++ do { ++ atom = get_current_atom_locked(); ++ ret = reiser4_fq_by_atom(atom, &fq); ++ } while (ret == -E_REPEAT); ++ ++ if (ret) ++ return ERR_PTR(ret); ++ return fq; ++} ++ ++/** ++ * Releasing flush queue object after exclusive use ++ */ ++void reiser4_fq_put_nolock(flush_queue_t *fq) ++{ ++ assert("zam-747", fq->atom != NULL); ++ assert("zam-902", list_empty_careful(ATOM_FQ_LIST(fq))); ++ mark_fq_ready(fq); ++ assert("vs-1245", fq->owner == current); ++ ON_DEBUG(fq->owner = NULL); ++} ++ ++void reiser4_fq_put(flush_queue_t *fq) ++{ ++ txn_atom *atom; ++ ++ spin_lock(&(fq->guard)); ++ atom = atom_locked_by_fq_nolock(fq); ++ ++ assert("zam-746", atom != NULL); ++ ++ reiser4_fq_put_nolock(fq); ++ reiser4_atom_send_event(atom); ++ ++ spin_unlock(&(fq->guard)); ++ spin_unlock_atom(atom); ++} ++ ++/** ++ * A part of atom object initialization related to the ++ * embedded flush queue list head ++ */ ++void init_atom_fq_parts(txn_atom *atom) ++{ ++ INIT_LIST_HEAD(&atom->flush_queues); ++} ++ ++#if REISER4_DEBUG ++void reiser4_check_fq(const txn_atom *atom) ++{ ++ flush_queue_t *fq; ++ int count; ++ struct list_head *pos; ++ /* ++ * check number of nodes on all atom's flush queues ++ */ ++ count = 0; ++ list_for_each_entry(fq, &atom->flush_queues, alink) { ++ spin_lock(&(fq->guard)); ++ /* ++ * calculate number of jnodes on fq' list of prepped jnodes ++ */ ++ list_for_each(pos, ATOM_FQ_LIST(fq)) ++ count++; ++ spin_unlock(&(fq->guard)); ++ } ++ if (count != atom->fq) ++ warning("", "fq counter %d, real %d\n", atom->fq, count); ++} ++#endif /* REISER4_DEBUG */ ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/forward.h linux-5.10.2/fs/reiser4/forward.h +--- linux-5.10.2.orig/fs/reiser4/forward.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/forward.h 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,276 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Forward declarations. Thank you Kernighan. */ ++ ++#if !defined(__REISER4_FORWARD_H__) ++#define __REISER4_FORWARD_H__ ++ ++#include ++#include ++ ++typedef struct zlock zlock; ++typedef struct lock_stack lock_stack; ++typedef struct lock_handle lock_handle; ++typedef struct znode znode; ++typedef struct flow flow_t; ++typedef struct coord coord_t; ++typedef struct tree_access_pointer tap_t; ++typedef struct reiser4_object_create_data reiser4_object_create_data; ++typedef union reiser4_plugin reiser4_plugin; ++typedef __u16 reiser4_plugin_id; ++typedef __u64 reiser4_plugin_groups; ++typedef struct item_plugin item_plugin; ++typedef struct jnode_plugin jnode_plugin; ++typedef struct reiser4_item_data reiser4_item_data; ++typedef union reiser4_key reiser4_key; ++typedef struct reiser4_tree reiser4_tree; ++typedef struct carry_cut_data carry_cut_data; ++typedef struct carry_kill_data carry_kill_data; ++typedef struct carry_tree_op carry_tree_op; ++typedef struct carry_tree_node carry_tree_node; ++typedef struct carry_plugin_info carry_plugin_info; ++typedef struct reiser4_journal reiser4_journal; ++typedef struct txn_atom txn_atom; ++typedef struct txn_handle txn_handle; ++typedef struct txn_mgr txn_mgr; ++typedef struct reiser4_dir_entry_desc reiser4_dir_entry_desc; ++typedef struct reiser4_context reiser4_context; ++typedef struct atom_brick_info atom_brick_info; ++typedef struct ctx_brick_info ctx_brick_info; ++typedef struct flush_brick_info flush_brick_info; ++typedef struct carry_level carry_level; ++typedef struct blocknr_set_entry blocknr_set_entry; ++typedef struct blocknr_list_entry blocknr_list_entry; ++typedef struct reiser4_volinfo reiser4_volinfo; ++typedef struct reiser4_volume reiser4_volume; ++typedef struct reiser4_subvol reiser4_subvol; ++/* super_block->s_fs_info points to this */ ++typedef struct reiser4_super_info_data reiser4_super_info_data; ++/* next two objects are fields of reiser4_super_info_data */ ++typedef struct reiser4_oid_allocator reiser4_oid_allocator; ++typedef struct reiser4_space_allocator reiser4_space_allocator; ++ ++typedef struct flush_scan flush_scan; ++typedef struct flush_position flush_pos_t; ++ ++typedef unsigned short pos_in_node_t; ++ ++typedef struct lv_conf lv_conf; ++typedef reiser4_subvol *mirror_t; ++typedef mirror_t *slot_t; ++typedef void *bucket_t; ++ ++#define MAX_POS_IN_NODE 65535 ++#define MAX_NUM_SUBVOLS 8 ++ ++typedef struct jnode jnode; ++typedef struct reiser4_blocknr_hint reiser4_blocknr_hint; ++ ++typedef struct uf_coord uf_coord_t; ++typedef struct hint hint_t; ++ ++typedef struct ktxnmgrd_context ktxnmgrd_context; ++typedef union reiser4_dcx reiser4_dcx; ++typedef struct fnode fnode; ++ ++struct inode; ++struct page; ++struct file; ++struct dentry; ++struct super_block; ++ ++/* return values of coord_by_key(). cbk == coord_by_key */ ++typedef enum { ++ CBK_COORD_FOUND = 0, ++ CBK_COORD_NOTFOUND = -ENOENT, ++} lookup_result; ++ ++/* results of lookup with directory file */ ++typedef enum { ++ FILE_NAME_FOUND = 0, ++ FILE_NAME_NOTFOUND = -ENOENT, ++ FILE_IO_ERROR = -EIO, /* FIXME: it seems silly to have special OOM, ++ IO_ERROR return codes for each search. */ ++ FILE_OOM = -ENOMEM /* FIXME: it seems silly to have special OOM, ++ IO_ERROR return codes for each search. */ ++} file_lookup_result; ++ ++/* behaviors of lookup. If coord we are looking for is actually in a tree, ++ both coincide. */ ++typedef enum { ++ /* search exactly for the coord with key given */ ++ FIND_EXACT, ++ /* search for coord with the maximal key not greater than one ++ given */ ++ FIND_MAX_NOT_MORE_THAN /*LEFT_SLANT_BIAS */ ++} lookup_bias; ++ ++typedef enum { ++ /* number of leaf level of the tree ++ The fake root has (tree_level=0). */ ++ LEAF_LEVEL = 1, ++ ++ /* number of level one above leaf level of the tree. ++ ++ It is supposed that internal tree used by reiser4 to store file ++ system data and meta data will have height 2 initially (when ++ created by mkfs). ++ */ ++ TWIG_LEVEL = 2, ++} tree_level; ++ ++/* The "real" maximum ztree height is the 0-origin size of any per-level ++ array, since the zero'th level is not used. */ ++#define REAL_MAX_ZTREE_HEIGHT (REISER4_MAX_ZTREE_HEIGHT-LEAF_LEVEL) ++ ++/* enumeration of possible mutual position of item and coord. This enum is ++ return type of ->is_in_item() item plugin method which see. */ ++typedef enum { ++ /* coord is on the left of an item */ ++ IP_ON_THE_LEFT, ++ /* coord is inside item */ ++ IP_INSIDE, ++ /* coord is inside item, but to the right of the rightmost unit of ++ this item */ ++ IP_RIGHT_EDGE, ++ /* coord is on the right of an item */ ++ IP_ON_THE_RIGHT ++} interposition; ++ ++/* type of lock to acquire on znode before returning it to caller */ ++typedef enum { ++ ZNODE_NO_LOCK = 0, ++ ZNODE_READ_LOCK = 1, ++ ZNODE_WRITE_LOCK = 2, ++} znode_lock_mode; ++ ++/* type of lock request */ ++typedef enum { ++ ZNODE_LOCK_LOPRI = 0, ++ ZNODE_LOCK_HIPRI = (1 << 0), ++ ++ /* By setting the ZNODE_LOCK_NONBLOCK flag in a lock request the call to ++ longterm_lock_znode will not sleep waiting for the lock to become ++ available. If the lock is unavailable, reiser4_znode_lock will ++ immediately return the value -E_REPEAT. */ ++ ZNODE_LOCK_NONBLOCK = (1 << 1), ++ /* An option for longterm_lock_znode which prevents atom fusion */ ++ ZNODE_LOCK_DONT_FUSE = (1 << 2) ++} znode_lock_request; ++ ++typedef enum { READ_OP = 0, WRITE_OP = 1 } rw_op; ++ ++/* used to specify direction of shift. These must be -1 and 1 */ ++typedef enum { ++ SHIFT_LEFT = 1, ++ SHIFT_RIGHT = -1 ++} shift_direction; ++ ++typedef enum { ++ LEFT_SIDE, ++ RIGHT_SIDE ++} sideof; ++ ++#define reiser4_round_up(value, order) \ ++ ((typeof(value))(((long) (value) + (order) - 1U) & \ ++ ~((order) - 1))) ++ ++/* values returned by squalloc_right_neighbor and its auxiliary functions */ ++typedef enum { ++ /* unit of internal item is moved */ ++ SUBTREE_MOVED = 0, ++ /* nothing else can be squeezed into left neighbor */ ++ SQUEEZE_TARGET_FULL = 1, ++ /* all content of node is squeezed into its left neighbor */ ++ SQUEEZE_SOURCE_EMPTY = 2, ++ /* one more item is copied (this is only returned by ++ allocate_and_copy_extent to squalloc_twig)) */ ++ SQUEEZE_CONTINUE = 3 ++} squeeze_result; ++ ++/* Do not change items ids. If you do - there will be format change */ ++typedef enum { ++ STATIC_STAT_DATA_ID = 0x0, ++ SIMPLE_DIR_ENTRY_ID = 0x1, ++ COMPOUND_DIR_ID = 0x2, ++ NODE_POINTER_ID = 0x3, ++ EXTENT40_POINTER_ID = 0x5, ++ FORMATTING_ID = 0x6, ++ CTAIL_ID = 0x7, ++ BLACK_BOX_ID = 0x8, ++ EXTENT41_POINTER_ID = 0x9, ++ BRICK_SYMBOL_ID = 0xa, ++ LAST_ITEM_ID = 0xb, ++} item_id; ++ ++/* Flags passed to jnode_flush() to allow it to distinguish default settings ++ based on whether commit() was called or VM memory pressure was applied. */ ++typedef enum { ++ /* submit flush queue to disk at jnode_flush completion */ ++ JNODE_FLUSH_WRITE_BLOCKS = 1, ++ ++ /* flush is called for commit */ ++ JNODE_FLUSH_COMMIT = 2, ++ /* not implemented */ ++ JNODE_FLUSH_MEMORY_FORMATTED = 4, ++ ++ /* not implemented */ ++ JNODE_FLUSH_MEMORY_UNFORMATTED = 8, ++} jnode_flush_flags; ++ ++/* Flags to insert/paste carry operations. Currently they only used in ++ flushing code, but in future, they can be used to optimize for repetitive ++ accesses. */ ++typedef enum { ++ /* carry is not allowed to shift data to the left when trying to find ++ free space */ ++ COPI_DONT_SHIFT_LEFT = (1 << 0), ++ /* carry is not allowed to shift data to the right when trying to find ++ free space */ ++ COPI_DONT_SHIFT_RIGHT = (1 << 1), ++ /* carry is not allowed to allocate new node(s) when trying to find ++ free space */ ++ COPI_DONT_ALLOCATE = (1 << 2), ++ /* try to load left neighbor if its not in a cache */ ++ COPI_LOAD_LEFT = (1 << 3), ++ /* try to load right neighbor if its not in a cache */ ++ COPI_LOAD_RIGHT = (1 << 4), ++ /* shift insertion point to the left neighbor */ ++ COPI_GO_LEFT = (1 << 5), ++ /* shift insertion point to the right neighbor */ ++ COPI_GO_RIGHT = (1 << 6), ++ /* try to step back into original node if insertion into new node ++ fails after shifting data there. */ ++ COPI_STEP_BACK = (1 << 7), ++ /* use all possible space in the node */ ++ COPI_SWEEP = (1 << 8) ++} cop_insert_flag; ++ ++typedef enum { ++ SAFE_UNLINK, /* safe-link for unlink */ ++ SAFE_TRUNCATE /* safe-link for truncate */ ++} reiser4_safe_link_t; ++ ++/* this is to show on which list of atom jnode is */ ++typedef enum { ++ NOT_CAPTURED, ++ DIRTY_LIST, ++ CLEAN_LIST, ++ FQ_LIST, ++ WB_LIST, ++ OVRWR_LIST ++} atom_list; ++ ++/* __REISER4_FORWARD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/fsdata.c linux-5.10.2/fs/reiser4/fsdata.c +--- linux-5.10.2.orig/fs/reiser4/fsdata.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/fsdata.c 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,801 @@ ++/* Copyright 2001, 2002, 2003, 2004, 2005 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "fsdata.h" ++#include "inode.h" ++ ++#include ++ ++/* cache or dir_cursors */ ++static struct kmem_cache *d_cursor_cache; ++ ++/* list of unused cursors */ ++static LIST_HEAD(cursor_cache); ++ ++/* number of cursors in list of ununsed cursors */ ++static unsigned long d_cursor_unused = 0; ++ ++/* spinlock protecting manipulations with dir_cursor's hash table and lists */ ++DEFINE_SPINLOCK(d_c_lock); ++ ++static reiser4_file_fsdata *create_fsdata(struct file *file); ++static int file_is_stateless(struct file *file); ++static void free_fsdata(reiser4_file_fsdata *fsdata); ++static void kill_cursor(dir_cursor *); ++ ++static unsigned long d_cursor_shrink_scan(struct shrinker *shrink, ++ struct shrink_control *sc) ++{ ++ dir_cursor *scan; ++ unsigned long freed = 0; ++ ++ spin_lock(&d_c_lock); ++ while (!list_empty(&cursor_cache) && sc->nr_to_scan) { ++ scan = list_entry(cursor_cache.next, dir_cursor, alist); ++ assert("nikita-3567", scan->ref == 0); ++ kill_cursor(scan); ++ freed++; ++ sc->nr_to_scan--; ++ } ++ spin_unlock(&d_c_lock); ++ return freed; ++} ++ ++static unsigned long d_cursor_shrink_count (struct shrinker *shrink, ++ struct shrink_control *sc) ++{ ++ return d_cursor_unused; ++} ++ ++/* ++ * actually, d_cursors are "priceless", because there is no way to ++ * recover information stored in them. On the other hand, we don't ++ * want to consume all kernel memory by them. As a compromise, just ++ * assign higher "seeks" value to d_cursor cache, so that it will be ++ * shrunk only if system is really tight on memory. ++ */ ++static struct shrinker d_cursor_shrinker = { ++ .count_objects = d_cursor_shrink_count, ++ .scan_objects = d_cursor_shrink_scan, ++ .seeks = DEFAULT_SEEKS << 3 ++}; ++ ++/** ++ * reiser4_init_d_cursor - create d_cursor cache ++ * ++ * Initializes slab cache of d_cursors. It is part of reiser4 module ++ * initialization. ++ */ ++int reiser4_init_d_cursor(void) ++{ ++ d_cursor_cache = kmem_cache_create("d_cursor", sizeof(dir_cursor), 0, ++ SLAB_HWCACHE_ALIGN, NULL); ++ if (d_cursor_cache == NULL) ++ return RETERR(-ENOMEM); ++ ++ register_shrinker(&d_cursor_shrinker); ++ return 0; ++} ++ ++/** ++ * reiser4_done_d_cursor - delete d_cursor cache and d_cursor shrinker ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void reiser4_done_d_cursor(void) ++{ ++ unregister_shrinker(&d_cursor_shrinker); ++ ++ destroy_reiser4_cache(&d_cursor_cache); ++} ++ ++#define D_CURSOR_TABLE_SIZE (256) ++ ++static inline unsigned long ++d_cursor_hash(d_cursor_hash_table * table, const struct d_cursor_key *key) ++{ ++ assert("nikita-3555", IS_POW(D_CURSOR_TABLE_SIZE)); ++ return (key->oid + key->cid) & (D_CURSOR_TABLE_SIZE - 1); ++} ++ ++static inline int d_cursor_eq(const struct d_cursor_key *k1, ++ const struct d_cursor_key *k2) ++{ ++ return k1->cid == k2->cid && k1->oid == k2->oid; ++} ++ ++/* ++ * define functions to manipulate reiser4 super block's hash table of ++ * dir_cursors ++ */ ++#define KMALLOC(size) kmalloc((size), reiser4_ctx_gfp_mask_get()) ++#define KFREE(ptr, size) kfree(ptr) ++TYPE_SAFE_HASH_DEFINE(d_cursor, ++ dir_cursor, ++ struct d_cursor_key, ++ key, hash, d_cursor_hash, d_cursor_eq); ++#undef KFREE ++#undef KMALLOC ++ ++/** ++ * reiser4_init_super_d_info - initialize per-super-block d_cursor resources ++ * @super: super block to initialize ++ * ++ * Initializes per-super-block d_cursor's hash table and radix tree. It is part ++ * of mount. ++ */ ++int reiser4_init_super_d_info(struct super_block *super) ++{ ++ struct d_cursor_info *p; ++ ++ p = &get_super_private(super)->d_info; ++ ++ INIT_RADIX_TREE(&p->tree, reiser4_ctx_gfp_mask_get()); ++ return d_cursor_hash_init(&p->table, D_CURSOR_TABLE_SIZE); ++} ++ ++/** ++ * reiser4_done_super_d_info - release per-super-block d_cursor resources ++ * @super: super block being umounted ++ * ++ * It is called on umount. Kills all directory cursors attached to suoer block. ++ */ ++void reiser4_done_super_d_info(struct super_block *super) ++{ ++ struct d_cursor_info *d_info; ++ dir_cursor *cursor, *next; ++ ++ d_info = &get_super_private(super)->d_info; ++ for_all_in_htable(&d_info->table, d_cursor, cursor, next) ++ kill_cursor(cursor); ++ ++ BUG_ON(!radix_tree_empty(&d_info->tree)); ++ d_cursor_hash_done(&d_info->table); ++} ++ ++/** ++ * kill_cursor - free dir_cursor and reiser4_file_fsdata attached to it ++ * @cursor: cursor to free ++ * ++ * Removes reiser4_file_fsdata attached to @cursor from readdir list of ++ * reiser4_inode, frees that reiser4_file_fsdata. Removes @cursor from from ++ * indices, hash table, list of unused cursors and frees it. ++ */ ++static void kill_cursor(dir_cursor *cursor) ++{ ++ unsigned long index; ++ ++ assert("nikita-3566", cursor->ref == 0); ++ assert("nikita-3572", cursor->fsdata != NULL); ++ ++ index = (unsigned long)cursor->key.oid; ++ list_del_init(&cursor->fsdata->dir.linkage); ++ free_fsdata(cursor->fsdata); ++ cursor->fsdata = NULL; ++ ++ if (list_empty_careful(&cursor->list)) ++ /* this is last cursor for a file. Kill radix-tree entry */ ++ radix_tree_delete(&cursor->info->tree, index); ++ else { ++ void **slot; ++ ++ /* ++ * there are other cursors for the same oid. ++ */ ++ ++ /* ++ * if radix tree point to the cursor being removed, re-target ++ * radix tree slot to the next cursor in the (non-empty as was ++ * checked above) element of the circular list of all cursors ++ * for this oid. ++ */ ++ slot = radix_tree_lookup_slot(&cursor->info->tree, index); ++ assert("nikita-3571", *slot != NULL); ++ if (*slot == cursor) ++ *slot = list_entry(cursor->list.next, dir_cursor, list); ++ /* remove cursor from circular list */ ++ list_del_init(&cursor->list); ++ } ++ /* remove cursor from the list of unused cursors */ ++ list_del_init(&cursor->alist); ++ /* remove cursor from the hash table */ ++ d_cursor_hash_remove(&cursor->info->table, cursor); ++ /* and free it */ ++ kmem_cache_free(d_cursor_cache, cursor); ++ --d_cursor_unused; ++} ++ ++/* possible actions that can be performed on all cursors for the given file */ ++enum cursor_action { ++ /* ++ * load all detached state: this is called when stat-data is loaded ++ * from the disk to recover information about all pending readdirs ++ */ ++ CURSOR_LOAD, ++ /* ++ * detach all state from inode, leaving it in the cache. This is called ++ * when inode is removed form the memory by memory pressure ++ */ ++ CURSOR_DISPOSE, ++ /* ++ * detach cursors from the inode, and free them. This is called when ++ * inode is destroyed ++ */ ++ CURSOR_KILL ++}; ++ ++/* ++ * return d_cursor data for the file system @inode is in. ++ */ ++static inline struct d_cursor_info *d_info(struct inode *inode) ++{ ++ return &get_super_private(inode->i_sb)->d_info; ++} ++ ++/* ++ * lookup d_cursor in the per-super-block radix tree. ++ */ ++static inline dir_cursor *lookup(struct d_cursor_info *info, ++ unsigned long index) ++{ ++ return (dir_cursor *) radix_tree_lookup(&info->tree, index); ++} ++ ++/* ++ * attach @cursor to the radix tree. There may be multiple cursors for the ++ * same oid, they are chained into circular list. ++ */ ++static void bind_cursor(dir_cursor * cursor, unsigned long index) ++{ ++ dir_cursor *head; ++ ++ head = lookup(cursor->info, index); ++ if (head == NULL) { ++ /* this is the first cursor for this index */ ++ INIT_LIST_HEAD(&cursor->list); ++ radix_tree_insert(&cursor->info->tree, index, cursor); ++ } else { ++ /* some cursor already exists. Chain ours */ ++ list_add(&cursor->list, &head->list); ++ } ++} ++ ++/* ++ * detach fsdata (if detachable) from file descriptor, and put cursor on the ++ * "unused" list. Called when file descriptor is not longer in active use. ++ */ ++static void clean_fsdata(struct file *file) ++{ ++ dir_cursor *cursor; ++ reiser4_file_fsdata *fsdata; ++ ++ assert("nikita-3570", file_is_stateless(file)); ++ ++ fsdata = (reiser4_file_fsdata *) file->private_data; ++ if (fsdata != NULL) { ++ cursor = fsdata->cursor; ++ if (cursor != NULL) { ++ spin_lock(&d_c_lock); ++ --cursor->ref; ++ if (cursor->ref == 0) { ++ list_add_tail(&cursor->alist, &cursor_cache); ++ ++d_cursor_unused; ++ } ++ spin_unlock(&d_c_lock); ++ file->private_data = NULL; ++ } ++ } ++} ++ ++/* ++ * global counter used to generate "client ids". These ids are encoded into ++ * high bits of fpos. ++ */ ++static __u32 cid_counter = 0; ++#define CID_SHIFT (20) ++#define CID_MASK (0xfffffull) ++ ++static void free_file_fsdata_nolock(struct file *); ++ ++/** ++ * insert_cursor - allocate file_fsdata, insert cursor to tree and hash table ++ * @cursor: ++ * @file: ++ * @inode: ++ * ++ * Allocates reiser4_file_fsdata, attaches it to @cursor, inserts cursor to ++ * reiser4 super block's hash table and radix tree. ++ add detachable readdir ++ * state to the @f ++ */ ++static int insert_cursor(dir_cursor *cursor, struct file *file, loff_t *fpos, ++ struct inode *inode) ++{ ++ int result; ++ reiser4_file_fsdata *fsdata; ++ ++ memset(cursor, 0, sizeof *cursor); ++ ++ /* this is either first call to readdir, or rewind. Anyway, create new ++ * cursor. */ ++ fsdata = create_fsdata(NULL); ++ if (fsdata != NULL) { ++ result = radix_tree_preload(reiser4_ctx_gfp_mask_get()); ++ if (result == 0) { ++ struct d_cursor_info *info; ++ oid_t oid; ++ ++ info = d_info(inode); ++ oid = get_inode_oid(inode); ++ /* cid occupies higher 12 bits of f->f_pos. Don't ++ * allow it to become negative: this confuses ++ * nfsd_readdir() */ ++ cursor->key.cid = (++cid_counter) & 0x7ff; ++ cursor->key.oid = oid; ++ cursor->fsdata = fsdata; ++ cursor->info = info; ++ cursor->ref = 1; ++ ++ spin_lock_inode(inode); ++ /* install cursor as @f's private_data, discarding old ++ * one if necessary */ ++#if REISER4_DEBUG ++ if (file->private_data) ++ warning("", "file has fsdata already"); ++#endif ++ clean_fsdata(file); ++ free_file_fsdata_nolock(file); ++ file->private_data = fsdata; ++ fsdata->cursor = cursor; ++ spin_unlock_inode(inode); ++ spin_lock(&d_c_lock); ++ /* insert cursor into hash table */ ++ d_cursor_hash_insert(&info->table, cursor); ++ /* and chain it into radix-tree */ ++ bind_cursor(cursor, (unsigned long)oid); ++ spin_unlock(&d_c_lock); ++ radix_tree_preload_end(); ++ *fpos = ((__u64) cursor->key.cid) << CID_SHIFT; ++ } ++ } else ++ result = RETERR(-ENOMEM); ++ return result; ++} ++ ++/** ++ * process_cursors - do action on each cursor attached to inode ++ * @inode: ++ * @act: action to do ++ * ++ * Finds all cursors of @inode in reiser4's super block radix tree of cursors ++ * and performs action specified by @act on each of cursors. ++ */ ++static void process_cursors(struct inode *inode, enum cursor_action act) ++{ ++ oid_t oid; ++ dir_cursor *start; ++ struct list_head *head; ++ reiser4_context *ctx; ++ struct d_cursor_info *info; ++ ++ /* this can be called by ++ * ++ * kswapd->...->prune_icache->..reiser4_destroy_inode ++ * ++ * without reiser4_context ++ */ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ warning("vs-23", "failed to init context"); ++ return; ++ } ++ ++ assert("nikita-3558", inode != NULL); ++ ++ info = d_info(inode); ++ oid = get_inode_oid(inode); ++ spin_lock_inode(inode); ++ head = get_readdir_list(inode); ++ spin_lock(&d_c_lock); ++ /* find any cursor for this oid: reference to it is hanging of radix ++ * tree */ ++ start = lookup(info, (unsigned long)oid); ++ if (start != NULL) { ++ dir_cursor *scan; ++ reiser4_file_fsdata *fsdata; ++ ++ /* process circular list of cursors for this oid */ ++ scan = start; ++ do { ++ dir_cursor *next; ++ ++ next = list_entry(scan->list.next, dir_cursor, list); ++ fsdata = scan->fsdata; ++ assert("nikita-3557", fsdata != NULL); ++ if (scan->key.oid == oid) { ++ switch (act) { ++ case CURSOR_DISPOSE: ++ list_del_init(&fsdata->dir.linkage); ++ break; ++ case CURSOR_LOAD: ++ list_add(&fsdata->dir.linkage, head); ++ break; ++ case CURSOR_KILL: ++ kill_cursor(scan); ++ break; ++ } ++ } ++ if (scan == next) ++ /* last cursor was just killed */ ++ break; ++ scan = next; ++ } while (scan != start); ++ } ++ spin_unlock(&d_c_lock); ++ /* check that we killed 'em all */ ++ assert("nikita-3568", ++ ergo(act == CURSOR_KILL, ++ list_empty_careful(get_readdir_list(inode)))); ++ assert("nikita-3569", ++ ergo(act == CURSOR_KILL, lookup(info, oid) == NULL)); ++ spin_unlock_inode(inode); ++ reiser4_exit_context(ctx); ++} ++ ++/** ++ * reiser4_dispose_cursors - removes cursors from inode's list ++ * @inode: inode to dispose cursors of ++ * ++ * For each of cursors corresponding to @inode - removes reiser4_file_fsdata ++ * attached to cursor from inode's readdir list. This is called when inode is ++ * removed from the memory by memory pressure. ++ */ ++void reiser4_dispose_cursors(struct inode *inode) ++{ ++ process_cursors(inode, CURSOR_DISPOSE); ++} ++ ++/** ++ * reiser4_load_cursors - attach cursors to inode ++ * @inode: inode to load cursors to ++ * ++ * For each of cursors corresponding to @inode - attaches reiser4_file_fsdata ++ * attached to cursor to inode's readdir list. This is done when inode is ++ * loaded into memory. ++ */ ++void reiser4_load_cursors(struct inode *inode) ++{ ++ process_cursors(inode, CURSOR_LOAD); ++} ++ ++/** ++ * reiser4_kill_cursors - kill all inode cursors ++ * @inode: inode to kill cursors of ++ * ++ * Frees all cursors for this inode. This is called when inode is destroyed. ++ */ ++void reiser4_kill_cursors(struct inode *inode) ++{ ++ process_cursors(inode, CURSOR_KILL); ++} ++ ++/** ++ * file_is_stateless - ++ * @file: ++ * ++ * true, if file descriptor @f is created by NFS server by "demand" to serve ++ * one file system operation. This means that there may be "detached state" ++ * for underlying inode. ++ */ ++static int file_is_stateless(struct file *file) ++{ ++ return reiser4_get_dentry_fsdata(file->f_path.dentry)->stateless; ++} ++ ++/** ++ * reiser4_get_dir_fpos - ++ * @dir: ++ * @fpos: effective value of dir->f_pos ++ * ++ * Calculates ->fpos from user-supplied cookie. Normally it is dir->f_pos, but ++ * in the case of stateless directory operation (readdir-over-nfs), client id ++ * was encoded in the high bits of cookie and should me masked off. ++ */ ++loff_t reiser4_get_dir_fpos(struct file *dir, loff_t fpos) ++{ ++ if (file_is_stateless(dir)) ++ return fpos & CID_MASK; ++ else ++ return fpos; ++} ++ ++/** ++ * reiser4_attach_fsdata - try to attach fsdata ++ * @file: ++ * @fpos: effective value of @file->f_pos ++ * @inode: ++ * ++ * Finds or creates cursor for readdir-over-nfs. ++ */ ++int reiser4_attach_fsdata(struct file *file, loff_t *fpos, struct inode *inode) ++{ ++ loff_t pos; ++ int result; ++ dir_cursor *cursor; ++ ++ /* ++ * we are serialized by inode->i_mutex ++ */ ++ if (!file_is_stateless(file)) ++ return 0; ++ ++ pos = *fpos; ++ result = 0; ++ if (pos == 0) { ++ /* ++ * first call to readdir (or rewind to the beginning of ++ * directory) ++ */ ++ cursor = kmem_cache_alloc(d_cursor_cache, ++ reiser4_ctx_gfp_mask_get()); ++ if (cursor != NULL) ++ result = insert_cursor(cursor, file, fpos, inode); ++ else ++ result = RETERR(-ENOMEM); ++ } else { ++ /* try to find existing cursor */ ++ struct d_cursor_key key; ++ ++ key.cid = pos >> CID_SHIFT; ++ key.oid = get_inode_oid(inode); ++ spin_lock(&d_c_lock); ++ cursor = d_cursor_hash_find(&d_info(inode)->table, &key); ++ if (cursor != NULL) { ++ /* cursor was found */ ++ if (cursor->ref == 0) { ++ /* move it from unused list */ ++ list_del_init(&cursor->alist); ++ --d_cursor_unused; ++ } ++ ++cursor->ref; ++ } ++ spin_unlock(&d_c_lock); ++ if (cursor != NULL) { ++ spin_lock_inode(inode); ++ assert("nikita-3556", cursor->fsdata->back == NULL); ++ clean_fsdata(file); ++ free_file_fsdata_nolock(file); ++ file->private_data = cursor->fsdata; ++ spin_unlock_inode(inode); ++ } ++ } ++ return result; ++} ++ ++/** ++ * reiser4_detach_fsdata - ??? ++ * @file: ++ * ++ * detach fsdata, if necessary ++ */ ++void reiser4_detach_fsdata(struct file *file) ++{ ++ struct inode *inode; ++ ++ if (!file_is_stateless(file)) ++ return; ++ ++ inode = file_inode(file); ++ spin_lock_inode(inode); ++ clean_fsdata(file); ++ spin_unlock_inode(inode); ++} ++ ++/* slab for reiser4_dentry_fsdata */ ++static struct kmem_cache *dentry_fsdata_cache; ++ ++/** ++ * reiser4_init_dentry_fsdata - create cache of dentry_fsdata ++ * ++ * Initializes slab cache of structures attached to denty->d_fsdata. It is ++ * part of reiser4 module initialization. ++ */ ++int reiser4_init_dentry_fsdata(void) ++{ ++ dentry_fsdata_cache = kmem_cache_create("dentry_fsdata", ++ sizeof(struct reiser4_dentry_fsdata), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, ++ NULL); ++ if (dentry_fsdata_cache == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++/** ++ * reiser4_done_dentry_fsdata - delete cache of dentry_fsdata ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void reiser4_done_dentry_fsdata(void) ++{ ++ destroy_reiser4_cache(&dentry_fsdata_cache); ++} ++ ++/** ++ * reiser4_get_dentry_fsdata - get fs-specific dentry data ++ * @dentry: queried dentry ++ * ++ * Allocates if necessary and returns per-dentry data that we attach to each ++ * dentry. ++ */ ++struct reiser4_dentry_fsdata *reiser4_get_dentry_fsdata(struct dentry *dentry) ++{ ++ assert("nikita-1365", dentry != NULL); ++ ++ if (dentry->d_fsdata == NULL) { ++ dentry->d_fsdata = kmem_cache_alloc(dentry_fsdata_cache, ++ reiser4_ctx_gfp_mask_get()); ++ if (dentry->d_fsdata == NULL) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ memset(dentry->d_fsdata, 0, ++ sizeof(struct reiser4_dentry_fsdata)); ++ } ++ return dentry->d_fsdata; ++} ++ ++/** ++ * reiser4_free_dentry_fsdata - detach and free dentry_fsdata ++ * @dentry: dentry to free fsdata of ++ * ++ * Detaches and frees fs-specific dentry data ++ */ ++void reiser4_free_dentry_fsdata(struct dentry *dentry) ++{ ++ if (dentry->d_fsdata != NULL) { ++ kmem_cache_free(dentry_fsdata_cache, dentry->d_fsdata); ++ dentry->d_fsdata = NULL; ++ } ++} ++ ++/* slab for reiser4_file_fsdata */ ++static struct kmem_cache *file_fsdata_cache; ++ ++/** ++ * reiser4_init_file_fsdata - create cache of reiser4_file_fsdata ++ * ++ * Initializes slab cache of structures attached to file->private_data. It is ++ * part of reiser4 module initialization. ++ */ ++int reiser4_init_file_fsdata(void) ++{ ++ file_fsdata_cache = kmem_cache_create("file_fsdata", ++ sizeof(reiser4_file_fsdata), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ if (file_fsdata_cache == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++/** ++ * reiser4_done_file_fsdata - delete cache of reiser4_file_fsdata ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void reiser4_done_file_fsdata(void) ++{ ++ destroy_reiser4_cache(&file_fsdata_cache); ++} ++ ++/** ++ * create_fsdata - allocate and initialize reiser4_file_fsdata ++ * @file: what to create file_fsdata for, may be NULL ++ * ++ * Allocates and initializes reiser4_file_fsdata structure. ++ */ ++static reiser4_file_fsdata *create_fsdata(struct file *file) ++{ ++ reiser4_file_fsdata *fsdata; ++ ++ fsdata = kmem_cache_alloc(file_fsdata_cache, ++ reiser4_ctx_gfp_mask_get()); ++ if (fsdata != NULL) { ++ memset(fsdata, 0, sizeof *fsdata); ++ fsdata->back = file; ++ INIT_LIST_HEAD(&fsdata->dir.linkage); ++ } ++ return fsdata; ++} ++ ++/** ++ * free_fsdata - free reiser4_file_fsdata ++ * @fsdata: object to free ++ * ++ * Dual to create_fsdata(). Free reiser4_file_fsdata. ++ */ ++static void free_fsdata(reiser4_file_fsdata *fsdata) ++{ ++ BUG_ON(fsdata == NULL); ++ kmem_cache_free(file_fsdata_cache, fsdata); ++} ++ ++/** ++ * reiser4_get_file_fsdata - get fs-specific file data ++ * @file: queried file ++ * ++ * Returns fs-specific data of @file. If it is NULL, allocates it and attaches ++ * to @file. ++ */ ++reiser4_file_fsdata *reiser4_get_file_fsdata(struct file *file) ++{ ++ assert("nikita-1603", file != NULL); ++ ++ if (file->private_data == NULL) { ++ reiser4_file_fsdata *fsdata; ++ struct inode *inode; ++ ++ fsdata = create_fsdata(file); ++ if (fsdata == NULL) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ ++ inode = file_inode(file); ++ spin_lock_inode(inode); ++ if (file->private_data == NULL) { ++ file->private_data = fsdata; ++ fsdata = NULL; ++ } ++ spin_unlock_inode(inode); ++ if (fsdata != NULL) ++ /* other thread initialized ->fsdata */ ++ kmem_cache_free(file_fsdata_cache, fsdata); ++ } ++ assert("nikita-2665", file->private_data != NULL); ++ return file->private_data; ++} ++ ++/** ++ * free_file_fsdata_nolock - detach and free reiser4_file_fsdata ++ * @file: ++ * ++ * Detaches reiser4_file_fsdata from @file, removes reiser4_file_fsdata from ++ * readdir list, frees if it is not linked to d_cursor object. ++ */ ++static void free_file_fsdata_nolock(struct file *file) ++{ ++ reiser4_file_fsdata *fsdata; ++ ++ assert("", spin_inode_is_locked(file_inode(file))); ++ fsdata = file->private_data; ++ if (fsdata != NULL) { ++ list_del_init(&fsdata->dir.linkage); ++ if (fsdata->cursor == NULL) ++ free_fsdata(fsdata); ++ } ++ file->private_data = NULL; ++} ++ ++/** ++ * reiser4_free_file_fsdata - detach from struct file and free reiser4_file_fsdata ++ * @file: ++ * ++ * Spinlocks inode and calls free_file_fsdata_nolock to do the work. ++ */ ++void reiser4_free_file_fsdata(struct file *file) ++{ ++ spin_lock_inode(file_inode(file)); ++ free_file_fsdata_nolock(file); ++ spin_unlock_inode(file_inode(file)); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/fsdata.h linux-5.10.2/fs/reiser4/fsdata.h +--- linux-5.10.2.orig/fs/reiser4/fsdata.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/fsdata.h 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,203 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#if !defined(__REISER4_FSDATA_H__) ++#define __REISER4_FSDATA_H__ ++ ++#include "debug.h" ++#include "kassign.h" ++#include "seal.h" ++#include "type_safe_hash.h" ++#include "plugin/file/file.h" ++#include "readahead.h" ++ ++/* ++ * comment about reiser4_dentry_fsdata ++ * ++ * ++ */ ++ ++/* ++ * locking: fields of per file descriptor readdir_pos and ->f_pos are ++ * protected by ->i_mutex on inode. Under this lock following invariant ++ * holds: ++ * ++ * file descriptor is "looking" at the entry_no-th directory entry from ++ * the beginning of directory. This entry has key dir_entry_key and is ++ * pos-th entry with duplicate-key sequence. ++ * ++ */ ++ ++/* logical position within directory */ ++struct dir_pos { ++ /* key of directory entry (actually, part of a key sufficient to ++ identify directory entry) */ ++ de_id dir_entry_key; ++ /* ordinal number of directory entry among all entries with the same ++ key. (Starting from 0.) */ ++ unsigned pos; ++}; ++ ++struct readdir_pos { ++ /* f_pos corresponding to this readdir position */ ++ __u64 fpos; ++ /* logical position within directory */ ++ struct dir_pos position; ++ /* logical number of directory entry within ++ directory */ ++ __u64 entry_no; ++}; ++ ++/* ++ * this is used to speed up lookups for directory entry: on initial call to ++ * ->lookup() seal and coord of directory entry (if found, that is) are stored ++ * in struct dentry and reused later to avoid tree traversals. ++ */ ++struct de_location { ++ /* seal covering directory entry */ ++ seal_t entry_seal; ++ /* coord of directory entry */ ++ coord_t entry_coord; ++ /* ordinal number of directory entry among all entries with the same ++ key. (Starting from 0.) */ ++ int pos; ++}; ++ ++/** ++ * reiser4_dentry_fsdata - reiser4-specific data attached to dentries ++ * ++ * This is allocated dynamically and released in d_op->d_release() ++ * ++ * Currently it only contains cached location (hint) of directory entry, but ++ * it is expected that other information will be accumulated here. ++ */ ++struct reiser4_dentry_fsdata { ++ /* ++ * here will go fields filled by ->lookup() to speedup next ++ * create/unlink, like blocknr of znode with stat-data, or key of ++ * stat-data. ++ */ ++ struct de_location dec; ++ int stateless; /* created through reiser4_decode_fh, needs ++ * special treatment in readdir. */ ++}; ++ ++extern int reiser4_init_dentry_fsdata(void); ++extern void reiser4_done_dentry_fsdata(void); ++extern struct reiser4_dentry_fsdata *reiser4_get_dentry_fsdata(struct dentry *); ++extern void reiser4_free_dentry_fsdata(struct dentry *dentry); ++ ++/** ++ * reiser4_file_fsdata - reiser4-specific data attached to file->private_data ++ * ++ * This is allocated dynamically and released in inode->i_fop->release ++ */ ++typedef struct reiser4_file_fsdata { ++ /* ++ * pointer back to the struct file which this reiser4_file_fsdata is ++ * part of ++ */ ++ struct file *back; ++ /* detached cursor for stateless readdir. */ ++ struct dir_cursor *cursor; ++ /* ++ * We need both directory and regular file parts here, because there ++ * are file system objects that are files and directories. ++ */ ++ struct { ++ /* ++ * position in directory. It is updated each time directory is ++ * modified ++ */ ++ struct readdir_pos readdir; ++ /* head of this list is reiser4_inode->lists.readdir_list */ ++ struct list_head linkage; ++ } dir; ++ /* hints to speed up operations with regular files: read and write. */ ++ struct { ++ hint_t hint; ++ } reg; ++} reiser4_file_fsdata; ++ ++extern int reiser4_init_file_fsdata(void); ++extern void reiser4_done_file_fsdata(void); ++extern reiser4_file_fsdata *reiser4_get_file_fsdata(struct file *); ++extern void reiser4_free_file_fsdata(struct file *); ++ ++/* ++ * d_cursor is reiser4_file_fsdata not attached to struct file. d_cursors are ++ * used to address problem reiser4 has with readdir accesses via NFS. See ++ * plugin/file_ops_readdir.c for more details. ++ */ ++struct d_cursor_key{ ++ __u16 cid; ++ __u64 oid; ++}; ++ ++/* ++ * define structures d_cursor_hash_table d_cursor_hash_link which are used to ++ * maintain hash table of dir_cursor-s in reiser4's super block ++ */ ++typedef struct dir_cursor dir_cursor; ++TYPE_SAFE_HASH_DECLARE(d_cursor, dir_cursor); ++ ++struct dir_cursor { ++ int ref; ++ reiser4_file_fsdata *fsdata; ++ ++ /* link to reiser4 super block hash table of cursors */ ++ d_cursor_hash_link hash; ++ ++ /* ++ * this is to link cursors to reiser4 super block's radix tree of ++ * cursors if there are more than one cursor of the same objectid ++ */ ++ struct list_head list; ++ struct d_cursor_key key; ++ struct d_cursor_info *info; ++ /* list of unused cursors */ ++ struct list_head alist; ++}; ++ ++extern int reiser4_init_d_cursor(void); ++extern void reiser4_done_d_cursor(void); ++ ++extern int reiser4_init_super_d_info(struct super_block *); ++extern void reiser4_done_super_d_info(struct super_block *); ++ ++extern loff_t reiser4_get_dir_fpos(struct file *, loff_t); ++extern int reiser4_attach_fsdata(struct file *, loff_t *, struct inode *); ++extern void reiser4_detach_fsdata(struct file *); ++ ++/* these are needed for "stateless" readdir. See plugin/file_ops_readdir.c for ++ more details */ ++void reiser4_dispose_cursors(struct inode *inode); ++void reiser4_load_cursors(struct inode *inode); ++void reiser4_kill_cursors(struct inode *inode); ++void reiser4_adjust_dir_file(struct inode *dir, const struct dentry *de, ++ int offset, int adj); ++ ++/* ++ * this structure is embedded to reise4_super_info_data. It maintains d_cursors ++ * (detached readdir state). See plugin/file_ops_readdir.c for more details. ++ */ ++struct d_cursor_info { ++ d_cursor_hash_table table; ++ struct radix_tree_root tree; ++}; ++ ++/* spinlock protecting readdir cursors */ ++extern spinlock_t d_c_lock; ++ ++/* __REISER4_FSDATA_H__ */ ++#endif ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/init_super.c linux-5.10.2/fs/reiser4/init_super.c +--- linux-5.10.2.orig/fs/reiser4/init_super.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/init_super.c 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,805 @@ ++/* Copyright by Hans Reiser, 2003 */ ++ ++#include "super.h" ++#include "inode.h" ++#include "plugin/plugin_set.h" ++ ++#include ++ ++/** ++ * init_fs_info - allocate reiser4 specific super block ++ * @super: super block of filesystem ++ * ++ * Allocates and initialize reiser4_super_info_data, attaches it to ++ * super->s_fs_info, initializes structures maintaining d_cursor-s. ++ */ ++int reiser4_init_fs_info(struct super_block *super) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = kzalloc(sizeof(reiser4_super_info_data), ++ reiser4_ctx_gfp_mask_get()); ++ if (!sbinfo) ++ return RETERR(-ENOMEM); ++ ++ super->s_fs_info = sbinfo; ++ super->s_op = NULL; ++ ++ ON_DEBUG(INIT_LIST_HEAD(&sbinfo->all_jnodes)); ++ ON_DEBUG(spin_lock_init(&sbinfo->all_guard)); ++ ++ mutex_init(&sbinfo->delete_mutex); ++ spin_lock_init(&(sbinfo->guard)); ++ ++ /* initialize per-super-block d_cursor resources */ ++ reiser4_init_super_d_info(super); ++ ++ /* initialize global tree lock */ ++ rwlock_init(&(sbinfo->tree_lock)); ++ ++ return 0; ++} ++ ++/** ++ * Release reiser4 specific super block ++ * ++ * release per-super-block d_cursor resources ++ * free reiser4_super_info_data ++ */ ++void reiser4_done_fs_info(struct super_block *super) ++{ ++ assert("zam-990", super->s_fs_info != NULL); ++ ++ reiser4_done_super_d_info(super); ++ kfree(super->s_fs_info); ++ super->s_fs_info = NULL; ++ super->s_op = NULL; ++} ++ ++/* type of option parseable by parse_option() */ ++typedef enum { ++ /* value of option is arbitrary string */ ++ OPT_STRING, ++ ++ /* ++ * option specifies bit in a bitmask. When option is set - bit in ++ * sbinfo->fs_flags is set. Examples are bsdgroups, 32bittimes, mtflush, ++ * dont_load_bitmap, atomic_write. ++ */ ++ OPT_BIT, ++ ++ /* ++ * value of option should conform to sprintf() format. Examples are ++ * tmgr.atom_max_size=N, tmgr.atom_max_age=N ++ */ ++ OPT_FORMAT, ++ ++ /* ++ * option can take one of predefined values. Example is onerror=panic or ++ * onerror=remount-ro ++ */ ++ OPT_ONEOF, ++ ++ /* ++ * option take one of txmod plugin labels. ++ * Example is "txmod=journal" or "txmod=wa" ++ */ ++ OPT_TXMOD, ++} opt_type_t; ++ ++#if 0 ++struct opt_bitmask_bit { ++ const char *bit_name; ++ int bit_nr; ++}; ++#endif ++ ++#define MAX_ONEOF_LIST 10 ++ ++/* description of option parseable by parse_option() */ ++struct opt_desc { ++ /* option name. ++ ++ parsed portion of string has a form "name=value". ++ */ ++ const char *name; ++ /* type of option */ ++ opt_type_t type; ++ union { ++ /* where to store value of string option (type == OPT_STRING) */ ++ char **string; ++ /* description of bits for bit option (type == OPT_BIT) */ ++ struct { ++ int nr; ++ void *addr; ++ } bit; ++ /* description of format and targets for format option (type ++ == OPT_FORMAT) */ ++ struct { ++ const char *format; ++ int nr_args; ++ void *arg1; ++ void *arg2; ++ void *arg3; ++ void *arg4; ++ } f; ++ struct { ++ int *result; ++ const char *list[MAX_ONEOF_LIST]; ++ } oneof; ++ struct { ++ reiser4_txmod_id *result; ++ } txmod; ++ struct { ++ void *addr; ++ int nr_bits; ++ /* struct opt_bitmask_bit *bits; */ ++ } bitmask; ++ } u; ++}; ++ ++/** ++ * parse_option - parse one option ++ * @opt_strin: starting point of parsing ++ * @opt: option description ++ * ++ * foo=bar, ++ * ^ ^ ^ ++ * | | +-- replaced to '\0' ++ * | +-- val_start ++ * +-- opt_string ++ * Figures out option type and handles option correspondingly. ++ */ ++static int parse_option(char *opt_string, struct opt_desc *opt) ++{ ++ char *val_start; ++ int result; ++ const char *err_msg; ++ ++ /* NOTE-NIKITA think about using lib/cmdline.c functions here. */ ++ ++ val_start = strchr(opt_string, '='); ++ if (val_start != NULL) { ++ *val_start = '\0'; ++ ++val_start; ++ } ++ ++ err_msg = NULL; ++ result = 0; ++ switch (opt->type) { ++ case OPT_STRING: ++ if (val_start == NULL) { ++ err_msg = "String arg missing"; ++ result = RETERR(-EINVAL); ++ } else ++ *opt->u.string = val_start; ++ break; ++ case OPT_BIT: ++ if (val_start != NULL) ++ err_msg = "Value ignored"; ++ else ++ set_bit(opt->u.bit.nr, opt->u.bit.addr); ++ break; ++ case OPT_FORMAT: ++ if (val_start == NULL) { ++ err_msg = "Formatted arg missing"; ++ result = RETERR(-EINVAL); ++ break; ++ } ++ if (sscanf(val_start, opt->u.f.format, ++ opt->u.f.arg1, opt->u.f.arg2, opt->u.f.arg3, ++ opt->u.f.arg4) != opt->u.f.nr_args) { ++ err_msg = "Wrong conversion"; ++ result = RETERR(-EINVAL); ++ } ++ break; ++ case OPT_ONEOF: ++ { ++ int i = 0; ++ ++ if (val_start == NULL) { ++ err_msg = "Value is missing"; ++ result = RETERR(-EINVAL); ++ break; ++ } ++ err_msg = "Wrong option value"; ++ result = RETERR(-EINVAL); ++ while (opt->u.oneof.list[i]) { ++ if (!strcmp(opt->u.oneof.list[i], val_start)) { ++ result = 0; ++ err_msg = NULL; ++ *opt->u.oneof.result = i; ++ break; ++ } ++ i++; ++ } ++ break; ++ } ++ break; ++ case OPT_TXMOD: ++ { ++ reiser4_txmod_id i = 0; ++ ++ if (val_start == NULL) { ++ err_msg = "Value is missing"; ++ result = RETERR(-EINVAL); ++ break; ++ } ++ err_msg = "Wrong option value"; ++ result = RETERR(-EINVAL); ++ while (i < LAST_TXMOD_ID) { ++ if (!strcmp(txmod_plugins[i].h.label, ++ val_start)) { ++ result = 0; ++ err_msg = NULL; ++ *opt->u.txmod.result = i; ++ break; ++ } ++ i++; ++ } ++ break; ++ } ++ default: ++ wrong_return_value("nikita-2100", "opt -> type"); ++ break; ++ } ++ if (err_msg != NULL) { ++ warning("nikita-2496", "%s when parsing option \"%s%s%s\"", ++ err_msg, opt->name, val_start ? "=" : "", ++ val_start ? : ""); ++ } ++ return result; ++} ++ ++/** ++ * parse_options - parse reiser4 mount options ++ * @opt_string: starting point ++ * @opts: array of option description ++ * @nr_opts: number of elements in @opts ++ * ++ * Parses comma separated list of reiser4 mount options. ++ */ ++static int parse_options(char *opt_string, struct opt_desc *opts, int nr_opts) ++{ ++ int result; ++ ++ result = 0; ++ while ((result == 0) && opt_string && *opt_string) { ++ int j; ++ char *next; ++ ++ next = strchr(opt_string, ','); ++ if (next != NULL) { ++ *next = '\0'; ++ ++next; ++ } ++ for (j = 0; j < nr_opts; ++j) { ++ if (!strncmp(opt_string, opts[j].name, ++ strlen(opts[j].name))) { ++ result = parse_option(opt_string, &opts[j]); ++ break; ++ } ++ } ++ if (j == nr_opts) { ++ warning("nikita-2307", "Unrecognized option: \"%s\"", ++ opt_string); ++ /* traditionally, -EINVAL is returned on wrong mount ++ option */ ++ result = RETERR(-EINVAL); ++ } ++ opt_string = next; ++ } ++ return result; ++} ++ ++#define NUM_OPT(label, fmt, addr) \ ++ { \ ++ .name = (label), \ ++ .type = OPT_FORMAT, \ ++ .u = { \ ++ .f = { \ ++ .format = (fmt), \ ++ .nr_args = 1, \ ++ .arg1 = (addr), \ ++ .arg2 = NULL, \ ++ .arg3 = NULL, \ ++ .arg4 = NULL \ ++ } \ ++ } \ ++ } ++ ++#define SB_FIELD_OPT(field, fmt) NUM_OPT(#field, fmt, &sbinfo->field) ++ ++#define BIT_OPT(label, bitnr) \ ++ { \ ++ .name = label, \ ++ .type = OPT_BIT, \ ++ .u = { \ ++ .bit = { \ ++ .nr = bitnr, \ ++ .addr = &sbinfo->fs_flags \ ++ } \ ++ } \ ++ } ++ ++#define MAX_NR_OPTIONS (30) ++ ++#if REISER4_DEBUG ++# define OPT_ARRAY_CHECK(opt, array) \ ++ if ((opt) > (array) + MAX_NR_OPTIONS) { \ ++ warning("zam-1046", "opt array is overloaded"); break; \ ++ } ++#else ++# define OPT_ARRAY_CHECK(opt, array) noop ++#endif ++ ++#define PUSH_OPT(opt, array, ...) \ ++do { \ ++ struct opt_desc o = __VA_ARGS__; \ ++ OPT_ARRAY_CHECK(opt, array); \ ++ *(opt) ++ = o; \ ++} while (0) ++ ++static noinline void push_sb_field_opts(struct opt_desc **p, ++ struct opt_desc *opts, ++ reiser4_super_info_data *sbinfo) ++{ ++#define PUSH_SB_FIELD_OPT(field, format) \ ++ PUSH_OPT(*p, opts, SB_FIELD_OPT(field, format)) ++ /* ++ * tmgr.atom_max_size=N ++ * Atoms containing more than N blocks will be forced to commit. N is ++ * decimal. ++ */ ++ PUSH_SB_FIELD_OPT(tmgr.atom_max_size, "%u"); ++ /* ++ * tmgr.atom_max_age=N ++ * Atoms older than N seconds will be forced to commit. N is decimal. ++ */ ++ PUSH_SB_FIELD_OPT(tmgr.atom_max_age, "%u"); ++ /* ++ * tmgr.atom_min_size=N ++ * In committing an atom to free dirty pages, force the atom less than ++ * N in size to fuse with another one. ++ */ ++ PUSH_SB_FIELD_OPT(tmgr.atom_min_size, "%u"); ++ /* ++ * tmgr.atom_max_flushers=N ++ * limit of concurrent flushers for one atom. 0 means no limit. ++ */ ++ PUSH_SB_FIELD_OPT(tmgr.atom_max_flushers, "%u"); ++ /* ++ * tree.cbk_cache_slots=N ++ * Number of slots in the cbk cache. ++ */ ++ //PUSH_SB_FIELD_OPT(tree.cbk_cache.nr_slots, "%u"); ++ /* ++ * If flush finds more than FLUSH_RELOCATE_THRESHOLD adjacent dirty ++ * leaf-level blocks it will force them to be relocated. ++ */ ++ //PUSH_SB_FIELD_OPT(flush.relocate_threshold, "%u"); ++ /* ++ * If flush finds can find a block allocation closer than at most ++ * FLUSH_RELOCATE_DISTANCE from the preceder it will relocate to that ++ * position. ++ */ ++ //PUSH_SB_FIELD_OPT(flush.relocate_distance, "%u"); ++ /* ++ * If we have written this much or more blocks before encountering busy ++ * jnode in flush list - abort flushing hoping that next time we get ++ * called this jnode will be clean already, and we will save some ++ * seeks. ++ */ ++ //PUSH_SB_FIELD_OPT(flush.written_threshold, "%u"); ++ /* The maximum number of nodes to scan left on a level during flush. */ ++ //PUSH_SB_FIELD_OPT(flush.scan_maxnodes, "%u"); ++ /* preferred IO size */ ++ PUSH_SB_FIELD_OPT(optimal_io_size, "%u"); ++ /* carry flags used for insertion of new nodes */ ++ //PUSH_SB_FIELD_OPT(tree.carry.new_node_flags, "%u"); ++ /* carry flags used for insertion of new extents */ ++ //PUSH_SB_FIELD_OPT(tree.carry.new_extent_flags, "%u"); ++ /* carry flags used for paste operations */ ++ //PUSH_SB_FIELD_OPT(tree.carry.paste_flags, "%u"); ++ /* carry flags used for insert operations */ ++ //PUSH_SB_FIELD_OPT(tree.carry.insert_flags, "%u"); ++ ++#ifdef CONFIG_REISER4_BADBLOCKS ++ /* ++ * Alternative master superblock location in case if it's original ++ * location is not writeable/accessable. This is offset in BYTES. ++ */ ++ PUSH_SB_FIELD_OPT(altsuper, "%lu"); ++#endif ++} ++ ++/** ++ * reiser4_init_super_data - initialize reiser4 private super block ++ * @super: super block to initialize ++ * @opt_string: list of reiser4 mount options ++ * ++ * Sets various reiser4 parameters to default values. Parses mount options and ++ * overwrites default settings. ++ */ ++int reiser4_init_super_data(struct super_block *super, char *opt_string) ++{ ++ int result; ++ struct opt_desc *opts, *p; ++ reiser4_super_info_data *sbinfo = get_super_private(super); ++ ++ /* initialize super, export, dentry operations */ ++ sbinfo->ops.super = reiser4_super_operations; ++ sbinfo->ops.export = reiser4_export_operations; ++ sbinfo->ops.dentry = reiser4_dentry_operations; ++ super->s_op = &sbinfo->ops.super; ++ super->s_export_op = &sbinfo->ops.export; ++ ++ /* initialize transaction manager parameters to default values */ ++ sbinfo->tmgr.atom_max_size = totalram_pages() / 4; ++ sbinfo->tmgr.atom_max_age = REISER4_ATOM_MAX_AGE / HZ; ++ sbinfo->tmgr.atom_min_size = 256; ++ sbinfo->tmgr.atom_max_flushers = ATOM_MAX_FLUSHERS; ++ ++ sbinfo->optimal_io_size = REISER4_OPTIMAL_IO_SIZE; ++ ++ /* initialize default readahead params */ ++ sbinfo->ra_params.max = totalram_pages() / 4; ++ sbinfo->ra_params.flags = 0; ++ ++ /* hard links for directories are not supported */ ++ sbinfo->fs_flags |= (1 << REISER4_ADG); ++ ++ /* allocate memory for structure describing reiser4 mount options */ ++ opts = kmalloc(sizeof(struct opt_desc) * MAX_NR_OPTIONS, ++ reiser4_ctx_gfp_mask_get()); ++ if (opts == NULL) ++ return RETERR(-ENOMEM); ++ ++ /* initialize structure describing reiser4 mount options */ ++ p = opts; ++ ++ push_sb_field_opts(&p, opts, sbinfo); ++ /* turn on BSD-style gid assignment */ ++ ++#define PUSH_BIT_OPT(name, bit) \ ++ PUSH_OPT(p, opts, BIT_OPT(name, bit)) ++ ++ PUSH_BIT_OPT("bsdgroups", REISER4_BSD_GID); ++ /* turn on 32 bit times */ ++ PUSH_BIT_OPT("32bittimes", REISER4_32_BIT_TIMES); ++ /* ++ * Don't load all bitmap blocks at mount time, it is useful for ++ * machines with tiny RAM and large disks. ++ */ ++ PUSH_BIT_OPT("dont_load_bitmap", REISER4_DONT_LOAD_BITMAP); ++ /* disable transaction commits during write() */ ++ PUSH_BIT_OPT("atomic_write", REISER4_ATOMIC_WRITE); ++ /* enable issuing of discard requests */ ++ PUSH_BIT_OPT("discard", REISER4_DISCARD); ++ /* disable hole punching at flush time */ ++ PUSH_BIT_OPT("dont_punch_holes", REISER4_DONT_PUNCH_HOLES); ++ ++ PUSH_OPT(p, opts, ++ { ++ /* ++ * tree traversal readahead parameters: ++ * -o readahead:MAXNUM:FLAGS ++ * MAXNUM - max number fo nodes to request readahead for: -1UL ++ * will set it to max_sane_readahead() ++ * FLAGS - combination of bits: RA_ADJCENT_ONLY, RA_ALL_LEVELS, ++ * CONTINUE_ON_PRESENT ++ */ ++ .name = "readahead", ++ .type = OPT_FORMAT, ++ .u = { ++ .f = { ++ .format = "%u:%u", ++ .nr_args = 2, ++ .arg1 = &sbinfo->ra_params.max, ++ .arg2 = &sbinfo->ra_params.flags, ++ .arg3 = NULL, ++ .arg4 = NULL ++ } ++ } ++ } ++ ); ++ ++ /* What to do in case of fs error */ ++ PUSH_OPT(p, opts, ++ { ++ .name = "onerror", ++ .type = OPT_ONEOF, ++ .u = { ++ .oneof = { ++ .result = &sbinfo->onerror, ++ .list = { ++ "remount-ro", "panic", NULL ++ }, ++ } ++ } ++ } ++ ); ++#if 0 ++ /* ++ * What trancaction model (journal, cow, etc) ++ * is used to commit transactions ++ */ ++ PUSH_OPT(p, opts, ++ { ++ .name = "txmod", ++ .type = OPT_TXMOD, ++ .u = { ++ .txmod = { ++ .result = &sbinfo->txmod ++ } ++ } ++ } ++ ); ++#endif ++ /* modify default settings to values set by mount options */ ++ result = parse_options(opt_string, opts, p - opts); ++ kfree(opts); ++ if (result != 0) ++ return result; ++ ++ /* correct settings to sanity values */ ++ sbinfo->tmgr.atom_max_age *= HZ; ++ if (sbinfo->tmgr.atom_max_age <= 0) ++ /* overflow */ ++ sbinfo->tmgr.atom_max_age = REISER4_ATOM_MAX_AGE; ++ ++ /* round optimal io size up to 512 bytes */ ++ sbinfo->optimal_io_size >>= VFS_BLKSIZE_BITS; ++ sbinfo->optimal_io_size <<= VFS_BLKSIZE_BITS; ++ if (sbinfo->optimal_io_size == 0) { ++ warning("nikita-2497", "optimal_io_size is too small"); ++ return RETERR(-EINVAL); ++ } ++ return result; ++} ++ ++/** ++ * reiser4_read_master - read reiser4 master super block ++ * @super: super block to fill ++ * @silent: if 0 - print warnings ++ * ++ * Reads reiser4 master super block either from predefined location or from ++ * location specified by altsuper mount option, set blocksize to super-block. ++ */ ++int reiser4_read_master(struct super_block *super, int silent, u8 *vol_uuid) ++{ ++ struct reiser4_volume *vol; ++ struct buffer_head *master_bh; ++ struct reiser4_master_sb *master_sb; ++ reiser4_super_info_data *sbinfo; ++ unsigned long blocksize; ++ ++ sbinfo = get_super_private(super); ++ ++ read_super_block: ++ ++#ifdef CONFIG_REISER4_BADBLOCKS ++ if (sbinfo->altsuper) ++ /* ++ * read reiser4 master super block at position specified by ++ * mount option ++ */ ++ master_bh = sb_bread(super, ++ (sector_t)(sbinfo->altsuper / super->s_blocksize)); ++ else ++#endif ++ /* ++ * read reiser4 master super block at 16-th 4096 block ++ */ ++ master_bh = sb_bread(super, ++ (sector_t)(REISER4_MAGIC_OFFSET / super->s_blocksize)); ++ if (!master_bh) ++ return RETERR(-EIO); ++ ++ master_sb = (struct reiser4_master_sb *)master_bh->b_data; ++ /* ++ * check reiser4 magic string ++ */ ++ if (!strncmp(master_sb->magic, ++ REISER4_SUPER_MAGIC_STRING, ++ sizeof(REISER4_SUPER_MAGIC_STRING))) { ++ /* ++ * reiser4 master super block contains filesystem blocksize ++ */ ++ blocksize = master_get_block_size(master_sb); ++ ++ if (blocksize != PAGE_SIZE) { ++ /* ++ * currenly reiser4's blocksize must be equal to ++ * pagesize ++ */ ++ if (!silent) ++ warning("nikita-2609", ++ "%s: wrong block size %ld\n", ++ super->s_id, ++ blocksize); ++ brelse(master_bh); ++ return RETERR(-EINVAL); ++ } ++ if (blocksize != super->s_blocksize) { ++ /* ++ * filesystem uses different blocksize. Reread master ++ * super block with correct blocksize ++ */ ++ brelse(master_bh); ++ if (!sb_set_blocksize(super, (int)blocksize)) ++ return RETERR(-EINVAL); ++ goto read_super_block; ++ } ++ /* ++ * there should be a respective registered volume in the system ++ */ ++ vol = reiser4_search_volume(master_sb->uuid); ++ if (!vol) { ++ warning("edward-1737", ++ "%s: volume is not registered", super->s_id); ++ goto error; ++ } ++ memcpy(vol_uuid, master_sb->uuid, 16); ++ brelse(master_bh); ++ return 0; ++ } ++ /* there is no reiser4 on the device */ ++ if (!silent) ++ warning("nikita-2608", ++ "%s: wrong master super block magic", super->s_id); ++ error: ++ brelse(master_bh); ++ return RETERR(-EINVAL); ++} ++ ++static struct { ++ reiser4_plugin_type type; ++ reiser4_plugin_id id; ++} default_plugins[PSET_LAST] = { ++ [PSET_FILE] = { ++ .type = REISER4_FILE_PLUGIN_TYPE, ++ .id = UNIX_FILE_PLUGIN_ID ++ }, ++ [PSET_DIR] = { ++ .type = REISER4_DIR_PLUGIN_TYPE, ++ .id = HASHED_DIR_PLUGIN_ID ++ }, ++ [PSET_HASH] = { ++ .type = REISER4_HASH_PLUGIN_TYPE, ++ .id = R5_HASH_ID ++ }, ++ [PSET_FIBRATION] = { ++ .type = REISER4_FIBRATION_PLUGIN_TYPE, ++ .id = FIBRATION_DOT_O ++ }, ++ [PSET_PERM] = { ++ .type = REISER4_PERM_PLUGIN_TYPE, ++ .id = NULL_PERM_ID ++ }, ++ [PSET_FORMATTING] = { ++ .type = REISER4_FORMATTING_PLUGIN_TYPE, ++ .id = SMALL_FILE_FORMATTING_ID ++ }, ++ [PSET_SD] = { ++ .type = REISER4_ITEM_PLUGIN_TYPE, ++ .id = STATIC_STAT_DATA_ID ++ }, ++ [PSET_DIR_ITEM] = { ++ .type = REISER4_ITEM_PLUGIN_TYPE, ++ .id = COMPOUND_DIR_ID ++ }, ++ [PSET_CIPHER] = { ++ .type = REISER4_CIPHER_PLUGIN_TYPE, ++ .id = NONE_CIPHER_ID ++ }, ++ [PSET_DIGEST] = { ++ .type = REISER4_DIGEST_PLUGIN_TYPE, ++ .id = SHA256_32_DIGEST_ID ++ }, ++ [PSET_COMPRESSION] = { ++ .type = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .id = LZO1_COMPRESSION_ID ++ }, ++ [PSET_COMPRESSION_MODE] = { ++ .type = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = CONVX_COMPRESSION_MODE_ID ++ }, ++ [PSET_CLUSTER] = { ++ .type = REISER4_CLUSTER_PLUGIN_TYPE, ++ .id = CLUSTER_64K_ID ++ }, ++ [PSET_CREATE] = { ++ .type = REISER4_FILE_PLUGIN_TYPE, ++ .id = UNIX_FILE_PLUGIN_ID ++ } ++}; ++ ++/* access to default plugin table */ ++reiser4_plugin *get_default_plugin(pset_member memb) ++{ ++ return plugin_by_id(default_plugins[memb].type, ++ default_plugins[memb].id); ++} ++ ++/** ++ * reiser4_init_root_inode - obtain inode of root directory ++ * @super: super block of filesystem ++ * ++ * Obtains inode of root directory (reading it from disk), initializes plugin ++ * set it was not initialized. ++ */ ++int reiser4_init_root_inode(struct super_block *super) ++{ ++ int result = 0; ++ struct inode *inode; ++ reiser4_super_info_data *sbinfo = get_super_private(super); ++ reiser4_subvol *root_subv = get_meta_subvol(); ++ ++ inode = reiser4_iget(super, ++ root_subv->df_plug->root_dir_key(super), ++ FIND_EXACT, 0); ++ if (IS_ERR(inode)) ++ return RETERR(PTR_ERR(inode)); ++ ++ super->s_root = d_make_root(inode); ++ if (!super->s_root) { ++ return RETERR(-ENOMEM); ++ } ++ ++ super->s_root->d_op = &sbinfo->ops.dentry; ++ ++ if (!is_inode_loaded(inode)) { ++ pset_member memb; ++ plugin_set *pset; ++ ++ pset = reiser4_inode_data(inode)->pset; ++ for (memb = 0; memb < PSET_LAST; ++memb) { ++ ++ if (aset_get(pset, memb) != NULL) ++ continue; ++ ++ result = grab_plugin_pset(inode, NULL, memb); ++ if (result != 0) ++ break; ++ ++ reiser4_inode_clr_flag(inode, REISER4_SDLEN_KNOWN); ++ } ++ ++ if (result == 0) { ++ if (REISER4_DEBUG) { ++ for (memb = 0; memb < PSET_LAST; ++memb) ++ assert("nikita-3500", ++ aset_get(pset, memb) != NULL); ++ } ++ } else ++ warning("nikita-3448", "Cannot set plugins of root: %i", ++ result); ++ reiser4_iget_complete(inode); ++ /* ++ * As the default pset kept in the root dir may has been changed ++ * (length is unknown), call update_sd ++ */ ++ if (!reiser4_inode_get_flag(inode, REISER4_SDLEN_KNOWN)) { ++ result = reiser4_grab_space(inode_file_plugin(inode)-> ++ estimate.update(inode), ++ BA_CAN_COMMIT, ++ root_subv); ++ if (result == 0) ++ result = reiser4_update_sd(inode); ++ all_grabbed2free(); ++ } ++ } ++ super->s_maxbytes = MAX_LFS_FILESIZE; ++ return result; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/init_volume.c linux-5.10.2/fs/reiser4/init_volume.c +--- linux-5.10.2.orig/fs/reiser4/init_volume.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/init_volume.c 2020-12-23 16:07:46.117813114 +0100 +@@ -0,0 +1,1105 @@ ++/* ++ Copyright (c) 2014-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++/* Reiser4 logical volume initialization and activation */ ++ ++#include "debug.h" ++#include "super.h" ++#include "plugin/item/brick_symbol.h" ++#include "plugin/volume/volume.h" ++#include ++ ++DEFINE_MUTEX(reiser4_volumes_mutex); ++static LIST_HEAD(reiser4_volumes); /* list of registered volumes */ ++ ++#define MAX_STRIPE_BITS (63) ++ ++/** ++ * Allocate and initialize a volume header. ++ * ++ * @uuid: unique volume ID; ++ * @vol_plug: volume plugin this volume is managed by; ++ * @dist_plug: plugin distributing stripes among bricks; ++ * @stripe_bits: defines size of stripe (minimal unit of distribution). ++ */ ++static reiser4_volume *reiser4_alloc_volume(u8 *uuid, ++ volume_plugin *vol_plug, ++ distribution_plugin *dist_plug, ++ int stripe_bits) ++{ ++ struct reiser4_volume *vol; ++ ++ vol = kzalloc(sizeof(*vol), GFP_KERNEL); ++ if (!vol) ++ return NULL; ++ memcpy(vol->uuid, uuid, 16); ++ vol->vol_plug = vol_plug; ++ vol->dist_plug = dist_plug; ++ vol->stripe_bits = stripe_bits; ++ ++ INIT_LIST_HEAD(&vol->list); ++ INIT_LIST_HEAD(&vol->subvols_list); ++ atomic_set(&vol->nr_origins, 0); ++ init_rwsem(&vol->volume_sem); ++ init_rwsem(&vol->brick_removal_sem); ++ return vol; ++} ++ ++/** ++ * Allocate and initialize a brick header. ++ * ++ * @df_plug: disk format plugin this brick is managed by; ++ * @uuid: bricks's external ID; ++ * @subvol_id: bricks's internal ID; ++ * @mirror_id: 0 if brick is original. Serial number of replica otherwise; ++ * @num_replicas: total number of replicas ++ */ ++struct reiser4_subvol *reiser4_alloc_subvol(u8 *uuid, ++ const char *path, ++ disk_format_plugin *df_plug, ++ u64 subvol_id, ++ u16 mirror_id, ++ u16 num_replicas) ++{ ++ struct reiser4_subvol *subv; ++ ++ subv = kzalloc(sizeof(*subv), GFP_KERNEL); ++ if (!subv) ++ return NULL; ++ memcpy(subv->uuid, uuid, 16); ++ ++ INIT_LIST_HEAD(&subv->list); ++ __init_ch_sub(&subv->ch); ++ ++ subv->name = kstrdup(path, GFP_KERNEL); ++ if (!subv->name) { ++ kfree(subv); ++ return NULL; ++ } ++ subv->df_plug = df_plug; ++ subv->id = subvol_id; ++ subv->mirror_id = mirror_id; ++ subv->num_replicas = num_replicas; ++ return subv; ++} ++ ++/** ++ * Lookup volume by its ID. ++ * Pre-condition: @reiser4_volumes_mutex is down ++ */ ++struct reiser4_volume *reiser4_search_volume(u8 *uuid) ++{ ++ struct reiser4_volume *vol; ++ ++ list_for_each_entry(vol, &reiser4_volumes, list) { ++ if (memcmp(uuid, vol->uuid, 16) == 0) ++ return vol; ++ } ++ return NULL; ++} ++ ++/** ++ * Lookup brick by its external ID. ++ * Pre-condition: @reiser4_volumes_mutex is down ++ */ ++static reiser4_subvol *reiser4_search_subvol(u8 *uuid, ++ struct list_head *where) ++{ ++ reiser4_subvol *sub; ++ ++ list_for_each_entry(sub, where, list) { ++ if (memcmp(uuid, sub->uuid, 16) == 0) ++ return sub; ++ } ++ return NULL; ++} ++ ++static int check_volume_params(reiser4_volume *vol, ++ volume_plugin *vol_plug, ++ distribution_plugin *dist_plug, ++ int stripe_bits, ++ const char **what_differs) ++{ ++ int ret = -EINVAL; ++ ++ if (vol->vol_plug != vol_plug) ++ *what_differs = "volume plugins"; ++ else if (vol->dist_plug != dist_plug) ++ *what_differs = "distribution plugins"; ++ else if (vol->stripe_bits != stripe_bits) ++ *what_differs = "stripe sizes"; ++ else ++ ret = 0; ++ return ret; ++} ++ ++/** ++ * Register a brick. ++ * Returns: ++ * 0 - first time subvolume is seen ++ * 1 - subvolume already registered ++ * < 0 - error ++ * ++ * Pre-condition: @reiser4_volumes_mutex is down, ++ * all passed volume parameters are valid. ++ */ ++static int reiser4_register_subvol(const char *path, ++ u8 *vol_uuid, ++ u8 *sub_uuid, ++ disk_format_plugin *df_plug, ++ volume_plugin *vol_plug, ++ distribution_plugin *dist_plug, ++ u16 mirror_id, ++ u16 num_replicas, ++ int stripe_bits, ++ u64 subvol_id, ++ reiser4_subvol **result, ++ reiser4_volume **vol) ++{ ++ const char *what_differs; ++ struct reiser4_subvol *sub; ++ ++ assert("edward-1964", vol != NULL); ++ ++ *vol = reiser4_search_volume(vol_uuid); ++ if (*vol) { ++ int ret = check_volume_params(*vol, ++ vol_plug, ++ dist_plug, ++ stripe_bits, ++ &what_differs); ++ if (ret) { ++ /* ++ * Found, but not happy. ++ * Most likely it is because user specified ++ * wrong options when formatting bricks. ++ */ ++ warning("edward-2317", ++ "%s: bricks w/ different %s in the same volume", ++ path, what_differs); ++ return ret; ++ } ++ sub = reiser4_search_subvol(sub_uuid, &(*vol)->subvols_list); ++ if (sub) { ++ if (result) ++ *result = sub; ++ return 1; ++ } ++ sub = reiser4_alloc_subvol(sub_uuid, ++ path, ++ df_plug, ++ subvol_id, ++ mirror_id, num_replicas); ++ if (!sub) ++ return -ENOMEM; ++ } else { ++ *vol = reiser4_alloc_volume(vol_uuid, ++ vol_plug, ++ dist_plug, ++ stripe_bits); ++ if (*vol == NULL) ++ return -ENOMEM; ++ sub = reiser4_alloc_subvol(sub_uuid, ++ path, ++ df_plug, ++ subvol_id, ++ mirror_id, num_replicas); ++ if (!sub) { ++ kfree(*vol); ++ return -ENOMEM; ++ } ++ list_add(&(*vol)->list, &reiser4_volumes); ++ } ++ list_add(&sub->list, &(*vol)->subvols_list); ++ if (result) ++ *result = sub; ++ notice("edward-1932", "brick %s has been registered", path); ++ return 0; ++} ++ ++static void reiser4_free_volume(struct reiser4_volume *vol) ++{ ++ assert("edward-1741", vol->conf == NULL); ++ kfree(vol); ++} ++ ++/** ++ * Retrieve information about a registered volume. ++ * This is a REISER4_SCAN_DEV ioctl handler. ++ */ ++int reiser4_volume_header(struct reiser4_vol_op_args *args) ++{ ++ int idx = 0; ++ const struct reiser4_volume *vol; ++ const struct reiser4_volume *this = NULL; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ ++ list_for_each_entry(vol, &reiser4_volumes, list) { ++ if (idx == args->s.vol_idx) { ++ this = vol; ++ break; ++ } ++ idx ++; ++ } ++ if (!this) { ++ mutex_unlock(&reiser4_volumes_mutex); ++ args->error = -ENOENT; ++ return 0; ++ } ++ memcpy(args->u.vol.id, this->uuid, 16); ++ if (this->conf) ++ args->u.vol.fs_flags |= (1 << REISER4_ACTIVATED_VOL); ++ ++ mutex_unlock(&reiser4_volumes_mutex); ++ return 0; ++} ++ ++/** ++ * Retrieve information about a registered brick. ++ * This is a REISER4_SCAN_DEV ioctl handler. ++ * ++ * Pre-condition: @args contains uuid of the host volume and ++ * serial number of the brick in the list of volume's bricks. ++ */ ++int reiser4_brick_header(struct reiser4_vol_op_args *args) ++{ ++ int idx = 0; ++ const reiser4_volume *vol; ++ const reiser4_subvol *subv; ++ const reiser4_subvol *this = NULL; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ vol = reiser4_search_volume(args->u.vol.id); ++ if (!vol) { ++ mutex_unlock(&reiser4_volumes_mutex); ++ args->error = -EINVAL; ++ return 0; ++ } ++ list_for_each_entry(subv, &vol->subvols_list, list) { ++ if (idx == args->s.brick_idx) { ++ this = subv; ++ break; ++ } ++ idx ++; ++ } ++ if (!this) { ++ mutex_unlock(&reiser4_volumes_mutex); ++ args->error = -ENOENT; ++ return 0; ++ } ++ memcpy(args->u.brick.ext_id, this->uuid, 16); ++ strncpy(args->d.name, this->name, REISER4_PATH_NAME_MAX + 1); ++ mutex_unlock(&reiser4_volumes_mutex); ++ return 0; ++} ++ ++/** ++ * Remove @subv from volume's list of registered subvolumes and release it. ++ * Pre-condition: @reiser4_volumes_mutex is down. ++ */ ++static void unregister_subvol_locked(struct reiser4_subvol *subv) ++{ ++ assert("edward-1742", subv->bdev == NULL); ++ assert("edward-1743", subv->apx == NULL); ++ assert("edward-1744", !subvol_is_set(subv, SUBVOL_ACTIVATED)); ++ assert("edward-1745", list_empty_careful(&subv->ch.overwrite_set)); ++ assert("edward-1746", list_empty_careful(&subv->ch.tx_list)); ++ assert("edward-1747", list_empty_careful(&subv->ch.wander_map)); ++ ++ notice("edward-2312", "brick %s has been unregistered", subv->name); ++ ++ list_del_init(&subv->list); ++ if (subv->name) ++ kfree(subv->name); ++ kfree(subv); ++} ++ ++/** ++ * Find a brick in the set of registered bricks, remove it ++ * from the set and release it. ++ * ++ * This is called when removing brick form a logical volume, ++ * and on error paths. ++ */ ++void reiser4_unregister_subvol(struct reiser4_subvol *victim) ++{ ++ struct reiser4_volume *vol, *vol_tmp; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ ++ list_for_each_entry_safe(vol, vol_tmp, &reiser4_volumes, list) { ++ struct reiser4_subvol *subv, *subv_tmp; ++ list_for_each_entry_safe(subv, subv_tmp, ++ &vol->subvols_list, list) { ++ if (subv == victim) { ++ unregister_subvol_locked(subv); ++ if (list_empty(&vol->subvols_list)) { ++ list_del(&vol->list); ++ reiser4_free_volume(vol); ++ } ++ goto out; ++ } ++ } ++ } ++ out: ++ mutex_unlock(&reiser4_volumes_mutex); ++} ++ ++/** ++ * Find a brick in the list of registered bricks by name, ++ * remove it from the list and release it. ++ * ++ * This is a REISER4_SCAN_DEV ioctl handler. ++ */ ++int reiser4_unregister_brick(struct reiser4_vol_op_args *args) ++{ ++ int ret = 0; ++ struct reiser4_volume *vol, *vol_tmp; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ ++ list_for_each_entry_safe(vol, vol_tmp, &reiser4_volumes, list) { ++ struct reiser4_subvol *subv, *subv_tmp; ++ list_for_each_entry_safe(subv, subv_tmp, ++ &vol->subvols_list, list) { ++ if (!strncmp(args->d.name, ++ subv->name, strlen(subv->name))) { ++ if (subvol_is_set(subv, SUBVOL_ACTIVATED)) { ++ warning("edward-2314", ++ "Can not unregister activated brick %s", ++ subv->name); ++ ret = -EINVAL; ++ goto out; ++ } ++ unregister_subvol_locked(subv); ++ if (list_empty(&vol->subvols_list)) { ++ list_del(&vol->list); ++ reiser4_free_volume(vol); ++ } ++ goto out; ++ } ++ } ++ } ++ warning("edward-2313", ++ "Can not find registered brick %s", args->d.name); ++ ret = -EINVAL; ++ out: ++ mutex_unlock(&reiser4_volumes_mutex); ++ return ret; ++} ++ ++/* ++ * Called on shutdown ++ */ ++void reiser4_unregister_volumes(void) ++{ ++ struct reiser4_volume *vol, *vol_tmp; ++ struct reiser4_subvol *sub, *sub_tmp; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ ++ list_for_each_entry_safe(vol, vol_tmp, &reiser4_volumes, list) { ++ list_for_each_entry_safe(sub, sub_tmp, &vol->subvols_list, list) ++ unregister_subvol_locked(sub); ++ assert("edward-2328", list_empty(&vol->subvols_list)); ++ list_del(&vol->list); ++ reiser4_free_volume(vol); ++ } ++ assert("edward-2329", list_empty(&reiser4_volumes)); ++ ++ mutex_unlock(&reiser4_volumes_mutex); ++} ++ ++/** ++ * read master super-block from disk and make its copy ++ */ ++int reiser4_read_master_sb(struct block_device *bdev, ++ struct reiser4_master_sb *copy) ++{ ++ struct page *page; ++ struct reiser4_master_sb *master; ++ /* ++ * read master super block ++ */ ++ page = read_cache_page_gfp(bdev->bd_inode->i_mapping, ++ REISER4_MAGIC_OFFSET >> PAGE_SHIFT, ++ GFP_KERNEL); ++ if (IS_ERR_OR_NULL(page)) ++ return -EINVAL; ++ master = kmap(page); ++ if (strncmp(master->magic, ++ REISER4_SUPER_MAGIC_STRING, ++ sizeof(REISER4_SUPER_MAGIC_STRING))) { ++ /* ++ * there is no reiser4 on the device ++ */ ++ kunmap(page); ++ put_page(page); ++ return -EINVAL; ++ } ++ memcpy(copy, master, sizeof(*master)); ++ kunmap(page); ++ put_page(page); ++ return 0; ++} ++ ++/** ++ * Read master and format super-blocks from device specified by @path and ++ * check their magics. ++ * If found, then check parameters of found master and format super-blocks ++ * and try to register a brick accociated with this device. ++ * On success store pointer to registered subvolume in @result. ++ * On success return 0. Otherwise return error. ++ */ ++int reiser4_scan_device(const char *path, fmode_t flags, void *holder, ++ reiser4_subvol **result, reiser4_volume **host) ++{ ++ int ret; ++ u64 subv_id; ++ struct block_device *bdev; ++ struct reiser4_master_sb master; ++ u16 df_pid, dist_pid, vol_pid; ++ u8 stripe_bits = 0; ++ u16 mirror_id, nr_replicas; ++ disk_format_plugin *df_plug; ++ volume_plugin *vol_plug; ++ distribution_plugin *dist_plug = NULL; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ ++ bdev = blkdev_get_by_path(path, flags, holder); ++ if (IS_ERR(bdev)) { ++ ret = PTR_ERR(bdev); ++ goto out; ++ } ++ ret = reiser4_read_master_sb(bdev, &master); ++ if (ret) ++ goto bdev_put; ++ ++ ret = -EINVAL; ++ df_pid = master_get_dformat_pid(&master); ++ df_plug = disk_format_plugin_by_unsafe_id(df_pid); ++ if (df_plug == NULL) ++ /* unknown disk format plugin */ ++ goto bdev_put; ++ ++ vol_pid = master_get_volume_pid(&master); ++ vol_plug = volume_plugin_by_unsafe_id(vol_pid); ++ if (!vol_plug) ++ /* unknown volume plugin */ ++ goto bdev_put; ++ ++ mirror_id = master_get_mirror_id(&master); ++ nr_replicas = master_get_num_replicas(&master); ++ if (mirror_id > nr_replicas) { ++ warning("edward-1739", ++ "%s: mirror id (%u) larger than number of replicas (%u)", ++ path, mirror_id, nr_replicas); ++ goto bdev_put; ++ } ++ ++ dist_pid = master_get_distrib_pid(&master); ++ dist_plug = distribution_plugin_by_unsafe_id(dist_pid); ++ if (!dist_plug) ++ /* unknown distribution plugin */ ++ goto bdev_put; ++ ++ stripe_bits = master_get_stripe_bits(&master); ++ if (stripe_bits != 0 && ++ stripe_bits < PAGE_SHIFT && ++ stripe_bits > MAX_STRIPE_BITS) { ++ warning("edward-1814", ++ "bad stripe_bits value (%d)n", stripe_bits); ++ goto bdev_put; ++ } ++ /* ++ * Now retrieve subvolume's internal ID from format super-block. ++ * It is allowed to do before activating subvolume, because ++ * internal ID never get changed during subvolume's life. ++ * Thus, format super-block always contains actual version of ++ * internal ID (even before transaction replay). ++ */ ++ ret = df_plug->extract_subvol_id(bdev, &subv_id); ++ if (ret) ++ goto bdev_put; ++ ret = reiser4_register_subvol(path, ++ master.uuid, ++ master.sub_uuid, ++ df_plug, ++ vol_plug, ++ dist_plug, ++ mirror_id, ++ nr_replicas, ++ stripe_bits, ++ subv_id, ++ result, host); ++ if (ret > 0) ++ /* ok, it was registered earlier */ ++ ret = 0; ++ bdev_put: ++ blkdev_put(bdev, flags); ++ out: ++ mutex_unlock(&reiser4_volumes_mutex); ++ return ret; ++} ++ ++/** ++ * Make sure that all replicas of the original subvolume ++ * @subv has been activated. ++ * ++ * Pre-conditions: ++ * Disk format superblock of the subvolume was found ++ */ ++int check_active_replicas(reiser4_subvol *subv) ++{ ++ u32 repl_id; ++ lv_conf *conf; ++ ++ assert("edward-2235", subv->super != NULL); ++ assert("edward-1748", !is_replica(subv)); ++ assert("edward-1751", super_volume(subv->super) != NULL); ++ ++ conf = super_conf(subv->super); ++ ++ if (has_replicas(subv) && ++ (conf == NULL || conf_mslot_at(conf, subv->id) == NULL)) { ++ ++ warning("edward-1750", ++ "%s requires replicas, which " ++ " are not registered.", ++ subv->name); ++ return -EINVAL; ++ } ++ ++ __for_each_replica(subv, repl_id) { ++ reiser4_subvol *repl; ++ ++ repl = super_mirror(subv->super, subv->id, repl_id); ++ if (repl == NULL) { ++ warning("edward-1752", ++ "%s: replica #%u is not registered.", ++ subv->name, repl_id); ++ return -EINVAL; ++ } ++ assert("edward-1965", ++ subvol_is_set(repl, SUBVOL_ACTIVATED)); ++ } ++ return 0; ++} ++ ++static void clear_subvol(reiser4_subvol *subv) ++{ ++ subv->bdev = NULL; ++ subv->super = NULL; ++ subv->mode = 0; ++ subv->flags = 0; ++ subv->txmod = 0; ++} ++ ++/* ++ * Initialize disk format 4.X.Y for a subvolume ++ * Pre-condition: subvolume @sub is registered ++ */ ++int reiser4_activate_subvol(struct super_block *super, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ fmode_t mode = FMODE_READ | FMODE_EXCL; ++ reiser4_volume *vol = super_volume(super); ++ ++ assert("edward-2309", vol != NULL); ++ assert("edward-2301", !subvol_is_set(subv, SUBVOL_ACTIVATED)); ++ ++ if (!(super->s_flags & SB_RDONLY)) ++ mode |= FMODE_WRITE; ++ ++ subv->bdev = blkdev_get_by_path(subv->name, ++ mode, get_reiser4_fs_type()); ++ if (IS_ERR(subv->bdev)) ++ return PTR_ERR(subv->bdev); ++ ++ subv->mode = mode; ++ subv->super = super; ++ ++ if (blk_queue_nonrot(bdev_get_queue(subv->bdev))) { ++ /* ++ * Solid state drive has been detected. ++ * Set Write-Anywhere transaction model ++ * for this subvolume ++ */ ++ subv->flags |= (1 << SUBVOL_IS_NONROT_DEVICE); ++ subv->txmod = WA_TXMOD_ID; ++ } ++ if (is_replica(subv)) { ++ if (!vol->conf) { ++ /* ++ * This is a replica of meta-data brick. ++ * Allocate temporary config needed to ++ * activate original meta-data brick. ++ * This temporary config will be replaced ++ * with an actual one after replaying ++ * transactions on the meta-data brick ++ * (see read_check_volume_params()). ++ */ ++ assert("edward-2310", ++ subv->id == METADATA_SUBVOL_ID); ++ vol->conf = alloc_lv_conf(1 /* one mslot */); ++ if (!vol->conf) ++ return -ENOMEM; ++ } ++ /* ++ * Nothing to do any more for replicas! ++ * Particularly, we are not entitled to ++ * replay journal on replicas (only on ++ * original bricks - it will also update ++ * replica blocks properly). ++ */ ++ goto ok; ++ } ++ /* ++ * This is an original subvolume. ++ * Before calling ->init_format() make sure that ++ * all its replicas were activated. ++ */ ++ ret = check_active_replicas(subv); ++ if (ret) ++ goto error; ++ ret = subv->df_plug->init_format(super, subv); ++ if (ret) ++ goto error; ++ ok: ++ printk("reiser4: brick %s activated\n", subv->name); ++ subv->flags |= (1 << SUBVOL_ACTIVATED); ++ return 0; ++ error: ++ blkdev_put(subv->bdev, subv->mode); ++ clear_subvol(subv); ++ return ret; ++} ++ ++mirror_t *alloc_mslot(u32 nr_mirrors) ++{ ++ return kzalloc(nr_mirrors * sizeof(mirror_t), GFP_KERNEL); ++} ++ ++void free_mslot(slot_t slot) ++{ ++ assert("edward-2229", slot != NULL); ++ kfree(slot); ++} ++ ++lv_conf *alloc_lv_conf(u32 nr_mslots) ++{ ++ lv_conf *ret; ++ ++ ret = kzalloc(sizeof(*ret) + nr_mslots * sizeof(slot_t), ++ GFP_KERNEL); ++ if (ret) ++ ret->nr_mslots = nr_mslots; ++ return ret; ++} ++ ++void free_lv_conf(lv_conf *conf) ++{ ++ if (conf == NULL) ++ return; ++ if (conf->tab) ++ current_dist_plug()->r.free(conf->tab); ++ kfree(conf); ++} ++ ++void free_mslot_at(lv_conf *conf, u64 idx) ++{ ++ assert("edward-2231", conf != NULL); ++ assert("edward-2190", conf->mslots[idx] != NULL); ++ ++ free_mslot(conf->mslots[idx]); ++ conf->mslots[idx] = NULL; ++} ++ ++void release_lv_conf(reiser4_volume *vol, lv_conf *conf) ++{ ++ u32 i; ++ ++ assert("edward-2263", vol->conf == conf); ++ ++ if (!conf) ++ return; ++ /* ++ * release distribution table ++ */ ++ if (vol->dist_plug->r.done) ++ vol->dist_plug->r.done(&conf->tab); ++ ++ assert("edward-2264", conf->tab == NULL); ++ /* ++ * release content of mslots ++ */ ++ for (i = 0; i < conf->nr_mslots; i++) ++ if (conf->mslots[i]) ++ free_mslot_at(conf, i); ++ free_lv_conf(conf); ++} ++ ++/** ++ * Deactivate subvolume. Called during umount, or in error paths ++ */ ++void reiser4_deactivate_subvol(struct super_block *super, reiser4_subvol *subv) ++{ ++ assert("edward-1755", subvol_is_set(subv, SUBVOL_ACTIVATED)); ++ assert("edward-1756", subv->bdev != NULL); ++ assert("edward-1757", subv->super != NULL); ++ ++ if (!is_replica(subv)) { ++ subvol_check_block_counters(subv); ++ subv->df_plug->release_format(super, subv); ++ } ++ assert("edward-1758", list_empty_careful(&subv->ch.overwrite_set)); ++ assert("edward-1759", list_empty_careful(&subv->ch.tx_list)); ++ assert("edward-1760", list_empty_careful(&subv->ch.wander_map)); ++ ++ blkdev_put(subv->bdev, subv->mode); ++ clear_subvol(subv); ++ clear_bit(SUBVOL_ACTIVATED, &subv->flags); ++ printk("reiser4: brick %s deactivated\n", subv->name); ++} ++ ++static void deactivate_subvolumes_cond(struct super_block *super, ++ int(*cond)(reiser4_subvol *)) ++{ ++ struct reiser4_subvol *subv; ++ reiser4_volume *vol = get_super_private(super)->vol; ++ ++ list_for_each_entry(subv, &vol->subvols_list, list) { ++ if (!subvol_is_set(subv, SUBVOL_ACTIVATED)) { ++ /* ++ * subvolume is not active ++ */ ++ assert("edward-1761", subv->super == NULL); ++ continue; ++ } ++ if (!cond(subv)) ++ continue; ++ reiser4_deactivate_subvol(super, subv); ++ } ++} ++ ++/** ++ * First we deactivate all non-replicas, as we need to have ++ * a complete set of active replicas for journal replay when ++ * deactivating original subvolumes. ++ */ ++void __reiser4_deactivate_volume(struct super_block *super) ++{ ++ int ret; ++ reiser4_subvol *subv; ++ reiser4_volume *vol = super_volume(super); ++ lv_conf *conf = vol->conf; ++ ++ if (reiser4_volume_is_activated(super) && !sb_rdonly(super)) { ++ u32 orig_id; ++ for_each_mslot(conf, orig_id) { ++ if (!conf->mslots[orig_id]) ++ continue; ++ subv = conf_origin(conf, orig_id); ++ if (!subvol_is_set(subv, SUBVOL_IS_ORPHAN)) { ++ ret = capture_brick_super(subv); ++ if (ret != 0) ++ warning("vs-898", ++ "Failed to capture superblock (%d)", ++ ret); ++ } ++ } ++ ret = txnmgr_force_commit_all(super, 1); ++ if (ret != 0) ++ warning("jmacd-74438", ++ "txn_force failed: %d", ret); ++ all_grabbed2free(); ++ } ++ if (vol->vol_plug->done_volume) ++ vol->vol_plug->done_volume(vol); ++ ++ deactivate_subvolumes_cond(super, is_origin); ++ deactivate_subvolumes_cond(super, is_replica); ++ ++ if (vol->new_conf) { ++ assert("edward-2254", ++ reiser4_volume_has_incomplete_removal(super)); ++ assert("edward-2255", ++ vol->new_conf->tab == vol->conf->tab); ++ ++ vol->new_conf->tab = NULL; ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ } ++ vol->victim = NULL; ++ ++ release_lv_conf(vol, vol->conf); ++ vol->conf = NULL; ++ vol->num_sgs_bits = 0; ++ atomic_set(&vol->nr_origins, 0); ++ ++ assert("edward-2302", !list_empty(&vol->subvols_list)); ++ ++ list_for_each_entry(subv, &vol->subvols_list, list) { ++ assert("edward-1763", !subvol_is_set(subv, SUBVOL_ACTIVATED)); ++ assert("edward-1764", subv->super == NULL); ++ assert("edward-1765", subv->bdev == NULL); ++ assert("edward-1766", subv->mode == 0); ++ } ++} ++ ++/** ++ * Deactivate volume. Called during umount, or in error paths ++ */ ++void reiser4_deactivate_volume(struct super_block *super) ++{ ++ mutex_lock(&reiser4_volumes_mutex); ++ __reiser4_deactivate_volume(super); ++ mutex_unlock(&reiser4_volumes_mutex); ++} ++ ++/** ++ * Set a pointer to activated subvolume @subv (original, or ++ * replica) at the respective slot in the table of activated ++ * subvolumes of logical volume @vol. Allocate column of the ++ * table, if needed. ++ */ ++static int set_activated_subvol(reiser4_volume *vol, reiser4_subvol *subv) ++{ ++ int ret = 0; ++ u64 orig_id = subv->id; ++ u16 mirr_id = subv->mirror_id; ++ lv_conf *conf = vol->conf; ++ ++ assert("edward-2232", conf != NULL); ++ ++ if (conf->mslots[orig_id] == NULL) { ++ /* ++ * slot is "empty". Allocate a "column" - ++ * array of pointers to mirrors ++ */ ++ conf->mslots[orig_id] = alloc_mslot(1 + subv->num_replicas); ++ if (conf->mslots[orig_id] == NULL) { ++ ret = -ENOMEM; ++ goto out; ++ } ++ } ++ if (conf->mslots[orig_id][mirr_id] != NULL) { ++ warning("edward-1767", ++ "wrong set of registered bricks: " ++ "%s and %s have identical mirror IDs (%llu,%u)", ++ conf->mslots[orig_id][mirr_id]->name, ++ subv->name, ++ orig_id, mirr_id); ++ ret = -EINVAL; ++ goto out; ++ } ++ conf->mslots[orig_id][mirr_id] = subv; ++ out: ++ return ret; ++} ++ ++/** ++ * Activate all subvolumes of type specified by @cond ++ */ ++static int activate_subvolumes_cond(struct super_block *super, u8 *vol_uuid, ++ int(*cond)(reiser4_subvol *)) ++{ ++ int ret; ++ struct reiser4_volume *vol; ++ struct reiser4_subvol *subv; ++ reiser4_super_info_data *info; ++ ++ vol = reiser4_search_volume(vol_uuid); ++ if (!vol) ++ return -EINVAL; ++ info = get_super_private(super); ++ info->vol = vol; ++ ++ list_for_each_entry(subv, &vol->subvols_list, list) { ++ if (list_empty_careful(&vol->subvols_list)) ++ return 0; ++ if (!cond(subv)) ++ continue; ++ if (subvol_is_set(subv, SUBVOL_ACTIVATED)) ++ continue; ++ ret = reiser4_activate_subvol(super, subv); ++ if (ret) ++ return ret; ++ assert("edward-1769", subvol_is_set(subv, SUBVOL_ACTIVATED)); ++ ++ ret = set_activated_subvol(vol, subv); ++ if (ret) ++ return ret; ++ } ++ return 0; ++} ++ ++static int is_meta_origin(reiser4_subvol *subv) ++{ ++ return is_meta_brick_id(subv->id) && is_origin(subv); ++} ++ ++static int is_meta_replica(reiser4_subvol *subv) ++{ ++ return is_meta_brick_id(subv->id) && is_replica(subv); ++} ++ ++static int volume_version_update(struct super_block *super) ++{ ++ int ret = 0; ++ u32 orig_id; ++ reiser4_volume *vol = get_super_private(super)->vol; ++ lv_conf *conf = vol->conf; ++ int nr_to_update = 0; ++ ++ for_each_mslot(conf, orig_id) { ++ reiser4_subvol *subv; ++ if (!conf->mslots[orig_id]) ++ continue; ++ subv = conf_origin(conf, orig_id); ++ ret = subv->df_plug->version_update(super, subv); ++ if (ret < 0) ++ return ret; ++ nr_to_update += ret; ++ } ++ if (!nr_to_update) ++ return 0; ++ /* force write_logs immediately */ ++ return force_commit_current_atom(); ++} ++ ++/** ++ * Activate all subvolumes (components) of asymmetric logical ++ * volume in a particular order. ++ * Handle all cases of incomplete registration (when not all ++ * components were registered in the system). ++ * ++ * @super: super-block associated with the logical volume; ++ * @vol_uuid: uuid of the logical volume. ++ */ ++int reiser4_activate_volume(struct super_block *super, u8 *vol_uuid) ++{ ++ int ret; ++ u32 orig_id; ++ u32 nr_origins = 0; ++ reiser4_volume *vol; ++ lv_conf *conf; ++ ++ mutex_lock(&reiser4_volumes_mutex); ++ /* ++ * Order of activation (don't change it). ++ * ++ * Before activating an original brick we need to activate ++ * all its replicas, because activation of original brick is ++ * followed with journal replay and for every IO submitted ++ * for the original brick we always immediately submit IOs ++ * for all its replicas. In contrast with original bricks, ++ * replicas are activated without journal replay. ++ * ++ * Besides, we need to start from the replica of meta-data ++ * brick, which contains system information needed to activate ++ * other (data) bricks. ++ */ ++ ret = activate_subvolumes_cond(super, vol_uuid, is_meta_replica); ++ if (ret) ++ goto deactivate; ++ ret = activate_subvolumes_cond(super, vol_uuid, is_meta_origin); ++ if (ret) ++ goto deactivate; ++ ret = activate_subvolumes_cond(super, vol_uuid, is_replica); ++ if (ret) ++ goto deactivate; ++ ret = activate_subvolumes_cond(super, vol_uuid, is_origin); ++ if (ret) ++ goto deactivate; ++ /* ++ * At this point all activated original bricks have complete ++ * sets of active replicas - it is guaranteed by calling ++ * check_active_replicas() when activating an original brick. ++ * Now make sure that the set of original bricks is complete. ++ */ ++ vol = get_super_private(super)->vol; ++ assert("edward-2207", vol != NULL); ++ ++ conf = vol->conf; ++ for_each_mslot(conf, orig_id) { ++ if (conf_mslot_at(conf, orig_id) && conf_origin(conf, orig_id)){ ++ assert("edward-1773", ++ subvol_is_set(conf_origin(conf, orig_id), ++ SUBVOL_ACTIVATED)); ++ nr_origins ++; ++ } ++ } ++ if (nr_origins != atomic_read(&vol->nr_origins)) { ++ warning("edward-1772", ++ "%s: wrong set of registered bricks (found %u, expected %u)", ++ super->s_id, nr_origins, atomic_read(&vol->nr_origins)); ++ ret = -EINVAL; ++ goto deactivate; ++ } ++ /* ++ * Identify activated subvolumes ++ */ ++ if (!get_meta_subvol()) { ++ warning("edward-2298", ++ "%s: meta-data brick is not registered", super->s_id); ++ ret = -EINVAL; ++ goto deactivate; ++ } ++ for_each_data_mslot(conf, orig_id) { ++ reiser4_subvol *subv; ++ if (!conf_mslot_at(conf, orig_id) || ++ !conf_origin(conf, orig_id)) ++ continue; ++ subv = conf_origin(conf, orig_id); ++ if (!brick_identify(subv)) { ++ warning("edward-2299", ++ "%s: Brick %s doesn't match logical volume.", ++ super->s_id, subv->name); ++ ret = -EINVAL; ++ goto deactivate; ++ } ++ } ++ /* ++ * initialize logical volume after activating all subvolumes ++ */ ++ if (vol->vol_plug->init_volume != NULL) { ++ ret = vol->vol_plug->init_volume(super, vol); ++ if (ret) { ++ warning("edward-1770", ++ "(%s): failed to init logical volume (%d)\n", ++ super->s_id, ret); ++ goto deactivate; ++ } ++ } ++ ret = volume_version_update(super); ++ if (ret) ++ goto deactivate; ++ reiser4_volume_set_activated(super); ++ goto out; ++ deactivate: ++ __reiser4_deactivate_volume(super); ++ out: ++ mutex_unlock(&reiser4_volumes_mutex); ++ return ret; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/inode.c linux-5.10.2/fs/reiser4/inode.c +--- linux-5.10.2.orig/fs/reiser4/inode.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/inode.c 2020-12-23 16:07:46.118813129 +0100 +@@ -0,0 +1,734 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Inode specific operations. */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "kassign.h" ++#include "coord.h" ++#include "seal.h" ++#include "dscale.h" ++#include "plugin/item/item.h" ++#include "plugin/security/perm.h" ++#include "plugin/plugin.h" ++#include "plugin/object.h" ++#include "znode.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include ++ ++/* return reiser4-specific inode flags */ ++static inline unsigned long *inode_flags(const struct inode *const inode) ++{ ++ assert("nikita-2842", inode != NULL); ++ return &reiser4_inode_data(inode)->flags; ++} ++ ++/* set reiser4-specific flag @f in @inode */ ++void reiser4_inode_set_flag(struct inode *inode, reiser4_file_plugin_flags f) ++{ ++ assert("nikita-2248", inode != NULL); ++ set_bit((int)f, inode_flags(inode)); ++} ++ ++/* clear reiser4-specific flag @f in @inode */ ++void reiser4_inode_clr_flag(struct inode *inode, reiser4_file_plugin_flags f) ++{ ++ assert("nikita-2250", inode != NULL); ++ clear_bit((int)f, inode_flags(inode)); ++} ++ ++/* true if reiser4-specific flag @f is set in @inode */ ++int reiser4_inode_get_flag(const struct inode *inode, ++ reiser4_file_plugin_flags f) ++{ ++ assert("nikita-2251", inode != NULL); ++ return test_bit((int)f, inode_flags(inode)); ++} ++ ++/* convert oid to inode number */ ++ino_t oid_to_ino(oid_t oid) ++{ ++ return (ino_t) oid; ++} ++ ++/* convert oid to user visible inode number */ ++ino_t oid_to_uino(oid_t oid) ++{ ++ /* reiser4 object is uniquely identified by oid which is 64 bit ++ quantity. Kernel in-memory inode is indexed (in the hash table) by ++ 32 bit i_ino field, but this is not a problem, because there is a ++ way to further distinguish inodes with identical inode numbers ++ (find_actor supplied to iget()). ++ ++ But user space expects unique 32 bit inode number. Obviously this ++ is impossible. Work-around is to somehow hash oid into user visible ++ inode number. ++ */ ++ oid_t max_ino = (ino_t) ~0; ++ ++ if (REISER4_INO_IS_OID || (oid <= max_ino)) ++ return oid; ++ else ++ /* this is remotely similar to algorithm used to find next pid ++ to use for process: after wrap-around start from some ++ offset rather than from 0. Idea is that there are some long ++ living objects with which we don't want to collide. ++ */ ++ return REISER4_UINO_SHIFT + ((oid - max_ino) & (max_ino >> 1)); ++} ++ ++/* check that "inode" is on reiser4 file-system */ ++int is_reiser4_inode(const struct inode *inode/* inode queried */) ++{ ++ return inode != NULL && is_reiser4_super(inode->i_sb); ++} ++ ++/* Maximal length of a name that can be stored in directory @inode. ++ ++ This is used in check during file creation and lookup. */ ++int reiser4_max_filename_len(const struct inode *inode/* inode queried */) ++{ ++ assert("nikita-287", is_reiser4_inode(inode)); ++ assert("nikita-1710", inode_dir_item_plugin(inode)); ++ if (inode_dir_item_plugin(inode)->s.dir.max_name_len) ++ return inode_dir_item_plugin(inode)->s.dir.max_name_len(inode); ++ else ++ return 255; ++} ++ ++#if REISER4_USE_COLLISION_LIMIT ++/* Maximal number of hash collisions for this directory. */ ++int max_hash_collisions(const struct inode *dir/* inode queried */) ++{ ++ assert("nikita-1711", dir != NULL); ++ return reiser4_inode_data(dir)->plugin.max_collisions; ++} ++#endif /* REISER4_USE_COLLISION_LIMIT */ ++ ++/* Install file, inode, and address_space operation on @inode, depending on ++ its mode. */ ++int setup_inode_ops(struct inode *inode /* inode to intialize */ , ++ reiser4_object_create_data * data /* parameters to create ++ * object */ ) ++{ ++ file_plugin *fplug; ++ dir_plugin *dplug; ++ ++ fplug = inode_file_plugin(inode); ++ dplug = inode_dir_plugin(inode); ++ ++ switch (inode->i_mode & S_IFMT) { ++ case S_IFSOCK: ++ case S_IFBLK: ++ case S_IFCHR: ++ case S_IFIFO: ++ { ++ dev_t rdev; /* to keep gcc happy */ ++ ++ assert("vs-46", fplug != NULL); ++ /* ugly hack with rdev */ ++ if (data == NULL) { ++ rdev = inode->i_rdev; ++ inode->i_rdev = 0; ++ } else ++ rdev = data->rdev; ++ inode->i_blocks = 0; ++ assert("vs-42", fplug->h.id == SPECIAL_FILE_PLUGIN_ID); ++ inode->i_op = file_plugins[fplug->h.id].inode_ops; ++ /* initialize inode->i_fop and inode->i_rdev for block ++ and char devices */ ++ init_special_inode(inode, inode->i_mode, rdev); ++ /* all address space operations are null */ ++ inode->i_mapping->a_ops = ++ file_plugins[fplug->h.id].as_ops; ++ break; ++ } ++ case S_IFLNK: ++ assert("vs-46", fplug != NULL); ++ assert("vs-42", fplug->h.id == SYMLINK_FILE_PLUGIN_ID); ++ inode->i_op = file_plugins[fplug->h.id].inode_ops; ++ inode->i_fop = NULL; ++ /* all address space operations are null */ ++ inode->i_mapping->a_ops = file_plugins[fplug->h.id].as_ops; ++ break; ++ case S_IFDIR: ++ assert("vs-46", dplug != NULL); ++ assert("vs-43", (dplug->h.id == HASHED_DIR_PLUGIN_ID || ++ dplug->h.id == SEEKABLE_HASHED_DIR_PLUGIN_ID)); ++ inode->i_op = dir_plugins[dplug->h.id].inode_ops; ++ inode->i_fop = dir_plugins[dplug->h.id].file_ops; ++ inode->i_mapping->a_ops = dir_plugins[dplug->h.id].as_ops; ++ break; ++ case S_IFREG: ++ assert("vs-46", fplug != NULL); ++ assert("vs-43", ++ fplug->h.id == UNIX_FILE_PLUGIN_ID || ++ fplug->h.id == CRYPTCOMPRESS_FILE_PLUGIN_ID || ++ fplug->h.id == STRIPED_FILE_PLUGIN_ID); ++ inode->i_op = file_plugins[fplug->h.id].inode_ops; ++ inode->i_fop = file_plugins[fplug->h.id].file_ops; ++ inode->i_mapping->a_ops = file_plugins[fplug->h.id].as_ops; ++ break; ++ default: ++ warning("nikita-291", "wrong file mode: %o for %llu", ++ inode->i_mode, ++ (unsigned long long)get_inode_oid(inode)); ++ reiser4_make_bad_inode(inode); ++ return RETERR(-EINVAL); ++ } ++ return 0; ++} ++ ++/* Initialize inode from disk data. Called with inode locked. ++ Return inode locked. */ ++static int init_inode(struct inode *inode /* inode to intialise */ , ++ coord_t *coord/* coord of stat data */) ++{ ++ int result; ++ item_plugin *iplug; ++ void *body; ++ int length; ++ reiser4_inode *state; ++ ++ assert("nikita-292", coord != NULL); ++ assert("nikita-293", inode != NULL); ++ ++ coord_clear_iplug(coord); ++ result = zload(coord->node); ++ if (result) ++ return result; ++ iplug = item_plugin_by_coord(coord); ++ body = item_body_by_coord(coord); ++ length = item_length_by_coord(coord); ++ ++ assert("nikita-295", iplug != NULL); ++ assert("nikita-296", body != NULL); ++ assert("nikita-297", length > 0); ++ ++ /* inode is under I_LOCK now */ ++ ++ state = reiser4_inode_data(inode); ++ /* call stat-data plugin method to load sd content into inode */ ++ result = iplug->s.sd.init_inode(inode, body, length); ++ set_plugin(&state->pset, PSET_SD, item_plugin_to_plugin(iplug)); ++ if (result == 0) { ++ result = setup_inode_ops(inode, NULL); ++ if (result == 0 && inode->i_sb->s_root && ++ inode->i_sb->s_root->d_inode) ++ result = finish_pset(inode); ++ } ++ zrelse(coord->node); ++ return result; ++} ++ ++/** ++ * Read @inode from the disk. ++ * This is what was previously in reiserfs_read_inode2(). ++ * Must be called with inode locked. Return inode still locked. ++ * ++ * @key: key of stat-data ++ * @bias: lookup bias - ++ * FIND_EXACT, if is the key is precise, ++ * FIND_MAX_NOT_MORE_THAN, if we don't know ordering ++ * component of the key ++ */ ++static int read_inode(struct inode *inode, const reiser4_key *key, ++ int bias, int silent) ++{ ++ int ret; ++ lock_handle lh; ++ reiser4_inode *info; ++ coord_t coord; ++ ++ assert("nikita-298", inode != NULL); ++ assert("nikita-1945", !is_inode_loaded(inode)); ++ ++ info = reiser4_inode_data(inode); ++ assert("nikita-300", info->locality_id != 0); ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ /* ++ * locate stat-data in a tree and return znode locked ++ */ ++ ret = lookup_sd(inode, ZNODE_READ_LOCK, &coord, &lh, ++ key, bias, silent); ++ assert("nikita-301", !is_inode_loaded(inode)); ++ if (ret) ++ goto error; ++ ++ if (bias == FIND_MAX_NOT_MORE_THAN) { ++ reiser4_key ikey; ++ /* ++ * check found coord - ++ * make sure that key of found item coincides ++ * with @key in all components except ordering ++ */ ++ ret = zload(coord.node); ++ if (ret) ++ goto error; ++ unit_key_by_coord(&coord, &ikey); ++ zrelse(coord.node); ++ ++ set_key_ordering((reiser4_key *)key, get_key_ordering(&ikey)); ++ ++ if (!keyeq(&ikey, key)) { ++ /* Stat-data killed by concurrent unlink */ ++#if REISER4_DEBUG ++ warning("edward-2134", ++ "inode %llu: stat-data not found by extent", ++ (unsigned long long)get_inode_oid(inode)); ++ reiser4_print_key("found", &ikey); ++#endif ++ ret = -ENOENT; ++ goto error; ++ } ++ } ++ /* ++ * load stat-data extensions into inode ++ */ ++ ret = init_inode(inode, &coord); ++ if (ret) ++ goto error; ++ ++ spin_lock_inode(inode); ++ reiser4_seal_init(&info->sd_seal, &coord, key); ++ info->sd_coord = coord; ++ spin_unlock_inode(inode); ++ /* ++ * call file plugin's method to initialize plugin ++ * specific part of inode ++ */ ++ if (inode_file_plugin(inode)->init_inode_data) ++ inode_file_plugin(inode)->init_inode_data(inode, NULL, key, 0); ++ /* ++ * load detached directory cursors for ++ * stateless directory readers (NFS) ++ */ ++ reiser4_load_cursors(inode); ++ ++ /* check the inode for consistency */ ++ ret = get_meta_subvol()->df_plug->check_open(inode); ++ /* ++ * lookup_sd() doesn't release coord because we want znode ++ * stay read-locked while stat-data fields are accessed in ++ * init_inode() ++ */ ++ done_lh(&lh); ++ return 0; ++ error: ++ done_lh(&lh); ++ reiser4_make_bad_inode(inode); ++ return ret; ++} ++ ++/* initialise new reiser4 inode being inserted into hash table. */ ++static int init_locked_inode(struct inode *inode /* new inode */ , ++ void *opaque /* key of stat data passed to ++ * the iget5_locked as cookie */) ++{ ++ reiser4_key *key; ++ ++ assert("nikita-1995", inode != NULL); ++ assert("nikita-1996", opaque != NULL); ++ key = opaque; ++ set_inode_oid(inode, get_key_objectid(key)); ++ reiser4_inode_data(inode)->locality_id = get_key_locality(key); ++ return 0; ++} ++ ++/* reiser4_inode_find_actor() - "find actor" supplied by reiser4 to ++ iget5_locked(). ++ ++ This function is called by iget5_locked() to distinguish reiser4 inodes ++ having the same inode numbers. Such inodes can only exist due to some error ++ condition. One of them should be bad. Inodes with identical inode numbers ++ (objectids) are distinguished by their packing locality. ++ ++*/ ++static int reiser4_inode_find_actor(struct inode *inode /* inode from hash table ++ * to check */ , ++ void *opaque /* "cookie" passed to ++ * iget5_locked(). This ++ * is stat-data key */) ++{ ++ reiser4_key *key; ++ ++ key = opaque; ++ return ++ /* oid is unique, so first term is enough, actually. */ ++ get_inode_oid(inode) == get_key_objectid(key) && ++ /* ++ * also, locality should be checked, but locality is stored in ++ * the reiser4-specific part of the inode, and actor can be ++ * called against arbitrary inode that happened to be in this ++ * hash chain. Hence we first have to check that this is ++ * reiser4 inode at least. is_reiser4_inode() is probably too ++ * early to call, as inode may have ->i_op not yet ++ * initialised. ++ */ ++ is_reiser4_super(inode->i_sb) && ++ /* ++ * usually objectid is unique, but pseudo files use counter to ++ * generate objectid. All pseudo files are placed into special ++ * (otherwise unused) locality. ++ */ ++ reiser4_inode_data(inode)->locality_id == get_key_locality(key); ++} ++ ++/* hook for kmem_cache_create */ ++void loading_init_once(reiser4_inode * info) ++{ ++ mutex_init(&info->loading); ++} ++ ++/* for reiser4_alloc_inode */ ++void loading_alloc(reiser4_inode * info) ++{ ++ assert("vs-1717", !mutex_is_locked(&info->loading)); ++} ++ ++/* for reiser4_destroy */ ++void loading_destroy(reiser4_inode * info) ++{ ++ assert("vs-1717a", !mutex_is_locked(&info->loading)); ++} ++ ++static void loading_begin(reiser4_inode * info) ++{ ++ mutex_lock(&info->loading); ++} ++ ++static void loading_end(reiser4_inode * info) ++{ ++ mutex_unlock(&info->loading); ++} ++ ++/** ++ * Obtain inode via iget5_locked, read from disk if necessary. ++ * This is helper function a la iget() called by lookup_common() and ++ * reiser4_read_super(). Return inode locked or error encountered. ++ * ++ * @super: super block of filesystem ++ * @key: key of inode's stat-data ++ * @bias: lookup bias - ++ * FIND_EXACT, if the key is precise, ++ * FIND_MAX_NOT_MORE_THAN, if we don't know ordering component ++ * of the key ++ */ ++struct inode *reiser4_iget(struct super_block *super, const reiser4_key *key, ++ lookup_bias bias, int silent) ++{ ++ struct inode *inode; ++ int result; ++ reiser4_inode *info; ++ ++ assert("nikita-302", super != NULL); ++ assert("nikita-303", key != NULL); ++ ++ result = 0; ++ ++ /* call iget(). Our ->read_inode() is dummy, so this will either ++ find inode in cache or return uninitialised inode */ ++ inode = iget5_locked(super, ++ (unsigned long)get_key_objectid(key), ++ reiser4_inode_find_actor, ++ init_locked_inode, (reiser4_key *) key); ++ if (inode == NULL) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ if (is_bad_inode(inode)) { ++ warning("nikita-304", "Bad inode found"); ++ reiser4_print_key("key", key); ++ iput(inode); ++ return ERR_PTR(RETERR(-EIO)); ++ } ++ ++ info = reiser4_inode_data(inode); ++ ++ /* Reiser4 inode state bit REISER4_LOADED is used to distinguish fully ++ loaded and initialized inode from just allocated inode. If ++ REISER4_LOADED bit is not set, reiser4_iget() completes loading under ++ info->loading. The place in reiser4 which uses not initialized inode ++ is the reiser4 repacker, see repacker-related functions in ++ plugin/item/extent.c */ ++ if (!is_inode_loaded(inode)) { ++ loading_begin(info); ++ if (!is_inode_loaded(inode)) { ++ /* locking: iget5_locked returns locked inode */ ++ assert("nikita-1941", !is_inode_loaded(inode)); ++ assert("nikita-1949", ++ reiser4_inode_find_actor(inode, ++ (reiser4_key *) key)); ++ /* now, inode has objectid as ->i_ino and locality in ++ reiser4-specific part. This is enough for ++ read_inode() to read stat data from the disk */ ++ result = read_inode(inode, key, bias, silent); ++ } else ++ loading_end(info); ++ } ++ ++ if (inode->i_state & I_NEW) ++ unlock_new_inode(inode); ++ ++ if (is_bad_inode(inode)) { ++ assert("vs-1717", result != 0); ++ loading_end(info); ++ iput(inode); ++ inode = ERR_PTR(result); ++ } else if (REISER4_DEBUG) { ++ reiser4_key found_key; ++ ++ assert("vs-1717", result == 0); ++ build_sd_key(inode, &found_key); ++ ++ if (bias == FIND_EXACT && ++ !keyeq(build_sd_key(inode, &found_key), key)) { ++ warning("nikita-305", "Wrong key in sd"); ++ reiser4_print_key("sought for", key); ++ reiser4_print_key("found", &found_key); ++ } ++ } ++ return inode; ++} ++ ++/* reiser4_iget() may return not fully initialized inode, this function should ++ * be called after one completes reiser4 inode initializing. */ ++void reiser4_iget_complete(struct inode *inode) ++{ ++ assert("zam-988", is_reiser4_inode(inode)); ++ ++ if (!is_inode_loaded(inode)) { ++ reiser4_inode_set_flag(inode, REISER4_LOADED); ++ loading_end(reiser4_inode_data(inode)); ++ } ++} ++ ++void reiser4_make_bad_inode(struct inode *inode) ++{ ++ assert("nikita-1934", inode != NULL); ++ ++ /* clear LOADED bit */ ++ reiser4_inode_clr_flag(inode, REISER4_LOADED); ++ make_bad_inode(inode); ++ return; ++} ++ ++file_plugin *inode_file_plugin(const struct inode *inode) ++{ ++ assert("nikita-1997", inode != NULL); ++ return reiser4_inode_data(inode)->pset->file; ++} ++ ++dir_plugin *inode_dir_plugin(const struct inode *inode) ++{ ++ assert("nikita-1998", inode != NULL); ++ return reiser4_inode_data(inode)->pset->dir; ++} ++ ++formatting_plugin *inode_formatting_plugin(const struct inode *inode) ++{ ++ assert("nikita-2000", inode != NULL); ++ return reiser4_inode_data(inode)->pset->formatting; ++} ++ ++hash_plugin *inode_hash_plugin(const struct inode *inode) ++{ ++ assert("nikita-2001", inode != NULL); ++ return reiser4_inode_data(inode)->pset->hash; ++} ++ ++fibration_plugin *inode_fibration_plugin(const struct inode *inode) ++{ ++ assert("nikita-2001", inode != NULL); ++ return reiser4_inode_data(inode)->pset->fibration; ++} ++ ++cipher_plugin *inode_cipher_plugin(const struct inode *inode) ++{ ++ assert("edward-36", inode != NULL); ++ return reiser4_inode_data(inode)->pset->cipher; ++} ++ ++compression_plugin *inode_compression_plugin(const struct inode *inode) ++{ ++ assert("edward-37", inode != NULL); ++ return reiser4_inode_data(inode)->pset->compression; ++} ++ ++compression_mode_plugin *inode_compression_mode_plugin(const struct inode * ++ inode) ++{ ++ assert("edward-1330", inode != NULL); ++ return reiser4_inode_data(inode)->pset->compression_mode; ++} ++ ++cluster_plugin *inode_cluster_plugin(const struct inode *inode) ++{ ++ assert("edward-1328", inode != NULL); ++ return reiser4_inode_data(inode)->pset->cluster; ++} ++ ++file_plugin *inode_create_plugin(const struct inode *inode) ++{ ++ assert("edward-1329", inode != NULL); ++ return reiser4_inode_data(inode)->pset->create; ++} ++ ++digest_plugin *inode_digest_plugin(const struct inode *inode) ++{ ++ assert("edward-86", inode != NULL); ++ return reiser4_inode_data(inode)->pset->digest; ++} ++ ++item_plugin *inode_sd_plugin(const struct inode *inode) ++{ ++ assert("vs-534", inode != NULL); ++ return reiser4_inode_data(inode)->pset->sd; ++} ++ ++item_plugin *inode_dir_item_plugin(const struct inode *inode) ++{ ++ assert("vs-534", inode != NULL); ++ return reiser4_inode_data(inode)->pset->dir_item; ++} ++ ++file_plugin *child_create_plugin(const struct inode *inode) ++{ ++ assert("edward-1329", inode != NULL); ++ return reiser4_inode_data(inode)->hset->create; ++} ++ ++void inode_set_extension(struct inode *inode, sd_ext_bits ext) ++{ ++ reiser4_inode *state; ++ ++ assert("nikita-2716", inode != NULL); ++ assert("nikita-2717", ext < LAST_SD_EXTENSION); ++ assert("nikita-3491", spin_inode_is_locked(inode)); ++ ++ state = reiser4_inode_data(inode); ++ state->extmask |= 1 << ext; ++ /* force re-calculation of stat-data length on next call to ++ update_sd(). */ ++ reiser4_inode_clr_flag(inode, REISER4_SDLEN_KNOWN); ++} ++ ++void inode_clr_extension(struct inode *inode, sd_ext_bits ext) ++{ ++ reiser4_inode *state; ++ ++ assert("vpf-1926", inode != NULL); ++ assert("vpf-1927", ext < LAST_SD_EXTENSION); ++ assert("vpf-1928", spin_inode_is_locked(inode)); ++ ++ state = reiser4_inode_data(inode); ++ state->extmask &= ~(1 << ext); ++ /* force re-calculation of stat-data length on next call to ++ update_sd(). */ ++ reiser4_inode_clr_flag(inode, REISER4_SDLEN_KNOWN); ++} ++ ++void inode_check_scale_nolock(struct inode *inode, __u64 old, __u64 new) ++{ ++ assert("edward-1287", inode != NULL); ++ if (!dscale_fit(old, new)) ++ reiser4_inode_clr_flag(inode, REISER4_SDLEN_KNOWN); ++ return; ++} ++ ++void inode_check_scale(struct inode *inode, __u64 old, __u64 new) ++{ ++ assert("nikita-2875", inode != NULL); ++ spin_lock_inode(inode); ++ inode_check_scale_nolock(inode, old, new); ++ spin_unlock_inode(inode); ++} ++ ++/** ++ * initialize ->ordering field of inode. This field defines how file stat-data ++ * and body is ordered within a tree with respect to other objects within the ++ * same parent directory. ++ */ ++void init_inode_ordering(struct inode *inode, reiser4_object_create_data *crd, ++ const reiser4_key *sd_key, int create) ++{ ++ if (create) { ++ reiser4_key key; ++ struct inode *parent; ++ ++ assert("edward-2210", crd != NULL); ++ parent = crd->parent; ++ assert("nikita-3224", inode_dir_plugin(parent) != NULL); ++ inode_dir_plugin(parent)->build_entry_key(parent, ++ &crd->dentry->d_name, ++ &key); ++ set_inode_ordering(inode, get_key_ordering(&key)); ++ } else { ++ assert("edward-2211", sd_key != NULL); ++ set_inode_ordering(inode, get_key_ordering(sd_key)); ++ } ++} ++ ++znode *inode_get_vroot(struct inode *inode) ++{ ++ reiser4_block_nr blk; ++ znode *result; ++ ++ spin_lock_inode(inode); ++ blk = reiser4_inode_data(inode)->vroot; ++ spin_unlock_inode(inode); ++ if (!disk_addr_eq(&UBER_TREE_ADDR, &blk)) ++ result = zlook(meta_subvol_tree(), &blk); ++ else ++ result = NULL; ++ return result; ++} ++ ++void inode_set_vroot(struct inode *inode, znode *vroot) ++{ ++ spin_lock_inode(inode); ++ reiser4_inode_data(inode)->vroot = *znode_get_block(vroot); ++ spin_unlock_inode(inode); ++} ++ ++#if REISER4_DEBUG ++ ++void reiser4_inode_invariant(const struct inode *inode) ++{ ++ assert("nikita-3077", spin_inode_is_locked(inode)); ++} ++ ++int inode_has_no_jnodes(reiser4_inode * r4_inode) ++{ ++ return radix_tree_empty(jnode_tree_by_reiser4_inode(r4_inode)) && ++ r4_inode->nr_jnodes == 0; ++} ++ ++#endif ++ ++/* true if directory is empty (only contains dot and dotdot) */ ++/* FIXME: shouldn't it be dir plugin method? */ ++int is_dir_empty(const struct inode *dir) ++{ ++ assert("nikita-1976", dir != NULL); ++ ++ /* rely on our method to maintain directory i_size being equal to the ++ number of entries. */ ++ return dir->i_size <= 2 ? 0 : RETERR(-ENOTEMPTY); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/inode.h linux-5.10.2/fs/reiser4/inode.h +--- linux-5.10.2.orig/fs/reiser4/inode.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/inode.h 2020-12-23 16:07:46.118813129 +0100 +@@ -0,0 +1,506 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* Inode functions. */ ++ ++#if !defined(__REISER4_INODE_H__) ++#define __REISER4_INODE_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "seal.h" ++#include "plugin/plugin.h" ++#include "plugin/file/cryptcompress.h" ++#include "plugin/file/file.h" ++#include "plugin/dir/dir.h" ++#include "plugin/plugin_set.h" ++#include "plugin/security/perm.h" ++#include "vfs_ops.h" ++#include "jnode.h" ++#include "fsdata.h" ++ ++#include /* for __u?? , ino_t */ ++#include /* for struct super_block, struct ++ * rw_semaphore, etc */ ++#include ++#include ++ ++/* reiser4-specific inode flags. They are "transient" and are not ++ supposed to be stored on disk. Used to trace "state" of ++ inode ++*/ ++typedef enum { ++ /* this is light-weight inode, inheriting some state from its ++ parent */ ++ REISER4_LIGHT_WEIGHT = 0, ++ /* stat data wasn't yet created */ ++ REISER4_NO_SD = 1, ++ /* internal immutable flag. Currently is only used ++ to avoid race condition during file creation. ++ See comment in create_object(). */ ++ REISER4_IMMUTABLE = 2, ++ /* inode was read from storage */ ++ REISER4_LOADED = 3, ++ /* this bit is set for symlinks. inode->i_private points to target ++ name of symlink. */ ++ REISER4_GENERIC_PTR_USED = 4, ++ /* set if size of stat-data item for this inode is known. If this is ++ * set we can avoid recalculating size of stat-data on each update. */ ++ REISER4_SDLEN_KNOWN = 5, ++ /* reiser4_inode->crypt points to the crypto stat */ ++ REISER4_CRYPTO_STAT_LOADED = 6, ++ /* cryptcompress_inode_data points to the secret key */ ++ REISER4_SECRET_KEY_INSTALLED = 7, ++ /* File (possibly) has pages corresponding to the tail items, that ++ * were created by ->readpage. It is set by mmap_unix_file() and ++ * sendfile_unix_file(). This bit is inspected by write_unix_file and ++ * kill-hook of tail items. It is never cleared once set. This bit is ++ * modified and inspected under i_mutex. */ ++ REISER4_HAS_MMAP = 8, ++ REISER4_FAKE_IMODE_ONDISK = 9, ++ REISER4_PART_MIXED = REISER4_FAKE_IMODE_ONDISK, ++ REISER4_FILE_IMMOBILE = REISER4_FAKE_IMODE_ONDISK, ++ REISER4_PART_IN_CONV = 10, ++ REISER4_FILE_IN_CONVERSION = 11, ++ REISER4_FILE_IN_MIGRATION = 12, ++} reiser4_file_plugin_flags; ++ ++/* state associated with each inode. ++ reiser4 inode. ++ ++ NOTE-NIKITA In 2.5 kernels it is not necessary that all file-system inodes ++ be of the same size. File-system allocates inodes by itself through ++ s_op->allocate_inode() method. So, it is possible to adjust size of inode ++ at the time of its creation. ++ ++ Invariants involving parts of this data-type: ++ ++ [inode->eflushed] ++ ++*/ ++ ++typedef struct reiser4_inode reiser4_inode; ++/* return pointer to reiser4-specific part of inode */ ++static inline reiser4_inode *reiser4_inode_data(const struct inode *inode ++ /* inode queried */ ); ++ ++#if BITS_PER_LONG == 64 ++ ++#define REISER4_INO_IS_OID (1) ++typedef struct {; ++} oid_hi_t; ++ ++/* BITS_PER_LONG == 64 */ ++#else ++ ++#define REISER4_INO_IS_OID (0) ++typedef __u32 oid_hi_t; ++ ++/* BITS_PER_LONG == 64 */ ++#endif ++ ++struct reiser4_inode { ++ /* spin lock protecting fields of this structure. */ ++ spinlock_t guard; ++ /* main plugin set that control the file ++ (see comments in plugin/plugin_set.c) */ ++ plugin_set *pset; ++ /* plugin set for inheritance ++ (see comments in plugin/plugin_set.c) */ ++ plugin_set *hset; ++ /* high 32 bits of object id */ ++ oid_hi_t oid_hi; ++ /* seal for stat-data */ ++ seal_t sd_seal; ++ /* locality id for this file */ ++ oid_t locality_id; ++#if REISER4_LARGE_KEY ++ __u64 ordering; ++#endif ++ /* coord of stat-data in sealed node */ ++ coord_t sd_coord; ++ /* bit-mask of stat-data extentions used by this file */ ++ __u64 extmask; ++ /* bitmask of non-default plugins for this inode */ ++ __u16 plugin_mask; ++ /* bitmask of set heir plugins for this inode. */ ++ __u16 heir_mask; ++ union { ++ struct list_head readdir_list; ++ struct list_head not_used; ++ } lists; ++ /* per-inode flags. Filled by values of reiser4_file_plugin_flags */ ++ unsigned long flags; ++ union { ++ /* fields specific to unix_file plugin */ ++ struct unix_file_info unix_file_info; ++ /* fields specific to cryptcompress file plugin */ ++ struct cryptcompress_info cryptcompress_info; ++ } file_plugin_data; ++ ++ /* this semaphore is to serialize readers and writers of @pset->file ++ * when file plugin conversion is enabled ++ */ ++ struct rw_semaphore conv_sem; ++ ++ /* tree of jnodes. Phantom jnodes (ones not attched to any atom) are ++ tagged in that tree by EFLUSH_TAG_ANONYMOUS */ ++ struct radix_tree_root jnodes_tree; ++#if REISER4_DEBUG ++ /* number of unformatted node jnodes of this file in jnode hash table */ ++ unsigned long nr_jnodes; ++#endif ++ /* block number of virtual root for this object. See comment above ++ * fs/reiser4/search.c:handle_vroot() */ ++ reiser4_block_nr vroot; ++ struct mutex loading; ++}; ++ ++void loading_init_once(reiser4_inode *); ++void loading_alloc(reiser4_inode *); ++void loading_destroy(reiser4_inode *); ++ ++struct reiser4_inode_object { ++ /* private part */ ++ reiser4_inode p; ++ /* generic fields not specific to reiser4, but used by VFS */ ++ struct inode vfs_inode; ++}; ++ ++/* return pointer to the reiser4 specific portion of @inode */ ++static inline reiser4_inode *reiser4_inode_data(const struct inode *inode ++ /* inode queried */ ) ++{ ++ assert("nikita-254", inode != NULL); ++ return &container_of(inode, struct reiser4_inode_object, vfs_inode)->p; ++} ++ ++static inline struct inode *inode_by_reiser4_inode(const reiser4_inode * ++ r4_inode /* inode queried */ ++ ) ++{ ++ return &container_of(r4_inode, struct reiser4_inode_object, ++ p)->vfs_inode; ++} ++ ++/* ++ * reiser4 inodes are identified by 64bit object-id (oid_t), but in struct ++ * inode ->i_ino field is of type ino_t (long) that can be either 32 or 64 ++ * bits. ++ * ++ * If ->i_ino is 32 bits we store remaining 32 bits in reiser4 specific part ++ * of inode, otherwise whole oid is stored in i_ino. ++ * ++ * Wrappers below ([sg]et_inode_oid()) are used to hide this difference. ++ */ ++ ++#define OID_HI_SHIFT (sizeof(ino_t) * 8) ++ ++#if REISER4_INO_IS_OID ++ ++static inline oid_t get_inode_oid(const struct inode *inode) ++{ ++ return inode->i_ino; ++} ++ ++static inline void set_inode_oid(struct inode *inode, oid_t oid) ++{ ++ inode->i_ino = oid; ++} ++ ++/* REISER4_INO_IS_OID */ ++#else ++ ++static inline oid_t get_inode_oid(const struct inode *inode) ++{ ++ return ++ ((__u64) reiser4_inode_data(inode)->oid_hi << OID_HI_SHIFT) | ++ inode->i_ino; ++} ++ ++static inline void set_inode_oid(struct inode *inode, oid_t oid) ++{ ++ assert("nikita-2519", inode != NULL); ++ inode->i_ino = (ino_t) (oid); ++ reiser4_inode_data(inode)->oid_hi = (oid) >> OID_HI_SHIFT; ++ assert("nikita-2521", get_inode_oid(inode) == (oid)); ++} ++ ++/* REISER4_INO_IS_OID */ ++#endif ++ ++static inline oid_t get_inode_locality(const struct inode *inode) ++{ ++ return reiser4_inode_data(inode)->locality_id; ++} ++ ++#if REISER4_LARGE_KEY ++static inline __u64 get_inode_ordering(const struct inode *inode) ++{ ++ return reiser4_inode_data(inode)->ordering; ++} ++ ++static inline void set_inode_ordering(const struct inode *inode, __u64 ordering) ++{ ++ reiser4_inode_data(inode)->ordering = ordering; ++} ++ ++#else ++ ++#define get_inode_ordering(inode) (0) ++#define set_inode_ordering(inode, val) noop ++ ++#endif ++ ++/* return inode in which @uf_info is embedded */ ++static inline struct inode * ++unix_file_info_to_inode(const struct unix_file_info *uf_info) ++{ ++ return &container_of(uf_info, struct reiser4_inode_object, ++ p.file_plugin_data.unix_file_info)->vfs_inode; ++} ++ ++extern ino_t oid_to_ino(oid_t oid) __attribute__ ((const)); ++extern ino_t oid_to_uino(oid_t oid) __attribute__ ((const)); ++ ++#if REISER4_DEBUG ++extern void reiser4_inode_invariant(const struct inode *inode); ++extern int inode_has_no_jnodes(reiser4_inode *); ++#else ++#define reiser4_inode_invariant(inode) noop ++#endif ++ ++static inline int spin_inode_is_locked(const struct inode *inode) ++{ ++ assert_spin_locked(&reiser4_inode_data(inode)->guard); ++ return 1; ++} ++ ++/** ++ * spin_lock_inode - lock reiser4_inode' embedded spinlock ++ * @inode: inode to lock ++ * ++ * In debug mode it checks that lower priority locks are not held and ++ * increments reiser4_context's lock counters on which lock ordering checking ++ * is based. ++ */ ++static inline void spin_lock_inode(struct inode *inode) ++{ ++ assert("", LOCK_CNT_NIL(spin_locked)); ++ /* check lock ordering */ ++ assert_spin_not_locked(&d_c_lock); ++ ++ spin_lock(&reiser4_inode_data(inode)->guard); ++ ++ LOCK_CNT_INC(spin_locked_inode); ++ LOCK_CNT_INC(spin_locked); ++ ++ reiser4_inode_invariant(inode); ++} ++ ++/** ++ * spin_unlock_inode - unlock reiser4_inode' embedded spinlock ++ * @inode: inode to unlock ++ * ++ * In debug mode it checks that spinlock is held and decrements ++ * reiser4_context's lock counters on which lock ordering checking is based. ++ */ ++static inline void spin_unlock_inode(struct inode *inode) ++{ ++ assert_spin_locked(&reiser4_inode_data(inode)->guard); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_inode)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ reiser4_inode_invariant(inode); ++ ++ LOCK_CNT_DEC(spin_locked_inode); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&reiser4_inode_data(inode)->guard); ++} ++ ++extern znode *inode_get_vroot(struct inode *inode); ++extern void inode_set_vroot(struct inode *inode, znode * vroot); ++ ++extern int reiser4_max_filename_len(const struct inode *inode); ++extern int max_hash_collisions(const struct inode *dir); ++extern void reiser4_unlock_inode(struct inode *inode); ++extern int is_reiser4_inode(const struct inode *inode); ++extern int setup_inode_ops(struct inode *inode, reiser4_object_create_data *); ++extern struct inode *reiser4_iget(struct super_block *super, const reiser4_key *key, ++ lookup_bias bias, int silent); ++extern void reiser4_iget_complete(struct inode *inode); ++extern void reiser4_inode_set_flag(struct inode *inode, ++ reiser4_file_plugin_flags f); ++extern void reiser4_inode_clr_flag(struct inode *inode, ++ reiser4_file_plugin_flags f); ++extern int reiser4_inode_get_flag(const struct inode *inode, ++ reiser4_file_plugin_flags f); ++ ++/* has inode been initialized? */ ++static inline int ++is_inode_loaded(const struct inode *inode/* inode queried */) ++{ ++ assert("nikita-1120", inode != NULL); ++ return reiser4_inode_get_flag(inode, REISER4_LOADED); ++} ++ ++extern file_plugin *inode_file_plugin(const struct inode *inode); ++extern dir_plugin *inode_dir_plugin(const struct inode *inode); ++extern formatting_plugin *inode_formatting_plugin(const struct inode *inode); ++extern hash_plugin *inode_hash_plugin(const struct inode *inode); ++extern fibration_plugin *inode_fibration_plugin(const struct inode *inode); ++extern cipher_plugin *inode_cipher_plugin(const struct inode *inode); ++extern digest_plugin *inode_digest_plugin(const struct inode *inode); ++extern compression_plugin *inode_compression_plugin(const struct inode *inode); ++extern compression_mode_plugin *inode_compression_mode_plugin(const struct inode ++ *inode); ++extern cluster_plugin *inode_cluster_plugin(const struct inode *inode); ++extern file_plugin *inode_create_plugin(const struct inode *inode); ++extern item_plugin *inode_sd_plugin(const struct inode *inode); ++extern item_plugin *inode_dir_item_plugin(const struct inode *inode); ++extern file_plugin *child_create_plugin(const struct inode *inode); ++ ++extern void reiser4_make_bad_inode(struct inode *inode); ++ ++extern void inode_set_extension(struct inode *inode, sd_ext_bits ext); ++extern void inode_clr_extension(struct inode *inode, sd_ext_bits ext); ++extern void inode_check_scale(struct inode *inode, __u64 old, __u64 new); ++extern void inode_check_scale_nolock(struct inode *inode, __u64 old, __u64 new); ++ ++#define INODE_SET_SIZE(i, value) \ ++({ \ ++ struct inode *__i; \ ++ typeof(value) __v; \ ++ \ ++ __i = (i); \ ++ __v = (value); \ ++ inode_check_scale(__i, __i->i_size, __v); \ ++ i_size_write(__i, __v); \ ++}) ++ ++/* ++ * update field @field in inode @i to contain value @value. ++ */ ++#define INODE_SET_FIELD(i, field, value) \ ++({ \ ++ struct inode *__i; \ ++ typeof(value) __v; \ ++ \ ++ __i = (i); \ ++ __v = (value); \ ++ inode_check_scale(__i, __i->field, __v); \ ++ __i->field = __v; \ ++}) ++ ++#define INODE_INC_FIELD(i, field) \ ++({ \ ++ struct inode *__i; \ ++ \ ++ __i = (i); \ ++ inode_check_scale(__i, __i->field, __i->field + 1); \ ++ ++ __i->field; \ ++}) ++ ++#define INODE_DEC_FIELD(i, field) \ ++({ \ ++ struct inode *__i; \ ++ \ ++ __i = (i); \ ++ inode_check_scale(__i, __i->field, __i->field - 1); \ ++ -- __i->field; \ ++}) ++ ++/* ++ * Update field i_nlink in inode @i using library function @op. ++ */ ++#define INODE_SET_NLINK(i, value) \ ++({ \ ++ struct inode *__i; \ ++ typeof(value) __v; \ ++ \ ++ __i = (i); \ ++ __v = (value); \ ++ inode_check_scale(__i, __i->i_nlink, __v); \ ++ set_nlink(__i, __v); \ ++}) ++ ++#define INODE_INC_NLINK(i) \ ++ ({ \ ++ struct inode *__i; \ ++ \ ++ __i = (i); \ ++ inode_check_scale(__i, __i->i_nlink, __i->i_nlink + 1); \ ++ inc_nlink(__i); \ ++}) ++ ++#define INODE_DROP_NLINK(i) \ ++ ({ \ ++ struct inode *__i; \ ++ \ ++ __i = (i); \ ++ inode_check_scale(__i, __i->i_nlink, __i->i_nlink - 1); \ ++ drop_nlink(__i); \ ++}) ++ ++#define INODE_CLEAR_NLINK(i) \ ++ ({ \ ++ struct inode *__i; \ ++ \ ++ __i = (i); \ ++ inode_check_scale(__i, __i->i_nlink, 0); \ ++ clear_nlink(__i); \ ++}) ++ ++ ++static inline void inode_add_blocks(struct inode *inode, __u64 blocks) ++{ ++ inode_add_bytes(inode, blocks << inode->i_blkbits); ++} ++ ++static inline void inode_sub_blocks(struct inode *inode, __u64 blocks) ++{ ++ inode_sub_bytes(inode, blocks << inode->i_blkbits); ++} ++ ++ ++/* See comment before reiser4_readdir_common() for description. */ ++static inline struct list_head *get_readdir_list(const struct inode *inode) ++{ ++ return &reiser4_inode_data(inode)->lists.readdir_list; ++} ++ ++extern void init_inode_ordering(struct inode *inode, ++ reiser4_object_create_data *crd, ++ const reiser4_key *sd_key, int create); ++ ++static inline struct radix_tree_root *jnode_tree_by_inode(struct inode *inode) ++{ ++ return &reiser4_inode_data(inode)->jnodes_tree; ++} ++ ++static inline struct radix_tree_root *jnode_tree_by_reiser4_inode(reiser4_inode ++ *r4_inode) ++{ ++ return &r4_inode->jnodes_tree; ++} ++ ++#if REISER4_DEBUG ++extern void print_inode(const char *prefix, const struct inode *i); ++#endif ++ ++int is_dir_empty(const struct inode *); ++ ++/* __REISER4_INODE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/ioctl.h linux-5.10.2/fs/reiser4/ioctl.h +--- linux-5.10.2.orig/fs/reiser4/ioctl.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/ioctl.h 2020-12-23 16:07:46.118813129 +0100 +@@ -0,0 +1,187 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#if !defined(__REISER4_IOCTL_H__) ++#define __REISER4_IOCTL_H__ ++ ++#include ++ ++/* ++ * ioctl(2) command used to "unpack" reiser4 file, that is, convert it into ++ * extents and fix in this state. This is used by applications that rely on ++ * ++ * . files being block aligned, and ++ * ++ * . files never migrating on disk ++ * ++ * for example, boot loaders (LILO) need this. ++ * ++ * This ioctl should be used as ++ * ++ * result = ioctl(fd, REISER4_IOC_UNPACK); ++ * ++ * File behind fd descriptor will be converted to the extents (if necessary), ++ * and its stat-data will be updated so that it will never be converted back ++ * into tails again. ++ */ ++ ++/* ++ * On-line per-volume and per-subvolume flags. ++ * They are set up for (re)mount session and are not stored on disk ++ */ ++typedef enum { ++ /* ++ * True if this file system doesn't support hard-links (multiple names) ++ * for directories: this is default UNIX behavior. ++ * ++ * If hard-links on directoires are not allowed, file system is Acyclic ++ * Directed Graph (modulo dot, and dotdot, of course). ++ * ++ * This is used by reiser4_link(). ++ */ ++ REISER4_ADG = 0, ++ /* if set, bsd gid assignment is supported. */ ++ REISER4_BSD_GID = 2, ++ /* [mac]_time are 32 bit in inode */ ++ REISER4_32_BIT_TIMES = 3, ++ /* load all bitmap blocks at mount time */ ++ REISER4_DONT_LOAD_BITMAP = 5, ++ /* enforce atomicity during write(2) */ ++ REISER4_ATOMIC_WRITE = 6, ++ /* enable issuing of discard requests */ ++ REISER4_DISCARD = 8, ++ /* disable hole punching at flush time */ ++ REISER4_DONT_PUNCH_HOLES = 9, ++ /* volume is ready for regular operations */ ++ REISER4_ACTIVATED_VOL = 10, ++ /* volume is in unbalanced state */ ++ REISER4_UNBALANCED_VOL = 12, ++ /* this flag indicates that volume operation was ++ interrupted for some reasons (e.g. system crash), ++ and should be completed in some context */ ++ REISER4_INCOMPLETE_BRICK_REMOVAL = 13, ++ /* proxy-subvolume is active */ ++ REISER4_PROXY_ENABLED = 15, ++ /* proxy subvolume accepts IO requests */ ++ REISER4_PROXY_IO = 16 ++} reiser4_fs_flag; ++ ++typedef enum { ++ /* set if all nodes in internal tree have the same ++ * node layout plugin. See znode_guess_plugin() */ ++ SUBVOL_ONE_NODE_PLUGIN = 0, ++ /* set if subvolume lives on a solid state drive */ ++ SUBVOL_IS_NONROT_DEVICE = 1, ++ /* set if subvol is registered */ ++ SUBVOL_REGISTERED = 2, ++ /* set if subvol is activated */ ++ SUBVOL_ACTIVATED = 3, ++ /* set if brick is used for data storage and participates ++ in regular data distribution */ ++ SUBVOL_HAS_DATA_ROOM = 4, ++ /* set if subvolume is not included in volume configuration ++ and doesn't accept any IOs */ ++ SUBVOL_IS_ORPHAN = 5, ++ /* set if brick was scheduled for removal. It may be not ++ empty and may accept IOs */ ++ SUBVOL_TO_BE_REMOVED = 6, ++ /* set if brick is used for data storage, but doesn't ++ participate in regular data distribution */ ++ SUBVOL_IS_PROXY = 7 ++} reiser4_subvol_flag; ++ ++#define REISER4_PATH_NAME_MAX 3900 /* FIXME: make it more precise */ ++ ++typedef enum { ++ REISER4_INVALID_OPT, ++ REISER4_REGISTER_BRICK, ++ REISER4_UNREGISTER_BRICK, ++ REISER4_LIST_BRICKS, ++ REISER4_VOLUME_HEADER, ++ REISER4_BRICK_HEADER, ++ REISER4_PRINT_VOLUME, ++ REISER4_PRINT_BRICK, ++ REISER4_RESIZE_BRICK, ++ REISER4_ADD_BRICK, ++ REISER4_REMOVE_BRICK, ++ REISER4_SCALE_VOLUME, ++ REISER4_BALANCE_VOLUME, ++ REISER4_ADD_PROXY, ++ REISER4_MIGRATE_FILE, ++ REISER4_SET_FILE_IMMOBILE, ++ REISER4_CLR_FILE_IMMOBILE, ++ REISER4_FINISH_REMOVAL, ++ REISER4_RESTORE_REGULAR_DST ++} reiser4_vol_op; ++ ++typedef enum { ++ COMPLETE_WITH_BALANCE = 0x1 ++} reiser4_vol_op_flags; ++ ++struct reiser4_volume_stat ++{ ++ u8 id[16]; /* unique ID */ ++ u32 nr_bricks; /* total number of bricks in the volume */ ++ u32 bricks_in_dsa; /* number of bricks in DSA */ ++ u16 vpid; /* volume plugin ID */ ++ u16 dpid; /* distribution plugin ID */ ++ u16 stripe_bits; /* logarithm of stripe size */ ++ u16 nr_sgs_bits; /* logarithm of number of hash space segments */ ++ u64 fs_flags; /* the same as the one of private super-block */ ++ u32 nr_mslots; /* number of slots */ ++ u32 nr_volinfo_blocks; /* Total number of blocks in the set ++ where volume configuration is stored */ ++}; ++ ++struct reiser4_brick_stat ++{ ++ u64 int_id; /* ordered number, 0 means meta-data brick */ ++ u8 ext_id[16]; /* external unique ID */ ++ u16 nr_replicas; /* number of replicas */ ++ u64 subv_flags; /* per-subvolume on-line flags */ ++ u64 block_count; /* total number of blocks on the device */ ++ u64 data_capacity; /* "weight" of the brick in data storage array */ ++ u64 blocks_used; /* number of blocks used by data and meta-data */ ++ u64 system_blocks; /* minimal number of blocks, which are occupied by ++ system data (super-blocks, bitmap blocks, etc) */ ++ u64 volinfo_addr; /* disk address of the first block of a portion ++ of volume configuration stored on this brick */ ++}; ++ ++struct reiser4_vol_op_args ++{ ++ reiser4_vol_op opcode; ++ int error; ++ u64 new_capacity; ++ u64 flags; ++ union { ++ u64 brick_idx; /* index of brick in logical volume */ ++ u64 vol_idx; /* serial num of volume in the list of volumes */ ++ u64 val; ++ }s; ++ union { ++ char name[REISER4_PATH_NAME_MAX + 1]; ++ }d; ++ struct { ++ struct reiser4_volume_stat vol; ++ struct reiser4_brick_stat brick; ++ }u; ++}; ++ ++#define REISER4_IOC_UNPACK _IOW(0xCD, 1, long) ++#define REISER4_IOC_VOLUME _IOWR(0xCD, 2, struct reiser4_vol_op_args) ++#define REISER4_IOC_SCAN_DEV _IOWR(0xCD, 3, struct reiser4_vol_op_args) ++ ++/* __REISER4_IOCTL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/jnode.c linux-5.10.2/fs/reiser4/jnode.c +--- linux-5.10.2.orig/fs/reiser4/jnode.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/jnode.c 2020-12-23 16:07:46.118813129 +0100 +@@ -0,0 +1,1969 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++/* Jnode manipulation functions. */ ++/* Jnode is entity used to track blocks with data and meta-data in reiser4. ++ ++ In particular, jnodes are used to track transactional information ++ associated with each block. Each znode contains jnode as ->zjnode field. ++ ++ Jnode stands for either Josh or Journal node. ++*/ ++ ++/* ++ * Taxonomy. ++ * ++ * Jnode represents block containing data or meta-data. There are jnodes ++ * for: ++ * ++ * unformatted blocks (jnodes proper). There are plans, however to ++ * have a handle per extent unit rather than per each unformatted ++ * block, because there are so many of them. ++ * ++ * For bitmaps. Each bitmap is actually represented by two jnodes--one ++ * for working and another for "commit" data, together forming bnode. ++ * ++ * For io-heads. These are used by log writer. ++ * ++ * For formatted nodes (znode). See comment at the top of znode.c for ++ * details specific to the formatted nodes (znodes). ++ * ++ * Node data. ++ * ++ * Jnode provides access to the data of node it represents. Data are ++ * stored in a page. Page is kept in a page cache. This means, that jnodes ++ * are highly interconnected with page cache and VM internals. ++ * ++ * jnode has a pointer to page (->pg) containing its data. Pointer to data ++ * themselves is cached in ->data field to avoid frequent calls to ++ * page_address(). ++ * ++ * jnode and page are attached to each other by jnode_attach_page(). This ++ * function places pointer to jnode in set_page_private(), sets PG_private ++ * flag and increments page counter. ++ * ++ * Opposite operation is performed by page_clear_jnode(). ++ * ++ * jnode->pg is protected by jnode spin lock, and page->private is ++ * protected by page lock. See comment at the top of page_cache.c for ++ * more. ++ * ++ * page can be detached from jnode for two reasons: ++ * ++ * . jnode is removed from a tree (file is truncated, of formatted ++ * node is removed by balancing). ++ * ++ * . during memory pressure, VM calls ->releasepage() method ++ * (reiser4_releasepage()) to evict page from memory. ++ * ++ * (there, of course, is also umount, but this is special case we are not ++ * concerned with here). ++ * ++ * To protect jnode page from eviction, one calls jload() function that ++ * "pins" page in memory (loading it if necessary), increments ++ * jnode->d_count, and kmap()s page. Page is unpinned through call to ++ * jrelse(). ++ * ++ * Jnode life cycle. ++ * ++ * jnode is created, placed in hash table, and, optionally, in per-inode ++ * radix tree. Page can be attached to jnode, pinned, released, etc. ++ * ++ * When jnode is captured into atom its reference counter is ++ * increased. While being part of an atom, jnode can be "early ++ * flushed". This means that as part of flush procedure, jnode is placed ++ * into "relocate set", and its page is submitted to the disk. After io ++ * completes, page can be detached, then loaded again, re-dirtied, etc. ++ * ++ * Thread acquired reference to jnode by calling jref() and releases it by ++ * jput(). When last reference is removed, jnode is still retained in ++ * memory (cached) if it has page attached, _unless_ it is scheduled for ++ * destruction (has JNODE_HEARD_BANSHEE bit set). ++ * ++ * Tree read-write lock was used as "existential" lock for jnodes. That is, ++ * jnode->x_count could be changed from 0 to 1 only under tree write lock, ++ * that is, tree lock protected unreferenced jnodes stored in the hash ++ * table, from recycling. ++ * ++ * This resulted in high contention on tree lock, because jref()/jput() is ++ * frequent operation. To ameliorate this problem, RCU is used: when jput() ++ * is just about to release last reference on jnode it sets JNODE_RIP bit ++ * on it, and then proceed with jnode destruction (removing jnode from hash ++ * table, cbk_cache, detaching page, etc.). All places that change jnode ++ * reference counter from 0 to 1 (jlookup(), zlook(), zget(), and ++ * cbk_cache_scan_slots()) check for JNODE_RIP bit (this is done by ++ * jnode_rip_check() function), and pretend that nothing was found in hash ++ * table if bit is set. ++ * ++ * jput defers actual return of jnode into slab cache to some later time ++ * (by call_rcu()), this guarantees that other threads can safely continue ++ * working with JNODE_RIP-ped jnode. ++ * ++ */ ++ ++#include "reiser4.h" ++#include "debug.h" ++#include "dformat.h" ++#include "jnode.h" ++#include "plugin/plugin_header.h" ++#include "plugin/plugin.h" ++#include "txnmgr.h" ++/*#include "jnode.h"*/ ++#include "znode.h" ++#include "tree.h" ++#include "tree_walk.h" ++#include "super.h" ++#include "inode.h" ++#include "page_cache.h" ++ ++#include /* UML needs this for PAGE_OFFSET */ ++#include ++#include ++#include ++#include ++#include /* for struct address_space */ ++#include /* for inode_wb_list_lock */ ++ ++static struct kmem_cache *_jnode_slab = NULL; ++ ++static void jnode_set_type(jnode *node, jnode_type type); ++static int jdelete(jnode *node); ++static int jnode_try_drop(jnode *node); ++static int jnode_start_read(jnode *node, struct page *page); ++ ++#if REISER4_DEBUG ++static int jnode_invariant(jnode *node, int tlocked, int jlocked); ++#endif ++ ++/* true if valid page is attached to jnode */ ++static inline int jnode_is_parsed(jnode * node) ++{ ++ return JF_ISSET(node, JNODE_PARSED); ++} ++ ++/* hash table support */ ++ ++/* compare two jnode keys for equality. Used by hash-table macros */ ++static inline int jnode_key_eq(const struct jnode_key *k1, ++ const struct jnode_key *k2) ++{ ++ assert("nikita-2350", k1 != NULL); ++ assert("nikita-2351", k2 != NULL); ++ ++ return (k1->index == k2->index && k1->objectid == k2->objectid); ++} ++ ++/* Hash jnode by its key (inode plus offset). Used by hash-table macros */ ++static inline __u32 jnode_key_hashfn(j_hash_table * table, ++ const struct jnode_key *key) ++{ ++ assert("nikita-2352", key != NULL); ++ assert("nikita-3346", IS_POW(table->_buckets)); ++ ++ /* yes, this is remarkable simply (where not stupid) hash function. */ ++ return (key->objectid + key->index) & (table->_buckets - 1); ++} ++ ++/* The hash table definition */ ++#define KMALLOC(size) reiser4_vmalloc(size) ++#define KFREE(ptr, size) vfree(ptr) ++TYPE_SAFE_HASH_DEFINE(j, jnode, struct jnode_key, key.j, link.j, ++ jnode_key_hashfn, jnode_key_eq); ++#undef KFREE ++#undef KMALLOC ++ ++int reiser4_jnodes_init(void) ++{ ++ return j_hash_init(&get_current_super_private()->jhash_table, 16384); ++} ++ ++/* call this to destroy jnode hash table. This is called during umount. */ ++int reiser4_jnodes_done(void) ++{ ++ j_hash_table *jtable; ++ jnode *node; ++ jnode *next; ++ /* ++ * Scan hash table and free all jnodes. ++ */ ++ jtable = &get_current_super_private()->jhash_table; ++ if (jtable->_table) { ++ for_all_in_htable(jtable, j, node, next) { ++ assert("nikita-2361", !atomic_read(&node->x_count)); ++ jdrop(node); ++ } ++ j_hash_done(&get_current_super_private()->jhash_table); ++ } ++ return 0; ++} ++ ++/** ++ * init_jnodes - create jnode cache ++ * ++ * Initializes slab cache jnodes. It is part of reiser4 module initialization. ++ */ ++int init_jnodes(void) ++{ ++ assert("umka-168", _jnode_slab == NULL); ++ ++ _jnode_slab = kmem_cache_create("jnode", sizeof(jnode), 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ if (_jnode_slab == NULL) ++ return RETERR(-ENOMEM); ++ ++ return 0; ++} ++ ++/** ++ * done_znodes - delete znode cache ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void done_jnodes(void) ++{ ++ destroy_reiser4_cache(&_jnode_slab); ++} ++ ++#if REISER4_DEBUG ++void jnode_init_tail(jnode *node) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_current_super_private(); ++ spin_lock_irq(&sbinfo->all_guard); ++ list_add(&node->jnodes, &sbinfo->all_jnodes); ++ spin_unlock_irq(&sbinfo->all_guard); ++} ++#else ++#define jnode_init_tail(node) noop ++#endif /* REISER4_DEBUG */ ++ ++/* Initialize a jnode. */ ++void jnode_init(jnode *node, reiser4_subvol *subv, jnode_type type) ++{ ++ assert("edward-2398", is_in_reiser4_context()); ++ ++ memset(node, 0, sizeof(jnode)); ++ ON_DEBUG(node->magic = JMAGIC); ++ jnode_set_type(node, type); ++ atomic_set(&node->d_count, 0); ++ atomic_set(&node->x_count, 0); ++ spin_lock_init(&node->guard); ++ spin_lock_init(&node->load); ++ node->atom = NULL; ++ node->subvol = subv; ++ node->super = reiser4_get_current_sb(); ++ INIT_LIST_HEAD(&node->capture_link); ++ init_waitqueue_head(&node->wait_jload); ++ ASSIGN_NODE_LIST(node, NOT_CAPTURED); ++ jnode_init_tail(node); ++} ++ ++#if REISER4_DEBUG ++/* ++ * Remove jnode from ->all_jnodes list. ++ */ ++static void jnode_done(jnode *node) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ ++ spin_lock_irq(&sbinfo->all_guard); ++ assert("nikita-2422", !list_empty(&node->jnodes)); ++ list_del_init(&node->jnodes); ++ spin_unlock_irq(&sbinfo->all_guard); ++} ++#endif ++ ++/* return already existing jnode of page */ ++jnode *jnode_by_page(struct page *pg) ++{ ++ assert("nikita-2400", PageLocked(pg)); ++ assert("nikita-2068", PagePrivate(pg)); ++ assert("nikita-2067", jprivate(pg) != NULL); ++ return jprivate(pg); ++} ++ ++/* exported functions to allocate/free jnode objects outside this file */ ++jnode *jalloc(void) ++{ ++ jnode *jal = kmem_cache_alloc(_jnode_slab, reiser4_ctx_gfp_mask_get()); ++ return jal; ++} ++ ++/* return jnode back to the slab allocator */ ++inline void jfree(jnode * node) ++{ ++ assert("nikita-2663", (list_empty_careful(&node->capture_link) && ++ NODE_LIST(node) == NOT_CAPTURED)); ++ assert("nikita-3222", list_empty(&node->jnodes)); ++ assert("nikita-3221", jnode_page(node) == NULL); ++ ++ /* not yet phash_jnode_destroy(node); */ ++ ++ kmem_cache_free(_jnode_slab, node); ++} ++ ++/* ++ * This function is supplied as RCU callback. It actually frees jnode when ++ * last reference to it is gone. ++ */ ++static void jnode_free_actor(struct rcu_head *head) ++{ ++ jnode *node; ++ jnode_type jtype; ++ ++ node = container_of(head, jnode, rcu); ++ jtype = jnode_get_type(node); ++ ++ ON_DEBUG(jnode_done(node)); ++ ++ switch (jtype) { ++ case JNODE_IO_HEAD: ++ case JNODE_BITMAP: ++ case JNODE_VOLINFO_HEAD: ++ case JNODE_UNFORMATTED_BLOCK: ++ jfree(node); ++ break; ++ case JNODE_FORMATTED_BLOCK: ++ zfree(JZNODE(node)); ++ break; ++ default: ++ wrong_return_value("nikita-3197", "Wrong jnode type"); ++ } ++} ++ ++/* ++ * Free a jnode. Post a callback to be executed later through RCU when all ++ * references to @node are released. ++ */ ++static inline void jnode_free(jnode * node, jnode_type jtype) ++{ ++ /*assert("nikita-3219", list_empty(&node->rcu.list)); */ ++ call_rcu(&node->rcu, jnode_free_actor); ++} ++ ++/* allocate new unformatted jnode */ ++static jnode *jnew_unformatted(void) ++{ ++ jnode *jal; ++ ++ jal = jalloc(); ++ if (jal == NULL) ++ return NULL; ++ ++ jnode_init(jal, NULL, JNODE_UNFORMATTED_BLOCK); ++ jal->key.j.mapping = NULL; ++ jal->key.j.index = (unsigned long)-1; ++ jal->key.j.objectid = 0; ++ return jal; ++} ++ ++/* look for jnode with given mapping and offset within hash table */ ++jnode *jlookup(oid_t objectid, unsigned long index) ++{ ++ struct jnode_key jkey; ++ jnode *node; ++ ++ jkey.objectid = objectid; ++ jkey.index = index; ++ ++ /* ++ * hash table is _not_ protected by any lock during lookups. All we ++ * have to do is to disable preemption to keep RCU happy. ++ */ ++ ++ rcu_read_lock(); ++ node = j_hash_find(&get_current_super_private()->jhash_table, &jkey); ++ if (node != NULL) { ++ /* protect @node from recycling */ ++ jref(node); ++ assert("nikita-2955", jnode_invariant(node, 0, 0)); ++ node = jnode_rip_check(node); ++ } ++ rcu_read_unlock(); ++ return node; ++} ++ ++/* per inode radix tree of jnodes is protected by tree's read write spin lock */ ++static jnode *jfind_nolock(struct address_space *mapping, unsigned long index) ++{ ++ assert("vs-1694", mapping->host != NULL); ++ ++ return radix_tree_lookup(jnode_tree_by_inode(mapping->host), index); ++} ++ ++jnode *jfind(struct address_space *mapping, unsigned long index) ++{ ++ reiser4_tree *tree; ++ jnode *node; ++ ++ assert("vs-1694", mapping->host != NULL); ++ tree = meta_subvol_tree(); ++ ++ read_lock_tree(); ++ node = jfind_nolock(mapping, index); ++ if (node != NULL) ++ jref(node); ++ read_unlock_tree(); ++ return node; ++} ++ ++static void inode_attach_jnode(jnode * node) ++{ ++ struct inode *inode; ++ reiser4_inode *info; ++ struct radix_tree_root *rtree; ++ ++ assert("zam-1043", node->key.j.mapping != NULL); ++ inode = node->key.j.mapping->host; ++ info = reiser4_inode_data(inode); ++ rtree = jnode_tree_by_reiser4_inode(info); ++ if (radix_tree_empty(rtree)) { ++ /* prevent inode from being pruned when it has jnodes attached ++ to it */ ++ xa_lock_irq(&inode->i_data.i_pages); ++ inode->i_data.nrpages++; ++ xa_unlock_irq(&inode->i_data.i_pages); ++ } ++ assert("zam-1049", ++ equi(!radix_tree_empty(rtree), info->nr_jnodes != 0)); ++ check_me("zam-1045", ++ !radix_tree_insert(rtree, node->key.j.index, node)); ++ ON_DEBUG(info->nr_jnodes++); ++} ++ ++static void inode_detach_jnode(jnode * node) ++{ ++ struct inode *inode; ++ reiser4_inode *info; ++ struct radix_tree_root *rtree; ++ ++ assert("zam-1044", node->key.j.mapping != NULL); ++ inode = node->key.j.mapping->host; ++ info = reiser4_inode_data(inode); ++ rtree = jnode_tree_by_reiser4_inode(info); ++ ++ assert("zam-1051", info->nr_jnodes != 0); ++ assert("zam-1052", !radix_tree_empty(rtree)); ++ ON_DEBUG(info->nr_jnodes--); ++ ++ /* delete jnode from inode's radix tree of jnodes */ ++ check_me("zam-1046", radix_tree_delete(rtree, node->key.j.index)); ++ if (radix_tree_empty(rtree)) { ++ /* inode can be pruned now */ ++ xa_lock_irq(&inode->i_data.i_pages); ++ inode->i_data.nrpages--; ++ xa_unlock_irq(&inode->i_data.i_pages); ++ } ++} ++ ++/* put jnode into hash table (where they can be found by flush who does not know ++ mapping) and to inode's tree of jnodes (where they can be found (hopefully ++ faster) in places where mapping is known). Currently it is used by ++ fs/reiser4/plugin/item/extent_file_ops.c:index_extent_jnode when new jnode is ++ created */ ++static void ++hash_unformatted_jnode(jnode * node, struct address_space *mapping, ++ unsigned long index) ++{ ++ j_hash_table *jtable; ++ ++ assert("vs-1446", jnode_is_unformatted(node)); ++ assert("vs-1442", node->key.j.mapping == 0); ++ assert("vs-1443", node->key.j.objectid == 0); ++ assert("vs-1444", node->key.j.index == (unsigned long)-1); ++ ++ node->key.j.mapping = mapping; ++ node->key.j.objectid = get_inode_oid(mapping->host); ++ node->key.j.index = index; ++ ++ jtable = &get_current_super_private()->jhash_table; ++ ++ /* race with some other thread inserting jnode into the hash table is ++ * impossible, because we keep the page lock. */ ++ /* ++ * following assertion no longer holds because of RCU: it is possible ++ * jnode is in the hash table, but with JNODE_RIP bit set. ++ */ ++ /* assert("nikita-3211", j_hash_find(jtable, &node->key.j) == NULL); */ ++ j_hash_insert_rcu(jtable, node); ++ inode_attach_jnode(node); ++} ++ ++static void unhash_unformatted_node_nolock(jnode *node) ++{ ++ assert("vs-1683", node->key.j.mapping != NULL); ++ assert("vs-1684", ++ node->key.j.objectid == ++ get_inode_oid(node->key.j.mapping->host)); ++ ++ /* remove jnode from hash-table */ ++ j_hash_remove_rcu(&get_super_private(jnode_get_super(node))->jhash_table, node); ++ inode_detach_jnode(node); ++ node->key.j.mapping = NULL; ++ node->key.j.index = (unsigned long)-1; ++ node->key.j.objectid = 0; ++} ++ ++/* remove jnode from hash table and from inode's tree of jnodes. This is used in ++ reiser4_invalidatepage and in kill_hook_extent -> truncate_inode_jnodes -> ++ reiser4_uncapture_jnode */ ++void unhash_unformatted_jnode(jnode *node) ++{ ++ assert("vs-1445", jnode_is_unformatted(node)); ++ ++ __write_lock_tree(get_super_private(jnode_get_super(node))); ++ unhash_unformatted_node_nolock(node); ++ __write_unlock_tree(get_super_private(jnode_get_super(node))); ++} ++ ++/* ++ * search hash table for a jnode with given oid and index. If not found, ++ * allocate new jnode, insert it, and also insert into radix tree for the ++ * given inode/mapping. ++ */ ++static jnode *find_get_jnode(struct address_space *mapping, ++ oid_t oid, unsigned long index) ++{ ++ jnode *result; ++ jnode *shadow; ++ int preload; ++ reiser4_super_info_data *info; ++ ++ info = get_super_private(mapping->host->i_sb); ++ result = jnew_unformatted(); ++ ++ if (unlikely(result == NULL)) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ ++ preload = radix_tree_preload(reiser4_ctx_gfp_mask_get()); ++ if (preload != 0) ++ return ERR_PTR(preload); ++ ++ __write_lock_tree(info); ++ shadow = jfind_nolock(mapping, index); ++ if (likely(shadow == NULL)) { ++ /* add new jnode to hash table and inode's radix tree of ++ * jnodes */ ++ jref(result); ++ hash_unformatted_jnode(result, mapping, index); ++ } else { ++ /* jnode is found in inode's radix tree of jnodes */ ++ jref(shadow); ++ jnode_free(result, JNODE_UNFORMATTED_BLOCK); ++ assert("vs-1498", shadow->key.j.mapping == mapping); ++ result = shadow; ++ } ++ __write_unlock_tree(info); ++ ++ assert("nikita-2955", ++ ergo(result != NULL, jnode_invariant(result, 0, 0))); ++ radix_tree_preload_end(); ++ return result; ++} ++ ++/* jget() (a la zget() but for unformatted nodes). Returns (and possibly ++ creates) jnode corresponding to page @pg. jnode is attached to page and ++ inserted into jnode hash-table. */ ++jnode *do_jget(struct page *pg) ++{ ++ /* ++ * There are two ways to create jnode: starting with pre-existing page ++ * and without page. ++ * ++ * When page already exists, jnode is created ++ * (jnode_of_page()->do_jget()) under page lock. This is done in ++ * ->writepage(), or when capturing anonymous page dirtied through ++ * mmap. ++ * ++ * Jnode without page is created by index_extent_jnode(). ++ * ++ */ ++ ++ jnode *result; ++ oid_t oid = get_inode_oid(pg->mapping->host); ++ ++ assert("umka-176", pg != NULL); ++ assert("nikita-2394", PageLocked(pg)); ++ ++ result = jprivate(pg); ++ if (likely(result != NULL)) ++ return jref(result); ++ ++ /* check hash-table first */ ++ result = jfind(pg->mapping, pg->index); ++ if (unlikely(result != NULL)) { ++ spin_lock_jnode(result); ++ jnode_attach_page(result, pg); ++ spin_unlock_jnode(result); ++ result->key.j.mapping = pg->mapping; ++ return result; ++ } ++ ++ /* since page is locked, jnode should be allocated with GFP_NOFS flag */ ++ reiser4_ctx_gfp_mask_force(GFP_NOFS); ++ result = find_get_jnode(pg->mapping, oid, pg->index); ++ if (unlikely(IS_ERR(result))) ++ return result; ++ /* attach jnode to page */ ++ spin_lock_jnode(result); ++ jnode_attach_page(result, pg); ++ spin_unlock_jnode(result); ++ return result; ++} ++ ++/** ++ * return jnode for @pg, creating it if necessary. ++ * ++ * @for_data_io: true, if jnode is to be bound with a data page and ++ * to participate in IO; ++ */ ++jnode *jnode_of_page(struct page *pg) ++{ ++ jnode *result; ++ ++ assert("nikita-2394", PageLocked(pg)); ++ ++ result = do_jget(pg); ++ ++ if (REISER4_DEBUG && !IS_ERR(result)) { ++ assert("nikita-3210", result == jprivate(pg)); ++ assert("nikita-2046", jnode_page(jprivate(pg)) == pg); ++ if (jnode_is_unformatted(jprivate(pg))) { ++ assert("nikita-2364", ++ jprivate(pg)->key.j.index == pg->index); ++ assert("nikita-2367", ++ jprivate(pg)->key.j.mapping == pg->mapping); ++ assert("nikita-2365", ++ jprivate(pg)->key.j.objectid == ++ get_inode_oid(pg->mapping->host)); ++ assert("vs-1200", ++ jprivate(pg)->key.j.objectid == ++ pg->mapping->host->i_ino); ++ assert("nikita-2356", ++ jnode_is_unformatted(jnode_by_page(pg))); ++ } ++ assert("nikita-2956", jnode_invariant(jprivate(pg), 0, 0)); ++ } ++ return result; ++} ++ ++/* attach page to jnode: set ->pg pointer in jnode, and ->private one in the ++ * page.*/ ++void jnode_attach_page(jnode * node, struct page *pg) ++{ ++ assert("nikita-2060", node != NULL); ++ assert("nikita-2061", pg != NULL); ++ ++ assert("nikita-2050", jprivate(pg) == 0ul); ++ assert("nikita-2393", !PagePrivate(pg)); ++ assert("vs-1741", node->pg == NULL); ++ ++ assert("nikita-2396", PageLocked(pg)); ++ assert_spin_locked(&(node->guard)); ++ ++ get_page(pg); ++ set_page_private(pg, (unsigned long)node); ++ node->pg = pg; ++ SetPagePrivate(pg); ++} ++ ++/* Dual to jnode_attach_page: break a binding between page and jnode */ ++void page_clear_jnode(struct page *page, jnode * node) ++{ ++ assert("nikita-2425", PageLocked(page)); ++ assert_spin_locked(&(node->guard)); ++ assert("nikita-2428", PagePrivate(page)); ++ ++ assert("nikita-3551", !PageWriteback(page)); ++ ++ JF_CLR(node, JNODE_PARSED); ++ set_page_private(page, 0ul); ++ ClearPagePrivate(page); ++ node->pg = NULL; ++ put_page(page); ++} ++ ++#if 0 ++/* it is only used in one place to handle error */ ++void ++page_detach_jnode(struct page *page, struct address_space *mapping, ++ unsigned long index) ++{ ++ assert("nikita-2395", page != NULL); ++ ++ lock_page(page); ++ if ((page->mapping == mapping) && (page->index == index) ++ && PagePrivate(page)) { ++ jnode *node; ++ ++ node = jprivate(page); ++ spin_lock_jnode(node); ++ page_clear_jnode(page, node); ++ spin_unlock_jnode(node); ++ } ++ unlock_page(page); ++} ++#endif /* 0 */ ++ ++/* return @node page locked. ++ ++ Locking ordering requires that one first takes page lock and afterwards ++ spin lock on node attached to this page. Sometimes it is necessary to go in ++ the opposite direction. This is done through standard trylock-and-release ++ loop. ++*/ ++static struct page *jnode_lock_page(jnode * node) ++{ ++ struct page *page; ++ ++ assert("nikita-2052", node != NULL); ++ assert("nikita-2401", LOCK_CNT_NIL(spin_locked_jnode)); ++ ++ while (1) { ++ ++ spin_lock_jnode(node); ++ page = jnode_page(node); ++ if (page == NULL) ++ break; ++ ++ /* no need to get_page( page ) here, because page cannot ++ be evicted from memory without detaching it from jnode and ++ this requires spin lock on jnode that we already hold. ++ */ ++ if (trylock_page(page)) { ++ /* We won a lock on jnode page, proceed. */ ++ break; ++ } ++ ++ /* Page is locked by someone else. */ ++ get_page(page); ++ spin_unlock_jnode(node); ++ wait_on_page_locked(page); ++ /* it is possible that page was detached from jnode and ++ returned to the free pool, or re-assigned while we were ++ waiting on locked bit. This will be rechecked on the next ++ loop iteration. ++ */ ++ put_page(page); ++ ++ /* try again */ ++ } ++ return page; ++} ++ ++static struct page *__jnode_get_page_locked(jnode * node, gfp_t gfp_flags); ++ ++/** ++ * Load jnode's data into memory and parse it. ++ * In the case of IO errors (original device has died, etc), or if ++ * parsing failed for some reasons (bitrot, etc), restart IO against ++ * replica devices and parse the results. ++ * ++ * Pre- and post-conditions: @node is spin-locked ++ */ ++static int __jload_gfp_failover(jnode *node, ++ gfp_t gfp_flags, ++ int do_kmap /* true if page should be ++ kmap-ped on success */) ++{ ++ int ret = 0; ++ u32 mirr_id; ++ struct page *page; ++ int first_iter = 1; ++ reiser4_subvol *orig = jnode_get_subvol(node); ++ ++ page = __jnode_get_page_locked(node, gfp_flags); ++ if (unlikely(IS_ERR(page))) ++ return PTR_ERR(page); ++ ++ spin_unlock_jnode(node); ++ ++ __for_each_mirror(orig, mirr_id) { ++ if (!first_iter) { ++ lock_page(page); ++ node->subvol = current_mirror(orig->id, mirr_id); ++ } ++ first_iter = 0; ++ ret = jnode_start_read(node, page); ++ if (unlikely(ret != 0)) ++ break; ++ wait_on_page_locked(page); ++ if (unlikely(!PageUptodate(page))) { ++ warning("edward-1810", "Can't load block %llu on %s.", ++ *jnode_get_block(node), ++ node->subvol->name); ++ ret = RETERR(-EIO); ++ goto load_from_replica; ++ } ++ node->data = kmap(page); ++ ret = jnode_ops(node)->parse(node); ++ if (likely(ret == 0)) ++ break; ++ ret = RETERR(-EIO); ++ warning("edward-1811", "Block %llu on %s looks corrupted.\n", ++ *jnode_get_block(node), ++ node->subvol->name); ++ ClearPageUptodate(page); ++ kunmap(page); ++ load_from_replica: ++ if (mirr_id < orig->num_replicas) ++ notice("edward-1812", ++ "Loading from replica device %s.", ++ current_mirror(orig->id, ++ mirr_id + 1)->name); ++ } ++ /* ++ * TODO: Correct "fixable" errors here (the case of failed parsing). ++ * That is, issue read IOs with correct content against devices with ++ * "problematic" blocks. ++ */ ++ spin_lock_jnode(node); ++ /* ++ * set back the original subvolume ++ */ ++ node->subvol = orig; ++ if (ret == 0 && !do_kmap) ++ kunmap(page); ++ return ret; ++} ++ ++/** ++ * Check if someone has already started to load @node. ++ * If so, then wait for completion and return the result of that attempt ++ * of loading. Otherwise, try to load it by yourself. ++ */ ++static int jload_gfp_failover(jnode *node, gfp_t gfp_flags, int do_kmap) ++{ ++ int result; ++ ++ assert("nikita-2466", node != NULL); ++ ++ spin_lock_jnode(node); ++ ++ if (JF_ISSET(node, JNODE_LOADING_IN_PROGRESS)) { ++ spin_unlock_jnode(node); ++ wait_event(node->wait_jload, ++ !JF_ISSET(node, JNODE_LOADING_IN_PROGRESS)); ++ spin_lock_jnode(node); ++ ++ if (likely(JF_ISSET(node, JNODE_PARSED))) ++ result = 0; ++ else { ++ BUG_ON(!JF_ISSET(node, JNODE_PARSING_FAILED)); ++ result = RETERR(-EIO); ++ } ++ } ++ else if (JF_ISSET(node, JNODE_PARSED)) ++ result = 0; ++ else if (JF_ISSET(node, JNODE_PARSING_FAILED)) ++ result = RETERR(-EIO); ++ else { ++ JF_SET(node, JNODE_LOADING_IN_PROGRESS); ++ result = __jload_gfp_failover(node, gfp_flags, do_kmap); ++ if (likely(result == 0)) ++ JF_SET(node, JNODE_PARSED); ++ else ++ JF_SET(node, JNODE_PARSING_FAILED); ++ JF_CLR(node, JNODE_LOADING_IN_PROGRESS); ++ wake_up(&node->wait_jload); ++ } ++ ++ spin_unlock_jnode(node); ++ return result; ++} ++ ++/** ++ * Lock a page attached to jnode, create and attach page to jnode ++ * if it had no one. ++ * ++ * Pre-condition: @node is spin-locked ++ */ ++static struct page *__jnode_get_page_locked(jnode * node, gfp_t gfp_flags) ++{ ++ struct page *page = jnode_page(node); ++ ++ if (page == NULL) { ++ spin_unlock_jnode(node); ++ page = find_or_create_page(jnode_get_mapping(node), ++ jnode_get_index(node), gfp_flags); ++ if (page == NULL) { ++ spin_lock_jnode(node); ++ return ERR_PTR(RETERR(-ENOMEM)); ++ } ++ } else { ++ if (trylock_page(page)) ++ return page; ++ get_page(page); ++ spin_unlock_jnode(node); ++ lock_page(page); ++ assert("nikita-3134", page->mapping == jnode_get_mapping(node)); ++ } ++ spin_lock_jnode(node); ++ if (!jnode_page(node)) ++ jnode_attach_page(node, page); ++ put_page(page); ++ assert("zam-894", jnode_page(node) == page); ++ return page; ++} ++ ++static struct page *jnode_get_page_locked(jnode *node, gfp_t gfp_flags) ++{ ++ struct page *page; ++ ++ spin_lock_jnode(node); ++ page = __jnode_get_page_locked(node, gfp_flags); ++ spin_unlock_jnode(node); ++ return page; ++} ++ ++/* Start read operation for jnode's page if page is not up-to-date. */ ++static int jnode_start_read(jnode * node, struct page *page) ++{ ++ assert("zam-893", PageLocked(page)); ++ ++ if (PageUptodate(page)) { ++ unlock_page(page); ++ return 0; ++ } ++ return reiser4_page_io(page, node, READ, reiser4_ctx_gfp_mask_get()); ++} ++ ++#if REISER4_DEBUG ++static void check_jload(jnode * node, struct page *page) ++{ ++ if (jnode_is_znode(node)) { ++ znode *z = JZNODE(node); ++ ++ if (znode_is_any_locked(z)) { ++ assert("nikita-3253", ++ z->nr_items == ++ node_plugin_by_node(z)->num_of_items(z)); ++ kunmap(page); ++ } ++ assert("nikita-3565", znode_invariant(z)); ++ } ++} ++#else ++#define check_jload(node, page) noop ++#endif ++ ++/** ++ * prefetch jnode to speed up next call to jload. Call this when you are going ++ * to call jload() shortly. This will bring appropriate portion of jnode into ++ * CPU cache ++ */ ++void jload_prefetch(jnode * node) ++{ ++ prefetchw(&node->x_count); ++} ++ ++/** ++ * Load jnode's data into memory ++ */ ++int jload_gfp(jnode *node /* node to load */ , ++ gfp_t gfp_flags /* allocation flags */ , ++ int do_kmap /* true if page should be kmapped */) ++{ ++ struct page *page; ++ int result = 0; ++ int parsed; ++ ++ assert("nikita-3010", reiser4_schedulable()); ++ ++ prefetchw(&node->pg); ++ /* ++ * taking d-reference implies taking x-reference ++ */ ++ jref(node); ++ /* ++ * acquiring d-reference to @jnode and check for JNODE_PARSED bit ++ * should be atomic, otherwise there is a race against ++ * reiser4_releasepage(). ++ */ ++ spin_lock(&(node->load)); ++ add_d_ref(node); ++ parsed = jnode_is_parsed(node); ++ spin_unlock(&(node->load)); ++ ++ if (unlikely(!parsed)) { ++ result = jload_gfp_failover(node, gfp_flags, do_kmap); ++ if (unlikely(result != 0)) ++ goto failed; ++ page = jnode_page(node); ++ } else { ++ page = jnode_page(node); ++ if (do_kmap) ++ node->data = kmap(page); ++ } ++ check_jload(node, page); ++ ++ if (!is_writeout_mode()) ++ /* ++ * We do not mark pages active if jload is called as a part of ++ * jnode_flush() or reiser4_write_logs(). Both jnode_flush() ++ * and write_logs() add no value to cached data, there is no ++ * sense to mark pages as active when they go to disk, it just ++ * confuses vm scanning routines because clean page could be ++ * moved out from inactive list as a result of this ++ * mark_page_accessed() call. ++ */ ++ mark_page_accessed(page); ++ return 0; ++failed: ++ jrelse_tail(node); ++ return result; ++ ++} ++ ++/* start asynchronous reading for given jnode's page. */ ++int jstartio(jnode * node) ++{ ++ struct page *page; ++ ++ page = jnode_get_page_locked(node, reiser4_ctx_gfp_mask_get()); ++ if (IS_ERR(page)) ++ return PTR_ERR(page); ++ ++ return jnode_start_read(node, page); ++} ++ ++/* Initialize a node by calling appropriate plugin instead of reading ++ * node from disk as in jload(). */ ++int jinit_new(jnode * node, gfp_t gfp_flags) ++{ ++ struct page *page; ++ int result; ++ ++ jref(node); ++ add_d_ref(node); ++ ++ page = jnode_get_page_locked(node, gfp_flags); ++ if (IS_ERR(page)) { ++ result = PTR_ERR(page); ++ goto failed; ++ } ++ SetPageUptodate(page); ++ unlock_page(page); ++ ++ node->data = kmap(page); ++ ++ if (!jnode_is_parsed(node)) { ++ jnode_plugin *jplug = jnode_ops(node); ++ assert("edward-1973", jplug != NULL); ++ assert("edward-1974", jplug->init != NULL); ++ ++ spin_lock_jnode(node); ++ result = jplug->init(node); ++ spin_unlock_jnode(node); ++ if (result) { ++ kunmap(page); ++ goto failed; ++ } ++ JF_SET(node, JNODE_PARSED); ++ } ++ return 0; ++failed: ++ jrelse(node); ++ return result; ++} ++ ++/* release a reference to jnode acquired by jload(), decrement ->d_count */ ++void jrelse_tail(jnode * node/* jnode to release references to */) ++{ ++ assert("nikita-489", atomic_read(&node->d_count) > 0); ++ atomic_dec(&node->d_count); ++ /* release reference acquired in jload_gfp() or jinit_new() */ ++ if (jnode_is_unformatted(node) || jnode_is_znode(node)) ++ LOCK_CNT_DEC(d_refs); ++ jput(node); ++} ++ ++/* drop reference to node data. When last reference is dropped, data are ++ unloaded. */ ++void jrelse(jnode * node/* jnode to release references to */) ++{ ++ struct page *page; ++ ++ assert("nikita-487", node != NULL); ++ assert_spin_not_locked(&(node->guard)); ++ ++ page = jnode_page(node); ++ if (likely(page != NULL)) { ++ /* ++ * it is safe not to lock jnode here, because at this point ++ * @node->d_count is greater than zero (if jrelse() is used ++ * correctly, that is). JNODE_PARSED may be not set yet, if, ++ * for example, we got here as a result of error handling path ++ * in jload(). Anyway, page cannot be detached by ++ * reiser4_releasepage(). truncate will invalidate page ++ * regardless, but this should not be a problem. ++ */ ++ kunmap(page); ++ } ++ jrelse_tail(node); ++} ++ ++/* called from jput() to wait for io completion */ ++static void jnode_finish_io(jnode * node) ++{ ++ struct page *page; ++ ++ assert("nikita-2922", node != NULL); ++ ++ spin_lock_jnode(node); ++ page = jnode_page(node); ++ if (page != NULL) { ++ get_page(page); ++ spin_unlock_jnode(node); ++ wait_on_page_writeback(page); ++ put_page(page); ++ } else ++ spin_unlock_jnode(node); ++} ++ ++/* ++ * This is called by jput() when last reference to jnode is released. This is ++ * separate function, because we want fast path of jput() to be inline and, ++ * therefore, small. ++ */ ++void jput_final(jnode *node) ++{ ++ int r_i_p; ++ ++ /* A fast check for keeping node in cache. We always keep node in cache ++ * if its page is present and node was not marked for deletion */ ++ if (jnode_page(node) != NULL && !JF_ISSET(node, JNODE_HEARD_BANSHEE)) { ++ rcu_read_unlock(); ++ return; ++ } ++ r_i_p = !JF_TEST_AND_SET(node, JNODE_RIP); ++ /* ++ * if r_i_p is true, we were first to set JNODE_RIP on this node. In ++ * this case it is safe to access node after unlock. ++ */ ++ rcu_read_unlock(); ++ if (r_i_p) { ++ jnode_finish_io(node); ++ if (JF_ISSET(node, JNODE_HEARD_BANSHEE)) ++ /* node is removed from the tree. */ ++ jdelete(node); ++ else ++ jnode_try_drop(node); ++ } ++ /* if !r_i_p some other thread is already killing it */ ++} ++ ++int jwait_io(jnode * node, int rw) ++{ ++ struct page *page; ++ int result; ++ ++ assert("zam-448", jnode_page(node) != NULL); ++ ++ page = jnode_page(node); ++ ++ result = 0; ++ if (rw == READ) { ++ wait_on_page_locked(page); ++ } else { ++ assert("nikita-2227", rw == WRITE); ++ wait_on_page_writeback(page); ++ } ++ if (PageError(page)) ++ result = RETERR(-EIO); ++ ++ return result; ++} ++ ++/* ++ * jnode types and plugins. ++ * ++ * jnode by itself is a "base type". There are several different jnode ++ * flavors, called "jnode types" (see jnode_type for a list). Sometimes code ++ * has to do different things based on jnode type. In the standard reiser4 way ++ * this is done by having jnode plugin (see fs/reiser4/plugin.h:jnode_plugin). ++ * ++ * Functions below deal with jnode types and define methods of jnode plugin. ++ * ++ */ ++ ++/* set jnode type. This is done during jnode initialization. */ ++static void jnode_set_type(jnode * node, jnode_type type) ++{ ++ static unsigned long type_to_mask[] = { ++ [JNODE_UNFORMATTED_BLOCK] = 1, ++ [JNODE_FORMATTED_BLOCK] = 0, ++ [JNODE_BITMAP] = 2, ++ [JNODE_IO_HEAD] = 6, ++ [JNODE_VOLINFO_HEAD] = 4 ++ }; ++ ++ assert("zam-647", type < LAST_JNODE_TYPE); ++ assert("nikita-2815", !jnode_is_loaded(node)); ++ assert("nikita-3386", node->state == 0); ++ ++ node->state |= (type_to_mask[type] << JNODE_TYPE_1); ++} ++ ++/* ->init() method of jnode plugin for jnodes that don't require plugin ++ * specific initialization. */ ++static int init_noinit(jnode * node UNUSED_ARG) ++{ ++ return 0; ++} ++ ++/* ->parse() method of jnode plugin for jnodes that don't require plugin ++ * specific pasring. */ ++static int parse_noparse(jnode * node UNUSED_ARG) ++{ ++ return 0; ++} ++ ++/* ->mapping() method for unformatted jnode */ ++struct address_space *mapping_jnode(const jnode * node) ++{ ++ struct address_space *map; ++ ++ assert("nikita-2713", node != NULL); ++ ++ /* mapping is stored in jnode */ ++ ++ map = node->key.j.mapping; ++ assert("nikita-2714", map != NULL); ++ assert("nikita-2897", is_reiser4_inode(map->host)); ++ assert("nikita-2715", get_inode_oid(map->host) == node->key.j.objectid); ++ return map; ++} ++ ++/* ->index() method for unformatted jnodes */ ++unsigned long index_jnode(const jnode * node) ++{ ++ /* index is stored in jnode */ ++ return node->key.j.index; ++} ++ ++/* ->remove() method for unformatted jnodes */ ++static inline void remove_jnode(jnode *node) ++{ ++ /* remove jnode from hash table and radix tree */ ++ if (node->key.j.mapping) ++ unhash_unformatted_node_nolock(node); ++} ++ ++/* ->mapping() method for znodes */ ++static struct address_space *mapping_znode(const jnode * node) ++{ ++ /* all znodes belong to fake inode */ ++ return reiser4_get_super_fake(jnode_get_super(node))->i_mapping; ++} ++ ++/* ->index() method for znodes */ ++static unsigned long index_znode(const jnode * node) ++{ ++ unsigned long addr; ++ assert("nikita-3317", (1 << znode_shift_order) < sizeof(znode)); ++ ++ /* index of znode is just its address (shifted) */ ++ addr = (unsigned long)node; ++ return (addr - PAGE_OFFSET) >> znode_shift_order; ++} ++ ++/* ->mapping() method for bitmap jnode */ ++static struct address_space *mapping_bitmap(const jnode * node) ++{ ++ /* all bitmap blocks belong to special bitmap inode */ ++ return get_super_private(jnode_get_super(node))->bitmap->i_mapping; ++} ++ ++/* ->index() method for jnodes that are indexed by address */ ++static unsigned long index_is_address(const jnode * node) ++{ ++ unsigned long ind; ++ ++ ind = (unsigned long)node; ++ return ind - PAGE_OFFSET; ++} ++ ++/* resolve race with jput */ ++jnode *jnode_rip_sync(jnode *node) ++{ ++ /* ++ * This is used as part of RCU-based jnode handling. ++ * ++ * jlookup(), zlook(), zget(), and cbk_cache_scan_slots() have to work ++ * with unreferenced jnodes (ones with ->x_count == 0). Hash table is ++ * not protected during this, so concurrent thread may execute ++ * zget-set-HEARD_BANSHEE-zput, or somehow else cause jnode to be ++ * freed in jput_final(). To avoid such races, jput_final() sets ++ * JNODE_RIP on jnode (under tree lock). All places that work with ++ * unreferenced jnodes call this function. It checks for JNODE_RIP bit ++ * (first without taking tree lock), and if this bit is set, released ++ * reference acquired by the current thread and returns NULL. ++ * ++ * As a result, if jnode is being concurrently freed, NULL is returned ++ * and caller should pretend that jnode wasn't found in the first ++ * place. ++ * ++ * Otherwise it's safe to release "rcu-read-lock" and continue with ++ * jnode. ++ */ ++ if (unlikely(JF_ISSET(node, JNODE_RIP))) { ++ read_lock_tree(); ++ if (JF_ISSET(node, JNODE_RIP)) { ++ dec_x_ref(node); ++ node = NULL; ++ } ++ read_unlock_tree(); ++ } ++ return node; ++} ++ ++reiser4_key *jnode_build_key(const jnode *node, reiser4_key *key) ++{ ++ loff_t off; ++ struct inode *inode; ++ file_plugin *fplug; ++ ++ assert("nikita-3092", node != NULL); ++ assert("nikita-3093", key != NULL); ++ assert("nikita-3094", jnode_is_unformatted(node)); ++ ++ off = ((loff_t) index_jnode(node)) << PAGE_SHIFT; ++ inode = mapping_jnode(node)->host; ++ fplug = inode_file_plugin(inode); ++ ++ assert("zam-1007", fplug != NULL); ++ assert("zam-1008", fplug->build_body_key != NULL); ++ ++ fplug->build_body_key(inode, off, key); ++ return key; ++} ++ ++/* ->parse() method for formatted nodes */ ++static int parse_znode(jnode * node) ++{ ++ return zparse(JZNODE(node)); ++} ++ ++/* ->delete() method for formatted nodes */ ++static void delete_znode(jnode *node) ++{ ++ znode *z; ++#if REISER4_DEBUG ++ reiser4_super_info_data *sbinfo; ++ ++ assert("edward-2023", jnode_get_subvol(node) != NULL); ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ ++ assert_rw_write_locked(&(sbinfo->tree_lock)); ++#endif ++ assert("vs-898", JF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ ++ z = JZNODE(node); ++ assert("vs-899", z->c_count == 0); ++ ++ /* delete znode from sibling list. */ ++ sibling_list_remove(z); ++ znode_remove(z); ++} ++ ++/* ++ * ->remove() method for formatted nodes ++ */ ++static int remove_znode(jnode *node) ++{ ++ znode *z; ++#if REISER4_DEBUG ++ reiser4_super_info_data *sbinfo; ++ ++ assert("edward-2024", jnode_get_subvol(node) != NULL); ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ assert_rw_write_locked(&(sbinfo->tree_lock)); ++#endif ++ z = JZNODE(node); ++ ++ if (z->c_count == 0) { ++ /* detach znode from sibling list. */ ++ sibling_list_drop(z); ++ /* this is called with tree spin-lock held, so call ++ znode_remove() directly (rather than znode_lock_remove()). */ ++ znode_remove(z); ++ return 0; ++ } ++ return RETERR(-EBUSY); ++} ++ ++/* ->init() method for formatted nodes */ ++int init_znode(jnode * node) ++{ ++ znode *z; ++ ++ z = JZNODE(node); ++ /* call node plugin to do actual initialization */ ++ z->nr_items = 0; ++ return z->nplug->init(z); ++} ++ ++/* ++ * Setup jnode plugin methods for various jnode types. ++ */ ++jnode_plugin jnode_plugins[LAST_JNODE_TYPE] = { ++ [JNODE_UNFORMATTED_BLOCK] = { ++ .h = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .id = JNODE_UNFORMATTED_BLOCK, ++ .pops = NULL, ++ .label = "unformatted", ++ .desc = "unformatted node", ++ .linkage = {NULL, NULL} ++ }, ++ .init = init_noinit, ++ .parse = parse_noparse, ++ .mapping = mapping_jnode, ++ .index = index_jnode ++ }, ++ [JNODE_FORMATTED_BLOCK] = { ++ .h = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .id = JNODE_FORMATTED_BLOCK, ++ .pops = NULL, ++ .label = "formatted", ++ .desc = "formatted tree node", ++ .linkage = {NULL, NULL} ++ }, ++ .init = init_znode, ++ .parse = parse_znode, ++ .mapping = mapping_znode, ++ .index = index_znode ++ }, ++ [JNODE_BITMAP] = { ++ .h = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .id = JNODE_BITMAP, ++ .pops = NULL, ++ .label = "bitmap", ++ .desc = "bitmap node", ++ .linkage = {NULL, NULL} ++ }, ++ .init = init_noinit, ++ .parse = parse_noparse, ++ .mapping = mapping_bitmap, ++ .index = index_is_address ++ }, ++ [JNODE_IO_HEAD] = { ++ .h = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .id = JNODE_IO_HEAD, ++ .pops = NULL, ++ .label = "io head", ++ .desc = "io head", ++ .linkage = {NULL, NULL} ++ }, ++ .init = init_noinit, ++ .parse = parse_noparse, ++ .mapping = mapping_bitmap, ++ .index = index_is_address ++ }, ++ [JNODE_VOLINFO_HEAD] = { ++ .h = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .id = JNODE_VOLINFO_HEAD, ++ .pops = NULL, ++ .label = "volinfo", ++ .desc = "volinfo head", ++ .linkage = {NULL, NULL} ++ }, ++ .init = init_noinit, ++ .parse = parse_noparse, ++ .mapping = mapping_bitmap, ++ .index = index_is_address ++ } ++}; ++ ++/* ++ * jnode destruction. ++ * ++ * Thread may use a jnode after it acquired a reference to it. References are ++ * counted in ->x_count field. Reference protects jnode from being ++ * recycled. This is different from protecting jnode data (that are stored in ++ * jnode page) from being evicted from memory. Data are protected by jload() ++ * and released by jrelse(). ++ * ++ * If thread already possesses a reference to the jnode it can acquire another ++ * one through jref(). Initial reference is obtained (usually) by locating ++ * jnode in some indexing structure that depends on jnode type: formatted ++ * nodes are kept in global hash table, where they are indexed by block ++ * number, and also in the cbk cache. Unformatted jnodes are also kept in hash ++ * table, which is indexed by oid and offset within file, and in per-inode ++ * radix tree. ++ * ++ * Reference to jnode is released by jput(). If last reference is released, ++ * jput_final() is called. This function determines whether jnode has to be ++ * deleted (this happens when corresponding node is removed from the file ++ * system, jnode is marked with JNODE_HEARD_BANSHEE bit in this case), or it ++ * should be just "removed" (deleted from memory). ++ * ++ * Jnode destruction is signally delicate dance because of locking and RCU. ++ */ ++ ++/* ++ * Returns true if jnode cannot be removed right now. This check is called ++ * under tree lock. If it returns true, jnode is irrevocably committed to be ++ * deleted/removed. ++ */ ++static inline int jnode_is_busy(const jnode * node, jnode_type jtype) ++{ ++ /* if other thread managed to acquire a reference to this jnode, don't ++ * free it. */ ++ if (atomic_read(&node->x_count) > 0) ++ return 1; ++ /* also, don't free znode that has children in memory */ ++ if (jtype == JNODE_FORMATTED_BLOCK && JZNODE(node)->c_count > 0) ++ return 1; ++ return 0; ++} ++ ++/* ++ * this is called as part of removing jnode. Based on jnode type, call ++ * corresponding function that removes jnode from indices and returns it back ++ * to the appropriate slab (through RCU). ++ */ ++static inline void jnode_remove(jnode *node, jnode_type jtype) ++{ ++ switch (jtype) { ++ case JNODE_UNFORMATTED_BLOCK: ++ remove_jnode(node); ++ break; ++ case JNODE_IO_HEAD: ++ case JNODE_BITMAP: ++ break; ++ case JNODE_VOLINFO_HEAD: ++ break; ++ case JNODE_FORMATTED_BLOCK: ++ remove_znode(node); ++ break; ++ default: ++ wrong_return_value("nikita-3196", "Wrong jnode type"); ++ } ++} ++ ++/* ++ * this is called as part of deleting jnode. Based on jnode type, call ++ * corresponding function that removes jnode from indices and returns it back ++ * to the appropriate slab (through RCU). ++ * ++ * This differs from jnode_remove() only for formatted nodes---for them ++ * sibling list handling is different for removal and deletion. ++ */ ++static inline void jnode_delete(jnode *node, jnode_type jtype) ++{ ++ switch (jtype) { ++ case JNODE_UNFORMATTED_BLOCK: ++ remove_jnode(node); ++ break; ++ case JNODE_IO_HEAD: ++ case JNODE_BITMAP: ++ break; ++ case JNODE_FORMATTED_BLOCK: ++ delete_znode(node); ++ break; ++ case JNODE_VOLINFO_HEAD: ++ default: ++ wrong_return_value("nikita-3195", "Wrong jnode type"); ++ } ++} ++ ++#if REISER4_DEBUG ++/* ++ * remove jnode from the debugging list of all jnodes hanging off super-block. ++ */ ++void jnode_list_remove(jnode * node) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ ++ spin_lock_irq(&sbinfo->all_guard); ++ assert("nikita-2422", !list_empty(&node->jnodes)); ++ list_del_init(&node->jnodes); ++ spin_unlock_irq(&sbinfo->all_guard); ++} ++#endif ++ ++/* ++ * this is called by jput_final() to remove jnode when last reference to it is ++ * released. ++ */ ++static int jnode_try_drop(jnode *node) ++{ ++ int result; ++ jnode_type jtype; ++ reiser4_super_info_data *sbinfo; ++ ++ assert("nikita-2491", node != NULL); ++ assert("nikita-2583", JF_ISSET(node, JNODE_RIP)); ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ jtype = jnode_get_type(node); ++ ++ spin_lock_jnode(node); ++ __write_lock_tree(sbinfo); ++ /* ++ * if jnode has a page---leave it alone. Memory pressure will ++ * eventually kill page and jnode. ++ */ ++ if (jnode_page(node) != NULL) { ++ __write_unlock_tree(sbinfo); ++ spin_unlock_jnode(node); ++ JF_CLR(node, JNODE_RIP); ++ return RETERR(-EBUSY); ++ } ++ ++ /* re-check ->x_count under tree lock. */ ++ result = jnode_is_busy(node, jtype); ++ if (result == 0) { ++ assert("nikita-2582", !JF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ assert("jmacd-511/b", atomic_read(&node->d_count) == 0); ++ ++ spin_unlock_jnode(node); ++ /* no page and no references---despatch him. */ ++ jnode_remove(node, jtype); ++ __write_unlock_tree(sbinfo); ++ jnode_free(node, jtype); ++ } else { ++ /* busy check failed: reference was acquired by concurrent ++ * thread. */ ++ __write_unlock_tree(sbinfo); ++ spin_unlock_jnode(node); ++ JF_CLR(node, JNODE_RIP); ++ } ++ return result; ++} ++ ++/* jdelete() -- Delete jnode from the tree and file system */ ++static int jdelete(jnode *node /* jnode to finish with */) ++{ ++ struct page *page; ++ int result; ++ jnode_type jtype; ++ reiser4_super_info_data *info; ++ ++ assert("nikita-467", node != NULL); ++ assert("nikita-2531", JF_ISSET(node, JNODE_RIP)); ++ ++ jtype = jnode_get_type(node); ++ ++ page = jnode_lock_page(node); ++ assert_spin_locked(&(node->guard)); ++ ++ info = get_super_private(jnode_get_super(node)); ++ ++ __write_lock_tree(info); ++ /* re-check ->x_count under tree lock. */ ++ result = jnode_is_busy(node, jtype); ++ if (likely(!result)) { ++ assert("nikita-2123", JF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ assert("jmacd-511", atomic_read(&node->d_count) == 0); ++ ++ /* detach page */ ++ if (page != NULL) { ++ /* ++ * FIXME this is racy against jnode_extent_write(). ++ */ ++ page_clear_jnode(page, node); ++ } ++ spin_unlock_jnode(node); ++ /* goodbye */ ++ jnode_delete(node, jtype); ++ __write_unlock_tree(info); ++ jnode_free(node, jtype); ++ /* @node is no longer valid pointer */ ++ if (page != NULL) ++ reiser4_drop_page(page); ++ } else { ++ /* busy check failed: reference was acquired by concurrent ++ * thread. */ ++ JF_CLR(node, JNODE_RIP); ++ __write_unlock_tree(info); ++ spin_unlock_jnode(node); ++ if (page != NULL) ++ unlock_page(page); ++ } ++ return result; ++} ++ ++/** ++ * This function frees jnode "if possible". ++ * In particular, [dcx]_count has to be 0 (where applicable). ++ * ++ * @tree: the tree that jnode belongs to. ++ * ++ * Return value: ++ * -EBUSY: failed to drop jnode, because there are still references to it ++ * 0: successfully dropped jnode ++ */ ++int jdrop(jnode *node) ++{ ++ struct page *page; ++ jnode_type jtype; ++ int result; ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_super_private(jnode_get_super(node)); ++ ++ assert_rw_not_read_locked(&(sbinfo->tree_lock)); ++ assert_rw_not_write_locked(&(sbinfo->tree_lock)); ++ assert("nikita-2403", !JF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ ++ jtype = jnode_get_type(node); ++ ++ page = jnode_lock_page(node); ++ assert_spin_locked(&(node->guard)); ++ ++ __write_lock_tree(sbinfo); ++ ++ /* re-check ->x_count under tree lock. */ ++ result = jnode_is_busy(node, jtype); ++ if (!result) { ++ assert("nikita-2488", page == jnode_page(node)); ++ assert("nikita-2533", atomic_read(&node->d_count) == 0); ++ if (page != NULL) { ++ assert("nikita-2126", !PageDirty(page)); ++ assert("nikita-2127", PageUptodate(page)); ++ assert("nikita-2181", PageLocked(page)); ++ page_clear_jnode(page, node); ++ } ++ spin_unlock_jnode(node); ++ jnode_remove(node, jtype); ++ __write_unlock_tree(sbinfo); ++ jnode_free(node, jtype); ++ if (page != NULL) ++ reiser4_drop_page(page); ++ } else { ++ /* busy check failed: reference was acquired by concurrent ++ * thread. */ ++ JF_CLR(node, JNODE_RIP); ++ __write_unlock_tree(sbinfo); ++ spin_unlock_jnode(node); ++ if (page != NULL) ++ unlock_page(page); ++ } ++ return result; ++} ++ ++/* IO head jnode implementation; The io heads are simple j-nodes with limited ++ functionality (these j-nodes are not in any hash table) just for reading ++ from and writing to disk. */ ++ ++jnode *reiser4_alloc_io_head(const reiser4_block_nr *block, ++ reiser4_subvol *subv) ++{ ++ jnode *jal = jalloc(); ++ ++ if (jal != NULL) { ++ jnode_init(jal, subv, JNODE_IO_HEAD); ++ jnode_set_block(jal, block); ++ } ++ ++ jref(jal); ++ ++ return jal; ++} ++ ++void reiser4_drop_io_head(jnode * node) ++{ ++ assert("zam-648", jnode_get_type(node) == JNODE_IO_HEAD); ++ ++ jput(node); ++ jdrop(node); ++} ++ ++jnode *reiser4_alloc_volinfo_head(const reiser4_block_nr *block, ++ reiser4_subvol *subv) ++{ ++ jnode *jal = jalloc(); ++ ++ if (jal != NULL) { ++ jnode_init(jal, subv, JNODE_VOLINFO_HEAD); ++ jnode_set_block(jal, block); ++ } ++ jref(jal); ++ ++ return jal; ++} ++ ++void reiser4_drop_volinfo_head(jnode *node) ++{ ++ assert("edward-1834", ++ jnode_get_type(node) == JNODE_VOLINFO_HEAD); ++ ++ jput(node); ++ jdrop(node); ++} ++ ++/* protect keep jnode data from reiser4_releasepage() */ ++void pin_jnode_data(jnode * node) ++{ ++ assert("zam-671", jnode_page(node) != NULL); ++ get_page(jnode_page(node)); ++} ++ ++/* make jnode data free-able again */ ++void unpin_jnode_data(jnode * node) ++{ ++ assert("zam-672", jnode_page(node) != NULL); ++ put_page(jnode_page(node)); ++} ++ ++struct address_space *jnode_get_mapping(const jnode * node) ++{ ++ return jnode_ops(node)->mapping(node); ++} ++ ++#if REISER4_DEBUG ++/* debugging aid: jnode invariant */ ++int jnode_invariant_f(const jnode * node, char const **msg) ++{ ++#define _ergo(ant, con) \ ++ ((*msg) = "{" #ant "} ergo {" #con "}", ergo((ant), (con))) ++#define _check(exp) ((*msg) = #exp, (exp)) ++ ++ return _check(node != NULL) && ++ /* [jnode-queued] */ ++ /* only relocated node can be queued, except that when znode ++ * is being deleted, its JNODE_RELOC bit is cleared */ ++ _ergo(JF_ISSET(node, JNODE_FLUSH_QUEUED), ++ JF_ISSET(node, JNODE_RELOC) || ++ JF_ISSET(node, JNODE_HEARD_BANSHEE)) && ++ _check(node->jnodes.prev != NULL) && ++ _check(node->jnodes.next != NULL) && ++ /* [jnode-dirty] invariant */ ++ /* dirty inode is part of atom */ ++ _ergo(JF_ISSET(node, JNODE_DIRTY), node->atom != NULL) && ++ /* [jnode-oid] invariant */ ++ /* for unformatted node ->objectid and ->mapping fields are ++ * consistent */ ++ _ergo(jnode_is_unformatted(node) && node->key.j.mapping != NULL, ++ node->key.j.objectid == ++ get_inode_oid(node->key.j.mapping->host)) && ++ /* [jnode-atom-valid] invariant */ ++ /* node atom has valid state */ ++ _ergo(node->atom != NULL, node->atom->stage != ASTAGE_INVALID) && ++ /* [jnode-page-binding] invariant */ ++ /* if node points to page, it points back to node */ ++ _ergo(node->pg != NULL, jprivate(node->pg) == node) && ++ /* [jnode-refs] invariant */ ++ /* only referenced jnode can be loaded */ ++ _check(atomic_read(&node->x_count) >= atomic_read(&node->d_count)); ++ ++} ++ ++static const char *jnode_type_name(jnode_type type) ++{ ++ switch (type) { ++ case JNODE_UNFORMATTED_BLOCK: ++ return "unformatted"; ++ case JNODE_FORMATTED_BLOCK: ++ return "formatted"; ++ case JNODE_BITMAP: ++ return "bitmap"; ++ case JNODE_IO_HEAD: ++ return "io head"; ++ case JNODE_VOLINFO_HEAD: ++ return "volinfo"; ++ case LAST_JNODE_TYPE: ++ return "last"; ++ default:{ ++ static char unknown[30]; ++ ++ sprintf(unknown, "unknown %i", type); ++ return unknown; ++ } ++ } ++} ++ ++#define jnode_state_name(node, flag) \ ++ (JF_ISSET((node), (flag)) ? ((#flag "|")+6) : "") ++ ++/* debugging aid: output human readable information about @node */ ++static void info_jnode(const char *prefix /* prefix to print */ , ++ const jnode * node/* node to print */) ++{ ++ assert("umka-068", prefix != NULL); ++ ++ if (node == NULL) { ++ printk("%s: null\n", prefix); ++ return; ++ } ++ ++ printk ++ ("%s: %p: state: %lx: [%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s%s], level: %i," ++ " block: %s, d_count: %d, x_count: %d, " ++ "pg: %p, atom: %p, lock: %i:%i, type: %s, ", prefix, node, ++ node->state, ++ jnode_state_name(node, JNODE_PARSED), ++ jnode_state_name(node, JNODE_HEARD_BANSHEE), ++ jnode_state_name(node, JNODE_LEFT_CONNECTED), ++ jnode_state_name(node, JNODE_RIGHT_CONNECTED), ++ jnode_state_name(node, JNODE_ORPHAN), ++ jnode_state_name(node, JNODE_CREATED), ++ jnode_state_name(node, JNODE_RELOC), ++ jnode_state_name(node, JNODE_OVRWR), ++ jnode_state_name(node, JNODE_DIRTY), ++ jnode_state_name(node, JNODE_IS_DYING), ++ jnode_state_name(node, JNODE_RIP), ++ jnode_state_name(node, JNODE_MISSED_IN_CAPTURE), ++ jnode_state_name(node, JNODE_WRITEBACK), ++ jnode_state_name(node, JNODE_DKSET), ++ jnode_state_name(node, JNODE_REPACK), ++ jnode_state_name(node, JNODE_CLUSTER_PAGE), ++ jnode_get_level(node), sprint_address(jnode_get_block(node)), ++ atomic_read(&node->d_count), atomic_read(&node->x_count), ++ jnode_page(node), node->atom, 0, 0, ++ jnode_type_name(jnode_get_type(node))); ++ if (jnode_is_unformatted(node)) { ++ printk("inode: %llu, index: %lu, ", ++ node->key.j.objectid, node->key.j.index); ++ } ++} ++ ++/* debugging aid: check znode invariant and panic if it doesn't hold */ ++static int jnode_invariant(jnode *node, int tlocked, int jlocked) ++{ ++ char const *failed_msg; ++ int result; ++ ++ assert("umka-063312", node != NULL); ++ ++ if (!jlocked && !tlocked) ++ spin_lock_jnode((jnode *) node); ++ if (!tlocked) ++ read_lock_tree(); ++ result = jnode_invariant_f(node, &failed_msg); ++ if (!result) { ++ info_jnode("corrupted node", node); ++ warning("jmacd-555", "Condition %s failed", failed_msg); ++ } ++ if (!tlocked) ++ read_unlock_tree(); ++ if (!jlocked && !tlocked) ++ spin_unlock_jnode((jnode *) node); ++ return result; ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/jnode.h linux-5.10.2/fs/reiser4/jnode.h +--- linux-5.10.2.orig/fs/reiser4/jnode.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/jnode.h 2020-12-23 16:07:46.118813129 +0100 +@@ -0,0 +1,726 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Declaration of jnode. See jnode.c for details. */ ++ ++#ifndef __JNODE_H__ ++#define __JNODE_H__ ++ ++#include "forward.h" ++#include "type_safe_hash.h" ++#include "txnmgr.h" ++#include "key.h" ++#include "debug.h" ++#include "dformat.h" ++#include "page_cache.h" ++#include "context.h" ++ ++#include "plugin/plugin.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* declare hash table of jnodes (jnodes proper, that is, unformatted ++ nodes) */ ++TYPE_SAFE_HASH_DECLARE(j, jnode); ++ ++/* declare hash table of znodes */ ++TYPE_SAFE_HASH_DECLARE(z, znode); ++ ++struct jnode_key { ++ __u64 objectid; ++ unsigned long index; ++ struct address_space *mapping; ++}; ++ ++/* ++ Jnode is the "base class" of other nodes in reiser4. It is also happens to ++ be exactly the node we use for unformatted tree nodes. ++ ++ Jnode provides following basic functionality: ++ ++ . reference counting and indexing. ++ ++ . integration with page cache. Jnode has ->pg reference to which page can ++ be attached. ++ ++ . interface to transaction manager. It is jnode that is kept in transaction ++ manager lists, attached to atoms, etc. (NOTE-NIKITA one may argue that this ++ means, there should be special type of jnode for inode.) ++ ++ Locking: ++ ++ Spin lock: the following fields are protected by the per-jnode spin lock: ++ ++ ->state ++ ->atom ++ ->capture_link ++ ++ Following fields are protected by the global tree lock: ++ ++ ->link ++ ->key.z (content of ->key.z is only changed in znode_rehash()) ++ ->key.j ++ ++ Atomic counters ++ ++ ->x_count ++ ->d_count ++ ++ ->pg, and ->data are protected by spin lock for unused jnode and are ++ immutable for used jnode (one for which fs/reiser4/vfs_ops.c:releasable() ++ is false). ++ ++ ->tree is immutable after creation ++ ++ Unclear ++ ++ ->blocknr: should be under jnode spin-lock, but current interface is based ++ on passing of block address. ++ ++ If you ever need to spin lock two nodes at once, do this in "natural" ++ memory order: lock znode with lower address first. (See lock_two_nodes().) ++ ++ Invariants involving this data-type: ++ ++ [jnode-dirty] ++ [jnode-refs] ++ [jnode-oid] ++ [jnode-queued] ++ [jnode-atom-valid] ++ [jnode-page-binding] ++*/ ++ ++struct jnode { ++#if REISER4_DEBUG ++#define JMAGIC 0x52654973 /* "ReIs" */ ++ int magic; ++#endif ++ /* FIRST CACHE LINE (16 bytes): data used by jload */ ++ ++ /* jnode's state: bitwise flags from the reiser4_jnode_state enum. */ ++ /* 0 */ unsigned long state; ++ ++ /* lock, protecting jnode's fields. */ ++ /* 4 */ spinlock_t load; ++ ++ /* counter of references to jnode itself. Increased on jref(). ++ Decreased on jput(). ++ */ ++ /* 8 */ atomic_t x_count; ++ ++ /* counter of references to jnode's data. Pin data page(s) in ++ memory while this is greater than 0. Increased on jload(). ++ Decreased on jrelse(). ++ */ ++ /* 12 */ atomic_t d_count; ++ ++ /* SECOND CACHE LINE: data used by hash table lookups */ ++ ++ /* 16 */ union { ++ /* znodes are hashed by block number */ ++ reiser4_block_nr z; ++ /* unformatted nodes are hashed by mapping plus offset */ ++ struct jnode_key j; ++ } key; ++ ++ /* THIRD CACHE LINE */ ++ ++ /* 32 */ union { ++ /* pointers to maintain hash-table */ ++ z_hash_link z; ++ j_hash_link j; ++ } link; ++ ++ /* pointer to jnode page. */ ++ /* 36 */ struct page *pg; ++ /* ++ * Pointer to node's content. ++ * This is page_address(node->pg) when page is attached to the jnode ++ */ ++ /* 40 */ void *data; ++ ++ /* Subvolume, where IO is going to/from. ++ The pair (subvol, blocknr) defines "IO address" ++ */ ++ /* 44 */ struct reiser4_subvol *subvol; ++ ++ /* FOURTH CACHE LINE: atom related fields */ ++ ++ /* 48 */ spinlock_t guard; ++ ++ /* atom the block is in, if any */ ++ /* 52 */ txn_atom *atom; ++ ++ /* capture list */ ++ /* 56 */ struct list_head capture_link; ++ ++ /* FIFTH CACHE LINE */ ++ ++ /* 64 */ struct rcu_head rcu; ++ /* crosses cache line */ ++ ++ /* SIXTH CACHE LINE */ ++ ++ /* the real blocknr (where io is going to/from) */ ++ /* 80 */ reiser4_block_nr blocknr; ++ /* Parent item type, unformatted and CRC need it for ++ * offset => key conversion. */ ++ /* NOTE: this parent_item_id looks like jnode type. */ ++ /* 88 */ reiser4_plugin_id parent_item_id; ++ /* wait on JNODE_LOADING_IN_PROGRESS flag */ ++ /* 92 */ wait_queue_head_t wait_jload; ++ /* 116 */ struct super_block *super; ++#if REISER4_DEBUG ++ /* list of all jnodes for debugging purposes. */ ++ struct list_head jnodes; ++ /* how many times this jnode was written in one transaction */ ++ int written; ++ /* this indicates which atom's list the jnode is on */ ++ atom_list list; ++#endif ++} __attribute__ ((aligned(16))); ++ ++/* ++ * jnode types. Enumeration of existing jnode types. ++ */ ++typedef enum { ++ JNODE_UNFORMATTED_BLOCK, /* unformatted block */ ++ JNODE_FORMATTED_BLOCK, /* formatted block, znode */ ++ JNODE_BITMAP, /* bitmap */ ++ JNODE_IO_HEAD, /* jnode representing a block in the ++ * wandering log */ ++ JNODE_VOLINFO_HEAD, /* jnode representing a block of logical ++ volume system information */ ++ LAST_JNODE_TYPE ++} jnode_type; ++ ++/* jnode states */ ++typedef enum { ++ /* jnode's page is loaded and data checked */ ++ JNODE_PARSED = 0, ++ /* node was deleted, not all locks on it were released. This ++ node is empty and is going to be removed from the tree ++ shortly. */ ++ JNODE_HEARD_BANSHEE = 1, ++ /* left sibling pointer is valid */ ++ JNODE_LEFT_CONNECTED = 2, ++ /* right sibling pointer is valid */ ++ JNODE_RIGHT_CONNECTED = 3, ++ ++ /* znode was just created and doesn't yet have a pointer from ++ its parent */ ++ JNODE_ORPHAN = 4, ++ ++ /* this node was created by its transaction and has not been assigned ++ a block address. */ ++ JNODE_CREATED = 5, ++ ++ /* this node is currently relocated */ ++ JNODE_RELOC = 6, ++ /* this node is currently wandered */ ++ JNODE_OVRWR = 7, ++ ++ /* this znode has been modified */ ++ JNODE_DIRTY = 8, ++ ++ /* znode lock is being invalidated */ ++ JNODE_IS_DYING = 9, ++ ++ /* THIS PLACE IS INTENTIONALLY LEFT BLANK */ ++ ++ /* jnode is queued for flushing. */ ++ JNODE_FLUSH_QUEUED = 12, ++ ++ /* In the following bits jnode type is encoded. */ ++ JNODE_TYPE_1 = 13, ++ JNODE_TYPE_2 = 14, ++ JNODE_TYPE_3 = 15, ++ ++ /* jnode is being destroyed */ ++ JNODE_RIP = 16, ++ ++ /* znode was not captured during locking (it might so be because ++ ->level != LEAF_LEVEL and lock_mode == READ_LOCK) */ ++ JNODE_MISSED_IN_CAPTURE = 17, ++ ++ /* write is in progress */ ++ JNODE_WRITEBACK = 18, ++ ++ /* indicates that someone has already started to load jnode, ++ so that other processes should wait on this flag */ ++ JNODE_LOADING_IN_PROGRESS = 19, ++ ++ /* delimiting keys are already set for this znode. */ ++ JNODE_DKSET = 20, ++ ++ /* when this bit is set page and jnode can not be disconnected */ ++ JNODE_WRITE_PREPARED = 21, ++ ++ JNODE_CLUSTER_PAGE = 22, ++ /* Jnode is marked for repacking, that means the reiser4 flush and the ++ * block allocator should process this node special way */ ++ JNODE_REPACK = 23, ++ /* node should be converted by flush in squalloc phase */ ++ JNODE_CONVERTIBLE = 24, ++ /* jnode parsing failed */ ++ JNODE_PARSING_FAILED = 25, ++ /* ++ * When jnode is dirtied for the first time in given transaction, ++ * do_jnode_make_dirty() checks whether this jnode can possible became ++ * member of overwrite set. If so, this bit is set, and one block is ++ * reserved in the ->flush_reserved space of atom. ++ * ++ * This block is "used" (and JNODE_FLUSH_RESERVED bit is cleared) when ++ * ++ * (1) flush decides that we want this block to go into relocate ++ * set after all. ++ * ++ * (2) wandering log is allocated (by log writer) ++ * ++ * (3) extent is allocated ++ * ++ */ ++ JNODE_FLUSH_RESERVED = 29 ++} reiser4_jnode_state; ++ ++/* Macros for accessing the jnode state. */ ++ ++static inline void JF_CLR(jnode * j, int f) ++{ ++ assert("unknown-1", j->magic == JMAGIC); ++ clear_bit(f, &j->state); ++} ++static inline int JF_ISSET(const jnode * j, int f) ++{ ++ assert("unknown-2", j->magic == JMAGIC); ++ return test_bit(f, &((jnode *) j)->state); ++} ++static inline void JF_SET(jnode * j, int f) ++{ ++ assert("unknown-3", j->magic == JMAGIC); ++ set_bit(f, &j->state); ++} ++ ++static inline int JF_TEST_AND_SET(jnode * j, int f) ++{ ++ assert("unknown-4", j->magic == JMAGIC); ++ return test_and_set_bit(f, &j->state); ++} ++ ++static inline void spin_lock_jnode(jnode *node) ++{ ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(rw_locked_tree) && ++ LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(spin_locked_zlock) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_LT(spin_locked_jnode, 2))); ++ ++ spin_lock(&(node->guard)); ++ ++ LOCK_CNT_INC(spin_locked_jnode); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void spin_unlock_jnode(jnode *node) ++{ ++ assert_spin_locked(&(node->guard)); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_jnode)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(spin_locked_jnode); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&(node->guard)); ++} ++ ++static inline int jnode_is_in_deleteset(const jnode * node) ++{ ++ return JF_ISSET(node, JNODE_RELOC); ++} ++ ++extern int init_jnodes(void); ++extern void done_jnodes(void); ++ ++/* Jnode routines */ ++extern jnode *jalloc(void); ++extern void jfree(jnode * node) NONNULL; ++extern jnode *jclone(jnode *); ++extern jnode *jlookup(oid_t objectid, unsigned long ind) NONNULL; ++extern jnode *jfind(struct address_space *, unsigned long index) NONNULL; ++extern jnode *jnode_by_page(struct page *pg) NONNULL; ++extern jnode *jnode_of_page(struct page *pg) NONNULL; ++void jnode_attach_page(jnode * node, struct page *pg); ++ ++void unhash_unformatted_jnode(jnode *); ++extern jnode *page_next_jnode(jnode * node) NONNULL; ++extern void jnode_init(jnode *node, ++ struct reiser4_subvol *sub, jnode_type); ++extern void jnode_init_tail(jnode *node) NONNULL; ++extern void jnode_make_dirty(jnode * node) NONNULL; ++extern void jnode_make_clean(jnode * node) NONNULL; ++extern void jnode_make_wander_nolock(jnode * node) NONNULL; ++extern void jnode_make_wander(jnode *) NONNULL; ++extern void znode_make_reloc(znode * , flush_queue_t *) NONNULL; ++extern void unformatted_make_reloc(jnode *, flush_queue_t *) NONNULL; ++extern struct address_space *jnode_get_mapping(const jnode * node) NONNULL; ++ ++static inline reiser4_subvol *jnode_get_subvol(const jnode *node) ++{ ++ assert("edward-1871", node != NULL); ++ assert("edward-1872", node->subvol != NULL); ++ ++ return node->subvol; ++} ++ ++static inline void jnode_set_subvol(jnode *node, reiser4_subvol *subv) ++{ ++ assert("edward-2222", node != NULL); ++ assert("edward-2224", subv != NULL); ++ assert("edward-2223", ergo(node->subvol != NULL, node->subvol == subv)); ++ ++ node->subvol = subv; ++} ++ ++#define jnode_get_super(node) ((node)->super) ++ ++static inline const reiser4_block_nr *jnode_get_block(const jnode *node) ++{ ++ assert("nikita-528", node != NULL); ++ ++ return &node->blocknr; ++} ++ ++static inline void jnode_set_block(jnode *node, const reiser4_block_nr *blocknr) ++{ ++ assert("nikita-2020", node != NULL); ++ assert("umka-055", blocknr != NULL); ++ node->blocknr = *blocknr; ++} ++ ++/** ++ * block number for IO. Usually this is the same as jnode_get_block(), ++ * unless jnode was emergency flushed - then block number chosen by ++ * eflush is used ++ */ ++static inline const reiser4_block_nr *jnode_get_io_block(jnode * node) ++{ ++ assert("nikita-2768", node != NULL); ++ assert_spin_locked(&(node->guard)); ++ ++ return jnode_get_block(node); ++} ++ ++/* Jnode flush interface. */ ++extern flush_queue_t *reiser4_pos_fq(flush_pos_t *pos); ++ ++/* FIXME-VS: these are used in plugin/item/extent.c */ ++ ++/* does extent_get_block have to be called */ ++#define jnode_mapped(node) JF_ISSET (node, JNODE_MAPPED) ++#define jnode_set_mapped(node) JF_SET (node, JNODE_MAPPED) ++ ++/* the node should be converted during flush squalloc phase */ ++#define jnode_convertible(node) JF_ISSET (node, JNODE_CONVERTIBLE) ++#define jnode_set_convertible(node) JF_SET (node, JNODE_CONVERTIBLE) ++ ++/* Macros to convert from jnode to znode, znode to jnode. These are macros ++ because C doesn't allow overloading of const prototypes. */ ++#define ZJNODE(x) (&(x)->zjnode) ++#define JZNODE(x) \ ++({ \ ++ typeof(x) __tmp_x; \ ++ \ ++ __tmp_x = (x); \ ++ assert("jmacd-1300", jnode_is_znode(__tmp_x)); \ ++ (znode*) __tmp_x; \ ++}) ++ ++extern int reiser4_jnodes_init(void); ++extern int reiser4_jnodes_done(void); ++ ++#if REISER4_DEBUG ++ ++extern int znode_is_any_locked(const znode * node); ++extern void jnode_list_remove(jnode * node); ++ ++#else ++ ++#define jnode_list_remove(node) noop ++ ++#endif ++ ++int znode_is_root(const znode * node) NONNULL; ++ ++/* bump reference counter on @node */ ++static inline void add_x_ref(jnode * node/* node to increase x_count of */) ++{ ++ assert("nikita-1911", node != NULL); ++ ++ atomic_inc(&node->x_count); ++ LOCK_CNT_INC(x_refs); ++} ++ ++static inline void dec_x_ref(jnode * node) ++{ ++ assert("nikita-3215", node != NULL); ++ assert("nikita-3216", atomic_read(&node->x_count) > 0); ++ ++ atomic_dec(&node->x_count); ++ assert("nikita-3217", LOCK_CNT_GTZ(x_refs)); ++ LOCK_CNT_DEC(x_refs); ++} ++ ++/* jref() - increase counter of references to jnode/znode (x_count) */ ++static inline jnode *jref(jnode * node) ++{ ++ assert("jmacd-508", (node != NULL) && !IS_ERR(node)); ++ add_x_ref(node); ++ return node; ++} ++ ++/* get the page of jnode */ ++static inline struct page *jnode_page(const jnode * node) ++{ ++ return node->pg; ++} ++ ++/* return pointer to jnode data */ ++static inline char *jdata(const jnode * node) ++{ ++ assert("nikita-1415", node != NULL); ++ assert("nikita-3198", jnode_page(node) != NULL); ++ return node->data; ++} ++ ++static inline int jnode_is_loaded(const jnode * node) ++{ ++ assert("zam-506", node != NULL); ++ return atomic_read(&node->d_count) > 0; ++} ++ ++extern void page_clear_jnode(struct page *page, jnode * node) NONNULL; ++ ++static inline void jnode_set_reloc(jnode * node) ++{ ++ assert("nikita-2431", node != NULL); ++ assert("nikita-2432", !JF_ISSET(node, JNODE_OVRWR)); ++ JF_SET(node, JNODE_RELOC); ++} ++ ++/* jload/jwrite/junload give a bread/bwrite/brelse functionality for jnodes */ ++ ++extern int jload_gfp(jnode *, gfp_t, int do_kmap) NONNULL; ++ ++static inline int jload(jnode *node) ++{ ++ return jload_gfp(node, reiser4_ctx_gfp_mask_get(), 1); ++} ++ ++extern int jinit_new(jnode *, gfp_t) NONNULL; ++extern int jstartio(jnode *) NONNULL; ++ ++extern int jdrop(jnode *) NONNULL; ++extern int jwait_io(jnode *, int rw) NONNULL; ++ ++void jload_prefetch(jnode *); ++ ++extern jnode *reiser4_alloc_io_head(const reiser4_block_nr *block, ++ reiser4_subvol *subv) NONNULL; ++extern jnode *reiser4_alloc_volinfo_head(const reiser4_block_nr *block, ++ reiser4_subvol *subv) NONNULL; ++extern void reiser4_drop_io_head(jnode * node) NONNULL; ++extern void reiser4_drop_volinfo_head(jnode * node) NONNULL; ++extern void pin_jnode_data(jnode *); ++extern void unpin_jnode_data(jnode *); ++ ++static inline jnode_type jnode_get_type(const jnode * node) ++{ ++ static const unsigned long state_mask = ++ (1 << JNODE_TYPE_1) | (1 << JNODE_TYPE_2) | (1 << JNODE_TYPE_3); ++ ++ static jnode_type mask_to_type[] = { ++ /* JNODE_TYPE_3 : JNODE_TYPE_2 : JNODE_TYPE_1 */ ++ ++ /* 000 */ ++ [0] = JNODE_FORMATTED_BLOCK, ++ /* 001 */ ++ [1] = JNODE_UNFORMATTED_BLOCK, ++ /* 010 */ ++ [2] = JNODE_BITMAP, ++ /* 011 */ ++ [3] = LAST_JNODE_TYPE, /*invalid */ ++ /* 100 */ ++ [4] = JNODE_VOLINFO_HEAD, ++ /* 101 */ ++ [5] = LAST_JNODE_TYPE, ++ /* 110 */ ++ [6] = JNODE_IO_HEAD, ++ /* 111 */ ++ [7] = LAST_JNODE_TYPE, /* invalid */ ++ }; ++ ++ return mask_to_type[(node->state & state_mask) >> JNODE_TYPE_1]; ++} ++ ++/* returns true if node is a znode */ ++static inline int jnode_is_znode(const jnode * node) ++{ ++ return jnode_get_type(node) == JNODE_FORMATTED_BLOCK; ++} ++ ++static inline int jnode_is_flushprepped(jnode * node) ++{ ++ assert("jmacd-78212", node != NULL); ++ assert_spin_locked(&(node->guard)); ++ return !JF_ISSET(node, JNODE_DIRTY) || JF_ISSET(node, JNODE_RELOC) || ++ JF_ISSET(node, JNODE_OVRWR); ++} ++ ++/* Return true if @node has already been processed by the squeeze and allocate ++ process. This implies the block address has been finalized for the ++ duration of this atom (or it is clean and will remain in place). If this ++ returns true you may use the block number as a hint. */ ++static inline int jnode_check_flushprepped(jnode * node) ++{ ++ int result; ++ ++ /* It must be clean or relocated or wandered. New allocations are set ++ * to relocate. */ ++ spin_lock_jnode(node); ++ result = jnode_is_flushprepped(node); ++ spin_unlock_jnode(node); ++ return result; ++} ++ ++/* returns true if node is unformatted */ ++static inline int jnode_is_unformatted(const jnode * node) ++{ ++ assert("jmacd-0123", node != NULL); ++ return jnode_get_type(node) == JNODE_UNFORMATTED_BLOCK; ++} ++ ++/* returns true if node represents a cluster cache page */ ++static inline int jnode_is_cluster_page(const jnode * node) ++{ ++ assert("edward-50", node != NULL); ++ return (JF_ISSET(node, JNODE_CLUSTER_PAGE)); ++} ++ ++/* returns true is node is builtin inode's jnode */ ++static inline int jnode_is_volinfo_head(const jnode * node) ++{ ++ assert("vs-1240", node != NULL); ++ return jnode_get_type(node) == JNODE_VOLINFO_HEAD; ++} ++ ++static inline jnode_plugin *jnode_ops_of(const jnode_type type) ++{ ++ assert("nikita-2367", type < LAST_JNODE_TYPE); ++ return jnode_plugin_by_id((reiser4_plugin_id) type); ++} ++ ++static inline jnode_plugin *jnode_ops(const jnode * node) ++{ ++ assert("nikita-2366", node != NULL); ++ ++ return jnode_ops_of(jnode_get_type(node)); ++} ++ ++/* Get the index of a block. */ ++static inline unsigned long jnode_get_index(jnode * node) ++{ ++ return jnode_ops(node)->index(node); ++} ++ ++/* return true if "node" is the root */ ++static inline int jnode_is_root(const jnode * node) ++{ ++ return jnode_is_znode(node) && znode_is_root(JZNODE(node)); ++} ++ ++extern struct address_space *mapping_jnode(const jnode * node); ++extern unsigned long index_jnode(const jnode * node); ++ ++static inline void jput(jnode * node); ++extern void jput_final(jnode *node); ++ ++/* bump data counter on @node */ ++static inline void add_d_ref(jnode * node/* node to increase d_count of */) ++{ ++ assert("nikita-1962", node != NULL); ++ ++ atomic_inc(&node->d_count); ++ if (jnode_is_unformatted(node) || jnode_is_znode(node)) ++ LOCK_CNT_INC(d_refs); ++} ++ ++/* jput() - decrement x_count reference counter on znode. ++ ++ Count may drop to 0, jnode stays in cache until memory pressure causes the ++ eviction of its page. The c_count variable also ensures that children are ++ pressured out of memory before the parent. The jnode remains hashed as ++ long as the VM allows its page to stay in memory. ++*/ ++static inline void jput(jnode * node) ++{ ++ assert("jmacd-509", node != NULL); ++ assert("jmacd-510", atomic_read(&node->x_count) > 0); ++ assert("zam-926", reiser4_schedulable()); ++ LOCK_CNT_DEC(x_refs); ++ ++ rcu_read_lock(); ++ /* ++ * we don't need any kind of lock here--jput_final() uses RCU. ++ */ ++ if (unlikely(atomic_dec_and_test(&node->x_count))) ++ jput_final(node); ++ else ++ rcu_read_unlock(); ++ assert("nikita-3473", reiser4_schedulable()); ++} ++ ++extern void jrelse(jnode * node); ++extern void jrelse_tail(jnode * node); ++ ++extern jnode *jnode_rip_sync(jnode *node); ++ ++/* resolve race with jput */ ++static inline jnode *jnode_rip_check(jnode *node) ++{ ++ if (unlikely(JF_ISSET(node, JNODE_RIP))) ++ node = jnode_rip_sync(node); ++ return node; ++} ++ ++static inline jnode *jnode_by_link(struct list_head *link) ++{ ++ return list_entry(link, jnode, capture_link); ++} ++ ++extern reiser4_key *jnode_build_key(const jnode *node, reiser4_key * key); ++ ++#if REISER4_DEBUG ++extern int jnode_invariant_f(const jnode *node, char const **msg); ++#endif ++ ++extern jnode_plugin jnode_plugins[LAST_JNODE_TYPE]; ++ ++/* __JNODE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/kassign.c linux-5.10.2/fs/reiser4/kassign.c +--- linux-5.10.2.orig/fs/reiser4/kassign.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/kassign.c 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,670 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Key assignment policy implementation */ ++ ++/* ++ * In reiser4 every piece of file system data and meta-data has a key. Keys ++ * are used to store information in and retrieve it from reiser4 internal ++ * tree. In addition to this, keys define _ordering_ of all file system ++ * information: things having close keys are placed into the same or ++ * neighboring (in the tree order) nodes of the tree. As our block allocator ++ * tries to respect tree order (see flush.c), keys also define order in which ++ * things are laid out on the disk, and hence, affect performance directly. ++ * ++ * Obviously, assignment of keys to data and meta-data should be consistent ++ * across whole file system. Algorithm that calculates a key for a given piece ++ * of data or meta-data is referred to as "key assignment". ++ * ++ * Key assignment is too expensive to be implemented as a plugin (that is, ++ * with an ability to support different key assignment schemas in the same ++ * compiled kernel image). As a compromise, all key-assignment functions and ++ * data-structures are collected in this single file, so that modifications to ++ * key assignment algorithm can be localized. Additional changes may be ++ * required in key.[ch]. ++ * ++ * Current default reiser4 key assignment algorithm is dubbed "Plan A". As one ++ * may guess, there is "Plan B" too. ++ * ++ */ ++ ++/* ++ * Additional complication with key assignment implementation is a requirement ++ * to support different key length. ++ */ ++ ++/* ++ * KEY ASSIGNMENT: PLAN A, LONG KEYS. ++ * ++ * DIRECTORY ITEMS ++ * ++ * | 60 | 4 | 7 |1| 56 | 64 | 64 | ++ * +--------------+---+---+-+-------------+------------------+-----------------+ ++ * | dirid | 0 | F |H| prefix-1 | prefix-2 | prefix-3/hash | ++ * +--------------+---+---+-+-------------+------------------+-----------------+ ++ * | | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * dirid objectid of directory this item is for ++ * ++ * F fibration, see fs/reiser4/plugin/fibration.[ch] ++ * ++ * H 1 if last 8 bytes of the key contain hash, ++ * 0 if last 8 bytes of the key contain prefix-3 ++ * ++ * prefix-1 first 7 characters of file name. ++ * Padded by zeroes if name is not long enough. ++ * ++ * prefix-2 next 8 characters of the file name. ++ * ++ * prefix-3 next 8 characters of the file name. ++ * ++ * hash hash of the rest of file name (i.e., portion of file ++ * name not included into prefix-1 and prefix-2). ++ * ++ * File names shorter than 23 (== 7 + 8 + 8) characters are completely encoded ++ * in the key. Such file names are called "short". They are distinguished by H ++ * bit set 0 in the key. ++ * ++ * Other file names are "long". For long name, H bit is 1, and first 15 (== 7 ++ * + 8) characters are encoded in prefix-1 and prefix-2 portions of the ++ * key. Last 8 bytes of the key are occupied by hash of the remaining ++ * characters of the name. ++ * ++ * This key assignment reaches following important goals: ++ * ++ * (1) directory entries are sorted in approximately lexicographical ++ * order. ++ * ++ * (2) collisions (when multiple directory items have the same key), while ++ * principally unavoidable in a tree with fixed length keys, are rare. ++ * ++ * STAT DATA ++ * ++ * | 60 | 4 | 64 | 4 | 60 | 64 | ++ * +--------------+---+-----------------+---+--------------+-----------------+ ++ * | locality id | 1 | ordering | 0 | objectid | 0 | ++ * +--------------+---+-----------------+---+--------------+-----------------+ ++ * | | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * locality id object id of a directory where first name was created for ++ * the object ++ * ++ * ordering copy of second 8-byte portion of the key of directory ++ * entry for the first name of this object. Ordering has a form ++ * { ++ * fibration :7; ++ * h :1; ++ * prefix1 :56; ++ * } ++ * see description of key for directory entry above. ++ * ++ * objectid object id for this object ++ * ++ * This key assignment policy is designed to keep stat-data in the same order ++ * as corresponding directory items, thus speeding up readdir/stat types of ++ * workload. ++ * ++ * FILE BODY ++ * ++ * | 60 | 4 | 64 | 4 | 60 | 64 | ++ * +--------------+---+-----------------+---+--------------+-----------------+ ++ * | locality id | 4 | ordering | 0 | objectid | offset | ++ * +--------------+---+-----------------+---+--------------+-----------------+ ++ * | | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * locality id object id of a directory where first name was created for ++ * the object ++ * ++ * ordering the same as in the key of stat-data for this object ++ * ++ * objectid object id for this object ++ * ++ * offset logical offset from the beginning of this file. ++ * Measured in bytes. ++ * ++ * ++ * KEY ASSIGNMENT: PLAN A, SHORT KEYS. ++ * ++ * DIRECTORY ITEMS ++ * ++ * | 60 | 4 | 7 |1| 56 | 64 | ++ * +--------------+---+---+-+-------------+-----------------+ ++ * | dirid | 0 | F |H| prefix-1 | prefix-2/hash | ++ * +--------------+---+---+-+-------------+-----------------+ ++ * | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * dirid objectid of directory this item is for ++ * ++ * F fibration, see fs/reiser4/plugin/fibration.[ch] ++ * ++ * H 1 if last 8 bytes of the key contain hash, ++ * 0 if last 8 bytes of the key contain prefix-2 ++ * ++ * prefix-1 first 7 characters of file name. ++ * Padded by zeroes if name is not long enough. ++ * ++ * prefix-2 next 8 characters of the file name. ++ * ++ * hash hash of the rest of file name (i.e., portion of file ++ * name not included into prefix-1). ++ * ++ * File names shorter than 15 (== 7 + 8) characters are completely encoded in ++ * the key. Such file names are called "short". They are distinguished by H ++ * bit set in the key. ++ * ++ * Other file names are "long". For long name, H bit is 0, and first 7 ++ * characters are encoded in prefix-1 portion of the key. Last 8 bytes of the ++ * key are occupied by hash of the remaining characters of the name. ++ * ++ * STAT DATA ++ * ++ * | 60 | 4 | 4 | 60 | 64 | ++ * +--------------+---+---+--------------+-----------------+ ++ * | locality id | 1 | 0 | objectid | 0 | ++ * +--------------+---+---+--------------+-----------------+ ++ * | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * locality id object id of a directory where first name was created for ++ * the object ++ * ++ * objectid object id for this object ++ * ++ * FILE BODY ++ * ++ * | 60 | 4 | 4 | 60 | 64 | ++ * +--------------+---+---+--------------+-----------------+ ++ * | locality id | 4 | 0 | objectid | offset | ++ * +--------------+---+---+--------------+-----------------+ ++ * | | | | ++ * | 8 bytes | 8 bytes | 8 bytes | ++ * ++ * locality id object id of a directory where first name was created for ++ * the object ++ * ++ * objectid object id for this object ++ * ++ * offset logical offset from the beginning of this file. ++ * Measured in bytes. ++ * ++ * ++ */ ++ ++#include "debug.h" ++#include "key.h" ++#include "kassign.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "super.h" ++#include "dscale.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block, etc */ ++ ++/* bitmask for H bit (see comment at the beginning of this file */ ++static const __u64 longname_mark = 0x0100000000000000ull; ++/* bitmask for F and H portions of the key. */ ++static const __u64 fibration_mask = 0xff00000000000000ull; ++ ++/* return true if name is not completely encoded in @key */ ++int is_longname_key(const reiser4_key * key) ++{ ++ __u64 highpart; ++ ++ assert("nikita-2863", key != NULL); ++ if (get_key_type(key) != KEY_FILE_NAME_MINOR) ++ reiser4_print_key("oops", key); ++ assert("nikita-2864", get_key_type(key) == KEY_FILE_NAME_MINOR); ++ ++ if (REISER4_LARGE_KEY) ++ highpart = get_key_ordering(key); ++ else ++ highpart = get_key_objectid(key); ++ ++ return (highpart & longname_mark) ? 1 : 0; ++} ++ ++/* return true if @name is too long to be completely encoded in the key */ ++int is_longname(const char *name UNUSED_ARG, int len) ++{ ++ if (REISER4_LARGE_KEY) ++ return len > 23; ++ else ++ return len > 15; ++} ++ ++/* code ascii string into __u64. ++ ++ Put characters of @name into result (@str) one after another starting ++ from @start_idx-th highest (arithmetically) byte. This produces ++ endian-safe encoding. memcpy(2) will not do. ++ ++*/ ++static __u64 pack_string(const char *name /* string to encode */ , ++ int start_idx /* highest byte in result from ++ * which to start encoding */ ) ++{ ++ unsigned i; ++ __u64 str; ++ ++ str = 0; ++ for (i = 0; (i < sizeof str - start_idx) && name[i]; ++i) { ++ str <<= 8; ++ str |= (unsigned char)name[i]; ++ } ++ str <<= (sizeof str - i - start_idx) << 3; ++ return str; ++} ++ ++/* opposite to pack_string(). Takes value produced by pack_string(), restores ++ * string encoded in it and stores result in @buf */ ++char *reiser4_unpack_string(__u64 value, char *buf) ++{ ++ do { ++ *buf = value >> (64 - 8); ++ if (*buf) ++ ++buf; ++ value <<= 8; ++ } while (value != 0); ++ *buf = 0; ++ return buf; ++} ++ ++/* obtain name encoded in @key and store it in @buf */ ++char *extract_name_from_key(const reiser4_key * key, char *buf) ++{ ++ char *c; ++ ++ assert("nikita-2868", !is_longname_key(key)); ++ ++ c = buf; ++ if (REISER4_LARGE_KEY) { ++ c = reiser4_unpack_string(get_key_ordering(key) & ++ ~fibration_mask, c); ++ c = reiser4_unpack_string(get_key_fulloid(key), c); ++ } else ++ c = reiser4_unpack_string(get_key_fulloid(key) & ++ ~fibration_mask, c); ++ reiser4_unpack_string(get_key_offset(key), c); ++ return buf; ++} ++ ++/** ++ * complete_entry_key - calculate entry key by name ++ * @dir: directory where entry is (or will be) in ++ * @name: name to calculate key of ++ * @len: lenth of name ++ * @result: place to store result in ++ * ++ * Sets fields of entry key @result which depend on file name. ++ * When REISER4_LARGE_KEY is defined three fields of @result are set: ordering, ++ * objectid and offset. Otherwise, objectid and offset are set. ++ */ ++void complete_entry_key(const struct inode *dir, const char *name, ++ int len, reiser4_key *result) ++{ ++#if REISER4_LARGE_KEY ++ __u64 ordering; ++ __u64 objectid; ++ __u64 offset; ++ ++ assert("nikita-1139", dir != NULL); ++ assert("nikita-1142", result != NULL); ++ assert("nikita-2867", strlen(name) == len); ++ ++ /* ++ * key allocation algorithm for directory entries in case of large ++ * keys: ++ * ++ * If name is not longer than 7 + 8 + 8 = 23 characters, put first 7 ++ * characters into ordering field of key, next 8 charactes (if any) ++ * into objectid field of key and next 8 ones (of any) into offset ++ * field of key ++ * ++ * If file name is longer than 23 characters, put first 7 characters ++ * into key's ordering, next 8 to objectid and hash of remaining ++ * characters into offset field. ++ * ++ * To distinguish above cases, in latter set up unused high bit in ++ * ordering field. ++ */ ++ ++ /* [0-6] characters to ordering */ ++ ordering = pack_string(name, 1); ++ if (len > 7) { ++ /* [7-14] characters to objectid */ ++ objectid = pack_string(name + 7, 0); ++ if (len > 15) { ++ if (len <= 23) { ++ /* [15-23] characters to offset */ ++ offset = pack_string(name + 15, 0); ++ } else { ++ /* note in a key the fact that offset contains ++ * hash */ ++ ordering |= longname_mark; ++ ++ /* offset is the hash of the file name's tail */ ++ offset = inode_hash_plugin(dir)->hash(name + 15, ++ len - 15); ++ } ++ } else { ++ offset = 0ull; ++ } ++ } else { ++ objectid = 0ull; ++ offset = 0ull; ++ } ++ ++ assert("nikita-3480", inode_fibration_plugin(dir) != NULL); ++ ordering |= inode_fibration_plugin(dir)->fibre(dir, name, len); ++ ++ set_key_ordering(result, ordering); ++ set_key_fulloid(result, objectid); ++ set_key_offset(result, offset); ++ return; ++ ++#else ++ __u64 objectid; ++ __u64 offset; ++ ++ assert("nikita-1139", dir != NULL); ++ assert("nikita-1142", result != NULL); ++ assert("nikita-2867", strlen(name) == len); ++ ++ /* ++ * key allocation algorithm for directory entries in case of not large ++ * keys: ++ * ++ * If name is not longer than 7 + 8 = 15 characters, put first 7 ++ * characters into objectid field of key, next 8 charactes (if any) ++ * into offset field of key ++ * ++ * If file name is longer than 15 characters, put first 7 characters ++ * into key's objectid, and hash of remaining characters into offset ++ * field. ++ * ++ * To distinguish above cases, in latter set up unused high bit in ++ * objectid field. ++ */ ++ ++ /* [0-6] characters to objectid */ ++ objectid = pack_string(name, 1); ++ if (len > 7) { ++ if (len <= 15) { ++ /* [7-14] characters to offset */ ++ offset = pack_string(name + 7, 0); ++ } else { ++ /* note in a key the fact that offset contains hash. */ ++ objectid |= longname_mark; ++ ++ /* offset is the hash of the file name. */ ++ offset = inode_hash_plugin(dir)->hash(name + 7, ++ len - 7); ++ } ++ } else ++ offset = 0ull; ++ ++ assert("nikita-3480", inode_fibration_plugin(dir) != NULL); ++ objectid |= inode_fibration_plugin(dir)->fibre(dir, name, len); ++ ++ set_key_fulloid(result, objectid); ++ set_key_offset(result, offset); ++ return; ++#endif /* ! REISER4_LARGE_KEY */ ++} ++ ++/* true, if @key is the key of "." */ ++int is_dot_key(const reiser4_key * key/* key to check */) ++{ ++ assert("nikita-1717", key != NULL); ++ assert("nikita-1718", get_key_type(key) == KEY_FILE_NAME_MINOR); ++ return ++ (get_key_ordering(key) == 0ull) && ++ (get_key_objectid(key) == 0ull) && (get_key_offset(key) == 0ull); ++} ++ ++/* build key for stat-data. ++ ++ return key of stat-data of this object. This should became sd plugin ++ method in the future. For now, let it be here. ++ ++*/ ++reiser4_key *build_sd_key(const struct inode *target /* inode of an object */ , ++ reiser4_key * result /* resulting key of @target ++ stat-data */ ) ++{ ++ assert("nikita-261", result != NULL); ++ ++ reiser4_key_init(result); ++ set_key_locality(result, reiser4_inode_data(target)->locality_id); ++ set_key_ordering(result, get_inode_ordering(target)); ++ set_key_objectid(result, get_inode_oid(target)); ++ set_key_type(result, KEY_SD_MINOR); ++ set_key_offset(result, (__u64) 0); ++ return result; ++} ++ ++/* encode part of key into &obj_key_id ++ ++ This encodes into @id part of @key sufficient to restore @key later, ++ given that latter is key of object (key of stat-data). ++ ++ See &obj_key_id ++*/ ++int build_obj_key_id(const reiser4_key * key /* key to encode */ , ++ obj_key_id * id/* id where key is encoded in */) ++{ ++ assert("nikita-1151", key != NULL); ++ assert("nikita-1152", id != NULL); ++ ++ memcpy(id, key, sizeof *id); ++ return 0; ++} ++ ++/* encode reference to @obj in @id. ++ ++ This is like build_obj_key_id() above, but takes inode as parameter. */ ++int build_inode_key_id(const struct inode *obj /* object to build key of */ , ++ obj_key_id * id/* result */) ++{ ++ reiser4_key sdkey; ++ ++ assert("nikita-1166", obj != NULL); ++ assert("nikita-1167", id != NULL); ++ ++ build_sd_key(obj, &sdkey); ++ build_obj_key_id(&sdkey, id); ++ return 0; ++} ++ ++/* decode @id back into @key ++ ++ Restore key of object stat-data from @id. This is dual to ++ build_obj_key_id() above. ++*/ ++int extract_key_from_id(const obj_key_id * id /* object key id to extract key ++ * from */ , ++ reiser4_key * key/* result */) ++{ ++ assert("nikita-1153", id != NULL); ++ assert("nikita-1154", key != NULL); ++ ++ reiser4_key_init(key); ++ memcpy(key, id, sizeof *id); ++ return 0; ++} ++ ++/* extract objectid of directory from key of directory entry within said ++ directory. ++ */ ++oid_t extract_dir_id_from_key(const reiser4_key * de_key /* key of ++ * directory ++ * entry */ ) ++{ ++ assert("nikita-1314", de_key != NULL); ++ return get_key_locality(de_key); ++} ++ ++/* encode into @id key of directory entry. ++ ++ Encode into @id information sufficient to later distinguish directory ++ entries within the same directory. This is not whole key, because all ++ directory entries within directory item share locality which is equal ++ to objectid of their directory. ++ ++*/ ++int build_de_id(const struct inode *dir /* inode of directory */ , ++ const struct qstr *name /* name to be given to @obj by ++ * directory entry being ++ * constructed */ , ++ de_id * id/* short key of directory entry */) ++{ ++ reiser4_key key; ++ ++ assert("nikita-1290", dir != NULL); ++ assert("nikita-1292", id != NULL); ++ ++ /* NOTE-NIKITA this is suboptimal. */ ++ inode_dir_plugin(dir)->build_entry_key(dir, name, &key); ++ return build_de_id_by_key(&key, id); ++} ++ ++/* encode into @id key of directory entry. ++ ++ Encode into @id information sufficient to later distinguish directory ++ entries within the same directory. This is not whole key, because all ++ directory entries within directory item share locality which is equal ++ to objectid of their directory. ++ ++*/ ++int build_de_id_by_key(const reiser4_key * entry_key /* full key of directory ++ * entry */ , ++ de_id * id/* short key of directory entry */) ++{ ++ memcpy(id, ((__u64 *) entry_key) + 1, sizeof *id); ++ return 0; ++} ++ ++/* restore from @id key of directory entry. ++ ++ Function dual to build_de_id(): given @id and locality, build full ++ key of directory entry within directory item. ++ ++*/ ++int extract_key_from_de_id(const oid_t locality /* locality of directory ++ * entry */ , ++ const de_id * id /* directory entry id */ , ++ reiser4_key * key/* result */) ++{ ++ /* no need to initialise key here: all fields are overwritten */ ++ memcpy(((__u64 *) key) + 1, id, sizeof *id); ++ set_key_locality(key, locality); ++ set_key_type(key, KEY_FILE_NAME_MINOR); ++ return 0; ++} ++ ++/* compare two &de_id's */ ++cmp_t de_id_cmp(const de_id * id1 /* first &de_id to compare */ , ++ const de_id * id2/* second &de_id to compare */) ++{ ++ /* NOTE-NIKITA ugly implementation */ ++ reiser4_key k1; ++ reiser4_key k2; ++ ++ extract_key_from_de_id((oid_t) 0, id1, &k1); ++ extract_key_from_de_id((oid_t) 0, id2, &k2); ++ return keycmp(&k1, &k2); ++} ++ ++/* compare &de_id with key */ ++cmp_t de_id_key_cmp(const de_id * id /* directory entry id to compare */ , ++ const reiser4_key * key/* key to compare */) ++{ ++ reiser4_key *k1; ++ ++ k1 = (reiser4_key *) (((unsigned long)id) - sizeof key->el[0]); ++ return short_keycmp(k1, key); ++} ++ ++/* ++ * return number of bytes necessary to encode @inode identity. ++ */ ++int inode_onwire_size(const struct inode *inode) ++{ ++ int result; ++ ++ result = dscale_bytes_to_write(get_inode_oid(inode)); ++ result += dscale_bytes_to_write(get_inode_locality(inode)); ++ ++ /* ++ * ordering is large (it usually has highest bits set), so it makes ++ * little sense to dscale it. ++ */ ++ if (REISER4_LARGE_KEY) ++ result += sizeof(get_inode_ordering(inode)); ++ return result; ++} ++ ++/* ++ * encode @inode identity at @start ++ */ ++char *build_inode_onwire(const struct inode *inode, char *start) ++{ ++ start += dscale_write(start, get_inode_locality(inode)); ++ start += dscale_write(start, get_inode_oid(inode)); ++ ++ if (REISER4_LARGE_KEY) { ++ put_unaligned(cpu_to_le64(get_inode_ordering(inode)), (__le64 *)start); ++ start += sizeof(get_inode_ordering(inode)); ++ } ++ return start; ++} ++ ++/* ++ * extract key that was previously encoded by build_inode_onwire() at @addr ++ */ ++char *extract_obj_key_id_from_onwire(char *addr, obj_key_id * key_id) ++{ ++ __u64 val; ++ ++ addr += dscale_read(addr, &val); ++ val = (val << KEY_LOCALITY_SHIFT) | KEY_SD_MINOR; ++ put_unaligned(cpu_to_le64(val), (__le64 *)key_id->locality); ++ addr += dscale_read(addr, &val); ++ put_unaligned(cpu_to_le64(val), (__le64 *)key_id->objectid); ++#if REISER4_LARGE_KEY ++ memcpy(&key_id->ordering, addr, sizeof key_id->ordering); ++ addr += sizeof key_id->ordering; ++#endif ++ return addr; ++} ++ ++/* ++ * skip a key that was previously encoded by build_inode_onwire() at @addr ++ * FIXME: handle IO errors. ++ */ ++char * locate_obj_key_id_onwire(char * addr) ++{ ++ /* locality */ ++ addr += dscale_bytes_to_read(addr); ++ /* objectid */ ++ addr += dscale_bytes_to_read(addr); ++#if REISER4_LARGE_KEY ++ addr += sizeof ((obj_key_id *)0)->ordering; ++#endif ++ return addr; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/kassign.h linux-5.10.2/fs/reiser4/kassign.h +--- linux-5.10.2.orig/fs/reiser4/kassign.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/kassign.h 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,111 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Key assignment policy interface. See kassign.c for details. */ ++ ++#if !defined(__KASSIGN_H__) ++#define __KASSIGN_H__ ++ ++#include "forward.h" ++#include "key.h" ++#include "dformat.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block, etc */ ++#include /* for struct qstr */ ++ ++/* key assignment functions */ ++ ++/* Information from which key of file stat-data can be uniquely ++ restored. This depends on key assignment policy for ++ stat-data. Currently it's enough to store object id and locality id ++ (60+60==120) bits, because minor packing locality and offset of ++ stat-data key are always known constants: KEY_SD_MINOR and 0 ++ respectively. For simplicity 4 bits are wasted in each id, and just ++ two 64 bit integers are stored. ++ ++ This field has to be byte-aligned, because we don't want to waste ++ space in directory entries. There is another side of a coin of ++ course: we waste CPU and bus bandwidth in stead, by copying data back ++ and forth. ++ ++ Next optimization: &obj_key_id is mainly used to address stat data from ++ directory entries. Under the assumption that majority of files only have ++ only name (one hard link) from *the* parent directory it seems reasonable ++ to only store objectid of stat data and take its locality from key of ++ directory item. ++ ++ This requires some flag to be added to the &obj_key_id to distinguish ++ between these two cases. Remaining bits in flag byte are then asking to be ++ used to store file type. ++ ++ This optimization requires changes in directory item handling code. ++ ++*/ ++typedef struct obj_key_id { ++ d8 locality[sizeof(__u64)]; ++ ON_LARGE_KEY(d8 ordering[sizeof(__u64)]; ++ ) ++ d8 objectid[sizeof(__u64)]; ++} ++obj_key_id; ++ ++/* Information sufficient to uniquely identify directory entry within ++ compressed directory item. ++ ++ For alignment issues see &obj_key_id above. ++*/ ++typedef struct de_id { ++ ON_LARGE_KEY(d8 ordering[sizeof(__u64)];) ++ d8 objectid[sizeof(__u64)]; ++ d8 offset[sizeof(__u64)]; ++} ++de_id; ++ ++extern int inode_onwire_size(const struct inode *obj); ++extern char *build_inode_onwire(const struct inode *obj, char *area); ++extern char *locate_obj_key_id_onwire(char *area); ++extern char *extract_obj_key_id_from_onwire(char *area, obj_key_id * key_id); ++ ++extern int build_inode_key_id(const struct inode *obj, obj_key_id * id); ++extern int extract_key_from_id(const obj_key_id * id, reiser4_key * key); ++extern int build_obj_key_id(const reiser4_key * key, obj_key_id * id); ++extern oid_t extract_dir_id_from_key(const reiser4_key * de_key); ++extern int build_de_id(const struct inode *dir, const struct qstr *name, ++ de_id * id); ++extern int build_de_id_by_key(const reiser4_key * entry_key, de_id * id); ++extern int extract_key_from_de_id(const oid_t locality, const de_id * id, ++ reiser4_key * key); ++extern cmp_t de_id_cmp(const de_id * id1, const de_id * id2); ++extern cmp_t de_id_key_cmp(const de_id * id, const reiser4_key * key); ++ ++extern int build_readdir_key_common(struct file *dir, reiser4_key * result); ++extern void build_entry_key_common(const struct inode *dir, ++ const struct qstr *name, ++ reiser4_key * result); ++extern void build_entry_key_stable_entry(const struct inode *dir, ++ const struct qstr *name, ++ reiser4_key * result); ++extern int is_dot_key(const reiser4_key * key); ++extern reiser4_key *build_sd_key(const struct inode *target, ++ reiser4_key * result); ++ ++extern int is_longname_key(const reiser4_key * key); ++extern int is_longname(const char *name, int len); ++extern char *extract_name_from_key(const reiser4_key * key, char *buf); ++extern char *reiser4_unpack_string(__u64 value, char *buf); ++extern void complete_entry_key(const struct inode *dir, const char *name, ++ int len, reiser4_key *result); ++ ++/* __KASSIGN_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/Kconfig linux-5.10.2/fs/reiser4/Kconfig +--- linux-5.10.2.orig/fs/reiser4/Kconfig 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/Kconfig 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,45 @@ ++config REISER4_FS ++ tristate "Reiser4 (EXPERIMENTAL)" ++ select ZLIB_INFLATE ++ select ZLIB_DEFLATE ++ select LZO_COMPRESS ++ select LZO_DECOMPRESS ++ select ZSTD_COMPRESS ++ select ZSTD_DECOMPRESS ++ select CRYPTO ++ select CRYPTO_CRC32C ++ help ++ Reiser4 is a filesystem that performs all filesystem operations ++ as atomic transactions, which means that it either performs a ++ write, or it does not, and in the event of a crash it does not ++ partially perform it or corrupt it. ++ ++ It stores files in dancing trees, which are like balanced trees but ++ faster. It packs small files together so that they share blocks ++ without wasting space. This means you can use it to store really ++ small files. It also means that it saves you disk space. It avoids ++ hassling you with anachronisms like having a maximum number of ++ inodes, and wasting space if you use less than that number. ++ ++ Reiser4 is a distinct filesystem type from reiserfs (V3). ++ It's therefore not possible to use reiserfs file systems ++ with reiser4. ++ ++ To learn more about reiser4, go to http://reiser4.wiki.kernel.org/ ++ ++config REISER4_OLD ++ bool "Enable Plan-A key allocation scheme" ++ depends on REISER4_FS ++ help ++ Say Y if you intend to mount old reiser4 partitions. ++ Note, that it will disable some new features like logical volumes. ++ ++ If unsure, say N. ++ ++config REISER4_DEBUG ++ bool "Enable reiser4 debug mode" ++ depends on REISER4_FS ++ help ++ Don't use this unless you are debugging reiser4. ++ ++ If unsure, say N. +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/key.c linux-5.10.2/fs/reiser4/key.c +--- linux-5.10.2.orig/fs/reiser4/key.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/key.c 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,138 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Key manipulations. */ ++ ++#include "debug.h" ++#include "key.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include /* for __u?? */ ++ ++/* Minimal possible key: all components are zero. It is presumed that this is ++ independent of key scheme. */ ++static const reiser4_key MINIMAL_KEY = { ++ .el = { ++ 0ull, ++ ON_LARGE_KEY(0ull,) ++ 0ull, ++ 0ull ++ } ++}; ++ ++/* Maximal possible key: all components are ~0. It is presumed that this is ++ independent of key scheme. */ ++static const reiser4_key MAXIMAL_KEY = { ++ .el = { ++ __constant_cpu_to_le64(~0ull), ++ ON_LARGE_KEY(__constant_cpu_to_le64(~0ull),) ++ __constant_cpu_to_le64(~0ull), ++ __constant_cpu_to_le64(~0ull) ++ } ++}; ++ ++/* Initialize key. */ ++void reiser4_key_init(reiser4_key * key/* key to init */) ++{ ++ assert("nikita-1169", key != NULL); ++ memset(key, 0, sizeof *key); ++} ++ ++/* minimal possible key in the tree. Return pointer to the static storage. */ ++const reiser4_key * reiser4_min_key(void) ++{ ++ return &MINIMAL_KEY; ++} ++ ++/* maximum possible key in the tree. Return pointer to the static storage. */ ++const reiser4_key * reiser4_max_key(void) ++{ ++ return &MAXIMAL_KEY; ++} ++ ++#if REISER4_DEBUG ++/* debugging aid: print symbolic name of key type */ ++static const char *type_name(unsigned int key_type/* key type */) ++{ ++ switch (key_type) { ++ case KEY_FILE_NAME_MINOR: ++ return "file name"; ++ case KEY_SD_MINOR: ++ return "stat data"; ++ case KEY_ATTR_NAME_MINOR: ++ return "attr name"; ++ case KEY_ATTR_BODY_MINOR: ++ return "attr body"; ++ case KEY_BODY_MINOR: ++ return "file body"; ++ default: ++ return "unknown"; ++ } ++} ++ ++/* debugging aid: print human readable information about key */ ++void reiser4_print_key(const char *prefix /* prefix to print */ , ++ const reiser4_key * key/* key to print */) ++{ ++ /* turn bold on */ ++ /* printf ("\033[1m"); */ ++ if (key == NULL) ++ printk("%s: null key\n", prefix); ++ else { ++ if (REISER4_LARGE_KEY) ++ printk("%s: (%Lx:%x:%Lx:%Lx:%Lx:%Lx)", prefix, ++ get_key_locality(key), ++ get_key_type(key), ++ get_key_ordering(key), ++ get_key_band(key), ++ get_key_objectid(key), get_key_offset(key)); ++ else ++ printk("%s: (%Lx:%x:%Lx:%Lx:%Lx)", prefix, ++ get_key_locality(key), ++ get_key_type(key), ++ get_key_band(key), ++ get_key_objectid(key), get_key_offset(key)); ++ /* ++ * if this is a key of directory entry, try to decode part of ++ * a name stored in the key, and output it. ++ */ ++ if (get_key_type(key) == KEY_FILE_NAME_MINOR) { ++ char buf[DE_NAME_BUF_LEN]; ++ char *c; ++ ++ c = buf; ++ c = reiser4_unpack_string(get_key_ordering(key), c); ++ reiser4_unpack_string(get_key_fulloid(key), c); ++ printk("[%s", buf); ++ if (is_longname_key(key)) ++ /* ++ * only part of the name is stored in the key. ++ */ ++ printk("...]\n"); ++ else { ++ /* ++ * whole name is stored in the key. ++ */ ++ reiser4_unpack_string(get_key_offset(key), buf); ++ printk("%s]\n", buf); ++ } ++ } else { ++ printk("[%s]\n", type_name(get_key_type(key))); ++ } ++ } ++ /* turn bold off */ ++ /* printf ("\033[m\017"); */ ++} ++ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/key.h linux-5.10.2/fs/reiser4/key.h +--- linux-5.10.2.orig/fs/reiser4/key.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/key.h 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,445 @@ ++/* Copyright 2000, 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Declarations of key-related data-structures and operations on keys. */ ++ ++#if !defined(__REISER4_KEY_H__) ++#define __REISER4_KEY_H__ ++ ++#include "dformat.h" ++#include "forward.h" ++#include "debug.h" ++ ++#include ++#include /* for __u?? */ ++ ++/* Operations on keys in reiser4 tree */ ++ ++/* No access to any of these fields shall be done except via a ++ wrapping macro/function, and that wrapping macro/function shall ++ convert to little endian order. Compare keys will consider cpu byte order. */ ++ ++/* A storage layer implementation difference between a regular unix file body ++ and its attributes is in the typedef below which causes all of the attributes ++ of a file to be near in key to all of the other attributes for all of the ++ files within that directory, and not near to the file itself. It is ++ interesting to consider whether this is the wrong approach, and whether there ++ should be no difference at all. For current usage patterns this choice is ++ probably the right one. */ ++ ++/* possible values for minor packing locality (4 bits required) */ ++typedef enum { ++ /* file name */ ++ KEY_FILE_NAME_MINOR = 0, ++ /* stat-data */ ++ KEY_SD_MINOR = 1, ++ /* file attribute name */ ++ KEY_ATTR_NAME_MINOR = 2, ++ /* file attribute value */ ++ KEY_ATTR_BODY_MINOR = 3, ++ /* file body (tail or extent) */ ++ KEY_BODY_MINOR = 4, ++} key_minor_locality; ++ ++/* Everything stored in the tree has a unique key, which means that the tree is ++ (logically) fully ordered by key. Physical order is determined by dynamic ++ heuristics that attempt to reflect key order when allocating available space, ++ and by the repacker. It is stylistically better to put aggregation ++ information into the key. Thus, if you want to segregate extents from tails, ++ it is better to give them distinct minor packing localities rather than ++ changing block_alloc.c to check the node type when deciding where to allocate ++ the node. ++ ++ The need to randomly displace new directories and large files disturbs this ++ symmetry unfortunately. However, it should be noted that this is a need that ++ is not clearly established given the existence of a repacker. Also, in our ++ current implementation tails have a different minor packing locality from ++ extents, and no files have both extents and tails, so maybe symmetry can be ++ had without performance cost after all. Symmetry is what we ship for now.... ++*/ ++ ++/* Arbitrary major packing localities can be assigned to objects using ++ the reiser4(filenameA/..packing<=some_number) system call. ++ ++ In reiser4, the creat() syscall creates a directory ++ ++ whose default flow (that which is referred to if the directory is ++ read as a file) is the traditional unix file body. ++ ++ whose directory plugin is the 'filedir' ++ ++ whose major packing locality is that of the parent of the object created. ++ ++ The static_stat item is a particular commonly used directory ++ compression (the one for normal unix files). ++ ++ The filedir plugin checks to see if the static_stat item exists. ++ There is a unique key for static_stat. If yes, then it uses the ++ static_stat item for all of the values that it contains. The ++ static_stat item contains a flag for each stat it contains which ++ indicates whether one should look outside the static_stat item for its ++ contents. ++*/ ++ ++/* offset of fields in reiser4_key. Value of each element of this enum ++ is index within key (thought as array of __u64's) where this field ++ is. */ ++typedef enum { ++ /* major "locale", aka dirid. Sits in 1st element */ ++ KEY_LOCALITY_INDEX = 0, ++ /* minor "locale", aka item type. Sits in 1st element */ ++ KEY_TYPE_INDEX = 0, ++ ON_LARGE_KEY(KEY_ORDERING_INDEX,) ++ /* "object band". Sits in 2nd element */ ++ KEY_BAND_INDEX, ++ /* objectid. Sits in 2nd element */ ++ KEY_OBJECTID_INDEX = KEY_BAND_INDEX, ++ /* full objectid. Sits in 2nd element */ ++ KEY_FULLOID_INDEX = KEY_BAND_INDEX, ++ /* Offset. Sits in 3rd element */ ++ KEY_OFFSET_INDEX, ++ /* Name hash. Sits in 3rd element */ ++ KEY_HASH_INDEX = KEY_OFFSET_INDEX, ++ KEY_CACHELINE_END = KEY_OFFSET_INDEX, ++ KEY_LAST_INDEX ++} reiser4_key_field_index; ++ ++/* key in reiser4 internal "balanced" tree. It is just array of three ++ 64bit integers in disk byte order (little-endian by default). This ++ array is actually indexed by reiser4_key_field. Each __u64 within ++ this array is called "element". Logical key component encoded within ++ elements are called "fields". ++ ++ We declare this as union with second component dummy to suppress ++ inconvenient array<->pointer casts implied in C. */ ++union reiser4_key { ++ __le64 el[KEY_LAST_INDEX]; ++ int pad; ++}; ++ ++/* bitmasks showing where within reiser4_key particular key is stored. */ ++/* major locality occupies higher 60 bits of the first element */ ++#define KEY_LOCALITY_MASK 0xfffffffffffffff0ull ++ ++/* minor locality occupies lower 4 bits of the first element */ ++#define KEY_TYPE_MASK 0xfull ++ ++/* controversial band occupies higher 4 bits of the 2nd element */ ++#define KEY_BAND_MASK 0xf000000000000000ull ++ ++/* objectid occupies lower 60 bits of the 2nd element */ ++#define KEY_OBJECTID_MASK 0x0fffffffffffffffull ++ ++/* full 64bit objectid*/ ++#define KEY_FULLOID_MASK 0xffffffffffffffffull ++ ++/* offset is just 3rd L.M.Nt itself */ ++#define KEY_OFFSET_MASK 0xffffffffffffffffull ++ ++/* ordering is whole second element */ ++#define KEY_ORDERING_MASK 0xffffffffffffffffull ++ ++/* how many bits key element should be shifted to left to get particular field ++ */ ++typedef enum { ++ KEY_LOCALITY_SHIFT = 4, ++ KEY_TYPE_SHIFT = 0, ++ KEY_BAND_SHIFT = 60, ++ KEY_OBJECTID_SHIFT = 0, ++ KEY_FULLOID_SHIFT = 0, ++ KEY_OFFSET_SHIFT = 0, ++ KEY_ORDERING_SHIFT = 0, ++} reiser4_key_field_shift; ++ ++static inline __u64 ++get_key_el(const reiser4_key * key, reiser4_key_field_index off) ++{ ++ assert("nikita-753", key != NULL); ++ assert("nikita-754", off < KEY_LAST_INDEX); ++ return le64_to_cpu(get_unaligned(&key->el[off])); ++} ++ ++static inline void ++set_key_el(reiser4_key * key, reiser4_key_field_index off, __u64 value) ++{ ++ assert("nikita-755", key != NULL); ++ assert("nikita-756", off < KEY_LAST_INDEX); ++ put_unaligned(cpu_to_le64(value), &key->el[off]); ++} ++ ++/* macro to define getter and setter functions for field F with type T */ ++#define DEFINE_KEY_FIELD(L, U, T) \ ++static inline T get_key_ ## L(const reiser4_key *key) \ ++{ \ ++ assert("nikita-750", key != NULL); \ ++ return (T) (get_key_el(key, KEY_ ## U ## _INDEX) & \ ++ KEY_ ## U ## _MASK) >> KEY_ ## U ## _SHIFT; \ ++} \ ++ \ ++static inline void set_key_ ## L(reiser4_key * key, T loc) \ ++{ \ ++ __u64 el; \ ++ \ ++ assert("nikita-752", key != NULL); \ ++ \ ++ el = get_key_el(key, KEY_ ## U ## _INDEX); \ ++ /* clear field bits in the key */ \ ++ el &= ~KEY_ ## U ## _MASK; \ ++ /* actually it should be \ ++ \ ++ el |= ( loc << KEY_ ## U ## _SHIFT ) & KEY_ ## U ## _MASK; \ ++ \ ++ but we trust user to never pass values that wouldn't fit \ ++ into field. Clearing extra bits is one operation, but this \ ++ function is time-critical. \ ++ But check this in assertion. */ \ ++ assert("nikita-759", ((loc << KEY_ ## U ## _SHIFT) & \ ++ ~KEY_ ## U ## _MASK) == 0); \ ++ el |= (loc << KEY_ ## U ## _SHIFT); \ ++ set_key_el(key, KEY_ ## U ## _INDEX, el); \ ++} ++ ++typedef __u64 oid_t; ++ ++/* define get_key_locality(), set_key_locality() */ ++DEFINE_KEY_FIELD(locality, LOCALITY, oid_t); ++/* define get_key_type(), set_key_type() */ ++DEFINE_KEY_FIELD(type, TYPE, key_minor_locality); ++/* define get_key_band(), set_key_band() */ ++DEFINE_KEY_FIELD(band, BAND, __u64); ++/* define get_key_objectid(), set_key_objectid() */ ++DEFINE_KEY_FIELD(objectid, OBJECTID, oid_t); ++/* define get_key_fulloid(), set_key_fulloid() */ ++DEFINE_KEY_FIELD(fulloid, FULLOID, oid_t); ++/* define get_key_offset(), set_key_offset() */ ++DEFINE_KEY_FIELD(offset, OFFSET, __u64); ++#if (REISER4_LARGE_KEY) ++/* define get_key_ordering(), set_key_ordering() */ ++DEFINE_KEY_FIELD(ordering, ORDERING, __u64); ++#else ++static inline __u64 get_key_ordering(const reiser4_key * key) ++{ ++ return 0; ++} ++ ++static inline void set_key_ordering(reiser4_key * key, __u64 val) ++{ ++} ++#endif /* REISER4_LARGE_KEY */ ++ ++/* key comparison result */ ++typedef enum { ++ LESS_THAN = -1, /* if first key is less than second */ ++ EQUAL_TO = 0, /* if keys are equal */ ++ GREATER_THAN = +1 /* if first key is greater than second */ ++} cmp_t; ++ ++void reiser4_key_init(reiser4_key * key); ++ ++/* minimal possible key in the tree. Return pointer to the static storage. */ ++extern const reiser4_key *reiser4_min_key(void); ++extern const reiser4_key *reiser4_max_key(void); ++ ++/* helper macro for keycmp() */ ++#define KEY_DIFF(k1, k2, field) \ ++({ \ ++ typeof(get_key_ ## field(k1)) f1; \ ++ typeof(get_key_ ## field(k2)) f2; \ ++ \ ++ f1 = get_key_ ## field(k1); \ ++ f2 = get_key_ ## field(k2); \ ++ \ ++ (f1 < f2) ? LESS_THAN : ((f1 == f2) ? EQUAL_TO : GREATER_THAN); \ ++}) ++ ++/* helper macro for keycmp() */ ++#define KEY_DIFF_EL(k1, k2, off) \ ++({ \ ++ __u64 e1; \ ++ __u64 e2; \ ++ \ ++ e1 = get_key_el(k1, off); \ ++ e2 = get_key_el(k2, off); \ ++ \ ++ (e1 < e2) ? LESS_THAN : ((e1 == e2) ? EQUAL_TO : GREATER_THAN); \ ++}) ++ ++/** ++ * compare `k1' and `k2'. The following pair of functions is a heart of ++ * "key allocation policy". All you need to implement new policy is to ++ * add yet another clause here. ++ */ ++static inline cmp_t keycmp(const reiser4_key * k1 /* first key to compare */, ++ const reiser4_key * k2/* second key to compare */) ++{ ++ cmp_t result; ++ ++ /* ++ * This function is the heart of reiser4 tree-routines. Key comparison ++ * is among most heavily used operations in the file system. ++ */ ++ ++ assert("nikita-439", k1 != NULL); ++ assert("nikita-440", k2 != NULL); ++ ++ /* there is no actual branch here: condition is compile time constant ++ * and constant folding and propagation ensures that only one branch ++ * is actually compiled in. */ ++ ++ /* In Plan-A and Plan-B schemes we compare type and locality at once, ++ because their physical order is identical with the logical one). ++ */ ++ if (REISER4_PLANA_KEY_ALLOCATION) { ++ /* logical order of fields in plan-A: ++ locality->type->(ordering)->objectid->offset */ ++ ++ result = KEY_DIFF_EL(k1, k2, 0); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 1); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 2); ++ if (REISER4_LARGE_KEY && result == EQUAL_TO) ++ result = KEY_DIFF_EL(k1, k2, 3); ++ } ++ } ++ } else if (REISER4_PLANB_KEY_ALLOCATION) { ++ /* logical order of fields in plan-B: ++ locality->type->objectid->offset->(ordering) */ ++ ++ result = KEY_DIFF_EL(k1, k2, 0); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 2); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 3); ++ if (REISER4_LARGE_KEY && result == EQUAL_TO) ++ result = KEY_DIFF_EL(k1, k2, 1); ++ } ++ } ++ } else if (REISER4_3_5_KEY_ALLOCATION) { ++ /* Old good key allocation scheme from ReiserFS(v3) ++ FIXME: support it in Reiser4progs */ ++ ++ result = KEY_DIFF(k1, k2, locality); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF(k1, k2, objectid); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF(k1, k2, type); ++ if (result == EQUAL_TO) ++ result = KEY_DIFF(k1, k2, offset); ++ } ++ } ++ } else ++ impossible("nikita-441", "Unknown key allocation scheme!"); ++ return result; ++} ++ ++/** ++ * compare "sub-keys" of @k1 and @k2 (i.e. keys without the first component). ++ */ ++static inline cmp_t short_keycmp(const reiser4_key *k1, const reiser4_key *k2) ++{ ++ cmp_t result; ++ ++ if (REISER4_PLANA_KEY_ALLOCATION) { ++ result = KEY_DIFF_EL(k1, k2, 1); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 2); ++ if (REISER4_LARGE_KEY && result == EQUAL_TO) ++ result = KEY_DIFF_EL(k1, k2, 3); ++ } ++ } else if (REISER4_PLANB_KEY_ALLOCATION) { ++ result = KEY_DIFF_EL(k1, k2, 2); ++ if (result == EQUAL_TO) { ++ result = KEY_DIFF_EL(k1, k2, 3); ++ if (REISER4_LARGE_KEY && result == EQUAL_TO) ++ result = KEY_DIFF_EL(k1, k2, 1); ++ } ++ } else ++ impossible("edward-2142", "Unsupported key allocation scheme!"); ++ return result; ++} ++ ++/* true if @k1 equals @k2 */ ++static inline int keyeq(const reiser4_key * k1 /* first key to compare */ , ++ const reiser4_key * k2/* second key to compare */) ++{ ++ assert("nikita-1879", k1 != NULL); ++ assert("nikita-1880", k2 != NULL); ++ return !memcmp(k1, k2, sizeof *k1); ++} ++ ++/* true if @k1 is less than @k2 */ ++static inline int keylt(const reiser4_key * k1 /* first key to compare */ , ++ const reiser4_key * k2/* second key to compare */) ++{ ++ assert("nikita-1952", k1 != NULL); ++ assert("nikita-1953", k2 != NULL); ++ return keycmp(k1, k2) == LESS_THAN; ++} ++ ++/* true if @k1 is less than or equal to @k2 */ ++static inline int keyle(const reiser4_key * k1 /* first key to compare */ , ++ const reiser4_key * k2/* second key to compare */) ++{ ++ assert("nikita-1954", k1 != NULL); ++ assert("nikita-1955", k2 != NULL); ++ return keycmp(k1, k2) != GREATER_THAN; ++} ++ ++/* true if @k1 is greater than @k2 */ ++static inline int keygt(const reiser4_key * k1 /* first key to compare */ , ++ const reiser4_key * k2/* second key to compare */) ++{ ++ assert("nikita-1959", k1 != NULL); ++ assert("nikita-1960", k2 != NULL); ++ return keycmp(k1, k2) == GREATER_THAN; ++} ++ ++/* true if @k1 is greater than or equal to @k2 */ ++static inline int keyge(const reiser4_key * k1 /* first key to compare */ , ++ const reiser4_key * k2/* second key to compare */) ++{ ++ assert("nikita-1956", k1 != NULL); ++ assert("nikita-1957", k2 != NULL); /* October 4: sputnik launched ++ * November 3: Laika */ ++ return keycmp(k1, k2) != LESS_THAN; ++} ++ ++static inline int all_but_ordering_keyeq(const reiser4_key * k1, ++ const reiser4_key * k2) ++{ ++ return (get_key_locality(k1) == get_key_locality(k2) && ++ get_key_type(k1) == get_key_type(k2) && ++ get_key_fulloid(k1) == get_key_fulloid(k2) && ++ get_key_offset(k1) == get_key_offset(k2)); ++} ++ ++static inline void prefetchkey(reiser4_key * key) ++{ ++ prefetch(key); ++ prefetch(&key->el[KEY_CACHELINE_END]); ++} ++ ++/* (%Lx:%x:%Lx:%Lx:%Lx:%Lx) = ++ 1 + 16 + 1 + 1 + 1 + 1 + 1 + 16 + 1 + 16 + 1 + 16 + 1 */ ++/* size of a buffer suitable to hold human readable key representation */ ++#define KEY_BUF_LEN (80) ++ ++#if REISER4_DEBUG ++extern void reiser4_print_key(const char *prefix, const reiser4_key * key); ++#else ++#define reiser4_print_key(p, k) noop ++#endif ++ ++/* __FS_REISERFS_KEY_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/ktxnmgrd.c linux-5.10.2/fs/reiser4/ktxnmgrd.c +--- linux-5.10.2.orig/fs/reiser4/ktxnmgrd.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/ktxnmgrd.c 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,213 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* Transaction manager daemon. */ ++ ++/* ++ * ktxnmgrd is a kernel daemon responsible for committing transactions. It is ++ * needed/important for the following reasons: ++ * ++ * 1. in reiser4 atom is not committed immediately when last transaction ++ * handle closes, unless atom is either too old or too large (see ++ * atom_should_commit()). This is done to avoid committing too frequently. ++ * because: ++ * ++ * 2. sometimes we don't want to commit atom when closing last transaction ++ * handle even if it is old and fat enough. For example, because we are at ++ * this point under directory semaphore, and committing would stall all ++ * accesses to this directory. ++ * ++ * ktxnmgrd binds its time sleeping on condition variable. When is awakes ++ * either due to (tunable) timeout or because it was explicitly woken up by ++ * call to ktxnmgrd_kick(), it scans list of all atoms and commits ones ++ * eligible. ++ * ++ */ ++ ++#include "debug.h" ++#include "txnmgr.h" ++#include "tree.h" ++#include "ktxnmgrd.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include /* for struct task_struct */ ++#include ++#include ++#include ++#include ++#include ++#include ++ ++static int scan_mgr(struct super_block *); ++ ++/* ++ * change current->comm so that ps, top, and friends will see changed ++ * state. This serves no useful purpose whatsoever, but also costs nothing. May ++ * be it will make lonely system administrator feeling less alone at 3 A.M. ++ */ ++#define set_comm(state) \ ++ snprintf(current->comm, sizeof(current->comm), \ ++ "%s:%s:%s", __FUNCTION__, (super)->s_id, (state)) ++ ++/** ++ * ktxnmgrd - kernel txnmgr daemon ++ * @arg: pointer to super block ++ * ++ * The background transaction manager daemon, started as a kernel thread during ++ * reiser4 initialization. ++ */ ++static int ktxnmgrd(void *arg) ++{ ++ struct super_block *super; ++ ktxnmgrd_context *ctx; ++ txn_mgr *mgr; ++ int done = 0; ++ ++ super = arg; ++ mgr = &get_super_private(super)->tmgr; ++ ++ /* ++ * do_fork() just copies task_struct into the new thread. ->fs_context ++ * shouldn't be copied of course. This shouldn't be a problem for the ++ * rest of the code though. ++ */ ++ current->journal_info = NULL; ++ ctx = mgr->daemon; ++ while (1) { ++ try_to_freeze(); ++ set_comm("wait"); ++ { ++ DEFINE_WAIT(__wait); ++ ++ prepare_to_wait(&ctx->wait, &__wait, ++ TASK_INTERRUPTIBLE); ++ if (kthread_should_stop()) ++ done = 1; ++ else ++ schedule_timeout(ctx->timeout); ++ finish_wait(&ctx->wait, &__wait); ++ } ++ if (done) ++ break; ++ set_comm("run"); ++ spin_lock(&ctx->guard); ++ /* ++ * wait timed out or ktxnmgrd was woken up by explicit request ++ * to commit something. Scan list of atoms in txnmgr and look ++ * for too old atoms. ++ */ ++ do { ++ ctx->rescan = 0; ++ scan_mgr(super); ++ spin_lock(&ctx->guard); ++ if (ctx->rescan) { ++ /* ++ * the list could be modified while ctx ++ * spinlock was released, we have to repeat ++ * scanning from the beginning ++ */ ++ break; ++ } ++ } while (ctx->rescan); ++ spin_unlock(&ctx->guard); ++ } ++ return 0; ++} ++ ++#undef set_comm ++ ++/** ++ * reiser4_init_ktxnmgrd - initialize ktxnmgrd context and start kernel daemon ++ * @super: pointer to super block ++ * ++ * Allocates and initializes ktxnmgrd_context, attaches it to transaction ++ * manager. Starts kernel txnmgr daemon. This is called on mount. ++ */ ++int reiser4_init_ktxnmgrd(struct super_block *super) ++{ ++ txn_mgr *mgr; ++ ktxnmgrd_context *ctx; ++ ++ mgr = &get_super_private(super)->tmgr; ++ ++ assert("zam-1014", mgr->daemon == NULL); ++ ++ ctx = kzalloc(sizeof(ktxnmgrd_context), reiser4_ctx_gfp_mask_get()); ++ if (!ctx) ++ return RETERR(-ENOMEM); ++ ++ assert("nikita-2442", ctx != NULL); ++ ++ init_waitqueue_head(&ctx->wait); ++ ++ /*kcond_init(&ctx->startup);*/ ++ spin_lock_init(&ctx->guard); ++ ctx->timeout = REISER4_TXNMGR_TIMEOUT; ++ ctx->rescan = 1; ++ mgr->daemon = ctx; ++ ++ ctx->tsk = kthread_run(ktxnmgrd, super, "ktxnmgrd"); ++ if (IS_ERR(ctx->tsk)) { ++ int ret = PTR_ERR(ctx->tsk); ++ mgr->daemon = NULL; ++ kfree(ctx); ++ return RETERR(ret); ++ } ++ return 0; ++} ++ ++void ktxnmgrd_kick(txn_mgr *mgr) ++{ ++ assert("nikita-3234", mgr != NULL); ++ assert("nikita-3235", mgr->daemon != NULL); ++ wake_up(&mgr->daemon->wait); ++} ++ ++int is_current_ktxnmgrd(void) ++{ ++ return (get_current_super_private()->tmgr.daemon->tsk == current); ++} ++ ++/** ++ * scan_mgr - commit atoms which are to be committed ++ * @super: super block to commit atoms of ++ * ++ * Commits old atoms. ++ */ ++static int scan_mgr(struct super_block *super) ++{ ++ int ret; ++ reiser4_context ctx; ++ ++ init_stack_context(&ctx, super); ++ ret = commit_some_atoms(&get_super_private(super)->tmgr); ++ reiser4_exit_context(&ctx); ++ return ret; ++} ++ ++/** ++ * reiser4_done_ktxnmgrd - stop kernel thread and frees ktxnmgrd context ++ * @mgr: ++ * ++ * This is called on umount. Stops ktxnmgrd and free t ++ */ ++void reiser4_done_ktxnmgrd(struct super_block *super) ++{ ++ txn_mgr *mgr; ++ ++ mgr = &get_super_private(super)->tmgr; ++ assert("zam-1012", mgr->daemon != NULL); ++ ++ kthread_stop(mgr->daemon->tsk); ++ kfree(mgr->daemon); ++ mgr->daemon = NULL; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/ktxnmgrd.h linux-5.10.2/fs/reiser4/ktxnmgrd.h +--- linux-5.10.2.orig/fs/reiser4/ktxnmgrd.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/ktxnmgrd.h 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,52 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Transaction manager daemon. See ktxnmgrd.c for comments. */ ++ ++#ifndef __KTXNMGRD_H__ ++#define __KTXNMGRD_H__ ++ ++#include "txnmgr.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include /* for struct task_struct */ ++ ++/* in this structure all data necessary to start up, shut down and communicate ++ * with ktxnmgrd are kept. */ ++struct ktxnmgrd_context { ++ /* wait queue head on which ktxnmgrd sleeps */ ++ wait_queue_head_t wait; ++ /* spin lock protecting all fields of this structure */ ++ spinlock_t guard; ++ /* timeout of sleeping on ->wait */ ++ signed long timeout; ++ /* kernel thread running ktxnmgrd */ ++ struct task_struct *tsk; ++ /* list of all file systems served by this ktxnmgrd */ ++ struct list_head queue; ++ /* should ktxnmgrd repeat scanning of atoms? */ ++ unsigned int rescan:1; ++}; ++ ++extern int reiser4_init_ktxnmgrd(struct super_block *); ++extern void reiser4_done_ktxnmgrd(struct super_block *); ++ ++extern void ktxnmgrd_kick(txn_mgr * mgr); ++extern int is_current_ktxnmgrd(void); ++ ++/* __KTXNMGRD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/lock.c linux-5.10.2/fs/reiser4/lock.c +--- linux-5.10.2.orig/fs/reiser4/lock.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/lock.c 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,1237 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Traditional deadlock avoidance is achieved by acquiring all locks in a single ++ order. V4 balances the tree from the bottom up, and searches the tree from ++ the top down, and that is really the way we want it, so tradition won't work ++ for us. ++ ++ Instead we have two lock orderings, a high priority lock ordering, and a low ++ priority lock ordering. Each node in the tree has a lock in its znode. ++ ++ Suppose we have a set of processes which lock (R/W) tree nodes. Each process ++ has a set (maybe empty) of already locked nodes ("process locked set"). Each ++ process may have a pending lock request to a node locked by another process. ++ Note: we lock and unlock, but do not transfer locks: it is possible ++ transferring locks instead would save some bus locking.... ++ ++ Deadlock occurs when we have a loop constructed from process locked sets and ++ lock request vectors. ++ ++ NOTE: The reiser4 "tree" is a tree on disk, but its cached representation in ++ memory is extended with "znodes" with which we connect nodes with their left ++ and right neighbors using sibling pointers stored in the znodes. When we ++ perform balancing operations we often go from left to right and from right to ++ left. ++ ++ +-P1-+ +-P3-+ ++ |+--+| V1 |+--+| ++ ||N1|| -------> ||N3|| ++ |+--+| |+--+| ++ +----+ +----+ ++ ^ | ++ |V2 |V3 ++ | v ++ +---------P2---------+ ++ |+--+ +--+| ++ ||N2| -------- |N4|| ++ |+--+ +--+| ++ +--------------------+ ++ ++ We solve this by ensuring that only low priority processes lock in top to ++ bottom order and from right to left, and high priority processes lock from ++ bottom to top and left to right. ++ ++ ZAM-FIXME-HANS: order not just node locks in this way, order atom locks, and ++ kill those damn busy loops. ++ ANSWER(ZAM): atom locks (which are introduced by ASTAGE_CAPTURE_WAIT atom ++ stage) cannot be ordered that way. There are no rules what nodes can belong ++ to the atom and what nodes cannot. We cannot define what is right or left ++ direction, what is top or bottom. We can take immediate parent or side ++ neighbor of one node, but nobody guarantees that, say, left neighbor node is ++ not a far right neighbor for other nodes from the same atom. It breaks ++ deadlock avoidance rules and hi-low priority locking cannot be applied for ++ atom locks. ++ ++ How does it help to avoid deadlocks ? ++ ++ Suppose we have a deadlock with n processes. Processes from one priority ++ class never deadlock because they take locks in one consistent ++ order. ++ ++ So, any possible deadlock loop must have low priority as well as high ++ priority processes. There are no other lock priority levels except low and ++ high. We know that any deadlock loop contains at least one node locked by a ++ low priority process and requested by a high priority process. If this ++ situation is caught and resolved it is sufficient to avoid deadlocks. ++ ++ V4 DEADLOCK PREVENTION ALGORITHM IMPLEMENTATION. ++ ++ The deadlock prevention algorithm is based on comparing ++ priorities of node owners (processes which keep znode locked) and ++ requesters (processes which want to acquire a lock on znode). We ++ implement a scheme where low-priority owners yield locks to ++ high-priority requesters. We created a signal passing system that ++ is used to ask low-priority processes to yield one or more locked ++ znodes. ++ ++ The condition when a znode needs to change its owners is described by the ++ following formula: ++ ++ ############################################# ++ # # ++ # (number of high-priority requesters) > 0 # ++ # AND # ++ # (numbers of high-priority owners) == 0 # ++ # # ++ ############################################# ++ ++ Note that a low-priority process delays node releasing if another ++ high-priority process owns this node. So, slightly more strictly speaking, ++ to have a deadlock capable cycle you must have a loop in which a high ++ priority process is waiting on a low priority process to yield a node, which ++ is slightly different from saying a high priority process is waiting on a ++ node owned by a low priority process. ++ ++ It is enough to avoid deadlocks if we prevent any low-priority process from ++ falling asleep if its locked set contains a node which satisfies the ++ deadlock condition. ++ ++ That condition is implicitly or explicitly checked in all places where new ++ high-priority requests may be added or removed from node request queue or ++ high-priority process takes or releases a lock on node. The main ++ goal of these checks is to never lose the moment when node becomes "has ++ wrong owners" and send "must-yield-this-lock" signals to its low-pri owners ++ at that time. ++ ++ The information about received signals is stored in the per-process ++ structure (lock stack) and analyzed before a low-priority process goes to ++ sleep but after a "fast" attempt to lock a node fails. Any signal wakes ++ sleeping process up and forces him to re-check lock status and received ++ signal info. If "must-yield-this-lock" signals were received the locking ++ primitive (longterm_lock_znode()) fails with -E_DEADLOCK error code. ++ ++ V4 LOCKING DRAWBACKS ++ ++ If we have already balanced on one level, and we are propagating our changes ++ upward to a higher level, it could be very messy to surrender all locks on ++ the lower level because we put so much computational work into it, and ++ reverting them to their state before they were locked might be very complex. ++ We also don't want to acquire all locks before performing balancing because ++ that would either be almost as much work as the balancing, or it would be ++ too conservative and lock too much. We want balancing to be done only at ++ high priority. Yet, we might want to go to the left one node and use some ++ of its empty space... So we make one attempt at getting the node to the left ++ using try_lock, and if it fails we do without it, because we didn't really ++ need it, it was only a nice to have. ++ ++ LOCK STRUCTURES DESCRIPTION ++ ++ The following data structures are used in the reiser4 locking ++ implementation: ++ ++ All fields related to long-term locking are stored in znode->lock. ++ ++ The lock stack is a per thread object. It owns all znodes locked by the ++ thread. One znode may be locked by several threads in case of read lock or ++ one znode may be write locked by one thread several times. The special link ++ objects (lock handles) support n<->m relation between znodes and lock ++ owners. ++ ++ ++ ++ +---------+ +---------+ ++ | LS1 | | LS2 | ++ +---------+ +---------+ ++ ^ ^ ++ |---------------+ +----------+ ++ v v v v ++ +---------+ +---------+ +---------+ +---------+ ++ | LH1 | | LH2 | | LH3 | | LH4 | ++ +---------+ +---------+ +---------+ +---------+ ++ ^ ^ ^ ^ ++ | +------------+ | ++ v v v ++ +---------+ +---------+ +---------+ ++ | Z1 | | Z2 | | Z3 | ++ +---------+ +---------+ +---------+ ++ ++ Thread 1 locked znodes Z1 and Z2, thread 2 locked znodes Z2 and Z3. The ++ picture above shows that lock stack LS1 has a list of 2 lock handles LH1 and ++ LH2, lock stack LS2 has a list with lock handles LH3 and LH4 on it. Znode ++ Z1 is locked by only one thread, znode has only one lock handle LH1 on its ++ list, similar situation is for Z3 which is locked by the thread 2 only. Z2 ++ is locked (for read) twice by different threads and two lock handles are on ++ its list. Each lock handle represents a single relation of a locking of a ++ znode by a thread. Locking of a znode is an establishing of a locking ++ relation between the lock stack and the znode by adding of a new lock handle ++ to a list of lock handles, the lock stack. The lock stack links all lock ++ handles for all znodes locked by the lock stack. The znode list groups all ++ lock handles for all locks stacks which locked the znode. ++ ++ Yet another relation may exist between znode and lock owners. If lock ++ procedure cannot immediately take lock on an object it adds the lock owner ++ on special `requestors' list belongs to znode. That list represents a ++ queue of pending lock requests. Because one lock owner may request only ++ only one lock object at a time, it is a 1->n relation between lock objects ++ and a lock owner implemented as it is described above. Full information ++ (priority, pointers to lock and link objects) about each lock request is ++ stored in lock owner structure in `request' field. ++ ++ SHORT_TERM LOCKING ++ ++ This is a list of primitive operations over lock stacks / lock handles / ++ znodes and locking descriptions for them. ++ ++ 1. locking / unlocking which is done by two list insertion/deletion, one ++ to/from znode's list of lock handles, another one is to/from lock stack's ++ list of lock handles. The first insertion is protected by ++ znode->lock.guard spinlock. The list owned by the lock stack can be ++ modified only by thread who owns the lock stack and nobody else can ++ modify/read it. There is nothing to be protected by a spinlock or ++ something else. ++ ++ 2. adding/removing a lock request to/from znode requesters list. The rule is ++ that znode->lock.guard spinlock should be taken for this. ++ ++ 3. we can traverse list of lock handles and use references to lock stacks who ++ locked given znode if znode->lock.guard spinlock is taken. ++ ++ 4. If a lock stack is associated with a znode as a lock requestor or lock ++ owner its existence is guaranteed by znode->lock.guard spinlock. Some its ++ (lock stack's) fields should be protected from being accessed in parallel ++ by two or more threads. Please look at lock_stack structure definition ++ for the info how those fields are protected. */ ++ ++/* Znode lock and capturing intertwining. */ ++/* In current implementation we capture formatted nodes before locking ++ them. Take a look on longterm lock znode, reiser4_try_capture() request ++ precedes locking requests. The longterm_lock_znode function unconditionally ++ captures znode before even checking of locking conditions. ++ ++ Another variant is to capture znode after locking it. It was not tested, but ++ at least one deadlock condition is supposed to be there. One thread has ++ locked a znode (Node-1) and calls reiser4_try_capture() for it. ++ reiser4_try_capture() sleeps because znode's atom has CAPTURE_WAIT state. ++ Second thread is a flushing thread, its current atom is the atom Node-1 ++ belongs to. Second thread wants to lock Node-1 and sleeps because Node-1 ++ is locked by the first thread. The described situation is a deadlock. */ ++ ++#include "debug.h" ++#include "txnmgr.h" ++#include "znode.h" ++#include "jnode.h" ++#include "tree.h" ++#include "plugin/node/node.h" ++#include "super.h" ++ ++#include ++ ++#if REISER4_DEBUG ++static int request_is_deadlock_safe(znode * , znode_lock_mode, ++ znode_lock_request); ++#endif ++ ++/* Returns a lock owner associated with current thread */ ++lock_stack *get_current_lock_stack(void) ++{ ++ return &get_current_context()->stack; ++} ++ ++/* Wakes up all low priority owners informing them about possible deadlock */ ++static void wake_up_all_lopri_owners(znode * node) ++{ ++ lock_handle *handle; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ list_for_each_entry(handle, &node->lock.owners, owners_link) { ++ assert("nikita-1832", handle->node == node); ++ /* count this signal in owner->nr_signaled */ ++ if (!handle->signaled) { ++ handle->signaled = 1; ++ atomic_inc(&handle->owner->nr_signaled); ++ /* Wake up a single process */ ++ reiser4_wake_up(handle->owner); ++ } ++ } ++} ++ ++/* Adds a lock to a lock owner, which means creating a link to the lock and ++ putting the link into the two lists all links are on (the doubly linked list ++ that forms the lock_stack, and the doubly linked list of links attached ++ to a lock. ++*/ ++static inline void ++link_object(lock_handle * handle, lock_stack * owner, znode * node) ++{ ++ assert("jmacd-810", handle->owner == NULL); ++ assert_spin_locked(&(node->lock.guard)); ++ ++ handle->owner = owner; ++ handle->node = node; ++ ++ assert("reiser4-4", ++ ergo(list_empty_careful(&owner->locks), owner->nr_locks == 0)); ++ ++ /* add lock handle to the end of lock_stack's list of locks */ ++ list_add_tail(&handle->locks_link, &owner->locks); ++ ON_DEBUG(owner->nr_locks++); ++ reiser4_ctx_gfp_mask_set(); ++ ++ /* add lock handle to the head of znode's list of owners */ ++ list_add(&handle->owners_link, &node->lock.owners); ++ handle->signaled = 0; ++} ++ ++/* Breaks a relation between a lock and its owner */ ++static inline void unlink_object(lock_handle * handle) ++{ ++ assert("zam-354", handle->owner != NULL); ++ assert("nikita-1608", handle->node != NULL); ++ assert_spin_locked(&(handle->node->lock.guard)); ++ assert("nikita-1829", handle->owner == get_current_lock_stack()); ++ assert("reiser4-5", handle->owner->nr_locks > 0); ++ ++ /* remove lock handle from lock_stack's list of locks */ ++ list_del(&handle->locks_link); ++ ON_DEBUG(handle->owner->nr_locks--); ++ reiser4_ctx_gfp_mask_set(); ++ assert("reiser4-6", ++ ergo(list_empty_careful(&handle->owner->locks), ++ handle->owner->nr_locks == 0)); ++ /* remove lock handle from znode's list of owners */ ++ list_del(&handle->owners_link); ++ /* indicates that lock handle is free now */ ++ handle->node = NULL; ++#if REISER4_DEBUG ++ INIT_LIST_HEAD(&handle->locks_link); ++ INIT_LIST_HEAD(&handle->owners_link); ++ handle->owner = NULL; ++#endif ++} ++ ++/* Actually locks an object knowing that we are able to do this */ ++static void lock_object(lock_stack * owner) ++{ ++ struct lock_request *request; ++ znode *node; ++ ++ request = &owner->request; ++ node = request->node; ++ assert_spin_locked(&(node->lock.guard)); ++ if (request->mode == ZNODE_READ_LOCK) { ++ node->lock.nr_readers++; ++ } else { ++ /* check that we don't switched from read to write lock */ ++ assert("nikita-1840", node->lock.nr_readers <= 0); ++ /* We allow recursive locking; a node can be locked several ++ times for write by same process */ ++ node->lock.nr_readers--; ++ } ++ ++ link_object(request->handle, owner, node); ++ ++ if (owner->curpri) ++ node->lock.nr_hipri_owners++; ++} ++ ++/* Check for recursive write locking */ ++static int recursive(lock_stack * owner) ++{ ++ int ret; ++ znode *node; ++ lock_handle *lh; ++ ++ node = owner->request.node; ++ ++ /* Owners list is not empty for a locked node */ ++ assert("zam-314", !list_empty_careful(&node->lock.owners)); ++ assert("nikita-1841", owner == get_current_lock_stack()); ++ assert_spin_locked(&(node->lock.guard)); ++ ++ lh = list_entry(node->lock.owners.next, lock_handle, owners_link); ++ ret = (lh->owner == owner); ++ ++ /* Recursive read locking should be done usual way */ ++ assert("zam-315", !ret || owner->request.mode == ZNODE_WRITE_LOCK); ++ /* mixing of read/write locks is not allowed */ ++ assert("zam-341", !ret || znode_is_wlocked(node)); ++ ++ return ret; ++} ++ ++#if REISER4_DEBUG ++/* Returns true if the lock is held by the calling thread. */ ++int znode_is_any_locked(const znode * node) ++{ ++ lock_handle *handle; ++ lock_stack *stack; ++ int ret; ++ ++ if (!znode_is_locked(node)) ++ return 0; ++ ++ stack = get_current_lock_stack(); ++ ++ spin_lock_stack(stack); ++ ++ ret = 0; ++ ++ list_for_each_entry(handle, &stack->locks, locks_link) { ++ if (handle->node == node) { ++ ret = 1; ++ break; ++ } ++ } ++ ++ spin_unlock_stack(stack); ++ ++ return ret; ++} ++ ++#endif ++ ++/* Returns true if a write lock is held by the calling thread. */ ++int znode_is_write_locked(const znode * node) ++{ ++ lock_stack *stack; ++ lock_handle *handle; ++ ++ assert("jmacd-8765", node != NULL); ++ ++ if (!znode_is_wlocked(node)) ++ return 0; ++ ++ stack = get_current_lock_stack(); ++ ++ /* ++ * When znode is write locked, all owner handles point to the same lock ++ * stack. Get pointer to lock stack from the first lock handle from ++ * znode's owner list ++ */ ++ handle = list_entry(node->lock.owners.next, lock_handle, owners_link); ++ ++ return (handle->owner == stack); ++} ++ ++/* This "deadlock" condition is the essential part of reiser4 locking ++ implementation. This condition is checked explicitly by calling ++ check_deadlock_condition() or implicitly in all places where znode lock ++ state (set of owners and request queue) is changed. Locking code is ++ designed to use this condition to trigger procedure of passing object from ++ low priority owner(s) to high priority one(s). ++ ++ The procedure results in passing an event (setting lock_handle->signaled ++ flag) and counting this event in nr_signaled field of owner's lock stack ++ object and wakeup owner's process. ++*/ ++static inline int check_deadlock_condition(znode * node) ++{ ++ assert_spin_locked(&(node->lock.guard)); ++ return node->lock.nr_hipri_requests > 0 ++ && node->lock.nr_hipri_owners == 0; ++} ++ ++static int check_livelock_condition(znode * node, znode_lock_mode mode) ++{ ++ zlock * lock = &node->lock; ++ ++ return mode == ZNODE_READ_LOCK && ++ lock->nr_readers >= 0 && lock->nr_hipri_write_requests > 0; ++} ++ ++/* checks lock/request compatibility */ ++static int can_lock_object(lock_stack * owner) ++{ ++ znode *node = owner->request.node; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ ++ /* See if the node is disconnected. */ ++ if (unlikely(ZF_ISSET(node, JNODE_IS_DYING))) ++ return RETERR(-EINVAL); ++ ++ /* Do not ever try to take a lock if we are going in low priority ++ direction and a node have a high priority request without high ++ priority owners. */ ++ if (unlikely(!owner->curpri && check_deadlock_condition(node))) ++ return RETERR(-E_REPEAT); ++ if (unlikely(owner->curpri && ++ check_livelock_condition(node, owner->request.mode))) ++ return RETERR(-E_REPEAT); ++ if (unlikely(!is_lock_compatible(node, owner->request.mode))) ++ return RETERR(-E_REPEAT); ++ return 0; ++} ++ ++/* Setting of a high priority to the process. It clears "signaled" flags ++ because znode locked by high-priority process can't satisfy our "deadlock ++ condition". */ ++static void set_high_priority(lock_stack * owner) ++{ ++ assert("nikita-1846", owner == get_current_lock_stack()); ++ /* Do nothing if current priority is already high */ ++ if (!owner->curpri) { ++ /* We don't need locking for owner->locks list, because, this ++ * function is only called with the lock stack of the current ++ * thread, and no other thread can play with owner->locks list ++ * and/or change ->node pointers of lock handles in this list. ++ * ++ * (Interrupts also are not involved.) ++ */ ++ lock_handle *item = list_entry(owner->locks.next, lock_handle, ++ locks_link); ++ while (&owner->locks != &item->locks_link) { ++ znode *node = item->node; ++ ++ spin_lock_zlock(&node->lock); ++ ++ node->lock.nr_hipri_owners++; ++ ++ /* we can safely set signaled to zero, because ++ previous statement (nr_hipri_owners ++) guarantees ++ that signaled will be never set again. */ ++ item->signaled = 0; ++ spin_unlock_zlock(&node->lock); ++ ++ item = list_entry(item->locks_link.next, lock_handle, ++ locks_link); ++ } ++ owner->curpri = 1; ++ atomic_set(&owner->nr_signaled, 0); ++ } ++} ++ ++/* Sets a low priority to the process. */ ++static void set_low_priority(lock_stack * owner) ++{ ++ assert("nikita-3075", owner == get_current_lock_stack()); ++ /* Do nothing if current priority is already low */ ++ if (owner->curpri) { ++ /* scan all locks (lock handles) held by @owner, which is ++ actually current thread, and check whether we are reaching ++ deadlock possibility anywhere. ++ */ ++ lock_handle *handle = list_entry(owner->locks.next, lock_handle, ++ locks_link); ++ while (&owner->locks != &handle->locks_link) { ++ znode *node = handle->node; ++ spin_lock_zlock(&node->lock); ++ /* this thread just was hipri owner of @node, so ++ nr_hipri_owners has to be greater than zero. */ ++ assert("nikita-1835", node->lock.nr_hipri_owners > 0); ++ node->lock.nr_hipri_owners--; ++ /* If we have deadlock condition, adjust a nr_signaled ++ field. It is enough to set "signaled" flag only for ++ current process, other low-pri owners will be ++ signaled and waken up after current process unlocks ++ this object and any high-priority requestor takes ++ control. */ ++ if (check_deadlock_condition(node) ++ && !handle->signaled) { ++ handle->signaled = 1; ++ atomic_inc(&owner->nr_signaled); ++ } ++ spin_unlock_zlock(&node->lock); ++ handle = list_entry(handle->locks_link.next, ++ lock_handle, locks_link); ++ } ++ owner->curpri = 0; ++ } ++} ++ ++static void remove_lock_request(lock_stack * requestor) ++{ ++ zlock * lock = &requestor->request.node->lock; ++ ++ if (requestor->curpri) { ++ assert("nikita-1838", lock->nr_hipri_requests > 0); ++ lock->nr_hipri_requests--; ++ if (requestor->request.mode == ZNODE_WRITE_LOCK) ++ lock->nr_hipri_write_requests--; ++ } ++ list_del(&requestor->requestors_link); ++} ++ ++static void invalidate_all_lock_requests(znode * node) ++{ ++ lock_stack *requestor, *tmp; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ ++ list_for_each_entry_safe(requestor, tmp, &node->lock.requestors, ++ requestors_link) { ++ remove_lock_request(requestor); ++ requestor->request.ret_code = -EINVAL; ++ reiser4_wake_up(requestor); ++ requestor->request.mode = ZNODE_NO_LOCK; ++ } ++} ++ ++static void dispatch_lock_requests(znode * node) ++{ ++ lock_stack *requestor, *tmp; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ ++ list_for_each_entry_safe(requestor, tmp, &node->lock.requestors, ++ requestors_link) { ++ if (znode_is_write_locked(node)) ++ break; ++ if (!can_lock_object(requestor)) { ++ lock_object(requestor); ++ remove_lock_request(requestor); ++ requestor->request.ret_code = 0; ++ reiser4_wake_up(requestor); ++ requestor->request.mode = ZNODE_NO_LOCK; ++ } ++ } ++} ++ ++/* release long-term lock, acquired by longterm_lock_znode() */ ++void longterm_unlock_znode(lock_handle * handle) ++{ ++ znode *node = handle->node; ++ lock_stack *oldowner = handle->owner; ++ int hipri; ++ int readers; ++ int rdelta; ++ int youdie; ++ ++ /* ++ * this is time-critical and highly optimized code. Modify carefully. ++ */ ++ ++ assert("jmacd-1021", handle != NULL); ++ assert("jmacd-1022", handle->owner != NULL); ++ assert("nikita-1392", LOCK_CNT_GTZ(long_term_locked_znode)); ++ ++ assert("zam-130", oldowner == get_current_lock_stack()); ++ ++ LOCK_CNT_DEC(long_term_locked_znode); ++ ++ /* ++ * to minimize amount of operations performed under lock, pre-compute ++ * all variables used within critical section. This makes code ++ * obscure. ++ */ ++ ++ /* was this lock of hi or lo priority */ ++ hipri = oldowner->curpri ? 1 : 0; ++ /* number of readers */ ++ readers = node->lock.nr_readers; ++ /* +1 if write lock, -1 if read lock */ ++ rdelta = (readers > 0) ? -1 : +1; ++ /* true if node is to die and write lock is released */ ++ youdie = ZF_ISSET(node, JNODE_HEARD_BANSHEE) && (readers < 0); ++ ++ spin_lock_zlock(&node->lock); ++ ++ assert("zam-101", znode_is_locked(node)); ++ ++ /* Adjust a number of high priority owners of this lock */ ++ assert("nikita-1836", node->lock.nr_hipri_owners >= hipri); ++ node->lock.nr_hipri_owners -= hipri; ++ ++ /* Handle znode deallocation on last write-lock release. */ ++ if (znode_is_wlocked_once(node)) { ++ if (youdie) { ++ forget_znode(handle); ++ assert("nikita-2191", znode_invariant(node)); ++ zput(node); ++ return; ++ } ++ } ++ ++ if (handle->signaled) ++ atomic_dec(&oldowner->nr_signaled); ++ ++ /* Unlocking means owner<->object link deletion */ ++ unlink_object(handle); ++ ++ /* This is enough to be sure whether an object is completely ++ unlocked. */ ++ node->lock.nr_readers += rdelta; ++ ++ /* If the node is locked it must have an owners list. Likewise, if ++ the node is unlocked it must have an empty owners list. */ ++ assert("zam-319", equi(znode_is_locked(node), ++ !list_empty_careful(&node->lock.owners))); ++ ++#if REISER4_DEBUG ++ if (!znode_is_locked(node)) ++ ++node->times_locked; ++#endif ++ ++ /* If there are pending lock requests we wake up a requestor */ ++ if (!znode_is_wlocked(node)) ++ dispatch_lock_requests(node); ++ if (check_deadlock_condition(node)) ++ wake_up_all_lopri_owners(node); ++ spin_unlock_zlock(&node->lock); ++ ++ /* minus one reference from handle->node */ ++ assert("nikita-2190", znode_invariant(node)); ++ ON_DEBUG(check_lock_data()); ++ ON_DEBUG(check_lock_node_data(node)); ++ zput(node); ++} ++ ++/* final portion of longterm-lock */ ++static int ++lock_tail(lock_stack * owner, int ok, znode_lock_mode mode) ++{ ++ znode *node = owner->request.node; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ ++ /* If we broke with (ok == 0) it means we can_lock, now do it. */ ++ if (ok == 0) { ++ lock_object(owner); ++ owner->request.mode = 0; ++ /* count a reference from lockhandle->node ++ ++ znode was already referenced at the entry to this function, ++ hence taking spin-lock here is not necessary (see comment ++ in the zref()). ++ */ ++ zref(node); ++ ++ LOCK_CNT_INC(long_term_locked_znode); ++ } ++ spin_unlock_zlock(&node->lock); ++ ON_DEBUG(check_lock_data()); ++ ON_DEBUG(check_lock_node_data(node)); ++ return ok; ++} ++ ++/* ++ * version of longterm_znode_lock() optimized for the most common case: read ++ * lock without any special flags. This is the kind of lock that any tree ++ * traversal takes on the root node of the tree, which is very frequent. ++ */ ++static int longterm_lock_tryfast(lock_stack * owner) ++{ ++ int result; ++ znode *node; ++ zlock *lock; ++ ++ node = owner->request.node; ++ lock = &node->lock; ++ ++ assert("nikita-3340", reiser4_schedulable()); ++ assert("nikita-3341", request_is_deadlock_safe(node, ++ ZNODE_READ_LOCK, ++ ZNODE_LOCK_LOPRI)); ++ spin_lock_zlock(lock); ++ result = can_lock_object(owner); ++ spin_unlock_zlock(lock); ++ ++ if (likely(result != -EINVAL)) { ++ spin_lock_znode(node); ++ result = reiser4_try_capture(ZJNODE(node), ZNODE_READ_LOCK, 0); ++ spin_unlock_znode(node); ++ spin_lock_zlock(lock); ++ if (unlikely(result != 0)) { ++ owner->request.mode = 0; ++ } else { ++ result = can_lock_object(owner); ++ if (unlikely(result == -E_REPEAT)) { ++ /* fall back to longterm_lock_znode() */ ++ spin_unlock_zlock(lock); ++ return 1; ++ } ++ } ++ return lock_tail(owner, result, ZNODE_READ_LOCK); ++ } else ++ return 1; ++} ++ ++/* locks given lock object */ ++int longterm_lock_znode( ++ /* local link object (allocated by lock owner ++ * thread, usually on its own stack) */ ++ lock_handle * handle, ++ /* znode we want to lock. */ ++ znode * node, ++ /* {ZNODE_READ_LOCK, ZNODE_WRITE_LOCK}; */ ++ znode_lock_mode mode, ++ /* {0, -EINVAL, -E_DEADLOCK}, see return codes ++ description. */ ++ znode_lock_request request) { ++ int ret; ++ int hipri = (request & ZNODE_LOCK_HIPRI) != 0; ++ int non_blocking = 0; ++ int has_atom; ++ txn_capture cap_flags; ++ zlock *lock; ++ txn_handle *txnh; ++ tree_level level; ++ ++ /* Get current process context */ ++ lock_stack *owner = get_current_lock_stack(); ++ ++ /* Check that the lock handle is initialized and isn't already being ++ * used. */ ++ assert("jmacd-808", handle->owner == NULL); ++ assert("nikita-3026", reiser4_schedulable()); ++ assert("nikita-3219", request_is_deadlock_safe(node, mode, request)); ++ assert("zam-1056", atomic_read(&ZJNODE(node)->x_count) > 0); ++ /* long term locks are not allowed in the VM contexts (->writepage(), ++ * prune_{d,i}cache()). ++ * ++ * FIXME this doesn't work due to unused-dentry-with-unlinked-inode ++ * bug caused by d_splice_alias() only working for directories. ++ */ ++ assert("nikita-3547", 1 || ((current->flags & PF_MEMALLOC) == 0)); ++ assert("zam-1055", mode != ZNODE_NO_LOCK); ++ ++ cap_flags = 0; ++ if (request & ZNODE_LOCK_NONBLOCK) { ++ cap_flags |= TXN_CAPTURE_NONBLOCKING; ++ non_blocking = 1; ++ } ++ ++ if (request & ZNODE_LOCK_DONT_FUSE) ++ cap_flags |= TXN_CAPTURE_DONT_FUSE; ++ ++ /* If we are changing our process priority we must adjust a number ++ of high priority owners for each znode that we already lock */ ++ if (hipri) { ++ set_high_priority(owner); ++ } else { ++ set_low_priority(owner); ++ } ++ ++ level = znode_get_level(node); ++ ++ /* Fill request structure with our values. */ ++ owner->request.mode = mode; ++ owner->request.handle = handle; ++ owner->request.node = node; ++ ++ txnh = get_current_context()->trans; ++ lock = &node->lock; ++ ++ if (mode == ZNODE_READ_LOCK && request == 0) { ++ ret = longterm_lock_tryfast(owner); ++ if (ret <= 0) ++ return ret; ++ } ++ ++ has_atom = (txnh->atom != NULL); ++ ++ /* Synchronize on node's zlock guard lock. */ ++ spin_lock_zlock(lock); ++ ++ if (znode_is_locked(node) && ++ mode == ZNODE_WRITE_LOCK && recursive(owner)) ++ return lock_tail(owner, 0, mode); ++ ++ for (;;) { ++ /* Check the lock's availability: if it is unavaiable we get ++ E_REPEAT, 0 indicates "can_lock", otherwise the node is ++ invalid. */ ++ ret = can_lock_object(owner); ++ ++ if (unlikely(ret == -EINVAL)) { ++ /* @node is dying. Leave it alone. */ ++ break; ++ } ++ ++ if (unlikely(ret == -E_REPEAT && non_blocking)) { ++ /* either locking of @node by the current thread will ++ * lead to the deadlock, or lock modes are ++ * incompatible. */ ++ break; ++ } ++ ++ assert("nikita-1844", (ret == 0) ++ || ((ret == -E_REPEAT) && !non_blocking)); ++ /* If we can get the lock... Try to capture first before ++ taking the lock. */ ++ ++ /* first handle commonest case where node and txnh are already ++ * in the same atom. */ ++ /* safe to do without taking locks, because: ++ * ++ * 1. read of aligned word is atomic with respect to writes to ++ * this word ++ * ++ * 2. false negatives are handled in reiser4_try_capture(). ++ * ++ * 3. false positives are impossible. ++ * ++ * PROOF: left as an exercise to the curious reader. ++ * ++ * Just kidding. Here is one: ++ * ++ * At the time T0 txnh->atom is stored in txnh_atom. ++ * ++ * At the time T1 node->atom is stored in node_atom. ++ * ++ * At the time T2 we observe that ++ * ++ * txnh_atom != NULL && node_atom == txnh_atom. ++ * ++ * Imagine that at this moment we acquire node and txnh spin ++ * lock in this order. Suppose that under spin lock we have ++ * ++ * node->atom != txnh->atom, (S1) ++ * ++ * at the time T3. ++ * ++ * txnh->atom != NULL still, because txnh is open by the ++ * current thread. ++ * ++ * Suppose node->atom == NULL, that is, node was un-captured ++ * between T1, and T3. But un-capturing of formatted node is ++ * always preceded by the call to reiser4_invalidate_lock(), ++ * which marks znode as JNODE_IS_DYING under zlock spin ++ * lock. Contradiction, because can_lock_object() above checks ++ * for JNODE_IS_DYING. Hence, node->atom != NULL at T3. ++ * ++ * Suppose that node->atom != node_atom, that is, atom, node ++ * belongs to was fused into another atom: node_atom was fused ++ * into node->atom. Atom of txnh was equal to node_atom at T2, ++ * which means that under spin lock, txnh->atom == node->atom, ++ * because txnh->atom can only follow fusion ++ * chain. Contradicts S1. ++ * ++ * The same for hypothesis txnh->atom != txnh_atom. Hence, ++ * node->atom == node_atom == txnh_atom == txnh->atom. Again ++ * contradicts S1. Hence S1 is false. QED. ++ * ++ */ ++ ++ if (likely(has_atom && ZJNODE(node)->atom == txnh->atom)) { ++ ; ++ } else { ++ /* ++ * unlock zlock spin lock here. It is possible for ++ * longterm_unlock_znode() to sneak in here, but there ++ * is no harm: reiser4_invalidate_lock() will mark znode ++ * as JNODE_IS_DYING and this will be noted by ++ * can_lock_object() below. ++ */ ++ spin_unlock_zlock(lock); ++ spin_lock_znode(node); ++ ret = reiser4_try_capture(ZJNODE(node), mode, ++ cap_flags); ++ spin_unlock_znode(node); ++ spin_lock_zlock(lock); ++ if (unlikely(ret != 0)) { ++ /* In the failure case, the txnmgr releases ++ the znode's lock (or in some cases, it was ++ released a while ago). There's no need to ++ reacquire it so we should return here, ++ avoid releasing the lock. */ ++ owner->request.mode = 0; ++ break; ++ } ++ ++ /* Check the lock's availability again -- this is ++ because under some circumstances the capture code ++ has to release and reacquire the znode spinlock. */ ++ ret = can_lock_object(owner); ++ } ++ ++ /* This time, a return of (ret == 0) means we can lock, so we ++ should break out of the loop. */ ++ if (likely(ret != -E_REPEAT || non_blocking)) ++ break; ++ ++ /* Lock is unavailable, we have to wait. */ ++ ret = reiser4_prepare_to_sleep(owner); ++ if (unlikely(ret != 0)) ++ break; ++ ++ assert_spin_locked(&(node->lock.guard)); ++ if (hipri) { ++ /* If we are going in high priority direction then ++ increase high priority requests counter for the ++ node */ ++ lock->nr_hipri_requests++; ++ if (mode == ZNODE_WRITE_LOCK) ++ lock->nr_hipri_write_requests++; ++ /* If there are no high priority owners for a node, ++ then immediately wake up low priority owners, so ++ they can detect possible deadlock */ ++ if (lock->nr_hipri_owners == 0) ++ wake_up_all_lopri_owners(node); ++ } ++ list_add_tail(&owner->requestors_link, &lock->requestors); ++ ++ /* Ok, here we have prepared a lock request, so unlock ++ a znode ... */ ++ spin_unlock_zlock(lock); ++ /* ... and sleep */ ++ reiser4_go_to_sleep(owner); ++ if (owner->request.mode == ZNODE_NO_LOCK) ++ goto request_is_done; ++ spin_lock_zlock(lock); ++ if (owner->request.mode == ZNODE_NO_LOCK) { ++ spin_unlock_zlock(lock); ++request_is_done: ++ if (owner->request.ret_code == 0) { ++ LOCK_CNT_INC(long_term_locked_znode); ++ zref(node); ++ } ++ return owner->request.ret_code; ++ } ++ remove_lock_request(owner); ++ } ++ ++ return lock_tail(owner, ret, mode); ++} ++ ++/* lock object invalidation means changing of lock object state to `INVALID' ++ and waiting for all other processes to cancel theirs lock requests. */ ++void reiser4_invalidate_lock(lock_handle * handle /* path to lock ++ * owner and lock ++ * object is being ++ * invalidated. */ ) ++{ ++ znode *node = handle->node; ++ lock_stack *owner = handle->owner; ++ ++ assert("zam-325", owner == get_current_lock_stack()); ++ assert("zam-103", znode_is_write_locked(node)); ++ assert("nikita-1393", !ZF_ISSET(node, JNODE_LEFT_CONNECTED)); ++ assert("nikita-1793", !ZF_ISSET(node, JNODE_RIGHT_CONNECTED)); ++ assert("nikita-1394", ZF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ assert("nikita-3097", znode_is_wlocked_once(node)); ++ assert_spin_locked(&(node->lock.guard)); ++ ++ if (handle->signaled) ++ atomic_dec(&owner->nr_signaled); ++ ++ ZF_SET(node, JNODE_IS_DYING); ++ unlink_object(handle); ++ node->lock.nr_readers = 0; ++ ++ invalidate_all_lock_requests(node); ++ spin_unlock_zlock(&node->lock); ++} ++ ++/* Initializes lock_stack. */ ++void init_lock_stack(lock_stack * owner /* pointer to ++ * allocated ++ * structure. */ ) ++{ ++ INIT_LIST_HEAD(&owner->locks); ++ INIT_LIST_HEAD(&owner->requestors_link); ++ spin_lock_init(&owner->sguard); ++ owner->curpri = 1; ++ init_waitqueue_head(&owner->wait); ++} ++ ++/* Initializes lock object. */ ++void reiser4_init_lock(zlock * lock /* pointer on allocated ++ * uninitialized lock object ++ * structure. */ ) ++{ ++ memset(lock, 0, sizeof(zlock)); ++ spin_lock_init(&lock->guard); ++ INIT_LIST_HEAD(&lock->requestors); ++ INIT_LIST_HEAD(&lock->owners); ++} ++ ++/* Transfer a lock handle (presumably so that variables can be moved between ++ stack and heap locations). */ ++static void ++move_lh_internal(lock_handle * new, lock_handle * old, int unlink_old) ++{ ++ znode *node = old->node; ++ lock_stack *owner = old->owner; ++ int signaled; ++ ++ /* locks_list, modified by link_object() is not protected by ++ anything. This is valid because only current thread ever modifies ++ locks_list of its lock_stack. ++ */ ++ assert("nikita-1827", owner == get_current_lock_stack()); ++ assert("nikita-1831", new->owner == NULL); ++ ++ spin_lock_zlock(&node->lock); ++ ++ signaled = old->signaled; ++ if (unlink_old) { ++ unlink_object(old); ++ } else { ++ if (node->lock.nr_readers > 0) { ++ node->lock.nr_readers += 1; ++ } else { ++ node->lock.nr_readers -= 1; ++ } ++ if (signaled) ++ atomic_inc(&owner->nr_signaled); ++ if (owner->curpri) ++ node->lock.nr_hipri_owners += 1; ++ LOCK_CNT_INC(long_term_locked_znode); ++ ++ zref(node); ++ } ++ link_object(new, owner, node); ++ new->signaled = signaled; ++ ++ spin_unlock_zlock(&node->lock); ++} ++ ++void move_lh(lock_handle * new, lock_handle * old) ++{ ++ move_lh_internal(new, old, /*unlink_old */ 1); ++} ++ ++void copy_lh(lock_handle * new, lock_handle * old) ++{ ++ move_lh_internal(new, old, /*unlink_old */ 0); ++} ++ ++/* after getting -E_DEADLOCK we unlock znodes until this function returns false ++ */ ++int reiser4_check_deadlock(void) ++{ ++ lock_stack *owner = get_current_lock_stack(); ++ return atomic_read(&owner->nr_signaled) != 0; ++} ++ ++/* Before going to sleep we re-check "release lock" requests which might come ++ from threads with hi-pri lock priorities. */ ++int reiser4_prepare_to_sleep(lock_stack * owner) ++{ ++ assert("nikita-1847", owner == get_current_lock_stack()); ++ ++ /* We return -E_DEADLOCK if one or more "give me the lock" messages are ++ * counted in nr_signaled */ ++ if (unlikely(atomic_read(&owner->nr_signaled) != 0)) { ++ assert("zam-959", !owner->curpri); ++ return RETERR(-E_DEADLOCK); ++ } ++ return 0; ++} ++ ++/* Wakes up a single thread */ ++void __reiser4_wake_up(lock_stack * owner) ++{ ++ atomic_set(&owner->wakeup, 1); ++ wake_up(&owner->wait); ++} ++ ++/* Puts a thread to sleep */ ++void reiser4_go_to_sleep(lock_stack * owner) ++{ ++ /* Well, we might sleep here, so holding of any spinlocks is no-no */ ++ assert("nikita-3027", reiser4_schedulable()); ++ ++ wait_event(owner->wait, atomic_read(&owner->wakeup)); ++ atomic_set(&owner->wakeup, 0); ++} ++ ++int lock_stack_isclean(lock_stack * owner) ++{ ++ if (list_empty_careful(&owner->locks)) { ++ assert("zam-353", atomic_read(&owner->nr_signaled) == 0); ++ return 1; ++ } ++ ++ return 0; ++} ++ ++#if REISER4_DEBUG ++ ++/* ++ * debugging functions ++ */ ++ ++static void list_check(struct list_head *head) ++{ ++ struct list_head *pos; ++ ++ list_for_each(pos, head) ++ assert("", (pos->prev != NULL && pos->next != NULL && ++ pos->prev->next == pos && pos->next->prev == pos)); ++} ++ ++/* check consistency of locking data-structures hanging of the @stack */ ++static void check_lock_stack(lock_stack * stack) ++{ ++ spin_lock_stack(stack); ++ /* check that stack->locks is not corrupted */ ++ list_check(&stack->locks); ++ spin_unlock_stack(stack); ++} ++ ++/* check consistency of locking data structures */ ++void check_lock_data(void) ++{ ++ check_lock_stack(&get_current_context()->stack); ++} ++ ++/* check consistency of locking data structures for @node */ ++void check_lock_node_data(znode * node) ++{ ++ spin_lock_zlock(&node->lock); ++ list_check(&node->lock.owners); ++ list_check(&node->lock.requestors); ++ spin_unlock_zlock(&node->lock); ++} ++ ++/* check that given lock request is dead lock safe. This check is, of course, ++ * not exhaustive. */ ++static int ++request_is_deadlock_safe(znode * node, znode_lock_mode mode, ++ znode_lock_request request) ++{ ++ lock_stack *owner; ++ ++ owner = get_current_lock_stack(); ++ /* ++ * check that hipri lock request is not issued when there are locked ++ * nodes at the higher levels. ++ */ ++ if (request & ZNODE_LOCK_HIPRI && !(request & ZNODE_LOCK_NONBLOCK) && ++ znode_get_level(node) != 0) { ++ lock_handle *item; ++ ++ list_for_each_entry(item, &owner->locks, locks_link) { ++ znode *other; ++ ++ other = item->node; ++ ++ if (znode_get_level(other) == 0) ++ continue; ++ if (znode_get_level(other) > znode_get_level(node)) ++ return 0; ++ } ++ } ++ return 1; ++} ++ ++#endif ++ ++/* return pointer to static storage with name of lock_mode. For ++ debugging */ ++const char *lock_mode_name(znode_lock_mode lock/* lock mode to get name of */) ++{ ++ if (lock == ZNODE_READ_LOCK) ++ return "read"; ++ else if (lock == ZNODE_WRITE_LOCK) ++ return "write"; ++ else { ++ static char buf[30]; ++ ++ sprintf(buf, "unknown: %i", lock); ++ return buf; ++ } ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 79 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/lock.h linux-5.10.2/fs/reiser4/lock.h +--- linux-5.10.2.orig/fs/reiser4/lock.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/lock.h 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,250 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Long term locking data structures. See lock.c for details. */ ++ ++#ifndef __LOCK_H__ ++#define __LOCK_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/node/node.h" ++#include "txnmgr.h" ++#include "readahead.h" ++ ++#include ++#include ++#include /* for PAGE_CACHE_SIZE */ ++#include ++#include ++ ++/* Per-znode lock object */ ++struct zlock { ++ spinlock_t guard; ++ /* The number of readers if positive; the number of recursively taken ++ write locks if negative. Protected by zlock spin lock. */ ++ int nr_readers; ++ /* A number of processes (lock_stacks) that have this object ++ locked with high priority */ ++ unsigned nr_hipri_owners; ++ /* A number of attempts to lock znode in high priority direction */ ++ unsigned nr_hipri_requests; ++ /* A linked list of lock_handle objects that contains pointers ++ for all lock_stacks which have this lock object locked */ ++ unsigned nr_hipri_write_requests; ++ struct list_head owners; ++ /* A linked list of lock_stacks that wait for this lock */ ++ struct list_head requestors; ++}; ++ ++static inline void spin_lock_zlock(zlock *lock) ++{ ++ /* check that zlock is not locked */ ++ assert("", LOCK_CNT_NIL(spin_locked_zlock)); ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", LOCK_CNT_NIL(spin_locked_stack)); ++ ++ spin_lock(&lock->guard); ++ ++ LOCK_CNT_INC(spin_locked_zlock); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void spin_unlock_zlock(zlock *lock) ++{ ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_zlock)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(spin_locked_zlock); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&lock->guard); ++} ++ ++#define lock_is_locked(lock) ((lock)->nr_readers != 0) ++#define lock_is_rlocked(lock) ((lock)->nr_readers > 0) ++#define lock_is_wlocked(lock) ((lock)->nr_readers < 0) ++#define lock_is_wlocked_once(lock) ((lock)->nr_readers == -1) ++#define lock_can_be_rlocked(lock) ((lock)->nr_readers >= 0) ++#define lock_mode_compatible(lock, mode) \ ++ (((mode) == ZNODE_WRITE_LOCK && !lock_is_locked(lock)) || \ ++ ((mode) == ZNODE_READ_LOCK && lock_can_be_rlocked(lock))) ++ ++/* Since we have R/W znode locks we need additional bidirectional `link' ++ objects to implement n<->m relationship between lock owners and lock ++ objects. We call them `lock handles'. ++ ++ Locking: see lock.c/"SHORT-TERM LOCKING" ++*/ ++struct lock_handle { ++ /* This flag indicates that a signal to yield a lock was passed to ++ lock owner and counted in owner->nr_signalled ++ ++ Locking: this is accessed under spin lock on ->node. ++ */ ++ int signaled; ++ /* A link to owner of a lock */ ++ lock_stack *owner; ++ /* A link to znode locked */ ++ znode *node; ++ /* A list of all locks for a process */ ++ struct list_head locks_link; ++ /* A list of all owners for a znode */ ++ struct list_head owners_link; ++}; ++ ++struct lock_request { ++ /* A pointer to uninitialized link object */ ++ lock_handle *handle; ++ /* A pointer to the object we want to lock */ ++ znode *node; ++ /* Lock mode (ZNODE_READ_LOCK or ZNODE_WRITE_LOCK) */ ++ znode_lock_mode mode; ++ /* how dispatch_lock_requests() returns lock request result code */ ++ int ret_code; ++}; ++ ++/* A lock stack structure for accumulating locks owned by a process */ ++struct lock_stack { ++ /* A guard lock protecting a lock stack */ ++ spinlock_t sguard; ++ /* number of znodes which were requested by high priority processes */ ++ atomic_t nr_signaled; ++ /* Current priority of a process ++ ++ This is only accessed by the current thread and thus requires no ++ locking. ++ */ ++ int curpri; ++ /* A list of all locks owned by this process. Elements can be added to ++ * this list only by the current thread. ->node pointers in this list ++ * can be only changed by the current thread. */ ++ struct list_head locks; ++ /* When lock_stack waits for the lock, it puts itself on double-linked ++ requestors list of that lock */ ++ struct list_head requestors_link; ++ /* Current lock request info. ++ ++ This is only accessed by the current thread and thus requires no ++ locking. ++ */ ++ struct lock_request request; ++ /* the following two fields are the lock stack's ++ * synchronization object to use with the standard linux/wait.h ++ * interface. See reiser4_go_to_sleep and __reiser4_wake_up for ++ * usage details. */ ++ wait_queue_head_t wait; ++ atomic_t wakeup; ++#if REISER4_DEBUG ++ int nr_locks; /* number of lock handles in the above list */ ++#endif ++}; ++ ++/* ++ User-visible znode locking functions ++*/ ++ ++extern int longterm_lock_znode(lock_handle * handle, ++ znode * node, ++ znode_lock_mode mode, ++ znode_lock_request request); ++ ++extern void longterm_unlock_znode(lock_handle * handle); ++ ++extern int reiser4_check_deadlock(void); ++ ++extern lock_stack *get_current_lock_stack(void); ++ ++extern void init_lock_stack(lock_stack * owner); ++extern void reiser4_init_lock(zlock * lock); ++ ++static inline void init_lh(lock_handle *lh) ++{ ++#if REISER4_DEBUG ++ memset(lh, 0, sizeof *lh); ++ INIT_LIST_HEAD(&lh->locks_link); ++ INIT_LIST_HEAD(&lh->owners_link); ++#else ++ lh->node = NULL; ++#endif ++} ++ ++static inline void done_lh(lock_handle *lh) ++{ ++ assert("zam-342", lh != NULL); ++ if (lh->node != NULL) ++ longterm_unlock_znode(lh); ++} ++ ++extern void move_lh(lock_handle * new, lock_handle * old); ++extern void copy_lh(lock_handle * new, lock_handle * old); ++ ++extern int reiser4_prepare_to_sleep(lock_stack * owner); ++extern void reiser4_go_to_sleep(lock_stack * owner); ++extern void __reiser4_wake_up(lock_stack * owner); ++ ++extern int lock_stack_isclean(lock_stack * owner); ++ ++/* zlock object state check macros: only used in assertions. Both forms imply ++ that the lock is held by the current thread. */ ++extern int znode_is_write_locked(const znode *); ++extern void reiser4_invalidate_lock(lock_handle *); ++ ++/* lock ordering is: first take zlock spin lock, then lock stack spin lock */ ++#define spin_ordering_pred_stack(stack) \ ++ (LOCK_CNT_NIL(spin_locked_stack) && \ ++ LOCK_CNT_NIL(spin_locked_txnmgr) && \ ++ LOCK_CNT_NIL(spin_locked_inode) && \ ++ LOCK_CNT_NIL(rw_locked_cbk_cache) && \ ++ LOCK_CNT_NIL(spin_locked_super_eflush)) ++ ++static inline void spin_lock_stack(lock_stack *stack) ++{ ++ assert("", spin_ordering_pred_stack(stack)); ++ spin_lock(&(stack->sguard)); ++ LOCK_CNT_INC(spin_locked_stack); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void spin_unlock_stack(lock_stack *stack) ++{ ++ assert_spin_locked(&(stack->sguard)); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_stack)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ LOCK_CNT_DEC(spin_locked_stack); ++ LOCK_CNT_DEC(spin_locked); ++ spin_unlock(&(stack->sguard)); ++} ++ ++static inline void reiser4_wake_up(lock_stack * owner) ++{ ++ spin_lock_stack(owner); ++ __reiser4_wake_up(owner); ++ spin_unlock_stack(owner); ++} ++ ++const char *lock_mode_name(znode_lock_mode lock); ++ ++#if REISER4_DEBUG ++extern void check_lock_data(void); ++extern void check_lock_node_data(znode * node); ++#else ++#define check_lock_data() noop ++#define check_lock_node_data() noop ++#endif ++ ++/* __LOCK_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/Makefile linux-5.10.2/fs/reiser4/Makefile +--- linux-5.10.2.orig/fs/reiser4/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/Makefile 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,115 @@ ++# ++# reiser4/Makefile ++# ++ ++obj-$(CONFIG_REISER4_FS) += reiser4.o ++ ++reiser4-y := \ ++ debug.o \ ++ jnode.o \ ++ znode.o \ ++ key.o \ ++ pool.o \ ++ tree_mod.o \ ++ estimate.o \ ++ carry.o \ ++ carry_ops.o \ ++ lock.o \ ++ tree.o \ ++ context.o \ ++ tap.o \ ++ coord.o \ ++ block_alloc.o \ ++ txnmgr.o \ ++ kassign.o \ ++ flush.o \ ++ wander.o \ ++ eottl.o \ ++ search.o \ ++ page_cache.o \ ++ seal.o \ ++ dscale.o \ ++ flush_queue.o \ ++ ktxnmgrd.o \ ++ blocknrset.o \ ++ super.o \ ++ init_volume.o \ ++ super_ops.o \ ++ volume_ops.o \ ++ fsdata.o \ ++ export_ops.o \ ++ oid.o \ ++ tree_walk.o \ ++ inode.o \ ++ vfs_ops.o \ ++ as_ops.o \ ++ entd.o\ ++ readahead.o \ ++ status_flags.o \ ++ init_super.o \ ++ safe_link.o \ ++ blocknrlist.o \ ++ discard.o \ ++ checksum.o \ ++ \ ++ plugin/plugin.o \ ++ plugin/plugin_set.o \ ++ plugin/node/node.o \ ++ plugin/object.o \ ++ plugin/cluster.o \ ++ plugin/txmod.o \ ++ plugin/inode_ops.o \ ++ plugin/inode_ops_rename.o \ ++ plugin/file_ops.o \ ++ plugin/file_ops_readdir.o \ ++ plugin/file_plugin_common.o \ ++ plugin/file/file.o \ ++ plugin/file/tail_conversion.o \ ++ plugin/file/file_conversion.o \ ++ plugin/file/symlink.o \ ++ plugin/file/cryptcompress.o \ ++ plugin/file/stripe.o \ ++ plugin/dir_plugin_common.o \ ++ plugin/dir/hashed_dir.o \ ++ plugin/dir/seekable_dir.o \ ++ plugin/node/node40.o \ ++ plugin/node/node41.o \ ++ \ ++ plugin/crypto/cipher.o \ ++ plugin/crypto/digest.o \ ++ \ ++ plugin/compress/compress.o \ ++ plugin/compress/compress_mode.o \ ++ \ ++ plugin/volume/volume.o \ ++ \ ++ plugin/dst/hash.o \ ++ plugin/dst/fsx32.o \ ++ plugin/dst/dst.o \ ++ \ ++ plugin/item/static_stat.o \ ++ plugin/item/sde.o \ ++ plugin/item/cde.o \ ++ plugin/item/blackbox.o \ ++ plugin/item/brick_symbol.o \ ++ plugin/item/internal.o \ ++ plugin/item/tail.o \ ++ plugin/item/ctail.o \ ++ plugin/item/extent.o \ ++ plugin/item/extent_item_ops.o \ ++ plugin/item/extent_file_ops.o \ ++ plugin/item/extent_stripe_ops.o \ ++ plugin/item/extent_flush_ops.o \ ++ plugin/item/extent_volume_ops.o \ ++ \ ++ plugin/hash.o \ ++ plugin/fibration.o \ ++ plugin/tail_policy.o \ ++ plugin/item/item.o \ ++ \ ++ plugin/security/perm.o \ ++ plugin/space/bitmap.o \ ++ \ ++ plugin/disk_format/disk_format40.o \ ++ plugin/disk_format/disk_format.o ++ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/oid.c linux-5.10.2/fs/reiser4/oid.c +--- linux-5.10.2.orig/fs/reiser4/oid.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/oid.c 2020-12-23 16:07:46.119813143 +0100 +@@ -0,0 +1,141 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "debug.h" ++#include "super.h" ++#include "txnmgr.h" ++ ++/* we used to have oid allocation plugin. It was removed because it ++ was recognized as providing unneeded level of abstraction. If one ++ ever will find it useful - look at yet_unneeded_abstractions/oid ++*/ ++ ++/* ++ * initialize in-memory data for oid allocator at @super. @nr_files and @next ++ * are provided by disk format plugin that reads them from the disk during ++ * mount. ++ */ ++int oid_init_allocator(struct super_block *super, oid_t nr_files, oid_t next) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_super_private(super); ++ ++ sbinfo->next_to_use = next; ++ sbinfo->oids_in_use = nr_files; ++ return 0; ++} ++ ++/* ++ * allocate oid and return it. ABSOLUTE_MAX_OID is returned when allocator ++ * runs out of oids. ++ */ ++oid_t oid_allocate(struct super_block *super) ++{ ++ reiser4_super_info_data *sbinfo; ++ oid_t oid; ++ ++ sbinfo = get_super_private(super); ++ ++ spin_lock_reiser4_super(sbinfo); ++ if (sbinfo->next_to_use != ABSOLUTE_MAX_OID) { ++ oid = sbinfo->next_to_use++; ++ sbinfo->oids_in_use++; ++ } else ++ oid = ABSOLUTE_MAX_OID; ++ spin_unlock_reiser4_super(sbinfo); ++ return oid; ++} ++ ++/* ++ * Tell oid allocator that @oid is now free. ++ */ ++int oid_release(struct super_block *super, oid_t oid UNUSED_ARG) ++{ ++ reiser4_super_info_data *sbinfo; ++ ++ sbinfo = get_super_private(super); ++ ++ spin_lock_reiser4_super(sbinfo); ++ sbinfo->oids_in_use--; ++ spin_unlock_reiser4_super(sbinfo); ++ return 0; ++} ++ ++/* ++ * return next @oid that would be allocated (i.e., returned by oid_allocate()) ++ * without actually allocating it. This is used by disk format plugin to save ++ * oid allocator state on the disk. ++ */ ++oid_t oid_next(const struct super_block *super) ++{ ++ reiser4_super_info_data *sbinfo; ++ oid_t oid; ++ ++ sbinfo = get_super_private(super); ++ ++ spin_lock_reiser4_super(sbinfo); ++ oid = sbinfo->next_to_use; ++ spin_unlock_reiser4_super(sbinfo); ++ return oid; ++} ++ ++/* ++ * returns number of currently used oids. This is used by statfs(2) to report ++ * number of "inodes" and by disk format plugin to save oid allocator state on ++ * the disk. ++ */ ++long oids_used(const struct super_block *super) ++{ ++ reiser4_super_info_data *sbinfo; ++ oid_t used; ++ ++ sbinfo = get_super_private(super); ++ ++ spin_lock_reiser4_super(sbinfo); ++ used = sbinfo->oids_in_use; ++ spin_unlock_reiser4_super(sbinfo); ++ if (used < (__u64) ((long)~0) >> 1) ++ return (long)used; ++ else ++ return (long)-1; ++} ++ ++/* ++ * Count oid as allocated in atom. This is done after call to oid_allocate() ++ * at the point when we are irrevocably committed to creation of the new file ++ * (i.e., when oid allocation cannot be any longer rolled back due to some ++ * error). ++ */ ++void oid_count_allocated(void) ++{ ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked(); ++ atom->nr_objects_created++; ++ spin_unlock_atom(atom); ++} ++ ++/* ++ * Count oid as free in atom. This is done after call to oid_release() at the ++ * point when we are irrevocably committed to the deletion of the file (i.e., ++ * when oid release cannot be any longer rolled back due to some error). ++ */ ++void oid_count_released(void) ++{ ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked(); ++ atom->nr_objects_deleted++; ++ spin_unlock_atom(atom); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/page_cache.c linux-5.10.2/fs/reiser4/page_cache.c +--- linux-5.10.2.orig/fs/reiser4/page_cache.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/page_cache.c 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,686 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Memory pressure hooks. Fake inodes handling. */ ++ ++/* GLOSSARY ++ ++ . Formatted and unformatted nodes. ++ Elements of reiser4 balanced tree to store data and metadata. ++ Unformatted nodes are pointed to by extent pointers. Such nodes ++ are used to store data of large objects. Unlike unformatted nodes, ++ formatted ones have associated format described by node4X plugin. ++ ++ . Jnode (or journal node) ++ The in-memory header which is used to track formatted and unformatted ++ nodes, bitmap nodes, etc. In particular, jnodes are used to track ++ transactional information associated with each block(see reiser4/jnode.c ++ for details). ++ ++ . Znode ++ The in-memory header which is used to track formatted nodes. Contains ++ embedded jnode (see reiser4/znode.c for details). ++*/ ++ ++/* We store all file system meta data (and data, of course) in the page cache. ++ ++ What does this mean? In stead of using bread/brelse we create special ++ "fake" inode (one per super block) and store content of formatted nodes ++ into pages bound to this inode in the page cache. In newer kernels bread() ++ already uses inode attached to block device (bd_inode). Advantage of having ++ our own fake inode is that we can install appropriate methods in its ++ address_space operations. Such methods are called by VM on memory pressure ++ (or during background page flushing) and we can use them to react ++ appropriately. ++ ++ In initial version we only support one block per page. Support for multiple ++ blocks per page is complicated by relocation. ++ ++ To each page, used by reiser4, jnode is attached. jnode is analogous to ++ buffer head. Difference is that jnode is bound to the page permanently: ++ jnode cannot be removed from memory until its backing page is. ++ ++ jnode contain pointer to page (->pg field) and page contain pointer to ++ jnode in ->private field. Pointer from jnode to page is protected to by ++ jnode's spinlock and pointer from page to jnode is protected by page lock ++ (PG_locked bit). Lock ordering is: first take page lock, then jnode spin ++ lock. To go into reverse direction use jnode_lock_page() function that uses ++ standard try-lock-and-release device. ++ ++ Properties: ++ ++ 1. when jnode-to-page mapping is established (by jnode_attach_page()), page ++ reference counter is increased. ++ ++ 2. when jnode-to-page mapping is destroyed (by page_clear_jnode(), page ++ reference counter is decreased. ++ ++ 3. on jload() reference counter on jnode page is increased, page is ++ kmapped and `referenced'. ++ ++ 4. on jrelse() inverse operations are performed. ++ ++ 5. kmapping/kunmapping of unformatted pages is done by read/write methods. ++ ++ DEADLOCKS RELATED TO MEMORY PRESSURE. [OUTDATED. Only interesting ++ historically.] ++ ++ [In the following discussion, `lock' invariably means long term lock on ++ znode.] (What about page locks?) ++ ++ There is some special class of deadlock possibilities related to memory ++ pressure. Locks acquired by other reiser4 threads are accounted for in ++ deadlock prevention mechanism (lock.c), but when ->vm_writeback() is ++ invoked additional hidden arc is added to the locking graph: thread that ++ tries to allocate memory waits for ->vm_writeback() to finish. If this ++ thread keeps lock and ->vm_writeback() tries to acquire this lock, deadlock ++ prevention is useless. ++ ++ Another related problem is possibility for ->vm_writeback() to run out of ++ memory itself. This is not a problem for ext2 and friends, because their ++ ->vm_writeback() don't allocate much memory, but reiser4 flush is ++ definitely able to allocate huge amounts of memory. ++ ++ It seems that there is no reliable way to cope with the problems above. In ++ stead it was decided that ->vm_writeback() (as invoked in the kswapd ++ context) wouldn't perform any flushing itself, but rather should just wake ++ up some auxiliary thread dedicated for this purpose (or, the same thread ++ that does periodic commit of old atoms (ktxnmgrd.c)). ++ ++ Details: ++ ++ 1. Page is called `reclaimable' against particular reiser4 mount F if this ++ page can be ultimately released by try_to_free_pages() under presumptions ++ that: ++ ++ a. ->vm_writeback() for F is no-op, and ++ ++ b. none of the threads accessing F are making any progress, and ++ ++ c. other reiser4 mounts obey the same memory reservation protocol as F ++ (described below). ++ ++ For example, clean un-pinned page, or page occupied by ext2 data are ++ reclaimable against any reiser4 mount. ++ ++ When there is more than one reiser4 mount in a system, condition (c) makes ++ reclaim-ability not easily verifiable beyond trivial cases mentioned above. ++ ++ THIS COMMENT IS VALID FOR "MANY BLOCKS ON PAGE" CASE ++ ++ Fake inode is used to bound formatted nodes and each node is indexed within ++ fake inode by its block number. If block size of smaller than page size, it ++ may so happen that block mapped to the page with formatted node is occupied ++ by unformatted node or is unallocated. This lead to some complications, ++ because flushing whole page can lead to an incorrect overwrite of ++ unformatted node that is moreover, can be cached in some other place as ++ part of the file body. To avoid this, buffers for unformatted nodes are ++ never marked dirty. Also pages in the fake are never marked dirty. This ++ rules out usage of ->writepage() as memory pressure hook. In stead ++ ->releasepage() is used. ++ ++ Josh is concerned that page->buffer is going to die. This should not pose ++ significant problem though, because we need to add some data structures to ++ the page anyway (jnode) and all necessary book keeping can be put there. ++ ++*/ ++ ++/* Life cycle of pages/nodes. ++ ++ jnode contains reference to page and page contains reference back to ++ jnode. This reference is counted in page ->count. Thus, page bound to jnode ++ cannot be released back into free pool. ++ ++ 1. Formatted nodes. ++ ++ 1. formatted node is represented by znode. When new znode is created its ++ ->pg pointer is NULL initially. ++ ++ 2. when node content is loaded into znode (by call to zload()) for the ++ first time following happens (in call to ->read_node() or ++ ->allocate_node()): ++ ++ 1. new page is added to the page cache. ++ ++ 2. this page is attached to znode and its ->count is increased. ++ ++ 3. page is kmapped. ++ ++ 3. if more calls to zload() follow (without corresponding zrelses), page ++ counter is left intact and in its stead ->d_count is increased in znode. ++ ++ 4. each call to zrelse decreases ->d_count. When ->d_count drops to zero ++ ->release_node() is called and page is kunmapped as result. ++ ++ 5. at some moment node can be captured by a transaction. Its ->x_count ++ is then increased by transaction manager. ++ ++ 6. if node is removed from the tree (empty node with JNODE_HEARD_BANSHEE ++ bit set) following will happen (also see comment at the top of znode.c): ++ ++ 1. when last lock is released, node will be uncaptured from ++ transaction. This released reference that transaction manager acquired ++ at the step 5. ++ ++ 2. when last reference is released, zput() detects that node is ++ actually deleted and calls ->delete_node() ++ operation. page_cache_delete_node() implementation detaches jnode from ++ page and releases page. ++ ++ 7. otherwise (node wasn't removed from the tree), last reference to ++ znode will be released after transaction manager committed transaction ++ node was in. This implies squallocing of this node (see ++ flush.c). Nothing special happens at this point. Znode is still in the ++ hash table and page is still attached to it. ++ ++ 8. znode is actually removed from the memory because of the memory ++ pressure, or during umount (znodes_tree_done()). Anyway, znode is ++ removed by the call to zdrop(). At this moment, page is detached from ++ znode and removed from the inode address space. ++ ++*/ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "super.h" ++#include "entd.h" ++#include "page_cache.h" ++#include "ktxnmgrd.h" ++ ++#include ++#include ++#include /* for struct page */ ++#include /* for struct page */ ++#include ++#include ++#include ++#include ++ ++static struct bio *page_bio(struct page *, jnode * , int rw, gfp_t gfp); ++ ++static struct address_space_operations formatted_fake_as_ops; ++ ++static const oid_t fake_ino = 0x1; ++static const oid_t bitmap_ino = 0x2; ++static const oid_t cc_ino = 0x3; ++ ++static void ++init_fake_inode(struct super_block *super, struct inode *fake, ++ struct inode **pfake) ++{ ++ assert("nikita-2168", fake->i_state & I_NEW); ++ fake->i_mapping->a_ops = &formatted_fake_as_ops; ++ inode_attach_wb(fake, NULL); ++ *pfake = fake; ++ /* NOTE-NIKITA something else? */ ++ unlock_new_inode(fake); ++} ++ ++/** ++ * reiser4_init_formatted_fake - iget inodes for formatted nodes and bitmaps ++ * @super: super block to init fake inode for ++ * ++ * Initializes fake inode to which formatted nodes are bound in the page cache ++ * and inode for bitmaps. ++ */ ++int reiser4_init_formatted_fake(struct super_block *super) ++{ ++ struct inode *fake; ++ struct inode *bitmap; ++ struct inode *cc; ++ reiser4_super_info_data *sinfo; ++ ++ assert("nikita-1703", super != NULL); ++ ++ sinfo = get_super_private_nocheck(super); ++ fake = iget_locked(super, oid_to_ino(fake_ino)); ++ ++ if (fake != NULL) { ++ init_fake_inode(super, fake, &sinfo->fake); ++ ++ bitmap = iget_locked(super, oid_to_ino(bitmap_ino)); ++ if (bitmap != NULL) { ++ init_fake_inode(super, bitmap, &sinfo->bitmap); ++ ++ cc = iget_locked(super, oid_to_ino(cc_ino)); ++ if (cc != NULL) { ++ init_fake_inode(super, cc, &sinfo->cc); ++ return 0; ++ } else { ++ iput(sinfo->fake); ++ iput(sinfo->bitmap); ++ sinfo->fake = NULL; ++ sinfo->bitmap = NULL; ++ } ++ } else { ++ iput(sinfo->fake); ++ sinfo->fake = NULL; ++ } ++ } ++ return RETERR(-ENOMEM); ++} ++ ++/** ++ * reiser4_done_formatted_fake - release inode used by formatted nodes and bitmaps ++ * @super: super block to init fake inode for ++ * ++ * Releases inodes which were used as address spaces of bitmap and formatted ++ * nodes. ++ */ ++void reiser4_done_formatted_fake(struct super_block *super) ++{ ++ reiser4_super_info_data *sinfo; ++ ++ sinfo = get_super_private_nocheck(super); ++ ++ if (sinfo->fake != NULL) { ++ iput(sinfo->fake); ++ sinfo->fake = NULL; ++ } ++ ++ if (sinfo->bitmap != NULL) { ++ iput(sinfo->bitmap); ++ sinfo->bitmap = NULL; ++ } ++ ++ if (sinfo->cc != NULL) { ++ iput(sinfo->cc); ++ sinfo->cc = NULL; ++ } ++ return; ++} ++ ++void reiser4_wait_page_writeback(struct page *page) ++{ ++ assert("zam-783", PageLocked(page)); ++ ++ do { ++ unlock_page(page); ++ wait_on_page_writeback(page); ++ lock_page(page); ++ } while (PageWriteback(page)); ++} ++ ++/* completion handler for single page bio-based read. ++ ++ mpage_end_io_read() would also do. But it's static. ++ ++*/ ++static void end_bio_single_page_read(struct bio *bio) ++{ ++ struct page *page; ++ ++ page = bio->bi_io_vec[0].bv_page; ++ ++ if (!bio->bi_status) ++ SetPageUptodate(page); ++ else { ++ ClearPageUptodate(page); ++ SetPageError(page); ++ } ++ unlock_page(page); ++ bio_put(bio); ++} ++ ++/* completion handler for single page bio-based write. ++ ++ mpage_end_io_write() would also do. But it's static. ++ ++*/ ++static void end_bio_single_page_write(struct bio *bio) ++{ ++ struct page *page; ++ ++ page = bio->bi_io_vec[0].bv_page; ++ ++ if (bio->bi_status) ++ SetPageError(page); ++ end_page_writeback(page); ++ bio_put(bio); ++} ++ ++/* ->readpage() method for formatted nodes */ ++static int formatted_readpage(struct file *f UNUSED_ARG, ++ struct page *page/* page to read */) ++{ ++ assert("nikita-2412", PagePrivate(page) && jprivate(page)); ++ return reiser4_page_io(page, jprivate(page), READ, ++ reiser4_ctx_gfp_mask_get()); ++} ++ ++/** ++ * reiser4_page_io - submit single-page bio request ++ * @page: page to perform io for ++ * @node: jnode of page ++ * @rw: read or write ++ * @gfp: gfp mask for bio allocation ++ * ++ * Submits single page read or write. ++ */ ++int reiser4_page_io(struct page *page, jnode *node, int rw, gfp_t gfp) ++{ ++ struct bio *bio; ++ int result; ++ ++ assert("nikita-2094", page != NULL); ++ assert("nikita-2226", PageLocked(page)); ++ assert("nikita-2634", node != NULL); ++ assert("nikita-2893", rw == READ || rw == WRITE); ++ ++ if (rw) { ++ if (unlikely(IS_RDONLY(page->mapping->host))) { ++ unlock_page(page); ++ return 0; ++ } ++ } ++ ++ bio = page_bio(page, node, rw, gfp); ++ if (!IS_ERR(bio)) { ++ if (rw == WRITE) { ++ set_page_writeback(page); ++ unlock_page(page); ++ } ++ bio_set_op_attrs(bio, rw, 0); ++ submit_bio(bio); ++ result = 0; ++ } else { ++ unlock_page(page); ++ result = PTR_ERR(bio); ++ } ++ ++ return result; ++} ++ ++/** ++ * Helper function to construct bio for page ++ */ ++static struct bio *page_bio(struct page *page, jnode *node, int rw, gfp_t gfp) ++{ ++ struct bio *bio; ++ assert("nikita-2092", page != NULL); ++ assert("nikita-2633", node != NULL); ++ /* ++ * Simple implementation in the assumption that blocksize == pagesize. ++ * ++ * We only have to submit one block, but submit_bh() will allocate bio ++ * anyway, so lets use all the bells-and-whistles of bio code. ++ */ ++ bio = bio_alloc(gfp, 1); ++ if (bio != NULL) { ++ int blksz; ++ struct super_block *super; ++ reiser4_block_nr blocknr; ++ ++ super = page->mapping->host->i_sb; ++ assert("nikita-2029", super != NULL); ++ blksz = super->s_blocksize; ++ assert("nikita-2028", blksz == (int)PAGE_SIZE); ++ ++ spin_lock_jnode(node); ++ blocknr = *jnode_get_io_block(node); ++ spin_unlock_jnode(node); ++ ++ assert("nikita-2275", blocknr != (reiser4_block_nr) 0); ++ assert("nikita-2276", !reiser4_blocknr_is_fake(&blocknr)); ++ ++ bio_set_dev(bio, jnode_get_subvol(node)->bdev); ++ /* ++ * fill bio->bi_iter.bi_sector before calling bio_add_page(), ++ * because q->merge_bvec_fn may want to inspect it (see ++ * drivers/md/linear.c:linear_mergeable_bvec() for example. ++ */ ++ bio->bi_iter.bi_sector = blocknr * (blksz >> 9); ++ ++ if (!bio_add_page(bio, page, blksz, 0)) { ++ warning("nikita-3452", ++ "Single page bio cannot be constructed"); ++ return ERR_PTR(RETERR(-EINVAL)); ++ } ++ /* ++ * bio -> bi_idx is filled by bio_init() ++ */ ++ bio->bi_end_io = (rw == READ) ? ++ end_bio_single_page_read : end_bio_single_page_write; ++ return bio; ++ } else ++ return ERR_PTR(RETERR(-ENOMEM)); ++} ++ ++#if 0 ++static int can_hit_entd(reiser4_context *ctx, struct super_block *s) ++{ ++ if (ctx == NULL || ((unsigned long)ctx->magic) != context_magic) ++ return 1; ++ if (ctx->super != s) ++ return 1; ++ if (get_super_private(s)->entd.tsk == current) ++ return 0; ++ if (!lock_stack_isclean(&ctx->stack)) ++ return 0; ++ if (ctx->trans->atom != NULL) ++ return 0; ++ return 1; ++} ++#endif ++ ++/** ++ * reiser4_writepage - writepage of struct address_space_operations ++ * @page: page to write ++ * @wbc: ++ * ++ * ++ */ ++/* Common memory pressure notification. */ ++int reiser4_writepage(struct page *page, ++ struct writeback_control *wbc) ++{ ++ /* ++ * assert("edward-1562", ++ * can_hit_entd(get_current_context_check(), sb)); ++ */ ++ assert("vs-828", PageLocked(page)); ++ ++ return write_page_by_ent(page, wbc); ++} ++ ++/* ->set_page_dirty() method of formatted address_space */ ++static int formatted_set_page_dirty(struct page *page) ++{ ++ assert("nikita-2173", page != NULL); ++ BUG(); ++ return __set_page_dirty_nobuffers(page); ++} ++ ++/* writepages method of address space operations in reiser4 is used to involve ++ into transactions pages which are dirtied via mmap. Only regular files can ++ have such pages. Fake inode is used to access formatted nodes via page ++ cache. As formatted nodes can never be mmaped, fake inode's writepages has ++ nothing to do */ ++static int ++writepages_fake(struct address_space *mapping, struct writeback_control *wbc) ++{ ++ return 0; ++} ++ ++/* address space operations for the fake inode */ ++static struct address_space_operations formatted_fake_as_ops = { ++ /* Perform a writeback of a single page as a memory-freeing ++ * operation. */ ++ .writepage = reiser4_writepage, ++ /* this is called to read formatted node */ ++ .readpage = formatted_readpage, ++ /* ->sync_page() method of fake inode address space operations. Called ++ from wait_on_page() and lock_page(). ++ ++ This is most annoyingly misnomered method. Actually it is called ++ from wait_on_page_bit() and lock_page() and its purpose is to ++ actually start io by jabbing device drivers. ++ .sync_page = block_sync_page, ++ */ ++ /* Write back some dirty pages from this mapping. Called from sync. ++ called during sync (pdflush) */ ++ .writepages = writepages_fake, ++ /* Set a page dirty */ ++ .set_page_dirty = formatted_set_page_dirty, ++ /* used for read-ahead. Not applicable */ ++ .readpages = NULL, ++ .write_begin = NULL, ++ .write_end = NULL, ++ .bmap = NULL, ++ /* called just before page is being detached from inode mapping and ++ removed from memory. Called on truncate, cut/squeeze, and ++ umount. */ ++ .invalidatepage = reiser4_invalidatepage, ++ /* this is called by shrink_cache() so that file system can try to ++ release objects (jnodes, buffers, journal heads) attached to page ++ and, may be made page itself free-able. ++ */ ++ .releasepage = reiser4_releasepage, ++ .direct_IO = NULL, ++ .migratepage = reiser4_migratepage, ++ .batch_lock_tabu = 1 ++}; ++ ++/* called just before page is released (no longer used by reiser4). Callers: ++ jdelete() and extent2tail(). */ ++void reiser4_drop_page(struct page *page) ++{ ++ assert("nikita-2181", PageLocked(page)); ++ clear_page_dirty_for_io(page); ++ ClearPageUptodate(page); ++#if defined(PG_skipped) ++ ClearPageSkipped(page); ++#endif ++ unlock_page(page); ++} ++ ++#define JNODE_GANG_SIZE (16) ++ ++/* find all jnodes from range specified and invalidate them */ ++static int truncate_jnodes_range(struct inode *inode, ++ pgoff_t from, pgoff_t count) ++{ ++ reiser4_inode *info; ++ int truncated_jnodes; ++ unsigned long index; ++ unsigned long end; ++ ++ if (inode_file_plugin(inode) == ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)) ++ /* ++ * No need to get rid of jnodes here: if the single jnode of ++ * page cluster did not have page, then it was found and killed ++ * before in ++ * truncate_complete_page_cluster()->jput()->jput_final(), ++ * otherwise it will be dropped by reiser4_invalidatepage() ++ */ ++ return 0; ++ truncated_jnodes = 0; ++ ++ info = reiser4_inode_data(inode); ++ ++ index = from; ++ end = from + count; ++ ++ while (1) { ++ jnode *gang[JNODE_GANG_SIZE]; ++ int taken; ++ int i; ++ jnode *node; ++ ++ assert("nikita-3466", index <= end); ++ ++ read_lock_tree(); ++ taken = ++ radix_tree_gang_lookup(jnode_tree_by_reiser4_inode(info), ++ (void **)gang, index, ++ JNODE_GANG_SIZE); ++ for (i = 0; i < taken; ++i) { ++ node = gang[i]; ++ if (index_jnode(node) < end) ++ jref(node); ++ else ++ gang[i] = NULL; ++ } ++ read_unlock_tree(); ++ ++ for (i = 0; i < taken; ++i) { ++ node = gang[i]; ++ if (node != NULL) { ++ index = max(index, index_jnode(node)); ++ spin_lock_jnode(node); ++ assert("edward-1457", node->pg == NULL); ++ /* this is always called after ++ truncate_inode_pages_range(). Therefore, here ++ jnode can not have page. New pages can not be ++ created because truncate_jnodes_range goes ++ under exclusive access on file obtained, ++ where as new page creation requires ++ non-exclusive access obtained */ ++ JF_SET(node, JNODE_HEARD_BANSHEE); ++ reiser4_uncapture_jnode(node); ++ unhash_unformatted_jnode(node); ++ truncated_jnodes++; ++ jput(node); ++ } else ++ break; ++ } ++ if (i != taken || taken == 0) ++ break; ++ } ++ return truncated_jnodes; ++} ++ ++/* Truncating files in reiser4: problems and solutions. ++ ++ VFS calls fs's truncate after it has called truncate_inode_pages() ++ to get rid of pages corresponding to part of file being truncated. ++ In reiser4 it may cause existence of unallocated extents which do ++ not have jnodes. Flush code does not expect that. Solution of this ++ problem is straightforward. As vfs's truncate is implemented using ++ setattr operation, it seems reasonable to have ->setattr() that ++ will cut file body. However, flush code also does not expect dirty ++ pages without parent items, so it is impossible to cut all items, ++ then truncate all pages in two steps. We resolve this problem by ++ cutting items one-by-one. Each such fine-grained step performed ++ under longterm znode lock calls at the end ->kill_hook() method of ++ a killed item to remove its binded pages and jnodes. ++ ++ The following function is a common part of mentioned kill hooks. ++ Also, this is called before tail-to-extent conversion (to not manage ++ few copies of the data). ++*/ ++void reiser4_invalidate_pages(struct address_space *mapping, pgoff_t from, ++ unsigned long count, int even_cows) ++{ ++ loff_t from_bytes, count_bytes; ++ ++ if (count == 0) ++ return; ++ from_bytes = ((loff_t) from) << PAGE_SHIFT; ++ count_bytes = ((loff_t) count) << PAGE_SHIFT; ++ ++ unmap_mapping_range(mapping, from_bytes, count_bytes, even_cows); ++ truncate_inode_pages_range(mapping, from_bytes, ++ from_bytes + count_bytes - 1); ++ truncate_jnodes_range(mapping->host, from, count); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/page_cache.h linux-5.10.2/fs/reiser4/page_cache.h +--- linux-5.10.2.orig/fs/reiser4/page_cache.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/page_cache.h 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,60 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++/* Memory pressure hooks. Fake inodes handling. See page_cache.c. */ ++ ++#if !defined(__REISER4_PAGE_CACHE_H__) ++#define __REISER4_PAGE_CACHE_H__ ++ ++#include "forward.h" ++#include "context.h" /* for reiser4_ctx_gfp_mask_get() */ ++ ++#include /* for struct super_block, address_space */ ++#include /* for struct page */ ++#include /* for lock_page() */ ++#include /* for __vmalloc() */ ++ ++extern int reiser4_init_formatted_fake(struct super_block *); ++extern void reiser4_done_formatted_fake(struct super_block *); ++ ++extern void reiser4_wait_page_writeback(struct page *); ++static inline void lock_and_wait_page_writeback(struct page *page) ++{ ++ lock_page(page); ++ if (unlikely(PageWriteback(page))) ++ reiser4_wait_page_writeback(page); ++} ++ ++#define jprivate(page) ((jnode *)page_private(page)) ++ ++extern int reiser4_page_io(struct page *, jnode *, int rw, gfp_t); ++extern void reiser4_drop_page(struct page *); ++extern void reiser4_invalidate_pages(struct address_space *, pgoff_t from, ++ unsigned long count, int even_cows); ++extern void capture_reiser4_inodes(struct super_block *, ++ struct writeback_control *); ++static inline void *reiser4_vmalloc(unsigned long size) ++{ ++ return __vmalloc(size, reiser4_ctx_gfp_mask_get()); ++} ++ ++#define PAGECACHE_TAG_REISER4_MOVED PAGECACHE_TAG_DIRTY ++ ++#if REISER4_DEBUG ++extern void print_page(const char *prefix, struct page *page); ++#else ++#define print_page(prf, p) noop ++#endif ++ ++/* __REISER4_PAGE_CACHE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/cluster.c linux-5.10.2/fs/reiser4/plugin/cluster.c +--- linux-5.10.2.orig/fs/reiser4/plugin/cluster.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/cluster.c 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,72 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Contains reiser4 cluster plugins (see ++ http://www.namesys.com/cryptcompress_design.html ++ "Concepts of clustering" for details). */ ++ ++#include "plugin_header.h" ++#include "plugin.h" ++#include "../inode.h" ++ ++static int change_cluster(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ assert("edward-1324", inode != NULL); ++ assert("edward-1325", plugin != NULL); ++ assert("edward-1326", is_reiser4_inode(inode)); ++ assert("edward-1327", plugin->h.type_id == REISER4_CLUSTER_PLUGIN_TYPE); ++ ++ /* Can't change the cluster plugin for already existent regular files */ ++ if (!plugin_of_group(inode_file_plugin(inode), REISER4_DIRECTORY_FILE)) ++ return RETERR(-EINVAL); ++ ++ /* If matches, nothing to change. */ ++ if (inode_hash_plugin(inode) != NULL && ++ inode_hash_plugin(inode)->h.id == plugin->h.id) ++ return 0; ++ ++ return aset_set_unsafe(&reiser4_inode_data(inode)->pset, ++ PSET_CLUSTER, plugin); ++} ++ ++static reiser4_plugin_ops cluster_plugin_ops = { ++ .init = NULL, ++ .load = NULL, ++ .save_len = NULL, ++ .save = NULL, ++ .change = &change_cluster ++}; ++ ++#define SUPPORT_CLUSTER(SHIFT, ID, LABEL, DESC) \ ++ [CLUSTER_ ## ID ## _ID] = { \ ++ .h = { \ ++ .type_id = REISER4_CLUSTER_PLUGIN_TYPE, \ ++ .id = CLUSTER_ ## ID ## _ID, \ ++ .pops = &cluster_plugin_ops, \ ++ .label = LABEL, \ ++ .desc = DESC, \ ++ .linkage = {NULL, NULL} \ ++ }, \ ++ .shift = SHIFT \ ++ } ++ ++cluster_plugin cluster_plugins[LAST_CLUSTER_ID] = { ++ SUPPORT_CLUSTER(16, 64K, "64K", "Large"), ++ SUPPORT_CLUSTER(15, 32K, "32K", "Big"), ++ SUPPORT_CLUSTER(14, 16K, "16K", "Average"), ++ SUPPORT_CLUSTER(13, 8K, "8K", "Small"), ++ SUPPORT_CLUSTER(12, 4K, "4K", "Minimal") ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/cluster.h linux-5.10.2/fs/reiser4/plugin/cluster.h +--- linux-5.10.2.orig/fs/reiser4/plugin/cluster.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/cluster.h 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,410 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* This file contains size/offset translators, modulators ++ and other helper functions. */ ++ ++#if !defined(__FS_REISER4_CLUSTER_H__) ++#define __FS_REISER4_CLUSTER_H__ ++ ++#include "../inode.h" ++ ++static inline int inode_cluster_shift(struct inode *inode) ++{ ++ assert("edward-92", inode != NULL); ++ assert("edward-93", reiser4_inode_data(inode) != NULL); ++ ++ return inode_cluster_plugin(inode)->shift; ++} ++ ++static inline unsigned cluster_nrpages_shift(struct inode *inode) ++{ ++ return inode_cluster_shift(inode) - PAGE_SHIFT; ++} ++ ++/* cluster size in page units */ ++static inline unsigned cluster_nrpages(struct inode *inode) ++{ ++ return 1U << cluster_nrpages_shift(inode); ++} ++ ++static inline size_t inode_cluster_size(struct inode *inode) ++{ ++ assert("edward-96", inode != NULL); ++ ++ return 1U << inode_cluster_shift(inode); ++} ++ ++static inline cloff_t pg_to_clust(pgoff_t idx, struct inode *inode) ++{ ++ return idx >> cluster_nrpages_shift(inode); ++} ++ ++static inline pgoff_t clust_to_pg(cloff_t idx, struct inode *inode) ++{ ++ return idx << cluster_nrpages_shift(inode); ++} ++ ++static inline pgoff_t pg_to_clust_to_pg(pgoff_t idx, struct inode *inode) ++{ ++ return clust_to_pg(pg_to_clust(idx, inode), inode); ++} ++ ++static inline pgoff_t off_to_pg(loff_t off) ++{ ++ return (off >> PAGE_SHIFT); ++} ++ ++static inline loff_t pg_to_off(pgoff_t idx) ++{ ++ return ((loff_t) (idx) << PAGE_SHIFT); ++} ++ ++static inline cloff_t off_to_clust(loff_t off, struct inode *inode) ++{ ++ return off >> inode_cluster_shift(inode); ++} ++ ++static inline loff_t clust_to_off(cloff_t idx, struct inode *inode) ++{ ++ return (loff_t) idx << inode_cluster_shift(inode); ++} ++ ++static inline loff_t off_to_clust_to_off(loff_t off, struct inode *inode) ++{ ++ return clust_to_off(off_to_clust(off, inode), inode); ++} ++ ++static inline pgoff_t off_to_clust_to_pg(loff_t off, struct inode *inode) ++{ ++ return clust_to_pg(off_to_clust(off, inode), inode); ++} ++ ++static inline unsigned off_to_pgoff(loff_t off) ++{ ++ return off & (PAGE_SIZE - 1); ++} ++ ++static inline unsigned off_to_cloff(loff_t off, struct inode *inode) ++{ ++ return off & ((loff_t) (inode_cluster_size(inode)) - 1); ++} ++ ++static inline pgoff_t offset_in_clust(struct page *page) ++{ ++ assert("edward-1488", page != NULL); ++ assert("edward-1489", page->mapping != NULL); ++ ++ return page_index(page) & ((cluster_nrpages(page->mapping->host)) - 1); ++} ++ ++static inline int first_page_in_cluster(struct page *page) ++{ ++ return offset_in_clust(page) == 0; ++} ++ ++static inline int last_page_in_cluster(struct page *page) ++{ ++ return offset_in_clust(page) == ++ cluster_nrpages(page->mapping->host) - 1; ++} ++ ++static inline unsigned ++pg_to_off_to_cloff(unsigned long idx, struct inode *inode) ++{ ++ return off_to_cloff(pg_to_off(idx), inode); ++} ++ ++/*********************** Size translators **************************/ ++ ++/* Translate linear size. ++ * New units are (1 << @blk_shift) times larger, then old ones. ++ * In other words, calculate number of logical blocks, occupied ++ * by @count elements ++ */ ++static inline unsigned long size_in_blocks(loff_t count, unsigned blkbits) ++{ ++ return (count + (1UL << blkbits) - 1) >> blkbits; ++} ++ ++/* size in pages */ ++static inline pgoff_t size_in_pages(loff_t size) ++{ ++ return size_in_blocks(size, PAGE_SHIFT); ++} ++ ++/* size in logical clusters */ ++static inline cloff_t size_in_lc(loff_t size, struct inode *inode) ++{ ++ return size_in_blocks(size, inode_cluster_shift(inode)); ++} ++ ++/* size in pages to the size in page clusters */ ++static inline cloff_t sp_to_spcl(pgoff_t size, struct inode *inode) ++{ ++ return size_in_blocks(size, cluster_nrpages_shift(inode)); ++} ++ ++/*********************** Size modulators ***************************/ ++ ++/* ++ Modulate linear size by nominated block size and offset. ++ ++ The "finite" function (which is zero almost everywhere). ++ How much is a height of the figure at a position @pos, ++ when trying to construct rectangle of height (1 << @blkbits), ++ and square @size. ++ ++ ****** ++ ******* ++ ******* ++ ******* ++ ----------> pos ++*/ ++static inline unsigned __mbb(loff_t size, unsigned long pos, int blkbits) ++{ ++ unsigned end = size >> blkbits; ++ if (pos < end) ++ return 1U << blkbits; ++ if (unlikely(pos > end)) ++ return 0; ++ return size & ~(~0ull << blkbits); ++} ++ ++/* the same as above, but block size is page size */ ++static inline unsigned __mbp(loff_t size, pgoff_t pos) ++{ ++ return __mbb(size, pos, PAGE_SHIFT); ++} ++ ++/* number of file's bytes in the nominated logical cluster */ ++static inline unsigned lbytes(cloff_t index, struct inode *inode) ++{ ++ return __mbb(i_size_read(inode), index, inode_cluster_shift(inode)); ++} ++ ++/* number of file's bytes in the nominated page */ ++static inline unsigned pbytes(pgoff_t index, struct inode *inode) ++{ ++ return __mbp(i_size_read(inode), index); ++} ++ ++/** ++ * number of pages occuped by @win->count bytes starting from ++ * @win->off at logical cluster defined by @win. This is exactly ++ * a number of pages to be modified and dirtied in any cluster operation. ++ */ ++static inline pgoff_t win_count_to_nrpages(struct reiser4_slide * win) ++{ ++ return ((win->off + win->count + ++ (1UL << PAGE_SHIFT) - 1) >> PAGE_SHIFT) - ++ off_to_pg(win->off); ++} ++ ++/* return true, if logical cluster is not occupied by the file */ ++static inline int new_logical_cluster(struct cluster_handle *clust, ++ struct inode *inode) ++{ ++ return clust_to_off(clust->index, inode) >= i_size_read(inode); ++} ++ ++/* return true, if pages @p1 and @p2 are of the same page cluster */ ++static inline int same_page_cluster(struct page *p1, struct page *p2) ++{ ++ assert("edward-1490", p1 != NULL); ++ assert("edward-1491", p2 != NULL); ++ assert("edward-1492", p1->mapping != NULL); ++ assert("edward-1493", p2->mapping != NULL); ++ ++ return (pg_to_clust(page_index(p1), p1->mapping->host) == ++ pg_to_clust(page_index(p2), p2->mapping->host)); ++} ++ ++static inline int cluster_is_complete(struct cluster_handle *clust, ++ struct inode *inode) ++{ ++ return clust->tc.lsize == inode_cluster_size(inode); ++} ++ ++static inline void reiser4_slide_init(struct reiser4_slide *win) ++{ ++ assert("edward-1084", win != NULL); ++ memset(win, 0, sizeof *win); ++} ++ ++static inline tfm_action ++cluster_get_tfm_act(struct tfm_cluster *tc) ++{ ++ assert("edward-1356", tc != NULL); ++ return tc->act; ++} ++ ++static inline void ++cluster_set_tfm_act(struct tfm_cluster *tc, tfm_action act) ++{ ++ assert("edward-1356", tc != NULL); ++ tc->act = act; ++} ++ ++static inline void cluster_init_act(struct cluster_handle *clust, ++ tfm_action act, ++ struct reiser4_slide *window) ++{ ++ assert("edward-84", clust != NULL); ++ memset(clust, 0, sizeof *clust); ++ cluster_set_tfm_act(&clust->tc, act); ++ clust->dstat = INVAL_DISK_CLUSTER; ++ clust->win = window; ++} ++ ++static inline void cluster_init_read(struct cluster_handle *clust, ++ struct reiser4_slide *window) ++{ ++ cluster_init_act(clust, TFMA_READ, window); ++} ++ ++static inline void cluster_init_write(struct cluster_handle *clust, ++ struct reiser4_slide *window) ++{ ++ cluster_init_act(clust, TFMA_WRITE, window); ++} ++ ++/* true if @p1 and @p2 are items of the same disk cluster */ ++static inline int same_disk_cluster(const coord_t *p1, const coord_t *p2) ++{ ++ /* drop this if you have other items to aggregate */ ++ assert("edward-1494", item_id_by_coord(p1) == CTAIL_ID); ++ ++ return item_plugin_by_coord(p1)->b.mergeable(p1, p2); ++} ++ ++static inline int dclust_get_extension_dsize(hint_t *hint) ++{ ++ return hint->ext_coord.extension.ctail.dsize; ++} ++ ++static inline void dclust_set_extension_dsize(hint_t *hint, int dsize) ++{ ++ hint->ext_coord.extension.ctail.dsize = dsize; ++} ++ ++static inline int dclust_get_extension_shift(hint_t *hint) ++{ ++ return hint->ext_coord.extension.ctail.shift; ++} ++ ++static inline int dclust_get_extension_ncount(hint_t *hint) ++{ ++ return hint->ext_coord.extension.ctail.ncount; ++} ++ ++static inline void dclust_inc_extension_ncount(hint_t *hint) ++{ ++ hint->ext_coord.extension.ctail.ncount++; ++} ++ ++static inline void dclust_init_extension(hint_t *hint) ++{ ++ memset(&hint->ext_coord.extension.ctail, 0, ++ sizeof(hint->ext_coord.extension.ctail)); ++} ++ ++static inline int hint_is_unprepped_dclust(hint_t *hint) ++{ ++ assert("edward-1451", hint_is_valid(hint)); ++ return dclust_get_extension_shift(hint) == (int)UCTAIL_SHIFT; ++} ++ ++static inline void coord_set_between_clusters(coord_t *coord) ++{ ++#if REISER4_DEBUG ++ int result; ++ result = zload(coord->node); ++ assert("edward-1296", !result); ++#endif ++ if (!coord_is_between_items(coord)) { ++ coord->between = AFTER_ITEM; ++ coord->unit_pos = 0; ++ } ++#if REISER4_DEBUG ++ zrelse(coord->node); ++#endif ++} ++ ++int reiser4_inflate_cluster(struct cluster_handle *, struct inode *); ++int find_disk_cluster(struct cluster_handle *, struct inode *, int read, ++ znode_lock_mode mode); ++int checkout_logical_cluster(struct cluster_handle *, jnode * , struct inode *); ++int reiser4_deflate_cluster(struct cluster_handle *, struct inode *); ++void truncate_complete_page_cluster(struct inode *inode, cloff_t start, ++ int even_cows); ++void invalidate_hint_cluster(struct cluster_handle *clust); ++int get_disk_cluster_locked(struct cluster_handle *clust, struct inode *inode, ++ znode_lock_mode lock_mode); ++void reset_cluster_params(struct cluster_handle *clust); ++int set_cluster_by_page(struct cluster_handle *clust, struct page *page, ++ int count); ++int prepare_page_cluster(struct inode *inode, struct cluster_handle *clust, ++ rw_op rw); ++void __put_page_cluster(int from, int count, struct page **pages, ++ struct inode *inode); ++void put_page_cluster(struct cluster_handle *clust, ++ struct inode *inode, rw_op rw); ++void put_cluster_handle(struct cluster_handle *clust); ++int grab_tfm_stream(struct inode *inode, struct tfm_cluster *tc, ++ tfm_stream_id id); ++int tfm_cluster_is_uptodate(struct tfm_cluster *tc); ++void tfm_cluster_set_uptodate(struct tfm_cluster *tc); ++void tfm_cluster_clr_uptodate(struct tfm_cluster *tc); ++ ++/* move cluster handle to the target position ++ specified by the page of index @pgidx */ ++static inline void move_cluster_forward(struct cluster_handle *clust, ++ struct inode *inode, ++ pgoff_t pgidx) ++{ ++ assert("edward-1297", clust != NULL); ++ assert("edward-1298", inode != NULL); ++ ++ reset_cluster_params(clust); ++ if (clust->index_valid && ++ /* Hole in the indices. Hint became invalid and can not be ++ used by find_cluster_item() even if seal/node versions ++ will coincide */ ++ pg_to_clust(pgidx, inode) != clust->index + 1) { ++ reiser4_unset_hint(clust->hint); ++ invalidate_hint_cluster(clust); ++ } ++ clust->index = pg_to_clust(pgidx, inode); ++ clust->index_valid = 1; ++} ++ ++static inline int alloc_clust_pages(struct cluster_handle *clust, ++ struct inode *inode) ++{ ++ assert("edward-791", clust != NULL); ++ assert("edward-792", inode != NULL); ++ clust->pages = ++ kmalloc(sizeof(*clust->pages) << inode_cluster_shift(inode), ++ reiser4_ctx_gfp_mask_get()); ++ if (!clust->pages) ++ return -ENOMEM; ++ return 0; ++} ++ ++static inline void free_clust_pages(struct cluster_handle *clust) ++{ ++ kfree(clust->pages); ++} ++ ++#endif /* __FS_REISER4_CLUSTER_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/compress.c linux-5.10.2/fs/reiser4/plugin/compress/compress.c +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/compress.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/compress.c 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,521 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* reiser4 compression transform plugins */ ++ ++#include "../../debug.h" ++#include "../../inode.h" ++#include "../plugin.h" ++ ++#include ++#include ++#include ++#include ++#include ++ ++static int change_compression(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ assert("edward-1316", inode != NULL); ++ assert("edward-1317", plugin != NULL); ++ assert("edward-1318", is_reiser4_inode(inode)); ++ assert("edward-1319", ++ plugin->h.type_id == REISER4_COMPRESSION_PLUGIN_TYPE); ++ ++ /* cannot change compression plugin of already existing regular object */ ++ if (!plugin_of_group(inode_file_plugin(inode), REISER4_DIRECTORY_FILE)) ++ return RETERR(-EINVAL); ++ ++ /* If matches, nothing to change. */ ++ if (inode_hash_plugin(inode) != NULL && ++ inode_hash_plugin(inode)->h.id == plugin->h.id) ++ return 0; ++ ++ return aset_set_unsafe(&reiser4_inode_data(inode)->pset, ++ PSET_COMPRESSION, plugin); ++} ++ ++static reiser4_plugin_ops compression_plugin_ops = { ++ .init = NULL, ++ .load = NULL, ++ .save_len = NULL, ++ .save = NULL, ++ .change = &change_compression ++}; ++ ++/******************************************************************************/ ++/* gzip1 compression */ ++/******************************************************************************/ ++ ++#define GZIP1_DEF_LEVEL Z_BEST_SPEED ++#define GZIP1_DEF_WINBITS 15 ++#define GZIP1_DEF_MEMLEVEL MAX_MEM_LEVEL ++ ++static int gzip1_init(void) ++{ ++ return 0; ++} ++ ++static int gzip1_overrun(unsigned src_len UNUSED_ARG) ++{ ++ return 0; ++} ++ ++static coa_t gzip1_alloc(tfm_action act) ++{ ++ coa_t coa = NULL; ++ int ret = 0; ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ coa = reiser4_vmalloc(zlib_deflate_workspacesize(MAX_WBITS, ++ MAX_MEM_LEVEL)); ++ if (!coa) { ++ ret = -ENOMEM; ++ break; ++ } ++ break; ++ case TFMA_READ: /* decompress */ ++ coa = reiser4_vmalloc(zlib_inflate_workspacesize()); ++ if (!coa) { ++ ret = -ENOMEM; ++ break; ++ } ++ break; ++ default: ++ impossible("edward-767", "unknown tfm action"); ++ } ++ if (ret) ++ return ERR_PTR(ret); ++ return coa; ++} ++ ++static void gzip1_free(coa_t coa, tfm_action act) ++{ ++ assert("edward-769", coa != NULL); ++ ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ vfree(coa); ++ break; ++ case TFMA_READ: /* decompress */ ++ vfree(coa); ++ break; ++ default: ++ impossible("edward-770", "unknown tfm action"); ++ } ++ return; ++} ++ ++static int gzip1_min_size_deflate(void) ++{ ++ return 64; ++} ++ ++static void ++gzip1_compress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ int ret = 0; ++ struct z_stream_s stream; ++ ++ assert("edward-842", coa != NULL); ++ assert("edward-875", src_len != 0); ++ ++ stream.workspace = coa; ++ ret = zlib_deflateInit2(&stream, GZIP1_DEF_LEVEL, Z_DEFLATED, ++ -GZIP1_DEF_WINBITS, GZIP1_DEF_MEMLEVEL, ++ Z_DEFAULT_STRATEGY); ++ if (ret != Z_OK) { ++ warning("edward-771", "zlib_deflateInit2 returned %d\n", ret); ++ goto rollback; ++ } ++ ret = zlib_deflateReset(&stream); ++ if (ret != Z_OK) { ++ warning("edward-772", "zlib_deflateReset returned %d\n", ret); ++ goto rollback; ++ } ++ stream.next_in = src_first; ++ stream.avail_in = src_len; ++ stream.next_out = dst_first; ++ stream.avail_out = *dst_len; ++ ++ ret = zlib_deflate(&stream, Z_FINISH); ++ if (ret != Z_STREAM_END) { ++ if (ret != Z_OK) ++ warning("edward-773", ++ "zlib_deflate returned %d\n", ret); ++ goto rollback; ++ } ++ *dst_len = stream.total_out; ++ return; ++ rollback: ++ *dst_len = src_len; ++ return; ++} ++ ++static void ++gzip1_decompress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ int ret = 0; ++ struct z_stream_s stream; ++ ++ assert("edward-843", coa != NULL); ++ assert("edward-876", src_len != 0); ++ ++ stream.workspace = coa; ++ ret = zlib_inflateInit2(&stream, -GZIP1_DEF_WINBITS); ++ if (ret != Z_OK) { ++ warning("edward-774", "zlib_inflateInit2 returned %d\n", ret); ++ return; ++ } ++ ret = zlib_inflateReset(&stream); ++ if (ret != Z_OK) { ++ warning("edward-775", "zlib_inflateReset returned %d\n", ret); ++ return; ++ } ++ ++ stream.next_in = src_first; ++ stream.avail_in = src_len; ++ stream.next_out = dst_first; ++ stream.avail_out = *dst_len; ++ ++ ret = zlib_inflate(&stream, Z_SYNC_FLUSH); ++ /* ++ * Work around a bug in zlib, which sometimes wants to taste an extra ++ * byte when being used in the (undocumented) raw deflate mode. ++ * (From USAGI). ++ */ ++ if (ret == Z_OK && !stream.avail_in && stream.avail_out) { ++ u8 zerostuff = 0; ++ stream.next_in = &zerostuff; ++ stream.avail_in = 1; ++ ret = zlib_inflate(&stream, Z_FINISH); ++ } ++ if (ret != Z_STREAM_END) { ++ warning("edward-776", "zlib_inflate returned %d\n", ret); ++ return; ++ } ++ *dst_len = stream.total_out; ++ return; ++} ++ ++/******************************************************************************/ ++/* lzo1 compression */ ++/******************************************************************************/ ++ ++static int lzo1_init(void) ++{ ++ return 0; ++} ++ ++static int lzo1_overrun(unsigned in_len) ++{ ++ return in_len / 16 + 64 + 3; ++} ++ ++static coa_t lzo1_alloc(tfm_action act) ++{ ++ int ret = 0; ++ coa_t coa = NULL; ++ ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ coa = reiser4_vmalloc(LZO1X_1_MEM_COMPRESS); ++ if (!coa) { ++ ret = -ENOMEM; ++ break; ++ } ++ case TFMA_READ: /* decompress */ ++ break; ++ default: ++ impossible("edward-877", "unknown tfm action"); ++ } ++ if (ret) ++ return ERR_PTR(ret); ++ return coa; ++} ++ ++static void lzo1_free(coa_t coa, tfm_action act) ++{ ++ assert("edward-879", coa != NULL); ++ ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ vfree(coa); ++ break; ++ case TFMA_READ: /* decompress */ ++ impossible("edward-1304", ++ "trying to free non-allocated workspace"); ++ default: ++ impossible("edward-880", "unknown tfm action"); ++ } ++ return; ++} ++ ++static int lzo1_min_size_deflate(void) ++{ ++ return 256; ++} ++ ++static void ++lzo1_compress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ int result; ++ ++ assert("edward-846", coa != NULL); ++ assert("edward-847", src_len != 0); ++ ++ result = lzo1x_1_compress(src_first, src_len, dst_first, dst_len, coa); ++ if (unlikely(result != LZO_E_OK)) { ++ warning("edward-849", "lzo1x_1_compress failed\n"); ++ goto out; ++ } ++ if (*dst_len >= src_len) { ++ //warning("edward-850", "lzo1x_1_compress: incompressible data\n"); ++ goto out; ++ } ++ return; ++ out: ++ *dst_len = src_len; ++ return; ++} ++ ++static void ++lzo1_decompress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ int result; ++ ++ assert("edward-851", coa == NULL); ++ assert("edward-852", src_len != 0); ++ ++ result = lzo1x_decompress_safe(src_first, src_len, dst_first, dst_len); ++ if (result != LZO_E_OK) ++ warning("edward-853", "lzo1x_1_decompress failed\n"); ++ return; ++} ++ ++/******************************************************************************/ ++/* zstd1 compression */ ++/******************************************************************************/ ++ ++typedef struct { ++ ZSTD_parameters params; ++ void* workspace; ++ ZSTD_CCtx* cctx; ++} zstd1_coa_c; ++typedef struct { ++ void* workspace; ++ ZSTD_DCtx* dctx; ++} zstd1_coa_d; ++ ++static int zstd1_init(void) ++{ ++ return 0; ++} ++ ++static int zstd1_overrun(unsigned src_len UNUSED_ARG) ++{ ++ return ZSTD_compressBound(src_len) - src_len; ++} ++ ++static coa_t zstd1_alloc(tfm_action act) ++{ ++ int ret = 0; ++ size_t workspace_size; ++ coa_t coa = NULL; ++ ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ coa = reiser4_vmalloc(sizeof(zstd1_coa_c)); ++ if (!coa) { ++ ret = -ENOMEM; ++ break; ++ } ++ /* ZSTD benchmark use level 1 as default. Max is 22. */ ++ ((zstd1_coa_c*)coa)->params = ZSTD_getParams(1, 0, 0); ++ workspace_size = ZSTD_CCtxWorkspaceBound(((zstd1_coa_c*)coa)->params.cParams); ++ ((zstd1_coa_c*)coa)->workspace = reiser4_vmalloc(workspace_size); ++ if (!(((zstd1_coa_c*)coa)->workspace)) { ++ ret = -ENOMEM; ++ vfree(coa); ++ break; ++ } ++ ((zstd1_coa_c*)coa)->cctx = ZSTD_initCCtx(((zstd1_coa_c*)coa)->workspace, workspace_size); ++ if (!(((zstd1_coa_c*)coa)->cctx)) { ++ ret = -ENOMEM; ++ vfree(((zstd1_coa_c*)coa)->workspace); ++ vfree(coa); ++ break; ++ } ++ break; ++ case TFMA_READ: /* decompress */ ++ coa = reiser4_vmalloc(sizeof(zstd1_coa_d)); ++ if (!coa) { ++ ret = -ENOMEM; ++ break; ++ } ++ workspace_size = ZSTD_DCtxWorkspaceBound(); ++ ((zstd1_coa_d*)coa)->workspace = reiser4_vmalloc(workspace_size); ++ if (!(((zstd1_coa_d*)coa)->workspace)) { ++ ret = -ENOMEM; ++ vfree(coa); ++ break; ++ } ++ ((zstd1_coa_d*)coa)->dctx = ZSTD_initDCtx(((zstd1_coa_d*)coa)->workspace, workspace_size); ++ if (!(((zstd1_coa_d*)coa)->dctx)) { ++ ret = -ENOMEM; ++ vfree(((zstd1_coa_d*)coa)->workspace); ++ vfree(coa); ++ break; ++ } ++ break; ++ default: ++ impossible("bsinot-1", ++ "trying to alloc workspace for unknown tfm action"); ++ } ++ if (ret) { ++ warning("bsinot-2", ++ "alloc workspace for zstd (tfm action = %d) failed\n", ++ act); ++ return ERR_PTR(ret); ++ } ++ return coa; ++} ++ ++static void zstd1_free(coa_t coa, tfm_action act) ++{ ++ assert("bsinot-3", coa != NULL); ++ ++ switch (act) { ++ case TFMA_WRITE: /* compress */ ++ vfree(((zstd1_coa_c*)coa)->workspace); ++ vfree(coa); ++ //printk(KERN_WARNING "free comp memory -- %p\n", coa); ++ break; ++ case TFMA_READ: /* decompress */ ++ vfree(((zstd1_coa_d*)coa)->workspace); ++ vfree(coa); ++ //printk(KERN_WARNING "free decomp memory -- %p\n", coa); ++ break; ++ default: ++ impossible("bsinot-4", "unknown tfm action"); ++ } ++ return; ++} ++ ++static int zstd1_min_size_deflate(void) ++{ ++ return 256; /* I'm not sure about the correct value, so took from LZO1 */ ++} ++ ++static void ++zstd1_compress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ unsigned int result; ++ ++ assert("bsinot-5", coa != NULL); ++ assert("bsinot-6", src_len != 0); ++ result = ZSTD_compressCCtx(((zstd1_coa_c*)coa)->cctx, dst_first, *dst_len, src_first, src_len, ((zstd1_coa_c*)coa)->params); ++ if (ZSTD_isError(result)) { ++ warning("bsinot-7", "zstd1_compressCCtx failed\n"); ++ goto out; ++ } ++ *dst_len = result; ++ if (*dst_len >= src_len) { ++ //warning("bsinot-8", "zstd1_compressCCtx: incompressible data\n"); ++ goto out; ++ } ++ return; ++ out: ++ *dst_len = src_len; ++ return; ++} ++ ++static void ++zstd1_decompress(coa_t coa, __u8 * src_first, size_t src_len, ++ __u8 * dst_first, size_t *dst_len) ++{ ++ unsigned int result; ++ ++ assert("bsinot-9", coa != NULL); ++ assert("bsinot-10", src_len != 0); ++ ++ result = ZSTD_decompressDCtx(((zstd1_coa_d*)coa)->dctx, dst_first, *dst_len, src_first, src_len); ++ /* Same here. */ ++ if (ZSTD_isError(result)) ++ warning("bsinot-11", "zstd1_decompressDCtx failed\n"); ++ *dst_len = result; ++ return; ++} ++ ++ ++compression_plugin compression_plugins[LAST_COMPRESSION_ID] = { ++ [LZO1_COMPRESSION_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .id = LZO1_COMPRESSION_ID, ++ .pops = &compression_plugin_ops, ++ .label = "lzo1", ++ .desc = "lzo1 compression transform", ++ .linkage = {NULL, NULL} ++ }, ++ .init = lzo1_init, ++ .overrun = lzo1_overrun, ++ .alloc = lzo1_alloc, ++ .free = lzo1_free, ++ .min_size_deflate = lzo1_min_size_deflate, ++ .checksum = reiser4_adler32, ++ .compress = lzo1_compress, ++ .decompress = lzo1_decompress ++ }, ++ [GZIP1_COMPRESSION_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .id = GZIP1_COMPRESSION_ID, ++ .pops = &compression_plugin_ops, ++ .label = "gzip1", ++ .desc = "gzip1 compression transform", ++ .linkage = {NULL, NULL} ++ }, ++ .init = gzip1_init, ++ .overrun = gzip1_overrun, ++ .alloc = gzip1_alloc, ++ .free = gzip1_free, ++ .min_size_deflate = gzip1_min_size_deflate, ++ .checksum = reiser4_adler32, ++ .compress = gzip1_compress, ++ .decompress = gzip1_decompress ++ }, ++ [ZSTD1_COMPRESSION_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .id = ZSTD1_COMPRESSION_ID, ++ .pops = &compression_plugin_ops, ++ .label = "zstd1", ++ .desc = "zstd1 compression transform", ++ .linkage = {NULL, NULL} ++ }, ++ .init = zstd1_init, ++ .overrun = zstd1_overrun, ++ .alloc = zstd1_alloc, ++ .free = zstd1_free, ++ .min_size_deflate = zstd1_min_size_deflate, ++ .checksum = reiser4_adler32, ++ .compress = zstd1_compress, ++ .decompress = zstd1_decompress ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/compress.h linux-5.10.2/fs/reiser4/plugin/compress/compress.h +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/compress.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/compress.h 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,44 @@ ++#if !defined( __FS_REISER4_COMPRESS_H__ ) ++#define __FS_REISER4_COMPRESS_H__ ++ ++#include ++#include ++ ++/* transform direction */ ++typedef enum { ++ TFMA_READ, /* decrypt, decompress */ ++ TFMA_WRITE, /* encrypt, compress */ ++ TFMA_LAST ++} tfm_action; ++ ++/* supported compression algorithms */ ++typedef enum { ++ LZO1_COMPRESSION_ID, ++ GZIP1_COMPRESSION_ID, ++ ZSTD1_COMPRESSION_ID, ++ LAST_COMPRESSION_ID, ++} reiser4_compression_id; ++ ++/* the same as pgoff, but units are page clusters */ ++typedef unsigned long cloff_t; ++ ++/* working data of a (de)compression algorithm */ ++typedef void *coa_t; ++ ++/* table for all supported (de)compression algorithms */ ++typedef coa_t coa_set[LAST_COMPRESSION_ID][TFMA_LAST]; ++ ++__u32 reiser4_adler32(char *data, __u32 len); ++ ++#endif /* __FS_REISER4_COMPRESS_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/compress_mode.c linux-5.10.2/fs/reiser4/plugin/compress/compress_mode.c +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/compress_mode.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/compress_mode.c 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,162 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* This file contains Reiser4 compression mode plugins. ++ ++ Compression mode plugin is a set of handlers called by compressor ++ at flush time and represent some heuristics including the ones ++ which are to avoid compression of incompressible data, see ++ http://www.namesys.com/cryptcompress_design.html for more details. ++*/ ++#include "../../inode.h" ++#include "../plugin.h" ++ ++static int should_deflate_none(struct inode * inode, cloff_t index) ++{ ++ return 0; ++} ++ ++static int should_deflate_common(struct inode * inode, cloff_t index) ++{ ++ return compression_is_on(cryptcompress_inode_data(inode)); ++} ++ ++static int discard_hook_ultim(struct inode *inode, cloff_t index) ++{ ++ turn_off_compression(cryptcompress_inode_data(inode)); ++ return 0; ++} ++ ++static int discard_hook_lattd(struct inode *inode, cloff_t index) ++{ ++ struct cryptcompress_info * info = cryptcompress_inode_data(inode); ++ ++ assert("edward-1462", ++ get_lattice_factor(info) >= MIN_LATTICE_FACTOR && ++ get_lattice_factor(info) <= MAX_LATTICE_FACTOR); ++ ++ turn_off_compression(info); ++ if (get_lattice_factor(info) < MAX_LATTICE_FACTOR) ++ set_lattice_factor(info, get_lattice_factor(info) << 1); ++ return 0; ++} ++ ++static int accept_hook_lattd(struct inode *inode, cloff_t index) ++{ ++ turn_on_compression(cryptcompress_inode_data(inode)); ++ set_lattice_factor(cryptcompress_inode_data(inode), MIN_LATTICE_FACTOR); ++ return 0; ++} ++ ++/* Check on dynamic lattice, the adaptive compression modes which ++ defines the following behavior: ++ ++ Compression is on: try to compress everything and turn ++ it off, whenever cluster is incompressible. ++ ++ Compression is off: try to compress clusters of indexes ++ k * FACTOR (k = 0, 1, 2, ...) and turn it on, if some of ++ them is compressible. If incompressible, then increase FACTOR */ ++ ++/* check if @index belongs to one-dimensional lattice ++ of sparce factor @factor */ ++static int is_on_lattice(cloff_t index, int factor) ++{ ++ return (factor ? index % factor == 0: index == 0); ++} ++ ++static int should_deflate_lattd(struct inode * inode, cloff_t index) ++{ ++ return should_deflate_common(inode, index) || ++ is_on_lattice(index, ++ get_lattice_factor ++ (cryptcompress_inode_data(inode))); ++} ++ ++/* compression mode_plugins */ ++compression_mode_plugin compression_mode_plugins[LAST_COMPRESSION_MODE_ID] = { ++ [NONE_COMPRESSION_MODE_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = NONE_COMPRESSION_MODE_ID, ++ .pops = NULL, ++ .label = "none", ++ .desc = "Compress nothing", ++ .linkage = {NULL, NULL} ++ }, ++ .should_deflate = should_deflate_none, ++ .accept_hook = NULL, ++ .discard_hook = NULL ++ }, ++ /* Check-on-dynamic-lattice adaptive compression mode */ ++ [LATTD_COMPRESSION_MODE_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = LATTD_COMPRESSION_MODE_ID, ++ .pops = NULL, ++ .label = "lattd", ++ .desc = "Check on dynamic lattice", ++ .linkage = {NULL, NULL} ++ }, ++ .should_deflate = should_deflate_lattd, ++ .accept_hook = accept_hook_lattd, ++ .discard_hook = discard_hook_lattd ++ }, ++ /* Check-ultimately compression mode: ++ Turn off compression forever as soon as we meet ++ incompressible data */ ++ [ULTIM_COMPRESSION_MODE_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = ULTIM_COMPRESSION_MODE_ID, ++ .pops = NULL, ++ .label = "ultim", ++ .desc = "Check ultimately", ++ .linkage = {NULL, NULL} ++ }, ++ .should_deflate = should_deflate_common, ++ .accept_hook = NULL, ++ .discard_hook = discard_hook_ultim ++ }, ++ /* Force-to-compress-everything compression mode */ ++ [FORCE_COMPRESSION_MODE_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = FORCE_COMPRESSION_MODE_ID, ++ .pops = NULL, ++ .label = "force", ++ .desc = "Force to compress everything", ++ .linkage = {NULL, NULL} ++ }, ++ .should_deflate = NULL, ++ .accept_hook = NULL, ++ .discard_hook = NULL ++ }, ++ /* Convert-to-extent compression mode. ++ In this mode items will be converted to extents and management ++ will be passed to (classic) unix file plugin as soon as ->write() ++ detects that the first complete logical cluster (of index #0) is ++ incompressible. */ ++ [CONVX_COMPRESSION_MODE_ID] = { ++ .h = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .id = CONVX_COMPRESSION_MODE_ID, ++ .pops = NULL, ++ .label = "conv", ++ .desc = "Convert to extent", ++ .linkage = {NULL, NULL} ++ }, ++ .should_deflate = should_deflate_common, ++ .accept_hook = NULL, ++ .discard_hook = NULL ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/lzoconf.h linux-5.10.2/fs/reiser4/plugin/compress/lzoconf.h +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/lzoconf.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/lzoconf.h 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,216 @@ ++/* lzoconf.h -- configuration for the LZO real-time data compression library ++ adopted for reiser4 compression transform plugin. ++ ++ This file is part of the LZO real-time data compression library ++ and not included in any proprietary licenses of reiser4. ++ ++ Copyright (C) 2002 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2001 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2000 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1999 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1998 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1997 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1996 Markus Franz Xaver Johannes Oberhumer ++ All Rights Reserved. ++ ++ The LZO library is free software; you can redistribute it and/or ++ modify it under the terms of the GNU General Public License as ++ published by the Free Software Foundation; either version 2 of ++ the License, or (at your option) any later version. ++ ++ The LZO library is distributed in the hope that it will be useful, ++ but WITHOUT ANY WARRANTY; without even the implied warranty of ++ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ++ GNU General Public License for more details. ++ ++ You should have received a copy of the GNU General Public License ++ along with the LZO library; see the file COPYING. ++ If not, write to the Free Software Foundation, Inc., ++ 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. ++ ++ Markus F.X.J. Oberhumer ++ ++ http://www.oberhumer.com/opensource/lzo/ ++ */ ++ ++#include /* for UINT_MAX, ULONG_MAX - edward */ ++ ++#ifndef __LZOCONF_H ++#define __LZOCONF_H ++ ++#define LZO_VERSION 0x1080 ++#define LZO_VERSION_STRING "1.08" ++#define LZO_VERSION_DATE "Jul 12 2002" ++ ++/* internal Autoconf configuration file - only used when building LZO */ ++ ++/*********************************************************************** ++// LZO requires a conforming ++************************************************************************/ ++ ++#define CHAR_BIT 8 ++#define USHRT_MAX 0xffff ++ ++/* workaround a cpp bug under hpux 10.20 */ ++#define LZO_0xffffffffL 4294967295ul ++ ++/*********************************************************************** ++// architecture defines ++************************************************************************/ ++ ++#if !defined(__LZO_i386) ++# if defined(__i386__) || defined(__386__) || defined(_M_IX86) ++# define __LZO_i386 ++# endif ++#endif ++ ++/* memory checkers */ ++#if !defined(__LZO_CHECKER) ++# if defined(__BOUNDS_CHECKING_ON) ++# define __LZO_CHECKER ++# elif defined(__CHECKER__) ++# define __LZO_CHECKER ++# elif defined(__INSURE__) ++# define __LZO_CHECKER ++# elif defined(__PURIFY__) ++# define __LZO_CHECKER ++# endif ++#endif ++ ++/*********************************************************************** ++// integral and pointer types ++************************************************************************/ ++ ++/* Integral types with 32 bits or more */ ++#if !defined(LZO_UINT32_MAX) ++# if (UINT_MAX >= LZO_0xffffffffL) ++ typedef unsigned int lzo_uint32; ++ typedef int lzo_int32; ++# define LZO_UINT32_MAX UINT_MAX ++# define LZO_INT32_MAX INT_MAX ++# define LZO_INT32_MIN INT_MIN ++# elif (ULONG_MAX >= LZO_0xffffffffL) ++ typedef unsigned long lzo_uint32; ++ typedef long lzo_int32; ++# define LZO_UINT32_MAX ULONG_MAX ++# define LZO_INT32_MAX LONG_MAX ++# define LZO_INT32_MIN LONG_MIN ++# else ++# error "lzo_uint32" ++# endif ++#endif ++ ++/* lzo_uint is used like size_t */ ++#if !defined(LZO_UINT_MAX) ++# if (UINT_MAX >= LZO_0xffffffffL) ++ typedef unsigned int lzo_uint; ++ typedef int lzo_int; ++# define LZO_UINT_MAX UINT_MAX ++# define LZO_INT_MAX INT_MAX ++# define LZO_INT_MIN INT_MIN ++# elif (ULONG_MAX >= LZO_0xffffffffL) ++ typedef unsigned long lzo_uint; ++ typedef long lzo_int; ++# define LZO_UINT_MAX ULONG_MAX ++# define LZO_INT_MAX LONG_MAX ++# define LZO_INT_MIN LONG_MIN ++# else ++# error "lzo_uint" ++# endif ++#endif ++ ++ typedef int lzo_bool; ++ ++/*********************************************************************** ++// memory models ++************************************************************************/ ++ ++/* Memory model that allows to access memory at offsets of lzo_uint. */ ++#if !defined(__LZO_MMODEL) ++# if (LZO_UINT_MAX <= UINT_MAX) ++# define __LZO_MMODEL ++# else ++# error "__LZO_MMODEL" ++# endif ++#endif ++ ++/* no typedef here because of const-pointer issues */ ++#define lzo_byte unsigned char __LZO_MMODEL ++#define lzo_bytep unsigned char __LZO_MMODEL * ++#define lzo_charp char __LZO_MMODEL * ++#define lzo_voidp void __LZO_MMODEL * ++#define lzo_shortp short __LZO_MMODEL * ++#define lzo_ushortp unsigned short __LZO_MMODEL * ++#define lzo_uint32p lzo_uint32 __LZO_MMODEL * ++#define lzo_int32p lzo_int32 __LZO_MMODEL * ++#define lzo_uintp lzo_uint __LZO_MMODEL * ++#define lzo_intp lzo_int __LZO_MMODEL * ++#define lzo_voidpp lzo_voidp __LZO_MMODEL * ++#define lzo_bytepp lzo_bytep __LZO_MMODEL * ++ ++#ifndef lzo_sizeof_dict_t ++# define lzo_sizeof_dict_t sizeof(lzo_bytep) ++#endif ++ ++typedef int (*lzo_compress_t) (const lzo_byte * src, lzo_uint src_len, ++ lzo_byte * dst, lzo_uintp dst_len, ++ lzo_voidp wrkmem); ++ ++ ++/*********************************************************************** ++// error codes and prototypes ++************************************************************************/ ++ ++/* Error codes for the compression/decompression functions. Negative ++ * values are errors, positive values will be used for special but ++ * normal events. ++ */ ++#define LZO_E_OK 0 ++#define LZO_E_ERROR (-1) ++#define LZO_E_OUT_OF_MEMORY (-2) /* not used right now */ ++#define LZO_E_NOT_COMPRESSIBLE (-3) /* not used right now */ ++#define LZO_E_INPUT_OVERRUN (-4) ++#define LZO_E_OUTPUT_OVERRUN (-5) ++#define LZO_E_LOOKBEHIND_OVERRUN (-6) ++#define LZO_E_EOF_NOT_FOUND (-7) ++#define LZO_E_INPUT_NOT_CONSUMED (-8) ++ ++/* lzo_init() should be the first function you call. ++ * Check the return code ! ++ * ++ * lzo_init() is a macro to allow checking that the library and the ++ * compiler's view of various types are consistent. ++ */ ++#define lzo_init() __lzo_init2(LZO_VERSION,(int)sizeof(short),(int)sizeof(int),\ ++ (int)sizeof(long),(int)sizeof(lzo_uint32),(int)sizeof(lzo_uint),\ ++ (int)lzo_sizeof_dict_t,(int)sizeof(char *),(int)sizeof(lzo_voidp),\ ++ (int)sizeof(lzo_compress_t)) ++ extern int __lzo_init2(unsigned, int, int, int, int, int, int, ++ int, int, int); ++ ++/* checksum functions */ ++extern lzo_uint32 lzo_crc32(lzo_uint32 _c, const lzo_byte * _buf, ++ lzo_uint _len); ++/* misc. */ ++ typedef union { ++ lzo_bytep p; ++ lzo_uint u; ++ } __lzo_pu_u; ++ typedef union { ++ lzo_bytep p; ++ lzo_uint32 u32; ++ } __lzo_pu32_u; ++ typedef union { ++ void *vp; ++ lzo_bytep bp; ++ lzo_uint32 u32; ++ long l; ++ } lzo_align_t; ++ ++#define LZO_PTR_ALIGN_UP(_ptr,_size) \ ++ ((_ptr) + (lzo_uint) __lzo_align_gap((const lzo_voidp)(_ptr),(lzo_uint)(_size))) ++ ++/* deprecated - only for backward compatibility */ ++#define LZO_ALIGN(_ptr,_size) LZO_PTR_ALIGN_UP(_ptr,_size) ++ ++#endif /* already included */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/Makefile linux-5.10.2/fs/reiser4/plugin/compress/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/Makefile 2020-12-23 16:07:46.120813158 +0100 +@@ -0,0 +1,5 @@ ++obj-$(CONFIG_REISER4_FS) += compress_plugins.o ++ ++compress_plugins-objs := \ ++ compress.o \ ++ compress_mode.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/minilzo.c linux-5.10.2/fs/reiser4/plugin/compress/minilzo.c +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/minilzo.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/minilzo.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,1967 @@ ++/* minilzo.c -- mini subset of the LZO real-time data compression library ++ adopted for reiser4 compression transform plugin. ++ ++ This file is part of the LZO real-time data compression library ++ and not included in any proprietary licenses of reiser4. ++ ++ Copyright (C) 2002 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2001 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2000 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1999 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1998 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1997 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1996 Markus Franz Xaver Johannes Oberhumer ++ All Rights Reserved. ++ ++ The LZO library is free software; you can redistribute it and/or ++ modify it under the terms of the GNU General Public License as ++ published by the Free Software Foundation; either version 2 of ++ the License, or (at your option) any later version. ++ ++ The LZO library is distributed in the hope that it will be useful, ++ but WITHOUT ANY WARRANTY; without even the implied warranty of ++ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ++ GNU General Public License for more details. ++ ++ You should have received a copy of the GNU General Public License ++ along with the LZO library; see the file COPYING. ++ If not, write to the Free Software Foundation, Inc., ++ 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. ++ ++ Markus F.X.J. Oberhumer ++ ++ http://www.oberhumer.com/opensource/lzo/ ++ */ ++ ++/* ++ * NOTE: ++ * the full LZO package can be found at ++ * http://www.oberhumer.com/opensource/lzo/ ++ */ ++ ++#include "../../debug.h" /* for reiser4 assert macro -edward */ ++ ++#define __LZO_IN_MINILZO ++#define LZO_BUILD ++ ++#include "minilzo.h" ++ ++#if !defined(MINILZO_VERSION) || (MINILZO_VERSION != 0x1080) ++# error "version mismatch in miniLZO source files" ++#endif ++ ++#ifndef __LZO_CONF_H ++#define __LZO_CONF_H ++ ++# define BOUNDS_CHECKING_OFF_DURING(stmt) stmt ++# define BOUNDS_CHECKING_OFF_IN_EXPR(expr) (expr) ++ ++# define HAVE_MEMCMP ++# define HAVE_MEMCPY ++# define HAVE_MEMMOVE ++# define HAVE_MEMSET ++ ++#undef NDEBUG ++#if !defined(LZO_DEBUG) ++# define NDEBUG ++#endif ++#if defined(LZO_DEBUG) || !defined(NDEBUG) ++# if !defined(NO_STDIO_H) ++# include ++# endif ++#endif ++ ++#if !defined(LZO_COMPILE_TIME_ASSERT) ++# define LZO_COMPILE_TIME_ASSERT(expr) \ ++ { typedef int __lzo_compile_time_assert_fail[1 - 2 * !(expr)]; } ++#endif ++ ++#if !defined(LZO_UNUSED) ++# if 1 ++# define LZO_UNUSED(var) ((void)&var) ++# elif 0 ++# define LZO_UNUSED(var) { typedef int __lzo_unused[sizeof(var) ? 2 : 1]; } ++# else ++# define LZO_UNUSED(parm) (parm = parm) ++# endif ++#endif ++ ++#if defined(NO_MEMCMP) ++# undef HAVE_MEMCMP ++#endif ++ ++#if !defined(HAVE_MEMSET) ++# undef memset ++# define memset lzo_memset ++#endif ++ ++# define LZO_BYTE(x) ((unsigned char) ((x) & 0xff)) ++ ++#define LZO_MAX(a,b) ((a) >= (b) ? (a) : (b)) ++#define LZO_MIN(a,b) ((a) <= (b) ? (a) : (b)) ++#define LZO_MAX3(a,b,c) ((a) >= (b) ? LZO_MAX(a,c) : LZO_MAX(b,c)) ++#define LZO_MIN3(a,b,c) ((a) <= (b) ? LZO_MIN(a,c) : LZO_MIN(b,c)) ++ ++#define lzo_sizeof(type) ((lzo_uint) (sizeof(type))) ++ ++#define LZO_HIGH(array) ((lzo_uint) (sizeof(array)/sizeof(*(array)))) ++ ++#define LZO_SIZE(bits) (1u << (bits)) ++#define LZO_MASK(bits) (LZO_SIZE(bits) - 1) ++ ++#define LZO_LSIZE(bits) (1ul << (bits)) ++#define LZO_LMASK(bits) (LZO_LSIZE(bits) - 1) ++ ++#define LZO_USIZE(bits) ((lzo_uint) 1 << (bits)) ++#define LZO_UMASK(bits) (LZO_USIZE(bits) - 1) ++ ++#define LZO_STYPE_MAX(b) (((1l << (8*(b)-2)) - 1l) + (1l << (8*(b)-2))) ++#define LZO_UTYPE_MAX(b) (((1ul << (8*(b)-1)) - 1ul) + (1ul << (8*(b)-1))) ++ ++#if !defined(SIZEOF_UNSIGNED) ++# if (UINT_MAX == 0xffff) ++# define SIZEOF_UNSIGNED 2 ++# elif (UINT_MAX == LZO_0xffffffffL) ++# define SIZEOF_UNSIGNED 4 ++# elif (UINT_MAX >= LZO_0xffffffffL) ++# define SIZEOF_UNSIGNED 8 ++# else ++# error "SIZEOF_UNSIGNED" ++# endif ++#endif ++ ++#if !defined(SIZEOF_UNSIGNED_LONG) ++# if (ULONG_MAX == LZO_0xffffffffL) ++# define SIZEOF_UNSIGNED_LONG 4 ++# elif (ULONG_MAX >= LZO_0xffffffffL) ++# define SIZEOF_UNSIGNED_LONG 8 ++# else ++# error "SIZEOF_UNSIGNED_LONG" ++# endif ++#endif ++ ++#if !defined(SIZEOF_SIZE_T) ++# define SIZEOF_SIZE_T SIZEOF_UNSIGNED ++#endif ++#if !defined(SIZE_T_MAX) ++# define SIZE_T_MAX LZO_UTYPE_MAX(SIZEOF_SIZE_T) ++#endif ++ ++#if 1 && defined(__LZO_i386) && (UINT_MAX == LZO_0xffffffffL) ++# if !defined(LZO_UNALIGNED_OK_2) && (USHRT_MAX == 0xffff) ++# define LZO_UNALIGNED_OK_2 ++# endif ++# if !defined(LZO_UNALIGNED_OK_4) && (LZO_UINT32_MAX == LZO_0xffffffffL) ++# define LZO_UNALIGNED_OK_4 ++# endif ++#endif ++ ++#if defined(LZO_UNALIGNED_OK_2) || defined(LZO_UNALIGNED_OK_4) ++# if !defined(LZO_UNALIGNED_OK) ++# define LZO_UNALIGNED_OK ++# endif ++#endif ++ ++#if defined(__LZO_NO_UNALIGNED) ++# undef LZO_UNALIGNED_OK ++# undef LZO_UNALIGNED_OK_2 ++# undef LZO_UNALIGNED_OK_4 ++#endif ++ ++#if defined(LZO_UNALIGNED_OK_2) && (USHRT_MAX != 0xffff) ++# error "LZO_UNALIGNED_OK_2 must not be defined on this system" ++#endif ++#if defined(LZO_UNALIGNED_OK_4) && (LZO_UINT32_MAX != LZO_0xffffffffL) ++# error "LZO_UNALIGNED_OK_4 must not be defined on this system" ++#endif ++ ++#if defined(__LZO_NO_ALIGNED) ++# undef LZO_ALIGNED_OK_4 ++#endif ++ ++#if defined(LZO_ALIGNED_OK_4) && (LZO_UINT32_MAX != LZO_0xffffffffL) ++# error "LZO_ALIGNED_OK_4 must not be defined on this system" ++#endif ++ ++#define LZO_LITTLE_ENDIAN 1234 ++#define LZO_BIG_ENDIAN 4321 ++#define LZO_PDP_ENDIAN 3412 ++ ++#if !defined(LZO_BYTE_ORDER) ++# if defined(MFX_BYTE_ORDER) ++# define LZO_BYTE_ORDER MFX_BYTE_ORDER ++# elif defined(__LZO_i386) ++# define LZO_BYTE_ORDER LZO_LITTLE_ENDIAN ++# elif defined(BYTE_ORDER) ++# define LZO_BYTE_ORDER BYTE_ORDER ++# elif defined(__BYTE_ORDER) ++# define LZO_BYTE_ORDER __BYTE_ORDER ++# endif ++#endif ++ ++#if defined(LZO_BYTE_ORDER) ++# if (LZO_BYTE_ORDER != LZO_LITTLE_ENDIAN) && \ ++ (LZO_BYTE_ORDER != LZO_BIG_ENDIAN) ++# error "invalid LZO_BYTE_ORDER" ++# endif ++#endif ++ ++#if defined(LZO_UNALIGNED_OK) && !defined(LZO_BYTE_ORDER) ++# error "LZO_BYTE_ORDER is not defined" ++#endif ++ ++#define LZO_OPTIMIZE_GNUC_i386_IS_BUGGY ++ ++#if defined(NDEBUG) && !defined(LZO_DEBUG) && !defined(__LZO_CHECKER) ++# if defined(__GNUC__) && defined(__i386__) ++# if !defined(LZO_OPTIMIZE_GNUC_i386_IS_BUGGY) ++# define LZO_OPTIMIZE_GNUC_i386 ++# endif ++# endif ++#endif ++ ++extern const lzo_uint32 _lzo_crc32_table[256]; ++ ++#define _LZO_STRINGIZE(x) #x ++#define _LZO_MEXPAND(x) _LZO_STRINGIZE(x) ++ ++#define _LZO_CONCAT2(a,b) a ## b ++#define _LZO_CONCAT3(a,b,c) a ## b ## c ++#define _LZO_CONCAT4(a,b,c,d) a ## b ## c ## d ++#define _LZO_CONCAT5(a,b,c,d,e) a ## b ## c ## d ## e ++ ++#define _LZO_ECONCAT2(a,b) _LZO_CONCAT2(a,b) ++#define _LZO_ECONCAT3(a,b,c) _LZO_CONCAT3(a,b,c) ++#define _LZO_ECONCAT4(a,b,c,d) _LZO_CONCAT4(a,b,c,d) ++#define _LZO_ECONCAT5(a,b,c,d,e) _LZO_CONCAT5(a,b,c,d,e) ++ ++#ifndef __LZO_PTR_H ++#define __LZO_PTR_H ++ ++#if !defined(lzo_ptrdiff_t) ++# if (UINT_MAX >= LZO_0xffffffffL) ++typedef ptrdiff_t lzo_ptrdiff_t; ++# else ++typedef long lzo_ptrdiff_t; ++# endif ++#endif ++ ++#if !defined(__LZO_HAVE_PTR_T) ++# if defined(lzo_ptr_t) ++# define __LZO_HAVE_PTR_T ++# endif ++#endif ++#if !defined(__LZO_HAVE_PTR_T) ++# if defined(SIZEOF_CHAR_P) && defined(SIZEOF_UNSIGNED_LONG) ++# if (SIZEOF_CHAR_P == SIZEOF_UNSIGNED_LONG) ++typedef unsigned long lzo_ptr_t; ++typedef long lzo_sptr_t; ++# define __LZO_HAVE_PTR_T ++# endif ++# endif ++#endif ++#if !defined(__LZO_HAVE_PTR_T) ++# if defined(SIZEOF_CHAR_P) && defined(SIZEOF_UNSIGNED) ++# if (SIZEOF_CHAR_P == SIZEOF_UNSIGNED) ++typedef unsigned int lzo_ptr_t; ++typedef int lzo_sptr_t; ++# define __LZO_HAVE_PTR_T ++# endif ++# endif ++#endif ++#if !defined(__LZO_HAVE_PTR_T) ++# if defined(SIZEOF_CHAR_P) && defined(SIZEOF_UNSIGNED_SHORT) ++# if (SIZEOF_CHAR_P == SIZEOF_UNSIGNED_SHORT) ++typedef unsigned short lzo_ptr_t; ++typedef short lzo_sptr_t; ++# define __LZO_HAVE_PTR_T ++# endif ++# endif ++#endif ++#if !defined(__LZO_HAVE_PTR_T) ++# if defined(LZO_HAVE_CONFIG_H) || defined(SIZEOF_CHAR_P) ++# error "no suitable type for lzo_ptr_t" ++# else ++typedef unsigned long lzo_ptr_t; ++typedef long lzo_sptr_t; ++# define __LZO_HAVE_PTR_T ++# endif ++#endif ++ ++#define PTR(a) ((lzo_ptr_t) (a)) ++#define PTR_LINEAR(a) PTR(a) ++#define PTR_ALIGNED_4(a) ((PTR_LINEAR(a) & 3) == 0) ++#define PTR_ALIGNED_8(a) ((PTR_LINEAR(a) & 7) == 0) ++#define PTR_ALIGNED2_4(a,b) (((PTR_LINEAR(a) | PTR_LINEAR(b)) & 3) == 0) ++#define PTR_ALIGNED2_8(a,b) (((PTR_LINEAR(a) | PTR_LINEAR(b)) & 7) == 0) ++ ++#define PTR_LT(a,b) (PTR(a) < PTR(b)) ++#define PTR_GE(a,b) (PTR(a) >= PTR(b)) ++#define PTR_DIFF(a,b) ((lzo_ptrdiff_t) (PTR(a) - PTR(b))) ++#define pd(a,b) ((lzo_uint) ((a)-(b))) ++ ++typedef union { ++ char a_char; ++ unsigned char a_uchar; ++ short a_short; ++ unsigned short a_ushort; ++ int a_int; ++ unsigned int a_uint; ++ long a_long; ++ unsigned long a_ulong; ++ lzo_int a_lzo_int; ++ lzo_uint a_lzo_uint; ++ lzo_int32 a_lzo_int32; ++ lzo_uint32 a_lzo_uint32; ++ ptrdiff_t a_ptrdiff_t; ++ lzo_ptrdiff_t a_lzo_ptrdiff_t; ++ lzo_ptr_t a_lzo_ptr_t; ++ lzo_voidp a_lzo_voidp; ++ void *a_void_p; ++ lzo_bytep a_lzo_bytep; ++ lzo_bytepp a_lzo_bytepp; ++ lzo_uintp a_lzo_uintp; ++ lzo_uint *a_lzo_uint_p; ++ lzo_uint32p a_lzo_uint32p; ++ lzo_uint32 *a_lzo_uint32_p; ++ unsigned char *a_uchar_p; ++ char *a_char_p; ++} lzo_full_align_t; ++ ++#endif ++#define LZO_DETERMINISTIC ++#define LZO_DICT_USE_PTR ++# define lzo_dict_t const lzo_bytep ++# define lzo_dict_p lzo_dict_t __LZO_MMODEL * ++#if !defined(lzo_moff_t) ++#define lzo_moff_t lzo_uint ++#endif ++#endif ++static lzo_ptr_t __lzo_ptr_linear(const lzo_voidp ptr) ++{ ++ return PTR_LINEAR(ptr); ++} ++ ++static unsigned __lzo_align_gap(const lzo_voidp ptr, lzo_uint size) ++{ ++ lzo_ptr_t p, s, n; ++ ++ assert("lzo-01", size > 0); ++ ++ p = __lzo_ptr_linear(ptr); ++ s = (lzo_ptr_t) (size - 1); ++ n = (((p + s) / size) * size) - p; ++ ++ assert("lzo-02", (long)n >= 0); ++ assert("lzo-03", n <= s); ++ ++ return (unsigned)n; ++} ++ ++#ifndef __LZO_UTIL_H ++#define __LZO_UTIL_H ++ ++#ifndef __LZO_CONF_H ++#endif ++ ++#if 1 && defined(HAVE_MEMCPY) ++#define MEMCPY8_DS(dest,src,len) \ ++ memcpy(dest,src,len); \ ++ dest += len; \ ++ src += len ++#endif ++ ++#if !defined(MEMCPY8_DS) ++ ++#define MEMCPY8_DS(dest,src,len) \ ++ { register lzo_uint __l = (len) / 8; \ ++ do { \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ *dest++ = *src++; \ ++ } while (--__l > 0); } ++ ++#endif ++ ++#define MEMCPY_DS(dest,src,len) \ ++ do *dest++ = *src++; \ ++ while (--len > 0) ++ ++#define MEMMOVE_DS(dest,src,len) \ ++ do *dest++ = *src++; \ ++ while (--len > 0) ++ ++#if (LZO_UINT_MAX <= SIZE_T_MAX) && defined(HAVE_MEMSET) ++ ++#define BZERO8_PTR(s,l,n) memset((s),0,(lzo_uint)(l)*(n)) ++ ++#else ++ ++#define BZERO8_PTR(s,l,n) \ ++ lzo_memset((lzo_voidp)(s),0,(lzo_uint)(l)*(n)) ++ ++#endif ++#endif ++ ++/* If you use the LZO library in a product, you *must* keep this ++ * copyright string in the executable of your product. ++ */ ++ ++static const lzo_byte __lzo_copyright[] = ++#if !defined(__LZO_IN_MINLZO) ++ LZO_VERSION_STRING; ++#else ++ "\n\n\n" ++ "LZO real-time data compression library.\n" ++ "Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002 Markus Franz Xaver Johannes Oberhumer\n" ++ "\n" ++ "http://www.oberhumer.com/opensource/lzo/\n" ++ "\n" ++ "LZO version: v" LZO_VERSION_STRING ", " LZO_VERSION_DATE "\n" ++ "LZO build date: " __DATE__ " " __TIME__ "\n\n" ++ "LZO special compilation options:\n" ++#ifdef __cplusplus ++ " __cplusplus\n" ++#endif ++#if defined(__PIC__) ++ " __PIC__\n" ++#elif defined(__pic__) ++ " __pic__\n" ++#endif ++#if (UINT_MAX < LZO_0xffffffffL) ++ " 16BIT\n" ++#endif ++#if defined(__LZO_STRICT_16BIT) ++ " __LZO_STRICT_16BIT\n" ++#endif ++#if (UINT_MAX > LZO_0xffffffffL) ++ " UINT_MAX=" _LZO_MEXPAND(UINT_MAX) "\n" ++#endif ++#if (ULONG_MAX > LZO_0xffffffffL) ++ " ULONG_MAX=" _LZO_MEXPAND(ULONG_MAX) "\n" ++#endif ++#if defined(LZO_BYTE_ORDER) ++ " LZO_BYTE_ORDER=" _LZO_MEXPAND(LZO_BYTE_ORDER) "\n" ++#endif ++#if defined(LZO_UNALIGNED_OK_2) ++ " LZO_UNALIGNED_OK_2\n" ++#endif ++#if defined(LZO_UNALIGNED_OK_4) ++ " LZO_UNALIGNED_OK_4\n" ++#endif ++#if defined(LZO_ALIGNED_OK_4) ++ " LZO_ALIGNED_OK_4\n" ++#endif ++#if defined(LZO_DICT_USE_PTR) ++ " LZO_DICT_USE_PTR\n" ++#endif ++#if defined(__LZO_QUERY_COMPRESS) ++ " __LZO_QUERY_COMPRESS\n" ++#endif ++#if defined(__LZO_QUERY_DECOMPRESS) ++ " __LZO_QUERY_DECOMPRESS\n" ++#endif ++#if defined(__LZO_IN_MINILZO) ++ " __LZO_IN_MINILZO\n" ++#endif ++ "\n\n" "$Id: LZO " LZO_VERSION_STRING " built " __DATE__ " " __TIME__ ++#if defined(__GNUC__) && defined(__VERSION__) ++ " by gcc " __VERSION__ ++#elif defined(__BORLANDC__) ++ " by Borland C " _LZO_MEXPAND(__BORLANDC__) ++#elif defined(_MSC_VER) ++ " by Microsoft C " _LZO_MEXPAND(_MSC_VER) ++#elif defined(__PUREC__) ++ " by Pure C " _LZO_MEXPAND(__PUREC__) ++#elif defined(__SC__) ++ " by Symantec C " _LZO_MEXPAND(__SC__) ++#elif defined(__TURBOC__) ++ " by Turbo C " _LZO_MEXPAND(__TURBOC__) ++#elif defined(__WATCOMC__) ++ " by Watcom C " _LZO_MEXPAND(__WATCOMC__) ++#endif ++ " $\n" ++ "$Copyright: LZO (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002 Markus Franz Xaver Johannes Oberhumer $\n"; ++#endif ++ ++#define LZO_BASE 65521u ++#define LZO_NMAX 5552 ++ ++#define LZO_DO1(buf,i) {s1 += buf[i]; s2 += s1;} ++#define LZO_DO2(buf,i) LZO_DO1(buf,i); LZO_DO1(buf,i+1); ++#define LZO_DO4(buf,i) LZO_DO2(buf,i); LZO_DO2(buf,i+2); ++#define LZO_DO8(buf,i) LZO_DO4(buf,i); LZO_DO4(buf,i+4); ++#define LZO_DO16(buf,i) LZO_DO8(buf,i); LZO_DO8(buf,i+8); ++ ++# define IS_SIGNED(type) (((type) (-1)) < ((type) 0)) ++# define IS_UNSIGNED(type) (((type) (-1)) > ((type) 0)) ++ ++#define IS_POWER_OF_2(x) (((x) & ((x) - 1)) == 0) ++ ++static lzo_bool schedule_insns_bug(void); ++static lzo_bool strength_reduce_bug(int *); ++ ++# define __lzo_assert(x) ((x) ? 1 : 0) ++ ++#undef COMPILE_TIME_ASSERT ++ ++# define COMPILE_TIME_ASSERT(expr) LZO_COMPILE_TIME_ASSERT(expr) ++ ++static lzo_bool basic_integral_check(void) ++{ ++ lzo_bool r = 1; ++ ++ COMPILE_TIME_ASSERT(CHAR_BIT == 8); ++ COMPILE_TIME_ASSERT(sizeof(char) == 1); ++ COMPILE_TIME_ASSERT(sizeof(short) >= 2); ++ COMPILE_TIME_ASSERT(sizeof(long) >= 4); ++ COMPILE_TIME_ASSERT(sizeof(int) >= sizeof(short)); ++ COMPILE_TIME_ASSERT(sizeof(long) >= sizeof(int)); ++ ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint) == sizeof(lzo_int)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint32) == sizeof(lzo_int32)); ++ ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint32) >= 4); ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint32) >= sizeof(unsigned)); ++#if defined(__LZO_STRICT_16BIT) ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint) == 2); ++#else ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint) >= 4); ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint) >= sizeof(unsigned)); ++#endif ++ ++#if (USHRT_MAX == 65535u) ++ COMPILE_TIME_ASSERT(sizeof(short) == 2); ++#elif (USHRT_MAX == LZO_0xffffffffL) ++ COMPILE_TIME_ASSERT(sizeof(short) == 4); ++#elif (USHRT_MAX >= LZO_0xffffffffL) ++ COMPILE_TIME_ASSERT(sizeof(short) > 4); ++#endif ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(unsigned char)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(unsigned short)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(unsigned)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(unsigned long)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(short)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(int)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(long)); ++ ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(lzo_uint32)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(lzo_uint)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(lzo_int32)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(lzo_int)); ++ ++ COMPILE_TIME_ASSERT(INT_MAX == LZO_STYPE_MAX(sizeof(int))); ++ COMPILE_TIME_ASSERT(UINT_MAX == LZO_UTYPE_MAX(sizeof(unsigned))); ++ COMPILE_TIME_ASSERT(LONG_MAX == LZO_STYPE_MAX(sizeof(long))); ++ COMPILE_TIME_ASSERT(ULONG_MAX == LZO_UTYPE_MAX(sizeof(unsigned long))); ++ COMPILE_TIME_ASSERT(USHRT_MAX == LZO_UTYPE_MAX(sizeof(unsigned short))); ++ COMPILE_TIME_ASSERT(LZO_UINT32_MAX == ++ LZO_UTYPE_MAX(sizeof(lzo_uint32))); ++ COMPILE_TIME_ASSERT(LZO_UINT_MAX == LZO_UTYPE_MAX(sizeof(lzo_uint))); ++ ++ r &= __lzo_assert(LZO_BYTE(257) == 1); ++ ++ return r; ++} ++ ++static lzo_bool basic_ptr_check(void) ++{ ++ lzo_bool r = 1; ++ ++ COMPILE_TIME_ASSERT(sizeof(char *) >= sizeof(int)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_byte *) >= sizeof(char *)); ++ ++ COMPILE_TIME_ASSERT(sizeof(lzo_voidp) == sizeof(lzo_byte *)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_voidp) == sizeof(lzo_voidpp)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_voidp) == sizeof(lzo_bytepp)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_voidp) >= sizeof(lzo_uint)); ++ ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptr_t) == sizeof(lzo_voidp)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptr_t) == sizeof(lzo_sptr_t)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptr_t) >= sizeof(lzo_uint)); ++ ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptrdiff_t) >= 4); ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptrdiff_t) >= sizeof(ptrdiff_t)); ++ ++ COMPILE_TIME_ASSERT(sizeof(ptrdiff_t) >= sizeof(size_t)); ++ COMPILE_TIME_ASSERT(sizeof(lzo_ptrdiff_t) >= sizeof(lzo_uint)); ++ ++#if defined(SIZEOF_CHAR_P) ++ COMPILE_TIME_ASSERT(SIZEOF_CHAR_P == sizeof(char *)); ++#endif ++#if defined(SIZEOF_PTRDIFF_T) ++ COMPILE_TIME_ASSERT(SIZEOF_PTRDIFF_T == sizeof(ptrdiff_t)); ++#endif ++ ++ COMPILE_TIME_ASSERT(IS_SIGNED(ptrdiff_t)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(size_t)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(lzo_ptrdiff_t)); ++ COMPILE_TIME_ASSERT(IS_SIGNED(lzo_sptr_t)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(lzo_ptr_t)); ++ COMPILE_TIME_ASSERT(IS_UNSIGNED(lzo_moff_t)); ++ ++ return r; ++} ++ ++static lzo_bool ptr_check(void) ++{ ++ lzo_bool r = 1; ++ int i; ++ char _wrkmem[10 * sizeof(lzo_byte *) + sizeof(lzo_full_align_t)]; ++ lzo_bytep wrkmem; ++ lzo_bytepp dict; ++ unsigned char x[4 * sizeof(lzo_full_align_t)]; ++ long d; ++ lzo_full_align_t a; ++ lzo_full_align_t u; ++ ++ for (i = 0; i < (int)sizeof(x); i++) ++ x[i] = LZO_BYTE(i); ++ ++ wrkmem = ++ LZO_PTR_ALIGN_UP((lzo_byte *) _wrkmem, sizeof(lzo_full_align_t)); ++ ++ u.a_lzo_bytep = wrkmem; ++ dict = u.a_lzo_bytepp; ++ ++ d = (long)((const lzo_bytep)dict - (const lzo_bytep)_wrkmem); ++ r &= __lzo_assert(d >= 0); ++ r &= __lzo_assert(d < (long)sizeof(lzo_full_align_t)); ++ ++ memset(&a, 0, sizeof(a)); ++ r &= __lzo_assert(a.a_lzo_voidp == NULL); ++ ++ memset(&a, 0xff, sizeof(a)); ++ r &= __lzo_assert(a.a_ushort == USHRT_MAX); ++ r &= __lzo_assert(a.a_uint == UINT_MAX); ++ r &= __lzo_assert(a.a_ulong == ULONG_MAX); ++ r &= __lzo_assert(a.a_lzo_uint == LZO_UINT_MAX); ++ r &= __lzo_assert(a.a_lzo_uint32 == LZO_UINT32_MAX); ++ ++ if (r == 1) { ++ for (i = 0; i < 8; i++) ++ r &= __lzo_assert((const lzo_voidp)(&dict[i]) == ++ (const ++ lzo_voidp)(&wrkmem[i * ++ sizeof(lzo_byte ++ *)])); ++ } ++ ++ memset(&a, 0, sizeof(a)); ++ r &= __lzo_assert(a.a_char_p == NULL); ++ r &= __lzo_assert(a.a_lzo_bytep == NULL); ++ r &= __lzo_assert(NULL == (void *)0); ++ if (r == 1) { ++ for (i = 0; i < 10; i++) ++ dict[i] = wrkmem; ++ BZERO8_PTR(dict + 1, sizeof(dict[0]), 8); ++ r &= __lzo_assert(dict[0] == wrkmem); ++ for (i = 1; i < 9; i++) ++ r &= __lzo_assert(dict[i] == NULL); ++ r &= __lzo_assert(dict[9] == wrkmem); ++ } ++ ++ if (r == 1) { ++ unsigned k = 1; ++ const unsigned n = (unsigned)sizeof(lzo_uint32); ++ lzo_byte *p0; ++ lzo_byte *p1; ++ ++ k += __lzo_align_gap(&x[k], n); ++ p0 = (lzo_bytep) & x[k]; ++#if defined(PTR_LINEAR) ++ r &= __lzo_assert((PTR_LINEAR(p0) & (n - 1)) == 0); ++#else ++ r &= __lzo_assert(n == 4); ++ r &= __lzo_assert(PTR_ALIGNED_4(p0)); ++#endif ++ ++ r &= __lzo_assert(k >= 1); ++ p1 = (lzo_bytep) & x[1]; ++ r &= __lzo_assert(PTR_GE(p0, p1)); ++ ++ r &= __lzo_assert(k < 1 + n); ++ p1 = (lzo_bytep) & x[1 + n]; ++ r &= __lzo_assert(PTR_LT(p0, p1)); ++ ++ if (r == 1) { ++ lzo_uint32 v0, v1; ++ ++ u.a_uchar_p = &x[k]; ++ v0 = *u.a_lzo_uint32_p; ++ u.a_uchar_p = &x[k + n]; ++ v1 = *u.a_lzo_uint32_p; ++ ++ r &= __lzo_assert(v0 > 0); ++ r &= __lzo_assert(v1 > 0); ++ } ++ } ++ ++ return r; ++} ++ ++static int _lzo_config_check(void) ++{ ++ lzo_bool r = 1; ++ int i; ++ union { ++ lzo_uint32 a; ++ unsigned short b; ++ lzo_uint32 aa[4]; ++ unsigned char x[4 * sizeof(lzo_full_align_t)]; ++ } u; ++ ++ COMPILE_TIME_ASSERT((int)((unsigned char)((signed char)-1)) == 255); ++ COMPILE_TIME_ASSERT((((unsigned char)128) << (int)(8 * sizeof(int) - 8)) ++ < 0); ++ ++ r &= basic_integral_check(); ++ r &= basic_ptr_check(); ++ if (r != 1) ++ return LZO_E_ERROR; ++ ++ u.a = 0; ++ u.b = 0; ++ for (i = 0; i < (int)sizeof(u.x); i++) ++ u.x[i] = LZO_BYTE(i); ++ ++#if defined(LZO_BYTE_ORDER) ++ if (r == 1) { ++# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN) ++ lzo_uint32 a = (lzo_uint32) (u.a & LZO_0xffffffffL); ++ unsigned short b = (unsigned short)(u.b & 0xffff); ++ r &= __lzo_assert(a == 0x03020100L); ++ r &= __lzo_assert(b == 0x0100); ++# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN) ++ lzo_uint32 a = u.a >> (8 * sizeof(u.a) - 32); ++ unsigned short b = u.b >> (8 * sizeof(u.b) - 16); ++ r &= __lzo_assert(a == 0x00010203L); ++ r &= __lzo_assert(b == 0x0001); ++# else ++# error "invalid LZO_BYTE_ORDER" ++# endif ++ } ++#endif ++ ++#if defined(LZO_UNALIGNED_OK_2) ++ COMPILE_TIME_ASSERT(sizeof(short) == 2); ++ if (r == 1) { ++ unsigned short b[4]; ++ ++ for (i = 0; i < 4; i++) ++ b[i] = *(const unsigned short *)&u.x[i]; ++ ++# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN) ++ r &= __lzo_assert(b[0] == 0x0100); ++ r &= __lzo_assert(b[1] == 0x0201); ++ r &= __lzo_assert(b[2] == 0x0302); ++ r &= __lzo_assert(b[3] == 0x0403); ++# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN) ++ r &= __lzo_assert(b[0] == 0x0001); ++ r &= __lzo_assert(b[1] == 0x0102); ++ r &= __lzo_assert(b[2] == 0x0203); ++ r &= __lzo_assert(b[3] == 0x0304); ++# endif ++ } ++#endif ++ ++#if defined(LZO_UNALIGNED_OK_4) ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint32) == 4); ++ if (r == 1) { ++ lzo_uint32 a[4]; ++ ++ for (i = 0; i < 4; i++) ++ a[i] = *(const lzo_uint32 *)&u.x[i]; ++ ++# if (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN) ++ r &= __lzo_assert(a[0] == 0x03020100L); ++ r &= __lzo_assert(a[1] == 0x04030201L); ++ r &= __lzo_assert(a[2] == 0x05040302L); ++ r &= __lzo_assert(a[3] == 0x06050403L); ++# elif (LZO_BYTE_ORDER == LZO_BIG_ENDIAN) ++ r &= __lzo_assert(a[0] == 0x00010203L); ++ r &= __lzo_assert(a[1] == 0x01020304L); ++ r &= __lzo_assert(a[2] == 0x02030405L); ++ r &= __lzo_assert(a[3] == 0x03040506L); ++# endif ++ } ++#endif ++ ++#if defined(LZO_ALIGNED_OK_4) ++ COMPILE_TIME_ASSERT(sizeof(lzo_uint32) == 4); ++#endif ++ ++ COMPILE_TIME_ASSERT(lzo_sizeof_dict_t == sizeof(lzo_dict_t)); ++ ++ if (r == 1) { ++ r &= __lzo_assert(!schedule_insns_bug()); ++ } ++ ++ if (r == 1) { ++ static int x[3]; ++ static unsigned xn = 3; ++ register unsigned j; ++ ++ for (j = 0; j < xn; j++) ++ x[j] = (int)j - 3; ++ r &= __lzo_assert(!strength_reduce_bug(x)); ++ } ++ ++ if (r == 1) { ++ r &= ptr_check(); ++ } ++ ++ return r == 1 ? LZO_E_OK : LZO_E_ERROR; ++} ++ ++static lzo_bool schedule_insns_bug(void) ++{ ++#if defined(__LZO_CHECKER) ++ return 0; ++#else ++ const int clone[] = { 1, 2, 0 }; ++ const int *q; ++ q = clone; ++ return (*q) ? 0 : 1; ++#endif ++} ++ ++static lzo_bool strength_reduce_bug(int *x) ++{ ++ return x[0] != -3 || x[1] != -2 || x[2] != -1; ++} ++ ++#undef COMPILE_TIME_ASSERT ++ ++int __lzo_init2(unsigned v, int s1, int s2, int s3, int s4, int s5, ++ int s6, int s7, int s8, int s9) ++{ ++ int r; ++ ++ if (v == 0) ++ return LZO_E_ERROR; ++ ++ r = (s1 == -1 || s1 == (int)sizeof(short)) && ++ (s2 == -1 || s2 == (int)sizeof(int)) && ++ (s3 == -1 || s3 == (int)sizeof(long)) && ++ (s4 == -1 || s4 == (int)sizeof(lzo_uint32)) && ++ (s5 == -1 || s5 == (int)sizeof(lzo_uint)) && ++ (s6 == -1 || s6 == (int)lzo_sizeof_dict_t) && ++ (s7 == -1 || s7 == (int)sizeof(char *)) && ++ (s8 == -1 || s8 == (int)sizeof(lzo_voidp)) && ++ (s9 == -1 || s9 == (int)sizeof(lzo_compress_t)); ++ if (!r) ++ return LZO_E_ERROR; ++ ++ r = _lzo_config_check(); ++ if (r != LZO_E_OK) ++ return r; ++ ++ return r; ++} ++ ++#define do_compress _lzo1x_1_do_compress ++ ++#define LZO_NEED_DICT_H ++#define D_BITS 14 ++#define D_INDEX1(d,p) d = DM((0x21*DX3(p,5,5,6)) >> 5) ++#define D_INDEX2(d,p) d = (d & (D_MASK & 0x7ff)) ^ (D_HIGH | 0x1f) ++ ++#ifndef __LZO_CONFIG1X_H ++#define __LZO_CONFIG1X_H ++ ++#if !defined(LZO1X) && !defined(LZO1Y) && !defined(LZO1Z) ++# define LZO1X ++#endif ++ ++#define LZO_EOF_CODE ++#undef LZO_DETERMINISTIC ++ ++#define M1_MAX_OFFSET 0x0400 ++#ifndef M2_MAX_OFFSET ++#define M2_MAX_OFFSET 0x0800 ++#endif ++#define M3_MAX_OFFSET 0x4000 ++#define M4_MAX_OFFSET 0xbfff ++ ++#define MX_MAX_OFFSET (M1_MAX_OFFSET + M2_MAX_OFFSET) ++ ++#define M1_MIN_LEN 2 ++#define M1_MAX_LEN 2 ++#define M2_MIN_LEN 3 ++#ifndef M2_MAX_LEN ++#define M2_MAX_LEN 8 ++#endif ++#define M3_MIN_LEN 3 ++#define M3_MAX_LEN 33 ++#define M4_MIN_LEN 3 ++#define M4_MAX_LEN 9 ++ ++#define M1_MARKER 0 ++#define M2_MARKER 64 ++#define M3_MARKER 32 ++#define M4_MARKER 16 ++ ++#ifndef MIN_LOOKAHEAD ++#define MIN_LOOKAHEAD (M2_MAX_LEN + 1) ++#endif ++ ++#if defined(LZO_NEED_DICT_H) ++ ++#ifndef LZO_HASH ++#define LZO_HASH LZO_HASH_LZO_INCREMENTAL_B ++#endif ++#define DL_MIN_LEN M2_MIN_LEN ++ ++#ifndef __LZO_DICT_H ++#define __LZO_DICT_H ++ ++#if !defined(D_BITS) && defined(DBITS) ++# define D_BITS DBITS ++#endif ++#if !defined(D_BITS) ++# error "D_BITS is not defined" ++#endif ++#if (D_BITS < 16) ++# define D_SIZE LZO_SIZE(D_BITS) ++# define D_MASK LZO_MASK(D_BITS) ++#else ++# define D_SIZE LZO_USIZE(D_BITS) ++# define D_MASK LZO_UMASK(D_BITS) ++#endif ++#define D_HIGH ((D_MASK >> 1) + 1) ++ ++#if !defined(DD_BITS) ++# define DD_BITS 0 ++#endif ++#define DD_SIZE LZO_SIZE(DD_BITS) ++#define DD_MASK LZO_MASK(DD_BITS) ++ ++#if !defined(DL_BITS) ++# define DL_BITS (D_BITS - DD_BITS) ++#endif ++#if (DL_BITS < 16) ++# define DL_SIZE LZO_SIZE(DL_BITS) ++# define DL_MASK LZO_MASK(DL_BITS) ++#else ++# define DL_SIZE LZO_USIZE(DL_BITS) ++# define DL_MASK LZO_UMASK(DL_BITS) ++#endif ++ ++#if (D_BITS != DL_BITS + DD_BITS) ++# error "D_BITS does not match" ++#endif ++#if (D_BITS < 8 || D_BITS > 18) ++# error "invalid D_BITS" ++#endif ++#if (DL_BITS < 8 || DL_BITS > 20) ++# error "invalid DL_BITS" ++#endif ++#if (DD_BITS < 0 || DD_BITS > 6) ++# error "invalid DD_BITS" ++#endif ++ ++#if !defined(DL_MIN_LEN) ++# define DL_MIN_LEN 3 ++#endif ++#if !defined(DL_SHIFT) ++# define DL_SHIFT ((DL_BITS + (DL_MIN_LEN - 1)) / DL_MIN_LEN) ++#endif ++ ++#define LZO_HASH_GZIP 1 ++#define LZO_HASH_GZIP_INCREMENTAL 2 ++#define LZO_HASH_LZO_INCREMENTAL_A 3 ++#define LZO_HASH_LZO_INCREMENTAL_B 4 ++ ++#if !defined(LZO_HASH) ++# error "choose a hashing strategy" ++#endif ++ ++#if (DL_MIN_LEN == 3) ++# define _DV2_A(p,shift1,shift2) \ ++ (((( (lzo_uint32)((p)[0]) << shift1) ^ (p)[1]) << shift2) ^ (p)[2]) ++# define _DV2_B(p,shift1,shift2) \ ++ (((( (lzo_uint32)((p)[2]) << shift1) ^ (p)[1]) << shift2) ^ (p)[0]) ++# define _DV3_B(p,shift1,shift2,shift3) \ ++ ((_DV2_B((p)+1,shift1,shift2) << (shift3)) ^ (p)[0]) ++#elif (DL_MIN_LEN == 2) ++# define _DV2_A(p,shift1,shift2) \ ++ (( (lzo_uint32)(p[0]) << shift1) ^ p[1]) ++# define _DV2_B(p,shift1,shift2) \ ++ (( (lzo_uint32)(p[1]) << shift1) ^ p[2]) ++#else ++# error "invalid DL_MIN_LEN" ++#endif ++#define _DV_A(p,shift) _DV2_A(p,shift,shift) ++#define _DV_B(p,shift) _DV2_B(p,shift,shift) ++#define DA2(p,s1,s2) \ ++ (((((lzo_uint32)((p)[2]) << (s2)) + (p)[1]) << (s1)) + (p)[0]) ++#define DS2(p,s1,s2) \ ++ (((((lzo_uint32)((p)[2]) << (s2)) - (p)[1]) << (s1)) - (p)[0]) ++#define DX2(p,s1,s2) \ ++ (((((lzo_uint32)((p)[2]) << (s2)) ^ (p)[1]) << (s1)) ^ (p)[0]) ++#define DA3(p,s1,s2,s3) ((DA2((p)+1,s2,s3) << (s1)) + (p)[0]) ++#define DS3(p,s1,s2,s3) ((DS2((p)+1,s2,s3) << (s1)) - (p)[0]) ++#define DX3(p,s1,s2,s3) ((DX2((p)+1,s2,s3) << (s1)) ^ (p)[0]) ++#define DMS(v,s) ((lzo_uint) (((v) & (D_MASK >> (s))) << (s))) ++#define DM(v) DMS(v,0) ++ ++#if (LZO_HASH == LZO_HASH_GZIP) ++# define _DINDEX(dv,p) (_DV_A((p),DL_SHIFT)) ++ ++#elif (LZO_HASH == LZO_HASH_GZIP_INCREMENTAL) ++# define __LZO_HASH_INCREMENTAL ++# define DVAL_FIRST(dv,p) dv = _DV_A((p),DL_SHIFT) ++# define DVAL_NEXT(dv,p) dv = (((dv) << DL_SHIFT) ^ p[2]) ++# define _DINDEX(dv,p) (dv) ++# define DVAL_LOOKAHEAD DL_MIN_LEN ++ ++#elif (LZO_HASH == LZO_HASH_LZO_INCREMENTAL_A) ++# define __LZO_HASH_INCREMENTAL ++# define DVAL_FIRST(dv,p) dv = _DV_A((p),5) ++# define DVAL_NEXT(dv,p) \ ++ dv ^= (lzo_uint32)(p[-1]) << (2*5); dv = (((dv) << 5) ^ p[2]) ++# define _DINDEX(dv,p) ((0x9f5f * (dv)) >> 5) ++# define DVAL_LOOKAHEAD DL_MIN_LEN ++ ++#elif (LZO_HASH == LZO_HASH_LZO_INCREMENTAL_B) ++# define __LZO_HASH_INCREMENTAL ++# define DVAL_FIRST(dv,p) dv = _DV_B((p),5) ++# define DVAL_NEXT(dv,p) \ ++ dv ^= p[-1]; dv = (((dv) >> 5) ^ ((lzo_uint32)(p[2]) << (2*5))) ++# define _DINDEX(dv,p) ((0x9f5f * (dv)) >> 5) ++# define DVAL_LOOKAHEAD DL_MIN_LEN ++ ++#else ++# error "choose a hashing strategy" ++#endif ++ ++#ifndef DINDEX ++#define DINDEX(dv,p) ((lzo_uint)((_DINDEX(dv,p)) & DL_MASK) << DD_BITS) ++#endif ++#if !defined(DINDEX1) && defined(D_INDEX1) ++#define DINDEX1 D_INDEX1 ++#endif ++#if !defined(DINDEX2) && defined(D_INDEX2) ++#define DINDEX2 D_INDEX2 ++#endif ++ ++#if !defined(__LZO_HASH_INCREMENTAL) ++# define DVAL_FIRST(dv,p) ((void) 0) ++# define DVAL_NEXT(dv,p) ((void) 0) ++# define DVAL_LOOKAHEAD 0 ++#endif ++ ++#if !defined(DVAL_ASSERT) ++#if defined(__LZO_HASH_INCREMENTAL) && !defined(NDEBUG) ++static void DVAL_ASSERT(lzo_uint32 dv, const lzo_byte * p) ++{ ++ lzo_uint32 df; ++ DVAL_FIRST(df, (p)); ++ assert(DINDEX(dv, p) == DINDEX(df, p)); ++} ++#else ++# define DVAL_ASSERT(dv,p) ((void) 0) ++#endif ++#endif ++ ++# define DENTRY(p,in) (p) ++# define GINDEX(m_pos,m_off,dict,dindex,in) m_pos = dict[dindex] ++ ++#if (DD_BITS == 0) ++ ++# define UPDATE_D(dict,drun,dv,p,in) dict[ DINDEX(dv,p) ] = DENTRY(p,in) ++# define UPDATE_I(dict,drun,index,p,in) dict[index] = DENTRY(p,in) ++# define UPDATE_P(ptr,drun,p,in) (ptr)[0] = DENTRY(p,in) ++ ++#else ++ ++# define UPDATE_D(dict,drun,dv,p,in) \ ++ dict[ DINDEX(dv,p) + drun++ ] = DENTRY(p,in); drun &= DD_MASK ++# define UPDATE_I(dict,drun,index,p,in) \ ++ dict[ (index) + drun++ ] = DENTRY(p,in); drun &= DD_MASK ++# define UPDATE_P(ptr,drun,p,in) \ ++ (ptr) [ drun++ ] = DENTRY(p,in); drun &= DD_MASK ++ ++#endif ++ ++#define LZO_CHECK_MPOS_DET(m_pos,m_off,in,ip,max_offset) \ ++ (m_pos == NULL || (m_off = (lzo_moff_t) (ip - m_pos)) > max_offset) ++ ++#define LZO_CHECK_MPOS_NON_DET(m_pos,m_off,in,ip,max_offset) \ ++ (BOUNDS_CHECKING_OFF_IN_EXPR( \ ++ (PTR_LT(m_pos,in) || \ ++ (m_off = (lzo_moff_t) PTR_DIFF(ip,m_pos)) <= 0 || \ ++ m_off > max_offset) )) ++ ++#if defined(LZO_DETERMINISTIC) ++# define LZO_CHECK_MPOS LZO_CHECK_MPOS_DET ++#else ++# define LZO_CHECK_MPOS LZO_CHECK_MPOS_NON_DET ++#endif ++#endif ++#endif ++#endif ++#define DO_COMPRESS lzo1x_1_compress ++static ++lzo_uint do_compress(const lzo_byte * in, lzo_uint in_len, ++ lzo_byte * out, lzo_uintp out_len, lzo_voidp wrkmem) ++{ ++ register const lzo_byte *ip; ++ lzo_byte *op; ++ const lzo_byte *const in_end = in + in_len; ++ const lzo_byte *const ip_end = in + in_len - M2_MAX_LEN - 5; ++ const lzo_byte *ii; ++ lzo_dict_p const dict = (lzo_dict_p) wrkmem; ++ ++ op = out; ++ ip = in; ++ ii = ip; ++ ++ ip += 4; ++ for (;;) { ++ register const lzo_byte *m_pos; ++ ++ lzo_moff_t m_off; ++ lzo_uint m_len; ++ lzo_uint dindex; ++ ++ DINDEX1(dindex, ip); ++ GINDEX(m_pos, m_off, dict, dindex, in); ++ if (LZO_CHECK_MPOS_NON_DET(m_pos, m_off, in, ip, M4_MAX_OFFSET)) ++ goto literal; ++#if 1 ++ if (m_off <= M2_MAX_OFFSET || m_pos[3] == ip[3]) ++ goto try_match; ++ DINDEX2(dindex, ip); ++#endif ++ GINDEX(m_pos, m_off, dict, dindex, in); ++ if (LZO_CHECK_MPOS_NON_DET(m_pos, m_off, in, ip, M4_MAX_OFFSET)) ++ goto literal; ++ if (m_off <= M2_MAX_OFFSET || m_pos[3] == ip[3]) ++ goto try_match; ++ goto literal; ++ ++ try_match: ++#if 1 && defined(LZO_UNALIGNED_OK_2) ++ if (*(const lzo_ushortp)m_pos != *(const lzo_ushortp)ip) { ++#else ++ if (m_pos[0] != ip[0] || m_pos[1] != ip[1]) { ++#endif ++ ; ++ } else { ++ if (m_pos[2] == ip[2]) { ++ goto match; ++ } else { ++ ; ++ } ++ } ++ ++ literal: ++ UPDATE_I(dict, 0, dindex, ip, in); ++ ++ip; ++ if (ip >= ip_end) ++ break; ++ continue; ++ ++ match: ++ UPDATE_I(dict, 0, dindex, ip, in); ++ if (pd(ip, ii) > 0) { ++ register lzo_uint t = pd(ip, ii); ++ ++ if (t <= 3) { ++ assert("lzo-04", op - 2 > out); ++ op[-2] |= LZO_BYTE(t); ++ } else if (t <= 18) ++ *op++ = LZO_BYTE(t - 3); ++ else { ++ register lzo_uint tt = t - 18; ++ ++ *op++ = 0; ++ while (tt > 255) { ++ tt -= 255; ++ *op++ = 0; ++ } ++ assert("lzo-05", tt > 0); ++ *op++ = LZO_BYTE(tt); ++ } ++ do ++ *op++ = *ii++; ++ while (--t > 0); ++ } ++ ++ assert("lzo-06", ii == ip); ++ ip += 3; ++ if (m_pos[3] != *ip++ || m_pos[4] != *ip++ || m_pos[5] != *ip++ ++ || m_pos[6] != *ip++ || m_pos[7] != *ip++ ++ || m_pos[8] != *ip++ ++#ifdef LZO1Y ++ || m_pos[9] != *ip++ || m_pos[10] != *ip++ ++ || m_pos[11] != *ip++ || m_pos[12] != *ip++ ++ || m_pos[13] != *ip++ || m_pos[14] != *ip++ ++#endif ++ ) { ++ --ip; ++ m_len = ip - ii; ++ assert("lzo-07", m_len >= 3); ++ assert("lzo-08", m_len <= M2_MAX_LEN); ++ ++ if (m_off <= M2_MAX_OFFSET) { ++ m_off -= 1; ++#if defined(LZO1X) ++ *op++ = ++ LZO_BYTE(((m_len - ++ 1) << 5) | ((m_off & 7) << 2)); ++ *op++ = LZO_BYTE(m_off >> 3); ++#elif defined(LZO1Y) ++ *op++ = ++ LZO_BYTE(((m_len + ++ 1) << 4) | ((m_off & 3) << 2)); ++ *op++ = LZO_BYTE(m_off >> 2); ++#endif ++ } else if (m_off <= M3_MAX_OFFSET) { ++ m_off -= 1; ++ *op++ = LZO_BYTE(M3_MARKER | (m_len - 2)); ++ goto m3_m4_offset; ++ } else ++#if defined(LZO1X) ++ { ++ m_off -= 0x4000; ++ assert("lzo-09", m_off > 0); ++ assert("lzo-10", m_off <= 0x7fff); ++ *op++ = LZO_BYTE(M4_MARKER | ++ ((m_off & 0x4000) >> 11) | ++ (m_len - 2)); ++ goto m3_m4_offset; ++ } ++#elif defined(LZO1Y) ++ goto m4_match; ++#endif ++ } else { ++ { ++ const lzo_byte *end = in_end; ++ const lzo_byte *m = m_pos + M2_MAX_LEN + 1; ++ while (ip < end && *m == *ip) ++ m++, ip++; ++ m_len = (ip - ii); ++ } ++ assert("lzo-11", m_len > M2_MAX_LEN); ++ ++ if (m_off <= M3_MAX_OFFSET) { ++ m_off -= 1; ++ if (m_len <= 33) ++ *op++ = ++ LZO_BYTE(M3_MARKER | (m_len - 2)); ++ else { ++ m_len -= 33; ++ *op++ = M3_MARKER | 0; ++ goto m3_m4_len; ++ } ++ } else { ++#if defined(LZO1Y) ++ m4_match: ++#endif ++ m_off -= 0x4000; ++ assert("lzo-12", m_off > 0); ++ assert("lzo-13", m_off <= 0x7fff); ++ if (m_len <= M4_MAX_LEN) ++ *op++ = LZO_BYTE(M4_MARKER | ++ ((m_off & 0x4000) >> ++ 11) | (m_len - 2)); ++ else { ++ m_len -= M4_MAX_LEN; ++ *op++ = ++ LZO_BYTE(M4_MARKER | ++ ((m_off & 0x4000) >> 11)); ++ m3_m4_len: ++ while (m_len > 255) { ++ m_len -= 255; ++ *op++ = 0; ++ } ++ assert("lzo-14", m_len > 0); ++ *op++ = LZO_BYTE(m_len); ++ } ++ } ++ ++ m3_m4_offset: ++ *op++ = LZO_BYTE((m_off & 63) << 2); ++ *op++ = LZO_BYTE(m_off >> 6); ++ } ++ ++ ii = ip; ++ if (ip >= ip_end) ++ break; ++ } ++ ++ *out_len = op - out; ++ return pd(in_end, ii); ++} ++ ++int DO_COMPRESS(const lzo_byte * in, lzo_uint in_len, ++ lzo_byte * out, lzo_uintp out_len, lzo_voidp wrkmem) ++{ ++ lzo_byte *op = out; ++ lzo_uint t; ++ ++#if defined(__LZO_QUERY_COMPRESS) ++ if (__LZO_IS_COMPRESS_QUERY(in, in_len, out, out_len, wrkmem)) ++ return __LZO_QUERY_COMPRESS(in, in_len, out, out_len, wrkmem, ++ D_SIZE, lzo_sizeof(lzo_dict_t)); ++#endif ++ ++ if (in_len <= M2_MAX_LEN + 5) ++ t = in_len; ++ else { ++ t = do_compress(in, in_len, op, out_len, wrkmem); ++ op += *out_len; ++ } ++ ++ if (t > 0) { ++ const lzo_byte *ii = in + in_len - t; ++ ++ if (op == out && t <= 238) ++ *op++ = LZO_BYTE(17 + t); ++ else if (t <= 3) ++ op[-2] |= LZO_BYTE(t); ++ else if (t <= 18) ++ *op++ = LZO_BYTE(t - 3); ++ else { ++ lzo_uint tt = t - 18; ++ ++ *op++ = 0; ++ while (tt > 255) { ++ tt -= 255; ++ *op++ = 0; ++ } ++ assert("lzo-15", tt > 0); ++ *op++ = LZO_BYTE(tt); ++ } ++ do ++ *op++ = *ii++; ++ while (--t > 0); ++ } ++ ++ *op++ = M4_MARKER | 1; ++ *op++ = 0; ++ *op++ = 0; ++ ++ *out_len = op - out; ++ return LZO_E_OK; ++} ++ ++#undef do_compress ++#undef DO_COMPRESS ++#undef LZO_HASH ++ ++#undef LZO_TEST_DECOMPRESS_OVERRUN ++#undef LZO_TEST_DECOMPRESS_OVERRUN_INPUT ++#undef LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT ++#undef LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND ++#undef DO_DECOMPRESS ++#define DO_DECOMPRESS lzo1x_decompress ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN) ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_INPUT) ++# define LZO_TEST_DECOMPRESS_OVERRUN_INPUT 2 ++# endif ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT) ++# define LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT 2 ++# endif ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND) ++# define LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND ++# endif ++#endif ++ ++#undef TEST_IP ++#undef TEST_OP ++#undef TEST_LOOKBEHIND ++#undef NEED_IP ++#undef NEED_OP ++#undef HAVE_TEST_IP ++#undef HAVE_TEST_OP ++#undef HAVE_NEED_IP ++#undef HAVE_NEED_OP ++#undef HAVE_ANY_IP ++#undef HAVE_ANY_OP ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_INPUT) ++# if (LZO_TEST_DECOMPRESS_OVERRUN_INPUT >= 1) ++# define TEST_IP (ip < ip_end) ++# endif ++# if (LZO_TEST_DECOMPRESS_OVERRUN_INPUT >= 2) ++# define NEED_IP(x) \ ++ if ((lzo_uint)(ip_end - ip) < (lzo_uint)(x)) goto input_overrun ++# endif ++#endif ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT) ++# if (LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT >= 1) ++# define TEST_OP (op <= op_end) ++# endif ++# if (LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT >= 2) ++# undef TEST_OP ++# define NEED_OP(x) \ ++ if ((lzo_uint)(op_end - op) < (lzo_uint)(x)) goto output_overrun ++# endif ++#endif ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND) ++# define TEST_LOOKBEHIND(m_pos,out) if (m_pos < out) goto lookbehind_overrun ++#else ++# define TEST_LOOKBEHIND(m_pos,op) ((void) 0) ++#endif ++ ++#if !defined(LZO_EOF_CODE) && !defined(TEST_IP) ++# define TEST_IP (ip < ip_end) ++#endif ++ ++#if defined(TEST_IP) ++# define HAVE_TEST_IP ++#else ++# define TEST_IP 1 ++#endif ++#if defined(TEST_OP) ++# define HAVE_TEST_OP ++#else ++# define TEST_OP 1 ++#endif ++ ++#if defined(NEED_IP) ++# define HAVE_NEED_IP ++#else ++# define NEED_IP(x) ((void) 0) ++#endif ++#if defined(NEED_OP) ++# define HAVE_NEED_OP ++#else ++# define NEED_OP(x) ((void) 0) ++#endif ++ ++#if defined(HAVE_TEST_IP) || defined(HAVE_NEED_IP) ++# define HAVE_ANY_IP ++#endif ++#if defined(HAVE_TEST_OP) || defined(HAVE_NEED_OP) ++# define HAVE_ANY_OP ++#endif ++ ++#undef __COPY4 ++#define __COPY4(dst,src) * (lzo_uint32p)(dst) = * (const lzo_uint32p)(src) ++ ++#undef COPY4 ++#if defined(LZO_UNALIGNED_OK_4) ++# define COPY4(dst,src) __COPY4(dst,src) ++#elif defined(LZO_ALIGNED_OK_4) ++# define COPY4(dst,src) __COPY4((lzo_ptr_t)(dst),(lzo_ptr_t)(src)) ++#endif ++ ++#if defined(DO_DECOMPRESS) ++int DO_DECOMPRESS(const lzo_byte * in, lzo_uint in_len, ++ lzo_byte * out, lzo_uintp out_len, lzo_voidp wrkmem) ++#endif ++{ ++ register lzo_byte *op; ++ register const lzo_byte *ip; ++ register lzo_uint t; ++#if defined(COPY_DICT) ++ lzo_uint m_off; ++ const lzo_byte *dict_end; ++#else ++ register const lzo_byte *m_pos; ++#endif ++ ++ const lzo_byte *const ip_end = in + in_len; ++#if defined(HAVE_ANY_OP) ++ lzo_byte *const op_end = out + *out_len; ++#endif ++#if defined(LZO1Z) ++ lzo_uint last_m_off = 0; ++#endif ++ ++ LZO_UNUSED(wrkmem); ++ ++#if defined(__LZO_QUERY_DECOMPRESS) ++ if (__LZO_IS_DECOMPRESS_QUERY(in, in_len, out, out_len, wrkmem)) ++ return __LZO_QUERY_DECOMPRESS(in, in_len, out, out_len, wrkmem, ++ 0, 0); ++#endif ++ ++#if defined(COPY_DICT) ++ if (dict) { ++ if (dict_len > M4_MAX_OFFSET) { ++ dict += dict_len - M4_MAX_OFFSET; ++ dict_len = M4_MAX_OFFSET; ++ } ++ dict_end = dict + dict_len; ++ } else { ++ dict_len = 0; ++ dict_end = NULL; ++ } ++#endif ++ ++ *out_len = 0; ++ ++ op = out; ++ ip = in; ++ ++ if (*ip > 17) { ++ t = *ip++ - 17; ++ if (t < 4) ++ goto match_next; ++ assert("lzo-16", t > 0); ++ NEED_OP(t); ++ NEED_IP(t + 1); ++ do ++ *op++ = *ip++; ++ while (--t > 0); ++ goto first_literal_run; ++ } ++ ++ while (TEST_IP && TEST_OP) { ++ t = *ip++; ++ if (t >= 16) ++ goto match; ++ if (t == 0) { ++ NEED_IP(1); ++ while (*ip == 0) { ++ t += 255; ++ ip++; ++ NEED_IP(1); ++ } ++ t += 15 + *ip++; ++ } ++ assert("lzo-17", t > 0); ++ NEED_OP(t + 3); ++ NEED_IP(t + 4); ++#if defined(LZO_UNALIGNED_OK_4) || defined(LZO_ALIGNED_OK_4) ++#if !defined(LZO_UNALIGNED_OK_4) ++ if (PTR_ALIGNED2_4(op, ip)) { ++#endif ++ COPY4(op, ip); ++ op += 4; ++ ip += 4; ++ if (--t > 0) { ++ if (t >= 4) { ++ do { ++ COPY4(op, ip); ++ op += 4; ++ ip += 4; ++ t -= 4; ++ } while (t >= 4); ++ if (t > 0) ++ do ++ *op++ = *ip++; ++ while (--t > 0); ++ } else ++ do ++ *op++ = *ip++; ++ while (--t > 0); ++ } ++#if !defined(LZO_UNALIGNED_OK_4) ++ } else ++#endif ++#endif ++#if !defined(LZO_UNALIGNED_OK_4) ++ { ++ *op++ = *ip++; ++ *op++ = *ip++; ++ *op++ = *ip++; ++ do ++ *op++ = *ip++; ++ while (--t > 0); ++ } ++#endif ++ ++ first_literal_run: ++ ++ t = *ip++; ++ if (t >= 16) ++ goto match; ++#if defined(COPY_DICT) ++#if defined(LZO1Z) ++ m_off = (1 + M2_MAX_OFFSET) + (t << 6) + (*ip++ >> 2); ++ last_m_off = m_off; ++#else ++ m_off = (1 + M2_MAX_OFFSET) + (t >> 2) + (*ip++ << 2); ++#endif ++ NEED_OP(3); ++ t = 3; ++ COPY_DICT(t, m_off) ++#else ++#if defined(LZO1Z) ++ t = (1 + M2_MAX_OFFSET) + (t << 6) + (*ip++ >> 2); ++ m_pos = op - t; ++ last_m_off = t; ++#else ++ m_pos = op - (1 + M2_MAX_OFFSET); ++ m_pos -= t >> 2; ++ m_pos -= *ip++ << 2; ++#endif ++ TEST_LOOKBEHIND(m_pos, out); ++ NEED_OP(3); ++ *op++ = *m_pos++; ++ *op++ = *m_pos++; ++ *op++ = *m_pos; ++#endif ++ goto match_done; ++ ++ while (TEST_IP && TEST_OP) { ++ match: ++ if (t >= 64) { ++#if defined(COPY_DICT) ++#if defined(LZO1X) ++ m_off = 1 + ((t >> 2) & 7) + (*ip++ << 3); ++ t = (t >> 5) - 1; ++#elif defined(LZO1Y) ++ m_off = 1 + ((t >> 2) & 3) + (*ip++ << 2); ++ t = (t >> 4) - 3; ++#elif defined(LZO1Z) ++ m_off = t & 0x1f; ++ if (m_off >= 0x1c) ++ m_off = last_m_off; ++ else { ++ m_off = 1 + (m_off << 6) + (*ip++ >> 2); ++ last_m_off = m_off; ++ } ++ t = (t >> 5) - 1; ++#endif ++#else ++#if defined(LZO1X) ++ m_pos = op - 1; ++ m_pos -= (t >> 2) & 7; ++ m_pos -= *ip++ << 3; ++ t = (t >> 5) - 1; ++#elif defined(LZO1Y) ++ m_pos = op - 1; ++ m_pos -= (t >> 2) & 3; ++ m_pos -= *ip++ << 2; ++ t = (t >> 4) - 3; ++#elif defined(LZO1Z) ++ { ++ lzo_uint off = t & 0x1f; ++ m_pos = op; ++ if (off >= 0x1c) { ++ assert(last_m_off > 0); ++ m_pos -= last_m_off; ++ } else { ++ off = ++ 1 + (off << 6) + ++ (*ip++ >> 2); ++ m_pos -= off; ++ last_m_off = off; ++ } ++ } ++ t = (t >> 5) - 1; ++#endif ++ TEST_LOOKBEHIND(m_pos, out); ++ assert("lzo-18", t > 0); ++ NEED_OP(t + 3 - 1); ++ goto copy_match; ++#endif ++ } else if (t >= 32) { ++ t &= 31; ++ if (t == 0) { ++ NEED_IP(1); ++ while (*ip == 0) { ++ t += 255; ++ ip++; ++ NEED_IP(1); ++ } ++ t += 31 + *ip++; ++ } ++#if defined(COPY_DICT) ++#if defined(LZO1Z) ++ m_off = 1 + (ip[0] << 6) + (ip[1] >> 2); ++ last_m_off = m_off; ++#else ++ m_off = 1 + (ip[0] >> 2) + (ip[1] << 6); ++#endif ++#else ++#if defined(LZO1Z) ++ { ++ lzo_uint off = ++ 1 + (ip[0] << 6) + (ip[1] >> 2); ++ m_pos = op - off; ++ last_m_off = off; ++ } ++#elif defined(LZO_UNALIGNED_OK_2) && (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN) ++ m_pos = op - 1; ++ m_pos -= (*(const lzo_ushortp)ip) >> 2; ++#else ++ m_pos = op - 1; ++ m_pos -= (ip[0] >> 2) + (ip[1] << 6); ++#endif ++#endif ++ ip += 2; ++ } else if (t >= 16) { ++#if defined(COPY_DICT) ++ m_off = (t & 8) << 11; ++#else ++ m_pos = op; ++ m_pos -= (t & 8) << 11; ++#endif ++ t &= 7; ++ if (t == 0) { ++ NEED_IP(1); ++ while (*ip == 0) { ++ t += 255; ++ ip++; ++ NEED_IP(1); ++ } ++ t += 7 + *ip++; ++ } ++#if defined(COPY_DICT) ++#if defined(LZO1Z) ++ m_off += (ip[0] << 6) + (ip[1] >> 2); ++#else ++ m_off += (ip[0] >> 2) + (ip[1] << 6); ++#endif ++ ip += 2; ++ if (m_off == 0) ++ goto eof_found; ++ m_off += 0x4000; ++#if defined(LZO1Z) ++ last_m_off = m_off; ++#endif ++#else ++#if defined(LZO1Z) ++ m_pos -= (ip[0] << 6) + (ip[1] >> 2); ++#elif defined(LZO_UNALIGNED_OK_2) && (LZO_BYTE_ORDER == LZO_LITTLE_ENDIAN) ++ m_pos -= (*(const lzo_ushortp)ip) >> 2; ++#else ++ m_pos -= (ip[0] >> 2) + (ip[1] << 6); ++#endif ++ ip += 2; ++ if (m_pos == op) ++ goto eof_found; ++ m_pos -= 0x4000; ++#if defined(LZO1Z) ++ last_m_off = op - m_pos; ++#endif ++#endif ++ } else { ++#if defined(COPY_DICT) ++#if defined(LZO1Z) ++ m_off = 1 + (t << 6) + (*ip++ >> 2); ++ last_m_off = m_off; ++#else ++ m_off = 1 + (t >> 2) + (*ip++ << 2); ++#endif ++ NEED_OP(2); ++ t = 2; ++ COPY_DICT(t, m_off) ++#else ++#if defined(LZO1Z) ++ t = 1 + (t << 6) + (*ip++ >> 2); ++ m_pos = op - t; ++ last_m_off = t; ++#else ++ m_pos = op - 1; ++ m_pos -= t >> 2; ++ m_pos -= *ip++ << 2; ++#endif ++ TEST_LOOKBEHIND(m_pos, out); ++ NEED_OP(2); ++ *op++ = *m_pos++; ++ *op++ = *m_pos; ++#endif ++ goto match_done; ++ } ++ ++#if defined(COPY_DICT) ++ ++ NEED_OP(t + 3 - 1); ++ t += 3 - 1; ++ COPY_DICT(t, m_off) ++#else ++ ++ TEST_LOOKBEHIND(m_pos, out); ++ assert("lzo-19", t > 0); ++ NEED_OP(t + 3 - 1); ++#if defined(LZO_UNALIGNED_OK_4) || defined(LZO_ALIGNED_OK_4) ++#if !defined(LZO_UNALIGNED_OK_4) ++ if (t >= 2 * 4 - (3 - 1) && PTR_ALIGNED2_4(op, m_pos)) { ++ assert((op - m_pos) >= 4); ++#else ++ if (t >= 2 * 4 - (3 - 1) && (op - m_pos) >= 4) { ++#endif ++ COPY4(op, m_pos); ++ op += 4; ++ m_pos += 4; ++ t -= 4 - (3 - 1); ++ do { ++ COPY4(op, m_pos); ++ op += 4; ++ m_pos += 4; ++ t -= 4; ++ } while (t >= 4); ++ if (t > 0) ++ do ++ *op++ = *m_pos++; ++ while (--t > 0); ++ } else ++#endif ++ { ++ copy_match: ++ *op++ = *m_pos++; ++ *op++ = *m_pos++; ++ do ++ *op++ = *m_pos++; ++ while (--t > 0); ++ } ++ ++#endif ++ ++ match_done: ++#if defined(LZO1Z) ++ t = ip[-1] & 3; ++#else ++ t = ip[-2] & 3; ++#endif ++ if (t == 0) ++ break; ++ ++ match_next: ++ assert("lzo-20", t > 0); ++ NEED_OP(t); ++ NEED_IP(t + 1); ++ do ++ *op++ = *ip++; ++ while (--t > 0); ++ t = *ip++; ++ } ++ } ++ ++#if defined(HAVE_TEST_IP) || defined(HAVE_TEST_OP) ++ *out_len = op - out; ++ return LZO_E_EOF_NOT_FOUND; ++#endif ++ ++ eof_found: ++ assert("lzo-21", t == 1); ++ *out_len = op - out; ++ return (ip == ip_end ? LZO_E_OK : ++ (ip < ip_end ? LZO_E_INPUT_NOT_CONSUMED : LZO_E_INPUT_OVERRUN)); ++ ++#if defined(HAVE_NEED_IP) ++ input_overrun: ++ *out_len = op - out; ++ return LZO_E_INPUT_OVERRUN; ++#endif ++ ++#if defined(HAVE_NEED_OP) ++ output_overrun: ++ *out_len = op - out; ++ return LZO_E_OUTPUT_OVERRUN; ++#endif ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND) ++ lookbehind_overrun: ++ *out_len = op - out; ++ return LZO_E_LOOKBEHIND_OVERRUN; ++#endif ++} ++ ++#define LZO_TEST_DECOMPRESS_OVERRUN ++#undef DO_DECOMPRESS ++#define DO_DECOMPRESS lzo1x_decompress_safe ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN) ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_INPUT) ++# define LZO_TEST_DECOMPRESS_OVERRUN_INPUT 2 ++# endif ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT) ++# define LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT 2 ++# endif ++# if !defined(LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND) ++# define LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND ++# endif ++#endif ++ ++#undef TEST_IP ++#undef TEST_OP ++#undef TEST_LOOKBEHIND ++#undef NEED_IP ++#undef NEED_OP ++#undef HAVE_TEST_IP ++#undef HAVE_TEST_OP ++#undef HAVE_NEED_IP ++#undef HAVE_NEED_OP ++#undef HAVE_ANY_IP ++#undef HAVE_ANY_OP ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_INPUT) ++# if (LZO_TEST_DECOMPRESS_OVERRUN_INPUT >= 1) ++# define TEST_IP (ip < ip_end) ++# endif ++# if (LZO_TEST_DECOMPRESS_OVERRUN_INPUT >= 2) ++# define NEED_IP(x) \ ++ if ((lzo_uint)(ip_end - ip) < (lzo_uint)(x)) goto input_overrun ++# endif ++#endif ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT) ++# if (LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT >= 1) ++# define TEST_OP (op <= op_end) ++# endif ++# if (LZO_TEST_DECOMPRESS_OVERRUN_OUTPUT >= 2) ++# undef TEST_OP ++# define NEED_OP(x) \ ++ if ((lzo_uint)(op_end - op) < (lzo_uint)(x)) goto output_overrun ++# endif ++#endif ++ ++#if defined(LZO_TEST_DECOMPRESS_OVERRUN_LOOKBEHIND) ++# define TEST_LOOKBEHIND(m_pos,out) if (m_pos < out) goto lookbehind_overrun ++#else ++# define TEST_LOOKBEHIND(m_pos,op) ((void) 0) ++#endif ++ ++#if !defined(LZO_EOF_CODE) && !defined(TEST_IP) ++# define TEST_IP (ip < ip_end) ++#endif ++ ++#if defined(TEST_IP) ++# define HAVE_TEST_IP ++#else ++# define TEST_IP 1 ++#endif ++#if defined(TEST_OP) ++# define HAVE_TEST_OP ++#else ++# define TEST_OP 1 ++#endif ++ ++#if defined(NEED_IP) ++# define HAVE_NEED_IP ++#else ++# define NEED_IP(x) ((void) 0) ++#endif ++#if defined(NEED_OP) ++# define HAVE_NEED_OP ++#else ++# define NEED_OP(x) ((void) 0) ++#endif ++ ++#if defined(HAVE_TEST_IP) || defined(HAVE_NEED_IP) ++# define HAVE_ANY_IP ++#endif ++#if defined(HAVE_TEST_OP) || defined(HAVE_NEED_OP) ++# define HAVE_ANY_OP ++#endif ++ ++#undef __COPY4 ++#define __COPY4(dst,src) * (lzo_uint32p)(dst) = * (const lzo_uint32p)(src) ++ ++#undef COPY4 ++#if defined(LZO_UNALIGNED_OK_4) ++# define COPY4(dst,src) __COPY4(dst,src) ++#elif defined(LZO_ALIGNED_OK_4) ++# define COPY4(dst,src) __COPY4((lzo_ptr_t)(dst),(lzo_ptr_t)(src)) ++#endif ++ ++/***** End of minilzo.c *****/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/compress/minilzo.h linux-5.10.2/fs/reiser4/plugin/compress/minilzo.h +--- linux-5.10.2.orig/fs/reiser4/plugin/compress/minilzo.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/compress/minilzo.h 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,70 @@ ++/* minilzo.h -- mini subset of the LZO real-time data compression library ++ adopted for reiser4 compression transform plugin. ++ ++ This file is part of the LZO real-time data compression library ++ and not included in any proprietary licenses of reiser4. ++ ++ Copyright (C) 2002 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2001 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 2000 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1999 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1998 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1997 Markus Franz Xaver Johannes Oberhumer ++ Copyright (C) 1996 Markus Franz Xaver Johannes Oberhumer ++ All Rights Reserved. ++ ++ The LZO library is free software; you can redistribute it and/or ++ modify it under the terms of the GNU General Public License as ++ published by the Free Software Foundation; either version 2 of ++ the License, or (at your option) any later version. ++ ++ The LZO library is distributed in the hope that it will be useful, ++ but WITHOUT ANY WARRANTY; without even the implied warranty of ++ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ++ GNU General Public License for more details. ++ ++ You should have received a copy of the GNU General Public License ++ along with the LZO library; see the file COPYING. ++ If not, write to the Free Software Foundation, Inc., ++ 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. ++ ++ Markus F.X.J. Oberhumer ++ ++ http://www.oberhumer.com/opensource/lzo/ ++ */ ++ ++/* ++ * NOTE: ++ * the full LZO package can be found at ++ * http://www.oberhumer.com/opensource/lzo/ ++ */ ++ ++#ifndef __MINILZO_H ++#define __MINILZO_H ++ ++#define MINILZO_VERSION 0x1080 ++ ++#include "lzoconf.h" ++ ++/* Memory required for the wrkmem parameter. ++ * When the required size is 0, you can also pass a NULL pointer. ++ */ ++ ++#define LZO1X_MEM_COMPRESS LZO1X_1_MEM_COMPRESS ++#define LZO1X_1_MEM_COMPRESS ((lzo_uint32) (16384L * lzo_sizeof_dict_t)) ++#define LZO1X_MEM_DECOMPRESS (0) ++ ++/* compression */ ++extern int lzo1x_1_compress(const lzo_byte * src, lzo_uint src_len, ++ lzo_byte * dst, lzo_uintp dst_len, ++ lzo_voidp wrkmem); ++/* decompression */ ++extern int lzo1x_decompress(const lzo_byte * src, lzo_uint src_len, ++ lzo_byte * dst, lzo_uintp dst_len, ++ lzo_voidp wrkmem /* NOT USED */); ++/* safe decompression with overrun testing */ ++extern int lzo1x_decompress_safe(const lzo_byte * src, lzo_uint src_len, ++ lzo_byte * dst, lzo_uintp dst_len, ++ lzo_voidp wrkmem /* NOT USED */ ); ++ ++#endif /* already included */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/crypto/cipher.c linux-5.10.2/fs/reiser4/plugin/crypto/cipher.c +--- linux-5.10.2.orig/fs/reiser4/plugin/crypto/cipher.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/crypto/cipher.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,37 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, ++ licensing governed by reiser4/README */ ++/* Reiser4 cipher transform plugins */ ++ ++#include "../../debug.h" ++#include "../plugin.h" ++ ++cipher_plugin cipher_plugins[LAST_CIPHER_ID] = { ++ [NONE_CIPHER_ID] = { ++ .h = { ++ .type_id = REISER4_CIPHER_PLUGIN_TYPE, ++ .id = NONE_CIPHER_ID, ++ .pops = NULL, ++ .label = "none", ++ .desc = "no cipher transform", ++ .linkage = {NULL, NULL} ++ }, ++ .alloc = NULL, ++ .free = NULL, ++ .scale = NULL, ++ .align_stream = NULL, ++ .setkey = NULL, ++ .encrypt = NULL, ++ .decrypt = NULL ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/crypto/cipher.h linux-5.10.2/fs/reiser4/plugin/crypto/cipher.h +--- linux-5.10.2.orig/fs/reiser4/plugin/crypto/cipher.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/crypto/cipher.h 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,55 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* This file contains definitions for the objects operated ++ by reiser4 key manager, which is something like keyring ++ wrapped by appropriate reiser4 plugin */ ++ ++#if !defined( __FS_REISER4_CRYPT_H__ ) ++#define __FS_REISER4_CRYPT_H__ ++ ++#include ++ ++/* key info imported from user space */ ++struct reiser4_crypto_data { ++ int keysize; /* uninstantiated key size */ ++ __u8 * key; /* uninstantiated key */ ++ int keyid_size; /* size of passphrase */ ++ __u8 * keyid; /* passphrase */ ++}; ++ ++/* This object contains all needed infrastructure to implement ++ cipher transform. This is operated (allocating, inheriting, ++ validating, binding to host inode, etc..) by reiser4 key manager. ++ ++ This info can be allocated in two cases: ++ 1. importing a key from user space. ++ 2. reading inode from disk */ ++struct reiser4_crypto_info { ++ struct inode * host; ++ struct crypto_hash * digest; ++ struct crypto_blkcipher * cipher; ++#if 0 ++ cipher_key_plugin * kplug; /* key manager */ ++#endif ++ __u8 * keyid; /* key fingerprint, created by digest plugin, ++ using uninstantiated key and passphrase. ++ supposed to be stored in disk stat-data */ ++ int inst; /* this indicates if the cipher key is ++ instantiated (case 1 above) */ ++ int keysize; /* uninstantiated key size (bytes), supposed ++ to be stored in disk stat-data */ ++ int keyload_count; /* number of the objects which has this ++ crypto-stat attached */ ++}; ++ ++#endif /* __FS_REISER4_CRYPT_H__ */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/crypto/digest.c linux-5.10.2/fs/reiser4/plugin/crypto/digest.c +--- linux-5.10.2.orig/fs/reiser4/plugin/crypto/digest.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/crypto/digest.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,58 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* reiser4 digest transform plugin (is used by cryptcompress object plugin) */ ++/* EDWARD-FIXME-HANS: and it does what? a digest is a what? */ ++#include "../../debug.h" ++#include "../plugin_header.h" ++#include "../plugin.h" ++#include "../file/cryptcompress.h" ++ ++#include ++ ++extern digest_plugin digest_plugins[LAST_DIGEST_ID]; ++ ++static struct crypto_hash * alloc_sha256 (void) ++{ ++#if REISER4_SHA256 ++ return crypto_alloc_hash ("sha256", 0, CRYPTO_ALG_ASYNC); ++#else ++ warning("edward-1418", "sha256 unsupported"); ++ return ERR_PTR(-EINVAL); ++#endif ++} ++ ++static void free_sha256 (struct crypto_hash * tfm) ++{ ++#if REISER4_SHA256 ++ crypto_free_hash(tfm); ++#endif ++ return; ++} ++ ++/* digest plugins */ ++digest_plugin digest_plugins[LAST_DIGEST_ID] = { ++ [SHA256_32_DIGEST_ID] = { ++ .h = { ++ .type_id = REISER4_DIGEST_PLUGIN_TYPE, ++ .id = SHA256_32_DIGEST_ID, ++ .pops = NULL, ++ .label = "sha256_32", ++ .desc = "sha256_32 digest transform", ++ .linkage = {NULL, NULL} ++ }, ++ .fipsize = sizeof(__u32), ++ .alloc = alloc_sha256, ++ .free = free_sha256 ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dir/dir.h linux-5.10.2/fs/reiser4/plugin/dir/dir.h +--- linux-5.10.2.orig/fs/reiser4/plugin/dir/dir.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dir/dir.h 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,38 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* this file contains declarations of methods implementing directory plugins */ ++ ++#if !defined( __REISER4_DIR_H__ ) ++#define __REISER4_DIR_H__ ++ ++/*#include "../../key.h" ++ ++#include */ ++ ++long reiser4_ioctl_dir_common(struct file *file, unsigned int cmd, unsigned long arg); ++ ++/* declarations of functions implementing HASHED_DIR_PLUGIN_ID dir plugin */ ++ ++/* "hashed" directory methods of dir plugin */ ++void build_entry_key_hashed(const struct inode *, const struct qstr *, ++ reiser4_key *); ++ ++/* declarations of functions implementing SEEKABLE_HASHED_DIR_PLUGIN_ID dir plugin */ ++ ++/* "seekable" directory methods of dir plugin */ ++void build_entry_key_seekable(const struct inode *, const struct qstr *, ++ reiser4_key *); ++ ++/* __REISER4_DIR_H__ */ ++#endif ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dir/hashed_dir.c linux-5.10.2/fs/reiser4/plugin/dir/hashed_dir.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dir/hashed_dir.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dir/hashed_dir.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,81 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Directory plugin using hashes (see fs/reiser4/plugin/hash.c) to map file ++ names to the files. */ ++ ++/* ++ * Hashed directory logically consists of persistent directory ++ * entries. Directory entry is a pair of a file name and a key of stat-data of ++ * a file that has this name in the given directory. ++ * ++ * Directory entries are stored in the tree in the form of directory ++ * items. Directory item should implement dir_entry_ops portion of item plugin ++ * interface (see plugin/item/item.h). Hashed directory interacts with ++ * directory item plugin exclusively through dir_entry_ops operations. ++ * ++ * Currently there are two implementations of directory items: "simple ++ * directory item" (plugin/item/sde.[ch]), and "compound directory item" ++ * (plugin/item/cde.[ch]) with the latter being the default. ++ * ++ * There is, however some delicate way through which directory code interferes ++ * with item plugin: key assignment policy. A key for a directory item is ++ * chosen by directory code, and as described in kassign.c, this key contains ++ * a portion of file name. Directory item uses this knowledge to avoid storing ++ * this portion of file name twice: in the key and in the directory item body. ++ * ++ */ ++ ++#include "../../inode.h" ++ ++void complete_entry_key(const struct inode *, const char *name, ++ int len, reiser4_key * result); ++ ++/* this is implementation of build_entry_key method of dir ++ plugin for HASHED_DIR_PLUGIN_ID ++ */ ++void build_entry_key_hashed(const struct inode *dir, /* directory where entry is ++ * (or will be) in.*/ ++ const struct qstr *qname, /* name of file referenced ++ * by this entry */ ++ reiser4_key * result /* resulting key of directory ++ * entry */ ) ++{ ++ const char *name; ++ int len; ++ ++ assert("nikita-1139", dir != NULL); ++ assert("nikita-1140", qname != NULL); ++ assert("nikita-1141", qname->name != NULL); ++ assert("nikita-1142", result != NULL); ++ ++ name = qname->name; ++ len = qname->len; ++ ++ assert("nikita-2867", strlen(name) == len); ++ ++ reiser4_key_init(result); ++ /* locality of directory entry's key is objectid of parent ++ directory */ ++ set_key_locality(result, get_inode_oid(dir)); ++ /* minor packing locality is constant */ ++ set_key_type(result, KEY_FILE_NAME_MINOR); ++ /* dot is special case---we always want it to be first entry in ++ a directory. Actually, we just want to have smallest ++ directory entry. ++ */ ++ if (len == 1 && name[0] == '.') ++ return; ++ ++ /* initialize part of entry key which depends on file name */ ++ complete_entry_key(dir, name, len, result); ++} ++ ++/* Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dir/Makefile linux-5.10.2/fs/reiser4/plugin/dir/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/dir/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dir/Makefile 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,5 @@ ++obj-$(CONFIG_REISER4_FS) += dir_plugins.o ++ ++dir_plugins-objs := \ ++ hashed_dir.o \ ++ seekable_dir.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dir/seekable_dir.c linux-5.10.2/fs/reiser4/plugin/dir/seekable_dir.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dir/seekable_dir.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dir/seekable_dir.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,46 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "../../inode.h" ++ ++/* this is implementation of build_entry_key method of dir ++ plugin for SEEKABLE_HASHED_DIR_PLUGIN_ID ++ This is for directories where we want repeatable and restartable readdir() ++ even in case 32bit user level struct dirent (readdir(3)). ++*/ ++void ++build_entry_key_seekable(const struct inode *dir, const struct qstr *name, ++ reiser4_key * result) ++{ ++ oid_t objectid; ++ ++ assert("nikita-2283", dir != NULL); ++ assert("nikita-2284", name != NULL); ++ assert("nikita-2285", name->name != NULL); ++ assert("nikita-2286", result != NULL); ++ ++ reiser4_key_init(result); ++ /* locality of directory entry's key is objectid of parent ++ directory */ ++ set_key_locality(result, get_inode_oid(dir)); ++ /* minor packing locality is constant */ ++ set_key_type(result, KEY_FILE_NAME_MINOR); ++ /* dot is special case---we always want it to be first entry in ++ a directory. Actually, we just want to have smallest ++ directory entry. ++ */ ++ if ((name->len == 1) && (name->name[0] == '.')) ++ return; ++ ++ /* objectid of key is 31 lowest bits of hash. */ ++ objectid = ++ inode_hash_plugin(dir)->hash(name->name, ++ (int)name->len) & 0x7fffffff; ++ ++ assert("nikita-2303", !(objectid & ~KEY_OBJECTID_MASK)); ++ set_key_objectid(result, objectid); ++ ++ /* offset is always 0. */ ++ set_key_offset(result, (__u64) 0); ++ return; ++} +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dir_plugin_common.c linux-5.10.2/fs/reiser4/plugin/dir_plugin_common.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dir_plugin_common.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dir_plugin_common.c 2020-12-23 16:07:46.121813173 +0100 +@@ -0,0 +1,869 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* this file contains typical implementations for most of methods of ++ directory plugin ++*/ ++ ++#include "../inode.h" ++ ++int reiser4_find_entry(struct inode *dir, struct dentry *name, ++ lock_handle * , znode_lock_mode, reiser4_dir_entry_desc *); ++int reiser4_lookup_name(struct inode *parent, struct dentry *dentry, ++ reiser4_key * key); ++void check_light_weight(struct inode *inode, struct inode *parent); ++ ++/* this is common implementation of get_parent method of dir plugin ++ this is used by NFS kernel server to "climb" up directory tree to ++ check permissions ++ */ ++struct dentry *get_parent_common(struct inode *child) ++{ ++ struct super_block *s; ++ struct inode *parent; ++ struct dentry dotdot; ++ struct dentry *dentry; ++ reiser4_key key; ++ int result; ++ ++ /* ++ * lookup dotdot entry. ++ */ ++ ++ s = child->i_sb; ++ memset(&dotdot, 0, sizeof(dotdot)); ++ dotdot.d_name.name = ".."; ++ dotdot.d_name.len = 2; ++ dotdot.d_op = &get_super_private(s)->ops.dentry; ++ ++ result = reiser4_lookup_name(child, &dotdot, &key); ++ if (result != 0) ++ return ERR_PTR(result); ++ ++ parent = reiser4_iget(s, &key, FIND_EXACT, 1); ++ if (!IS_ERR(parent)) { ++ /* ++ * FIXME-NIKITA dubious: attributes are inherited from @child ++ * to @parent. But: ++ * ++ * (*) this is the only this we can do ++ * ++ * (*) attributes of light-weight object are inherited ++ * from a parent through which object was looked up first, ++ * so it is ambiguous anyway. ++ * ++ */ ++ check_light_weight(parent, child); ++ reiser4_iget_complete(parent); ++ dentry = d_obtain_alias(parent); ++ if (!IS_ERR(dentry)) ++ dentry->d_op = &get_super_private(s)->ops.dentry; ++ } else if (PTR_ERR(parent) == -ENOENT) ++ dentry = ERR_PTR(RETERR(-ESTALE)); ++ else ++ dentry = (void *)parent; ++ return dentry; ++} ++ ++/* this is common implementation of is_name_acceptable method of dir ++ plugin ++ */ ++int is_name_acceptable_common(const struct inode *inode, /* directory to check*/ ++ const char *name UNUSED_ARG, /* name to check */ ++ int len/* @name's length */) ++{ ++ assert("nikita-733", inode != NULL); ++ assert("nikita-734", name != NULL); ++ assert("nikita-735", len > 0); ++ ++ return len <= reiser4_max_filename_len(inode); ++} ++ ++/* there is no common implementation of build_entry_key method of dir ++ plugin. See plugin/dir/hashed_dir.c:build_entry_key_hashed() or ++ plugin/dir/seekable.c:build_entry_key_seekable() for example ++*/ ++ ++/* this is common implementation of build_readdir_key method of dir ++ plugin ++ see reiser4_readdir_common for more details ++*/ ++int build_readdir_key_common(struct file *dir /* directory being read */ , ++ reiser4_key * result/* where to store key */) ++{ ++ reiser4_file_fsdata *fdata; ++ struct inode *inode; ++ ++ assert("nikita-1361", dir != NULL); ++ assert("nikita-1362", result != NULL); ++ assert("nikita-1363", dir->f_path.dentry != NULL); ++ inode = file_inode(dir); ++ assert("nikita-1373", inode != NULL); ++ ++ fdata = reiser4_get_file_fsdata(dir); ++ if (IS_ERR(fdata)) ++ return PTR_ERR(fdata); ++ assert("nikita-1364", fdata != NULL); ++ return extract_key_from_de_id(get_inode_oid(inode), ++ &fdata->dir.readdir.position.dir_entry_key, ++ result); ++} ++ ++void reiser4_adjust_dir_file(struct inode *, const struct dentry *, int offset, ++ int adj); ++ ++/* this is common implementation of add_entry method of dir plugin ++*/ ++int reiser4_add_entry_common(struct inode *object, /* directory to add new name ++ * in */ ++ struct dentry *where, /* new name */ ++ reiser4_object_create_data * data, /* parameters of ++ * new object */ ++ reiser4_dir_entry_desc * entry /* parameters of ++ * new directory ++ * entry */) ++{ ++ int result; ++ coord_t *coord; ++ lock_handle lh; ++ struct reiser4_dentry_fsdata *fsdata; ++ reiser4_block_nr reserve; ++ ++ assert("nikita-1114", object != NULL); ++ assert("nikita-1250", where != NULL); ++ ++ fsdata = reiser4_get_dentry_fsdata(where); ++ if (unlikely(IS_ERR(fsdata))) ++ return PTR_ERR(fsdata); ++ ++ reserve = inode_dir_plugin(object)->estimate.add_entry(object); ++ if (reiser4_grab_space(reserve, BA_CAN_COMMIT, get_meta_subvol())) ++ return RETERR(-ENOSPC); ++ ++ init_lh(&lh); ++ coord = &fsdata->dec.entry_coord; ++ coord_clear_iplug(coord); ++ ++ /* check for this entry in a directory. This is plugin method. */ ++ result = reiser4_find_entry(object, where, &lh, ZNODE_WRITE_LOCK, ++ entry); ++ if (likely(result == -ENOENT)) { ++ /* add new entry. Just pass control to the directory ++ item plugin. */ ++ assert("nikita-1709", inode_dir_item_plugin(object)); ++ assert("nikita-2230", coord->node == lh.node); ++ reiser4_seal_done(&fsdata->dec.entry_seal); ++ result = ++ inode_dir_item_plugin(object)->s.dir.add_entry(object, ++ coord, &lh, ++ where, ++ entry); ++ if (result == 0) { ++ reiser4_adjust_dir_file(object, where, ++ fsdata->dec.pos + 1, +1); ++ INODE_INC_FIELD(object, i_size); ++ } ++ } else if (result == 0) { ++ assert("nikita-2232", coord->node == lh.node); ++ result = RETERR(-EEXIST); ++ } ++ done_lh(&lh); ++ ++ return result; ++} ++ ++/** ++ * rem_entry - remove entry from directory item ++ * @dir: ++ * @dentry: ++ * @entry: ++ * @coord: ++ * @lh: ++ * ++ * Checks that coordinate @coord is set properly and calls item plugin ++ * method to cut entry. ++ */ ++static int ++rem_entry(struct inode *dir, struct dentry *dentry, ++ reiser4_dir_entry_desc * entry, coord_t *coord, lock_handle * lh) ++{ ++ item_plugin *iplug; ++ struct inode *child; ++ ++ iplug = inode_dir_item_plugin(dir); ++ child = dentry->d_inode; ++ assert("nikita-3399", child != NULL); ++ ++ /* check that we are really destroying an entry for @child */ ++ if (REISER4_DEBUG) { ++ int result; ++ reiser4_key key; ++ ++ result = iplug->s.dir.extract_key(coord, &key); ++ if (result != 0) ++ return result; ++ if (get_key_objectid(&key) != get_inode_oid(child)) { ++ warning("nikita-3397", ++ "rem_entry: %#llx != %#llx\n", ++ get_key_objectid(&key), ++ (unsigned long long)get_inode_oid(child)); ++ return RETERR(-EIO); ++ } ++ } ++ return iplug->s.dir.rem_entry(dir, &dentry->d_name, coord, lh, entry); ++} ++ ++/** ++ * reiser4_rem_entry_common - remove entry from a directory ++ * @dir: directory to remove entry from ++ * @where: name that is being removed ++ * @entry: description of entry being removed ++ * ++ * This is common implementation of rem_entry method of dir plugin. ++ */ ++int reiser4_rem_entry_common(struct inode *dir, ++ struct dentry *dentry, ++ reiser4_dir_entry_desc * entry) ++{ ++ int result; ++ coord_t *coord; ++ lock_handle lh; ++ struct reiser4_dentry_fsdata *fsdata; ++ __u64 tograb; ++ ++ assert("nikita-1124", dir != NULL); ++ assert("nikita-1125", dentry != NULL); ++ ++ tograb = inode_dir_plugin(dir)->estimate.rem_entry(dir); ++ result = reiser4_grab_space(tograb, BA_CAN_COMMIT | BA_RESERVED, ++ get_meta_subvol()); ++ if (result != 0) ++ return RETERR(-ENOSPC); ++ ++ init_lh(&lh); ++ ++ /* check for this entry in a directory. This is plugin method. */ ++ result = reiser4_find_entry(dir, dentry, &lh, ZNODE_WRITE_LOCK, entry); ++ fsdata = reiser4_get_dentry_fsdata(dentry); ++ if (IS_ERR(fsdata)) { ++ done_lh(&lh); ++ return PTR_ERR(fsdata); ++ } ++ ++ coord = &fsdata->dec.entry_coord; ++ ++ assert("nikita-3404", ++ get_inode_oid(dentry->d_inode) != get_inode_oid(dir) || ++ dir->i_size <= 1); ++ ++ coord_clear_iplug(coord); ++ if (result == 0) { ++ /* remove entry. Just pass control to the directory item ++ plugin. */ ++ assert("vs-542", inode_dir_item_plugin(dir)); ++ reiser4_seal_done(&fsdata->dec.entry_seal); ++ reiser4_adjust_dir_file(dir, dentry, fsdata->dec.pos, -1); ++ result = ++ WITH_COORD(coord, ++ rem_entry(dir, dentry, entry, coord, &lh)); ++ if (result == 0) { ++ if (dir->i_size >= 1) ++ INODE_DEC_FIELD(dir, i_size); ++ else { ++ warning("nikita-2509", "Dir %llu is runt", ++ (unsigned long long) ++ get_inode_oid(dir)); ++ result = RETERR(-EIO); ++ } ++ ++ assert("nikita-3405", dentry->d_inode->i_nlink != 1 || ++ dentry->d_inode->i_size != 2 || ++ inode_dir_plugin(dentry->d_inode) == NULL); ++ } ++ } ++ done_lh(&lh); ++ ++ return result; ++} ++ ++static reiser4_block_nr estimate_init(struct inode *parent, ++ struct inode *object); ++static int create_dot_dotdot(struct inode *object, struct inode *parent); ++ ++/* this is common implementation of init method of dir plugin ++ create "." and ".." entries ++*/ ++int reiser4_dir_init_common(struct inode *object, /* new directory */ ++ struct inode *parent, /* parent directory */ ++ reiser4_object_create_data * data /* info passed ++ * to us, this ++ * is filled by ++ * reiser4() ++ * syscall in ++ * particular */) ++{ ++ reiser4_block_nr reserve; ++ ++ assert("nikita-680", object != NULL); ++ assert("nikita-681", S_ISDIR(object->i_mode)); ++ assert("nikita-682", parent != NULL); ++ assert("nikita-684", data != NULL); ++ assert("nikita-686", data->id == DIRECTORY_FILE_PLUGIN_ID); ++ assert("nikita-687", object->i_mode & S_IFDIR); ++ ++ reserve = estimate_init(parent, object); ++ if (reiser4_grab_space(reserve, BA_CAN_COMMIT, get_meta_subvol())) ++ return RETERR(-ENOSPC); ++ ++ return create_dot_dotdot(object, parent); ++} ++ ++/* this is common implementation of done method of dir plugin ++ remove "." entry ++*/ ++int reiser4_dir_done_common(struct inode *object/* object being deleted */) ++{ ++ int result; ++ reiser4_block_nr reserve; ++ struct dentry goodby_dots; ++ reiser4_dir_entry_desc entry; ++ ++ assert("nikita-1449", object != NULL); ++ ++ if (reiser4_inode_get_flag(object, REISER4_NO_SD)) ++ return 0; ++ ++ /* of course, this can be rewritten to sweep everything in one ++ reiser4_cut_tree(). */ ++ memset(&entry, 0, sizeof entry); ++ ++ /* FIXME: this done method is called from reiser4_delete_dir_common ++ * which reserved space already */ ++ reserve = inode_dir_plugin(object)->estimate.rem_entry(object); ++ if (reiser4_grab_space(reserve, BA_CAN_COMMIT | BA_RESERVED, ++ get_meta_subvol())) ++ return RETERR(-ENOSPC); ++ ++ memset(&goodby_dots, 0, sizeof goodby_dots); ++ entry.obj = goodby_dots.d_inode = object; ++ goodby_dots.d_name.name = "."; ++ goodby_dots.d_name.len = 1; ++ result = reiser4_rem_entry_common(object, &goodby_dots, &entry); ++ reiser4_free_dentry_fsdata(&goodby_dots); ++ if (unlikely(result != 0 && result != -ENOMEM && result != -ENOENT)) ++ warning("nikita-2252", "Cannot remove dot of %lli: %i", ++ (unsigned long long)get_inode_oid(object), result); ++ return 0; ++} ++ ++/* this is common implementation of attach method of dir plugin ++*/ ++int reiser4_attach_common(struct inode *child UNUSED_ARG, ++ struct inode *parent UNUSED_ARG) ++{ ++ assert("nikita-2647", child != NULL); ++ assert("nikita-2648", parent != NULL); ++ ++ return 0; ++} ++ ++/* this is common implementation of detach method of dir plugin ++ remove "..", decrease nlink on parent ++*/ ++int reiser4_detach_common(struct inode *object, struct inode *parent) ++{ ++ int result; ++ struct dentry goodby_dots; ++ reiser4_dir_entry_desc entry; ++ ++ assert("nikita-2885", object != NULL); ++ assert("nikita-2886", !reiser4_inode_get_flag(object, REISER4_NO_SD)); ++ ++ memset(&entry, 0, sizeof entry); ++ ++ /* NOTE-NIKITA this only works if @parent is -the- parent of ++ @object, viz. object whose key is stored in dotdot ++ entry. Wouldn't work with hard-links on directories. */ ++ memset(&goodby_dots, 0, sizeof goodby_dots); ++ entry.obj = goodby_dots.d_inode = parent; ++ goodby_dots.d_name.name = ".."; ++ goodby_dots.d_name.len = 2; ++ result = reiser4_rem_entry_common(object, &goodby_dots, &entry); ++ reiser4_free_dentry_fsdata(&goodby_dots); ++ if (result == 0) { ++ /* the dot should be the only entry remaining at this time... */ ++ assert("nikita-3400", ++ object->i_size == 1 && object->i_nlink <= 2); ++#if 0 ++ /* and, together with the only name directory can have, they ++ * provides for the last 2 remaining references. If we get ++ * here as part of error handling during mkdir, @object ++ * possibly has no name yet, so its nlink == 1. If we get here ++ * from rename (targeting empty directory), it has no name ++ * already, so its nlink == 1. */ ++ assert("nikita-3401", ++ object->i_nlink == 2 || object->i_nlink == 1); ++#endif ++ ++ /* decrement nlink of directory removed ".." pointed ++ to */ ++ reiser4_del_nlink(parent, NULL, 0); ++ } ++ return result; ++} ++ ++/* this is common implementation of estimate.add_entry method of ++ dir plugin ++ estimation of adding entry which supposes that entry is inserting a ++ unit into item ++*/ ++reiser4_block_nr estimate_add_entry_common(const struct inode *inode) ++{ ++ return estimate_one_insert_into_item(meta_subvol_tree()); ++} ++ ++/* this is common implementation of estimate.rem_entry method of dir ++ plugin ++*/ ++reiser4_block_nr estimate_rem_entry_common(const struct inode *inode) ++{ ++ return estimate_one_item_removal(meta_subvol_tree()); ++} ++ ++/* this is common implementation of estimate.unlink method of dir ++ plugin ++*/ ++reiser4_block_nr ++dir_estimate_unlink_common(const struct inode *parent, ++ const struct inode *object) ++{ ++ reiser4_block_nr res; ++ ++ /* hashed_rem_entry(object) */ ++ res = inode_dir_plugin(object)->estimate.rem_entry(object); ++ /* del_nlink(parent) */ ++ res += 2 * inode_file_plugin(parent)->estimate.update(parent); ++ ++ return res; ++} ++ ++/* ++ * helper for inode_ops ->lookup() and dir plugin's ->get_parent() ++ * methods: if @inode is a light-weight file, setup its credentials ++ * that are not stored in the stat-data in this case ++ */ ++void check_light_weight(struct inode *inode, struct inode *parent) ++{ ++ if (reiser4_inode_get_flag(inode, REISER4_LIGHT_WEIGHT)) { ++ inode->i_uid = parent->i_uid; ++ inode->i_gid = parent->i_gid; ++ /* clear light-weight flag. If inode would be read by any ++ other name, [ug]id wouldn't change. */ ++ reiser4_inode_clr_flag(inode, REISER4_LIGHT_WEIGHT); ++ } ++} ++ ++/* looks for name specified in @dentry in directory @parent and if name is ++ found - key of object found entry points to is stored in @entry->key */ ++int reiser4_lookup_name(struct inode *parent, /* inode of directory to lookup ++ * for name in */ ++ struct dentry *dentry, /* name to look for */ ++ reiser4_key * key/* place to store key */) ++{ ++ int result; ++ coord_t *coord; ++ lock_handle lh; ++ const char *name; ++ int len; ++ reiser4_dir_entry_desc entry; ++ struct reiser4_dentry_fsdata *fsdata; ++ ++ assert("nikita-1247", parent != NULL); ++ assert("nikita-1248", dentry != NULL); ++ assert("nikita-1123", dentry->d_name.name != NULL); ++ assert("vs-1486", ++ dentry->d_op == &get_super_private(parent->i_sb)->ops.dentry); ++ ++ name = dentry->d_name.name; ++ len = dentry->d_name.len; ++ ++ if (!inode_dir_plugin(parent)->is_name_acceptable(parent, name, len)) ++ /* some arbitrary error code to return */ ++ return RETERR(-ENAMETOOLONG); ++ ++ fsdata = reiser4_get_dentry_fsdata(dentry); ++ if (IS_ERR(fsdata)) ++ return PTR_ERR(fsdata); ++ ++ coord = &fsdata->dec.entry_coord; ++ coord_clear_iplug(coord); ++ init_lh(&lh); ++ ++ /* find entry in a directory. This is plugin method. */ ++ result = reiser4_find_entry(parent, dentry, &lh, ZNODE_READ_LOCK, ++ &entry); ++ if (result == 0) { ++ /* entry was found, extract object key from it. */ ++ result = ++ WITH_COORD(coord, ++ item_plugin_by_coord(coord)->s.dir. ++ extract_key(coord, key)); ++ } ++ done_lh(&lh); ++ return result; ++ ++} ++ ++/* helper for reiser4_dir_init_common(): estimate number of blocks to reserve */ ++static reiser4_block_nr ++estimate_init(struct inode *parent, struct inode *object) ++{ ++ reiser4_block_nr res = 0; ++ ++ assert("vpf-321", parent != NULL); ++ assert("vpf-322", object != NULL); ++ ++ /* hashed_add_entry(object) */ ++ res += inode_dir_plugin(object)->estimate.add_entry(object); ++ /* reiser4_add_nlink(object) */ ++ res += inode_file_plugin(object)->estimate.update(object); ++ /* hashed_add_entry(object) */ ++ res += inode_dir_plugin(object)->estimate.add_entry(object); ++ /* reiser4_add_nlink(parent) */ ++ res += inode_file_plugin(parent)->estimate.update(parent); ++ ++ return 0; ++} ++ ++/* helper function for reiser4_dir_init_common(). Create "." and ".." */ ++static int create_dot_dotdot(struct inode *object/* object to create dot and ++ * dotdot for */ , ++ struct inode *parent/* parent of @object */) ++{ ++ int result; ++ struct dentry dots_entry; ++ reiser4_dir_entry_desc entry; ++ ++ assert("nikita-688", object != NULL); ++ assert("nikita-689", S_ISDIR(object->i_mode)); ++ assert("nikita-691", parent != NULL); ++ ++ /* We store dot and dotdot as normal directory entries. This is ++ not necessary, because almost all information stored in them ++ is already in the stat-data of directory, the only thing ++ being missed is objectid of grand-parent directory that can ++ easily be added there as extension. ++ ++ But it is done the way it is done, because not storing dot ++ and dotdot will lead to the following complications: ++ ++ . special case handling in ->lookup(). ++ . addition of another extension to the sd. ++ . dependency on key allocation policy for stat data. ++ ++ */ ++ ++ memset(&entry, 0, sizeof entry); ++ memset(&dots_entry, 0, sizeof dots_entry); ++ entry.obj = dots_entry.d_inode = object; ++ dots_entry.d_name.name = "."; ++ dots_entry.d_name.len = 1; ++ result = reiser4_add_entry_common(object, &dots_entry, NULL, &entry); ++ reiser4_free_dentry_fsdata(&dots_entry); ++ ++ if (result == 0) { ++ result = reiser4_add_nlink(object, object, 0); ++ if (result == 0) { ++ entry.obj = dots_entry.d_inode = parent; ++ dots_entry.d_name.name = ".."; ++ dots_entry.d_name.len = 2; ++ result = reiser4_add_entry_common(object, ++ &dots_entry, NULL, &entry); ++ reiser4_free_dentry_fsdata(&dots_entry); ++ /* if creation of ".." failed, iput() will delete ++ object with ".". */ ++ if (result == 0) { ++ result = reiser4_add_nlink(parent, object, 0); ++ if (result != 0) ++ /* ++ * if we failed to bump i_nlink, try ++ * to remove ".." ++ */ ++ reiser4_detach_common(object, parent); ++ } ++ } ++ } ++ ++ if (result != 0) { ++ /* ++ * in the case of error, at least update stat-data so that, ++ * ->i_nlink updates are not lingering. ++ */ ++ reiser4_update_sd(object); ++ reiser4_update_sd(parent); ++ } ++ ++ return result; ++} ++ ++/* ++ * return 0 iff @coord contains a directory entry for the file with the name ++ * @name. ++ */ ++static int ++check_item(const struct inode *dir, const coord_t *coord, const char *name) ++{ ++ item_plugin *iplug; ++ char buf[DE_NAME_BUF_LEN]; ++ ++ iplug = item_plugin_by_coord(coord); ++ if (iplug == NULL) { ++ warning("nikita-1135", "Cannot get item plugin"); ++ print_coord("coord", coord, 1); ++ return RETERR(-EIO); ++ } else if (item_id_by_coord(coord) != ++ item_id_by_plugin(inode_dir_item_plugin(dir))) { ++ /* item id of current item does not match to id of items a ++ directory is built of */ ++ warning("nikita-1136", "Wrong item plugin"); ++ print_coord("coord", coord, 1); ++ return RETERR(-EIO); ++ } ++ assert("nikita-1137", iplug->s.dir.extract_name); ++ ++ /* Compare name stored in this entry with name we are looking for. ++ ++ NOTE-NIKITA Here should go code for support of something like ++ unicode, code tables, etc. ++ */ ++ return !!strcmp(name, iplug->s.dir.extract_name(coord, buf)); ++} ++ ++static int ++check_entry(const struct inode *dir, coord_t *coord, const struct qstr *name) ++{ ++ return WITH_COORD(coord, check_item(dir, coord, name->name)); ++} ++ ++/* ++ * argument package used by entry_actor to scan entries with identical keys. ++ */ ++struct entry_actor_args { ++ /* name we are looking for */ ++ const char *name; ++ /* key of directory entry. entry_actor() scans through sequence of ++ * items/units having the same key */ ++ reiser4_key *key; ++ /* how many entries with duplicate key was scanned so far. */ ++ int non_uniq; ++#if REISER4_USE_COLLISION_LIMIT ++ /* scan limit */ ++ int max_non_uniq; ++#endif ++ /* return parameter: set to true, if ->name wasn't found */ ++ int not_found; ++ /* what type of lock to take when moving to the next node during ++ * scan */ ++ znode_lock_mode mode; ++ ++ /* last coord that was visited during scan */ ++ coord_t last_coord; ++ /* last node locked during scan */ ++ lock_handle last_lh; ++ /* inode of directory */ ++ const struct inode *inode; ++}; ++ ++/* Function called by reiser4_find_entry() to look for given name ++ in the directory. */ ++static int entry_actor(reiser4_tree * tree UNUSED_ARG /* tree being scanned */ , ++ coord_t *coord /* current coord */ , ++ lock_handle * lh /* current lock handle */ , ++ void *entry_actor_arg/* argument to scan */) ++{ ++ reiser4_key unit_key; ++ struct entry_actor_args *args; ++ ++ assert("nikita-1131", tree != NULL); ++ assert("nikita-1132", coord != NULL); ++ assert("nikita-1133", entry_actor_arg != NULL); ++ ++ args = entry_actor_arg; ++ ++args->non_uniq; ++#if REISER4_USE_COLLISION_LIMIT ++ if (args->non_uniq > args->max_non_uniq) { ++ args->not_found = 1; ++ /* hash collision overflow. */ ++ return RETERR(-EBUSY); ++ } ++#endif ++ ++ /* ++ * did we just reach the end of the sequence of items/units with ++ * identical keys? ++ */ ++ if (!keyeq(args->key, unit_key_by_coord(coord, &unit_key))) { ++ assert("nikita-1791", ++ keylt(args->key, unit_key_by_coord(coord, &unit_key))); ++ args->not_found = 1; ++ args->last_coord.between = AFTER_UNIT; ++ return 0; ++ } ++ ++ coord_dup(&args->last_coord, coord); ++ /* ++ * did scan just moved to the next node? ++ */ ++ if (args->last_lh.node != lh->node) { ++ int lock_result; ++ ++ /* ++ * if so, lock new node with the mode requested by the caller ++ */ ++ done_lh(&args->last_lh); ++ assert("nikita-1896", znode_is_any_locked(lh->node)); ++ lock_result = longterm_lock_znode(&args->last_lh, lh->node, ++ args->mode, ZNODE_LOCK_HIPRI); ++ if (lock_result != 0) ++ return lock_result; ++ } ++ return check_item(args->inode, coord, args->name); ++} ++ ++/* Look for given @name within directory @dir. ++ ++ This is called during lookup, creation and removal of directory ++ entries and on reiser4_rename_common ++ ++ First calculate key that directory entry for @name would have. Search ++ for this key in the tree. If such key is found, scan all items with ++ the same key, checking name in each directory entry along the way. ++*/ ++int reiser4_find_entry(struct inode *dir, /* directory to scan */ ++ struct dentry *de, /* name to search for */ ++ lock_handle * lh, /* resulting lock handle */ ++ znode_lock_mode mode, /* required lock mode */ ++ reiser4_dir_entry_desc * entry /* parameters of found ++ directory entry */) ++{ ++ const struct qstr *name; ++ seal_t *seal; ++ coord_t *coord; ++ int result; ++ __u32 flags; ++ struct de_location *dec; ++ struct reiser4_dentry_fsdata *fsdata; ++ ++ assert("nikita-1130", lh != NULL); ++ assert("nikita-1128", dir != NULL); ++ ++ name = &de->d_name; ++ assert("nikita-1129", name != NULL); ++ ++ /* dentry private data don't require lock, because dentry ++ manipulations are protected by i_mutex on parent. ++ ++ This is not so for inodes, because there is no -the- parent in ++ inode case. ++ */ ++ fsdata = reiser4_get_dentry_fsdata(de); ++ if (IS_ERR(fsdata)) ++ return PTR_ERR(fsdata); ++ dec = &fsdata->dec; ++ ++ coord = &dec->entry_coord; ++ coord_clear_iplug(coord); ++ seal = &dec->entry_seal; ++ /* compose key of directory entry for @name */ ++ inode_dir_plugin(dir)->build_entry_key(dir, name, &entry->key); ++ ++ if (reiser4_seal_is_set(seal)) { ++ /* check seal */ ++ result = reiser4_seal_validate(seal, ++ meta_subvol_tree(), ++ coord, &entry->key, ++ lh, mode, ZNODE_LOCK_LOPRI); ++ if (result == 0) { ++ /* key was found. Check that it is really item we are ++ looking for. */ ++ result = check_entry(dir, coord, name); ++ if (result == 0) ++ return 0; ++ } ++ } ++ flags = (mode == ZNODE_WRITE_LOCK) ? CBK_FOR_INSERT : 0; ++ /* ++ * find place in the tree where directory item should be located. ++ */ ++ result = reiser4_object_lookup(meta_subvol_tree(), ++ dir, &entry->key, coord, lh, mode, ++ FIND_EXACT, LEAF_LEVEL, LEAF_LEVEL, ++ flags, NULL/*ra_info */); ++ if (result == CBK_COORD_FOUND) { ++ struct entry_actor_args arg; ++ ++ /* fast path: no hash collisions */ ++ result = check_entry(dir, coord, name); ++ if (result == 0) { ++ reiser4_seal_init(seal, coord, &entry->key); ++ dec->pos = 0; ++ } else if (result > 0) { ++ /* Iterate through all units with the same keys. */ ++ arg.name = name->name; ++ arg.key = &entry->key; ++ arg.not_found = 0; ++ arg.non_uniq = 0; ++#if REISER4_USE_COLLISION_LIMIT ++ arg.max_non_uniq = max_hash_collisions(dir); ++ assert("nikita-2851", arg.max_non_uniq > 1); ++#endif ++ arg.mode = mode; ++ arg.inode = dir; ++ coord_init_zero(&arg.last_coord); ++ init_lh(&arg.last_lh); ++ ++ result = reiser4_iterate_tree(meta_subvol_tree(), ++ coord, lh, ++ entry_actor, ++ &arg, mode, 1); ++ /* if end of the tree or extent was reached during ++ scanning. */ ++ if (arg.not_found || (result == -E_NO_NEIGHBOR)) { ++ /* step back */ ++ done_lh(lh); ++ ++ result = zload(arg.last_coord.node); ++ if (result == 0) { ++ coord_clear_iplug(&arg.last_coord); ++ coord_dup(coord, &arg.last_coord); ++ move_lh(lh, &arg.last_lh); ++ result = RETERR(-ENOENT); ++ zrelse(arg.last_coord.node); ++ --arg.non_uniq; ++ } ++ } ++ ++ done_lh(&arg.last_lh); ++ if (result == 0) ++ reiser4_seal_init(seal, coord, &entry->key); ++ ++ if (result == 0 || result == -ENOENT) { ++ assert("nikita-2580", arg.non_uniq > 0); ++ dec->pos = arg.non_uniq - 1; ++ } ++ } ++ } else ++ dec->pos = -1; ++ return result; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format40.c linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format40.c +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format40.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format40.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,884 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../key.h" ++#include "../node/node.h" ++#include "../space/space_allocator.h" ++#include "disk_format40.h" ++#include "../plugin.h" ++#include "../../txnmgr.h" ++#include "../../jnode.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../../plugin/volume/volume.h" ++#include "../../wander.h" ++#include "../../inode.h" ++#include "../../ktxnmgrd.h" ++#include "../../status_flags.h" ++ ++#include ++#include ++#include ++ ++/* ++ * Methods of standard disk layout for simple volumes (i.e. volumes ++ * associated with a single physical, or logical (RAID, LVM) device. ++ */ ++ ++/* ++ * Amount of free blocks needed to perform release_format40 when fs gets ++ * mounted RW: ++ * 1 for SB, ++ * 1 for non-leaves in overwrite set, ++ * 2 for tx header & tx record ++ */ ++#define RELEASE_RESERVED 4 ++ ++/* ++ * This flag indicates that backup should be updated by fsck ++ */ ++#define FORMAT40_UPDATE_BACKUP (1 << 31) ++ ++/* ++ * Functions to access fields of format40_disk_super_block ++ */ ++static __u64 get_format40_block_count(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->block_count)); ++} ++ ++static __u64 get_format40_free_blocks(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->free_blocks)); ++} ++ ++static __u64 get_format40_root_block(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->root_block)); ++} ++ ++static __u16 get_format40_tree_height(const format40_disk_super_block * sb) ++{ ++ return le16_to_cpu(get_unaligned(&sb->tree_height)); ++} ++ ++static __u64 get_format40_file_count(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->file_count)); ++} ++ ++static __u64 get_format40_oid(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->oid)); ++} ++ ++static __u32 get_format40_mkfs_id(const format40_disk_super_block * sb) ++{ ++ return le32_to_cpu(get_unaligned(&sb->mkfs_id)); ++} ++ ++static __u32 get_format40_node_plugin_id(const format40_disk_super_block * sb) ++{ ++ return le32_to_cpu(get_unaligned(&sb->node_pid)); ++} ++ ++static __u64 get_format40_flags(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->flags)); ++} ++ ++static __u64 get_format40_origin_id(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->origin_id)); ++} ++ ++static __u64 get_format40_nr_origins(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->nr_origins)); ++} ++ ++static int get_format40_num_sgs_bits(const format40_disk_super_block * sb) ++{ ++ return sb->num_sgs_bits; ++} ++ ++static __u64 get_format40_data_capacity(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->data_capacity)); ++} ++ ++static __u64 get_format40_volinfo_loc(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->volinfo_loc)); ++} ++ ++static __u64 get_format40_nr_mslots(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->nr_mslots)); ++} ++ ++static __u64 get_format40_min_occup(const format40_disk_super_block * sb) ++{ ++ return le64_to_cpu(get_unaligned(&sb->min_occup)); ++} ++ ++static __u32 format40_get_minor_version_nr(const format40_disk_super_block * sb) ++{ ++ return le32_to_cpu(get_unaligned(&sb->version)) & ++ ~FORMAT40_UPDATE_BACKUP; ++} ++ ++static int update_backup_version(const format40_disk_super_block * sb) ++{ ++ return (le32_to_cpu(get_unaligned(&sb->version)) & ++ FORMAT40_UPDATE_BACKUP); ++} ++ ++static int update_disk_version_minor(const format40_disk_super_block * sb) ++{ ++ return format40_get_minor_version_nr(sb) < get_release_number_minor(); ++} ++ ++static int incomplete_compatibility(const format40_disk_super_block * sb) ++{ ++ return format40_get_minor_version_nr(sb) > get_release_number_minor(); ++} ++ ++static int get_sb_format_jnode(reiser4_subvol *subv) ++{ ++ int ret; ++ jnode *sb_jnode; ++ ++ sb_jnode = reiser4_alloc_io_head(&subv->loc_super, subv); ++ ++ ret = jload(sb_jnode); ++ ++ if (ret) { ++ reiser4_drop_io_head(sb_jnode); ++ return ret; ++ } ++ pin_jnode_data(sb_jnode); ++ jrelse(sb_jnode); ++ ++ subv->sb_jnode = sb_jnode; ++ ++ return 0; ++} ++ ++static void put_sb_format_jnode(reiser4_subvol *subv) ++{ ++ if (subv->sb_jnode) { ++ unpin_jnode_data(subv->sb_jnode); ++ reiser4_drop_io_head(subv->sb_jnode); ++ subv->sb_jnode = NULL; ++ } ++} ++ ++typedef enum format40_init_stage { ++ NONE_DONE = 0, ++ CONSULT_DISKMAP, ++ FIND_A_SUPER, ++ INIT_JOURNAL_INFO, ++ INIT_STATUS, ++ JOURNAL_REPLAY, ++ READ_SUPER, ++ KEY_CHECK, ++ INIT_OID, ++ INIT_TREE, ++ JOURNAL_RECOVER, ++ INIT_SA, ++ INIT_JNODE, ++ INIT_SYSTAB, ++ ALL_DONE ++} format40_init_stage; ++ ++static int check_key_format(const format40_disk_super_block *sb_copy) ++{ ++ if (!equi(REISER4_LARGE_KEY, ++ get_format40_flags(sb_copy) & (1 << FORMAT40_LARGE_KEYS))) { ++ warning("nikita-3228", "Key format mismatch. " ++ "Only %s keys are supported.", ++ REISER4_LARGE_KEY ? "large" : "small"); ++ return RETERR(-EINVAL); ++ } ++ if (!equi(REISER4_PLANB_KEY_ALLOCATION, ++ get_format40_flags(sb_copy) & (1 << FORMAT40_PLANB_KEY_ALLOC))) { ++ warning("edward-2311", "Key allocation scheme mismatch. " ++ "Only %s key allocation is supported.", ++ REISER4_PLANB_KEY_ALLOCATION ? "Plan-B" : "Plan-A"); ++ return RETERR(-EINVAL); ++ } ++ return 0; ++} ++ ++/** ++ * Read on-disk system parameters, which define volume configuration. ++ * Perform sanity check. ++ */ ++int read_check_volume_params(reiser4_subvol *subv, ++ format40_disk_super_block *sb_format) ++{ ++ reiser4_volume *vol; ++ ++ if (subvol_is_set(subv, SUBVOL_IS_ORPHAN)) { ++ /* ++ * Don't check parameters of new brick ++ * as they are invalid (to be set later). ++ * Set invalid brick ID to not confuse ++ * the new brick with meta-data brick ++ */ ++ subv->id = INVALID_SUBVOL_ID; ++ return 0; ++ } ++ vol = super_volume(subv->super); ++ ++ if (is_meta_brick_id(subv->id)) { ++ u32 nr_mslots; ++ u32 nr_origins; ++ ++ nr_origins = get_format40_nr_origins(sb_format); ++ if (nr_origins == 0) ++ /* ++ * This is a subvolume of format 4.0.Y ++ * We handle this special case for backward ++ * compatibility - guess number of subvolumes ++ */ ++ nr_origins = 1; ++ atomic_set(&vol->nr_origins, nr_origins); ++ vol->num_sgs_bits = get_format40_num_sgs_bits(sb_format); ++ ++ nr_mslots = get_format40_nr_mslots(sb_format); ++ if (nr_mslots == 0) { ++ /* ditto - guess number of mslots */ ++ assert("edward-2228", nr_origins == 1); ++ nr_mslots = 1; ++ } ++ if (!vol->conf) { ++ vol->conf = alloc_lv_conf(nr_mslots); ++ if (!vol->conf) ++ return -ENOMEM; ++ } else if (vol->conf != NULL && nr_mslots > 1) { ++ /* ++ * This it temporary config created ++ * for meta-data brick activation. ++ * Replace it with actual one. ++ */ ++ lv_conf *new_conf; ++ int meta_subv_id; ++ ++ meta_subv_id = vol->vol_plug->meta_subvol_id(); ++ ++ assert("edward-2304", vol->conf->nr_mslots == 1); ++ assert("edward-2305", ++ vol->conf->mslots[meta_subv_id][1] != NULL); ++ assert("edward-2306", vol->conf->tab == NULL); ++ ++ new_conf = alloc_lv_conf(nr_mslots); ++ if (!new_conf) ++ return -ENOMEM; ++ /* ++ * copy actual info from temporary config ++ * to the new one ++ */ ++ new_conf->mslots[meta_subv_id] = ++ vol->conf->mslots[meta_subv_id]; ++ free_lv_conf(vol->conf); ++ vol->conf = new_conf; ++ } ++ } ++ assert("edward-2307", vol->conf != NULL); ++ if (subv->id >= vol->conf->nr_mslots) { ++ warning("edward-2308", ++ "brick %s (ID %llu) is inappropriate: too few mslots (%llu)", ++ subv->name, subv->id, vol->conf->nr_mslots); ++ return -EINVAL; ++ } ++ return 0; ++} ++ ++/** ++ * Find disk format super block at specified location. Note that it ++ * may be not the most recent version in the case of calling before ++ * journal replay. In this case the caller should have a guarantee ++ * that needed data are really actual. ++ * Perform checks and initialisations in accordance with format40 ++ * specifications. ++ * ++ * Pre-condition: @super contains valid block size ++ */ ++static int find_format40(reiser4_subvol *subv, ++ format40_disk_super_block *disk_sb) ++{ ++ int ret; ++ struct page *page; ++ reiser4_volume *vol; ++ ++ assert("edward-1788", subv != NULL); ++ assert("edward-1789", subv->super != NULL); ++ ++ vol = super_volume(subv->super); ++ ++ page = read_cache_page_gfp(subv->bdev->bd_inode->i_mapping, ++ subv->loc_super, ++ GFP_NOFS); ++ if (IS_ERR_OR_NULL(page)) ++ return RETERR(-EIO); ++ ++ memcpy(disk_sb, kmap(page), sizeof (*disk_sb)); ++ kunmap(page); ++ put_page(page); ++ if (strncmp(disk_sb->magic, FORMAT40_MAGIC, sizeof(FORMAT40_MAGIC))) ++ /* ++ * there is no reiser4 on this device ++ */ ++ return RETERR(-EINVAL); ++ ret = read_check_volume_params(subv, disk_sb); ++ if (ret) ++ return RETERR(-EINVAL); ++ reiser4_subvol_set_block_count(subv, ++ get_format40_block_count(disk_sb)); ++ reiser4_subvol_set_free_blocks(subv, ++ get_format40_free_blocks(disk_sb)); ++ /* ++ * Set number of used blocks. The number of used blocks is stored ++ * neither in on-disk super block nor in the journal footer blocks. ++ * Instead we maintain it along with actual values of total blocks ++ * and free block counters in the in-memory subvolume header ++ */ ++ reiser4_subvol_set_used_blocks(subv, ++ reiser4_subvol_block_count(subv) - ++ reiser4_subvol_free_blocks(subv)); ++ return 0; ++} ++ ++int extract_subvol_id_format40(struct block_device *bdev, u64 *subv_id) ++{ ++ *subv_id = 0; ++ return 0; ++} ++ ++/** ++ * Read disk forat super-block, retrieve internal subvolume ID ++ * and store it in @subv_id ++ */ ++int extract_subvol_id_format41(struct block_device *bdev, u64 *subv_id) ++{ ++ struct page *page; ++ format40_disk_super_block *format_sb; ++ ++ page = read_cache_page_gfp(bdev->bd_inode->i_mapping, ++ FORMAT40_OFFSET >> PAGE_SHIFT, ++ GFP_NOFS); ++ if (IS_ERR_OR_NULL(page)) ++ return RETERR(-EIO); ++ ++ format_sb = kmap(page); ++ if (strncmp(format_sb->magic, ++ FORMAT40_MAGIC, sizeof(FORMAT40_MAGIC))) { ++ /* ++ * format40 not found ++ */ ++ kunmap(page); ++ put_page(page); ++ return RETERR(-EINVAL); ++ } ++ *subv_id = get_format40_origin_id(format_sb); ++ kunmap(page); ++ put_page(page); ++ return 0; ++} ++ ++/** ++ * Initialize in-memory subvolume header. ++ * Pre-condition: we are sure that subvolume is managed by expected ++ * disk format plugin(that is, format superblock with correct magic ++ * was found). ++ */ ++static int try_init_format(struct super_block *super, ++ format40_init_stage *stage, ++ reiser4_subvol *subv, int major_version_nr) ++{ ++ int result; ++ format40_disk_super_block sb_format; ++ tree_level height; ++ reiser4_block_nr root_block; ++ node_plugin *nplug; ++ u64 extended_status; ++ reiser4_volume *vol; ++ ++ assert("vs-475", super != NULL); ++ assert("vs-474", get_super_private(super) != NULL); ++ assert("edward-1790", get_super_private(super)->vol != NULL); ++ assert("edward-1791", !is_replica(subv)); ++ ++ vol = get_super_private(super)->vol; ++ ++ *stage = NONE_DONE; ++ ++ subv->jloc.footer = FORMAT40_JOURNAL_FOOTER_BLOCKNR; ++ subv->jloc.header = FORMAT40_JOURNAL_HEADER_BLOCKNR; ++ subv->loc_super = FORMAT40_OFFSET / subv->super->s_blocksize; ++ ++ result = reiser4_init_journal_info(subv); ++ if (result) ++ return result; ++ *stage = INIT_JOURNAL_INFO; ++ ++ result = reiser4_status_init(subv, FORMAT40_STATUS_BLOCKNR); ++ if (result != 0 && result != -EINVAL) ++ /* ++ * -EINVAL means there is no magic, so probably just old fs ++ */ ++ return result; ++ *stage = INIT_STATUS; ++ ++ result = reiser4_status_query(subv, NULL, &extended_status); ++ if (result == REISER4_STATUS_MOUNT_WARN) ++ warning("vpf-1363", "Mounting %s with errors.", ++ super->s_id); ++ ++ if (result == REISER4_STATUS_MOUNT_RO) { ++ warning("vpf-1364", "Mounting %s with fatal errors. " ++ "Forcing read-only mount.", super->s_id); ++ super->s_flags |= SB_RDONLY; ++ } ++ if (has_replicas(subv) && ++ extended_status == REISER4_ESTATUS_MIRRORS_NOT_SYNCED) { ++ warning("edward-1792", ++ "Mounting %s with not synced mirrors. " ++ "Forcing read-only mount.", super->s_id); ++ super->s_flags |= SB_RDONLY; ++ } ++ /* ++ * Start form journal replay to make sure we are dealing ++ * with actual (most recent) data. All replicas will get ++ * respective update. ++ */ ++ result = reiser4_journal_replay(subv); ++ if (result) ++ return result; ++ *stage = JOURNAL_REPLAY; ++ /* ++ * Now read the most recent version of format superblock ++ * after journal replay ++ */ ++ result = find_format40(subv, &sb_format); ++ if (result) ++ return result; ++ *stage = READ_SUPER; ++ ++ printk("reiser4 (%s): found disk format %d.%d.%d.\n", ++ super->s_id, ++ get_format_number_principal(major_version_nr), ++ major_version_nr, ++ format40_get_minor_version_nr(&sb_format)); ++ ++ if (incomplete_compatibility(&sb_format)) ++ printk("reiser4 (%s): format version number (%d.%d.%d) is " ++ "greater than release number (%d.%d.%d) of reiser4 " ++ "kernel module. Some objects of the subvolume can " ++ "be inaccessible.\n", ++ super->s_id, ++ get_format_number_principal(major_version_nr), ++ major_version_nr, ++ format40_get_minor_version_nr(&sb_format), ++ get_release_number_principal(), ++ get_release_number_major(), ++ get_release_number_minor()); ++ /* ++ * make sure that key format of kernel and filesystem match ++ */ ++ result = check_key_format(&sb_format); ++ if (result) ++ return result; ++ ++ *stage = KEY_CHECK; ++ /* ++ * convert on-disk flags to on-line state ++ */ ++ if (get_format40_flags(&sb_format) & (1 << FORMAT40_HAS_DATA_ROOM)) ++ subv->flags |= (1 << SUBVOL_HAS_DATA_ROOM); ++ ++ if (get_format40_flags(&sb_format) & (1 << FORMAT40_TO_BE_REMOVED)) { ++ subv->flags |= (1 << SUBVOL_TO_BE_REMOVED); ++ reiser4_volume_set_incomplete_removal(super); ++ } ++ ++ if (get_format40_flags(&sb_format) & (1 << FORMAT40_IS_PROXY)) { ++ subv->flags |= (1 << SUBVOL_IS_PROXY); ++ if (reiser4_is_set(super, REISER4_PROXY_ENABLED)) { ++ warning("edward-2430", ++ "Found second proxy subvolume %s", subv->name); ++ return -EINVAL; ++ } ++ reiser4_volume_set_proxy_enabled(super); ++ reiser4_volume_set_proxy_io(super); ++ } ++ if (is_meta_brick_id(subv->id)) { ++ result = oid_init_allocator(super, ++ get_format40_file_count(&sb_format), ++ get_format40_oid(&sb_format)); ++ if (result) ++ return result; ++ ++ if (get_format40_flags(&sb_format) & (1 << FORMAT40_UNBALANCED_VOLUME)) ++ reiser4_volume_set_unbalanced(super); ++ } ++ *stage = INIT_OID; ++ ++ root_block = get_format40_root_block(&sb_format); ++ height = get_format40_tree_height(&sb_format); ++ nplug = node_plugin_by_id(get_format40_node_plugin_id(&sb_format)); ++ /* ++ * initialize storage tree. ++ */ ++ result = reiser4_subvol_init_tree(subv, &root_block, height, nplug); ++ if (result) ++ return result; ++ *stage = INIT_TREE; ++ /* ++ * set private subvolume parameters ++ */ ++ subv->mkfs_id = get_format40_mkfs_id(&sb_format); ++ subv->version = format40_get_minor_version_nr(&sb_format); ++ subv->blocks_free_committed = subv->blocks_free; ++ ++ subv->flush.relocate_threshold = FLUSH_RELOCATE_THRESHOLD; ++ subv->flush.relocate_distance = FLUSH_RELOCATE_DISTANCE; ++ subv->flush.written_threshold = FLUSH_WRITTEN_THRESHOLD; ++ subv->flush.scan_maxnodes = FLUSH_SCAN_MAXNODES; ++ ++ if (update_backup_version(&sb_format)) ++ printk("reiser4: %s: use 'fsck.reiser4 --fix' " ++ "to complete disk format upgrade.\n", super->s_id); ++ /* ++ * all formatted nodes in a subvolume managed by format40 ++ * are of one plugin ++ */ ++ subv->flags |= (1 << SUBVOL_ONE_NODE_PLUGIN); ++ /* ++ * Recover sb data which were logged separately from sb block ++ * NOTE-NIKITA: reiser4_journal_recover_sb_data() calls ++ * oid_init_allocator() and reiser4_set_free_blocks() with new ++ * data. What's the reason to call them above? ++ */ ++ result = reiser4_journal_recover_sb_data(super, subv); ++ if (result) ++ return result; ++ *stage = JOURNAL_RECOVER; ++ /* ++ * recover_sb_data() sets actual data of free blocks, ++ * So we need to update the number of used blocks. ++ */ ++ reiser4_subvol_set_used_blocks(subv, ++ reiser4_subvol_block_count(subv) - ++ reiser4_subvol_free_blocks(subv)); ++ reiser4_subvol_set_min_blocks_used(subv, ++ get_format40_min_occup(&sb_format)); ++ /* ++ * init disk space allocator ++ */ ++ result = sa_init_allocator(&subv->space_allocator, super, subv, NULL); ++ if (result) ++ return result; ++ *stage = INIT_SA; ++ ++ result = get_sb_format_jnode(subv); ++ if (result) ++ return result; ++ *stage = INIT_JNODE; ++ ++ reiser4_subvol_set_data_capacity(subv, ++ get_format40_data_capacity(&sb_format)); ++ /* ++ * load addresses of volume configs ++ */ ++ subv->volmap_loc[CUR_VOL_CONF] = get_format40_volinfo_loc(&sb_format); ++ ++ if (vol->vol_plug->load_volume) { ++ result = vol->vol_plug->load_volume(subv); ++ if (result) ++ return result; ++ } ++ *stage = ALL_DONE; ++ ++ printk("reiser4 (%s): using %s.\n", subv->name, ++ txmod_plugin_by_id(subv->txmod)->h.desc); ++ return 0; ++} ++ ++static int init_format_generic(struct super_block *s, ++ reiser4_subvol *subv, int version) ++{ ++ int result; ++ format40_init_stage stage; ++ reiser4_volume *vol; ++ ++ vol = get_super_private(s)->vol; ++ ++ result = try_init_format(s, &stage, subv, version); ++ switch (stage) { ++ case ALL_DONE: ++ assert("nikita-3458", result == 0); ++ break; ++ case INIT_SYSTAB: ++ case INIT_JNODE: ++ put_sb_format_jnode(subv); ++ /* fall through */ ++ case INIT_SA: ++ sa_destroy_allocator(reiser4_get_space_allocator(subv), ++ s, subv); ++ /* fall through */ ++ case JOURNAL_RECOVER: ++ case INIT_TREE: ++ reiser4_done_tree(&subv->tree); ++ /* fall through */ ++ case INIT_OID: ++ case KEY_CHECK: ++ case READ_SUPER: ++ if (!sb_rdonly(s) && ++ reiser4_subvol_free_blocks(subv) < RELEASE_RESERVED) ++ result = RETERR(-ENOSPC); ++ /* fall through */ ++ case JOURNAL_REPLAY: ++ case INIT_STATUS: ++ reiser4_status_finish(subv); ++ /* fall through */ ++ case INIT_JOURNAL_INFO: ++ reiser4_done_journal_info(subv); ++ /* fall through */ ++ case NONE_DONE: ++ break; ++ default: ++ impossible("nikita-3457", "init stage: %i", stage); ++ } ++ return result; ++} ++ ++int init_format_format40(struct super_block *s, reiser4_subvol *subv) ++{ ++ return init_format_generic(s, subv, 0 /* version */); ++} ++ ++int init_format_format41(struct super_block *s, reiser4_subvol *subv) ++{ ++ return init_format_generic(s, subv, 1 /* version */); ++} ++ ++static void pack_format40_super(const struct super_block *s, ++ reiser4_subvol *subv, char *data) ++{ ++ format40_disk_super_block *format_sb = ++ (format40_disk_super_block *) data; ++ reiser4_volume *vol = super_volume(s); ++ lv_conf *conf = vol->conf; ++ u64 format_flags = get_format40_flags(format_sb); ++ ++ assert("zam-591", data != NULL); ++ ++ put_unaligned(cpu_to_le64(reiser4_subvol_free_committed_blocks(subv)), ++ &format_sb->free_blocks); ++ ++ put_unaligned(cpu_to_le64(subv->tree.root_block), ++ &format_sb->root_block); ++ ++ put_unaligned(cpu_to_le64(oid_next(s)), &format_sb->oid); ++ ++ put_unaligned(cpu_to_le64(oids_used(s)), &format_sb->file_count); ++ ++ put_unaligned(cpu_to_le16(subv->tree.height), &format_sb->tree_height); ++ ++ put_unaligned(cpu_to_le64(subv->id), &format_sb->origin_id); ++ ++ put_unaligned(cpu_to_le64(subv->data_capacity), &format_sb->data_capacity); ++ ++ if (update_disk_version_minor(format_sb)) { ++ __u32 version = PLUGIN_LIBRARY_VERSION | FORMAT40_UPDATE_BACKUP; ++ ++ put_unaligned(cpu_to_le32(version), &format_sb->version); ++ } ++ /* ++ * convert on-line state to on-disk flags ++ */ ++ if (subv->flags & (1 << SUBVOL_TO_BE_REMOVED)) ++ format_flags |= (1 << FORMAT40_TO_BE_REMOVED); ++ else ++ format_flags &= ~(1 << FORMAT40_TO_BE_REMOVED); ++ ++ if (subv->flags & (1 << SUBVOL_IS_PROXY)) ++ format_flags |= (1 << FORMAT40_IS_PROXY); ++ else ++ format_flags &= ~(1 << FORMAT40_IS_PROXY); ++ ++ if (subv->flags & (1 << SUBVOL_HAS_DATA_ROOM)) ++ format_flags |= (1 << FORMAT40_HAS_DATA_ROOM); ++ else ++ format_flags &= ~(1 << FORMAT40_HAS_DATA_ROOM); ++ ++ if (is_meta_brick(subv)) { ++ if (reiser4_volume_is_unbalanced(s)) ++ format_flags |= (1 << FORMAT40_UNBALANCED_VOLUME); ++ else ++ format_flags &= ~(1 << FORMAT40_UNBALANCED_VOLUME); ++ ++ put_unaligned(cpu_to_le64(vol_nr_origins(vol)), &format_sb->nr_origins); ++ ++ put_unaligned(cpu_to_le64(conf->nr_mslots), &format_sb->nr_mslots); ++ ++ put_unaligned(cpu_to_le64(subv->volmap_loc[CUR_VOL_CONF]), &format_sb->volinfo_loc); ++ ++ put_unaligned(vol->num_sgs_bits, &format_sb->num_sgs_bits); ++ } ++ put_unaligned(cpu_to_le64(format_flags), &format_sb->flags); ++} ++ ++/** ++ * ->log_super() method of disk_format40 plugin. ++ * Return a jnode which should be added to a transaction when the super block ++ * gets logged ++ */ ++jnode *log_super_format40(struct super_block *super, reiser4_subvol *subv) ++{ ++ jload(subv->sb_jnode); ++ pack_format40_super(super, subv, jdata(subv->sb_jnode)); ++ jrelse(subv->sb_jnode); ++ ++ return subv->sb_jnode; ++} ++ ++/** ++ * ->release() method of disk_format40 plugin ++ */ ++int release_format40(struct super_block *s, reiser4_subvol *subv) ++{ ++ sa_destroy_allocator(&subv->space_allocator, s, subv); ++ reiser4_done_journal_info(subv); ++ put_sb_format_jnode(subv); ++ ++ rcu_barrier(); ++ reiser4_done_tree(&subv->tree); ++ /* ++ * call finish_rcu(), because some znode ++ * were "released" in reiser4_done_tree() ++ */ ++ rcu_barrier(); ++ ++ return 0; ++} ++ ++#define FORMAT40_ROOT_LOCALITY 41 ++#define FORMAT40_ROOT_OBJECTID 42 ++ ++/** ++ * ->root_dir_key() method of disk_format40 plugin ++ */ ++const reiser4_key *root_dir_key_format40(const struct super_block *super ++ UNUSED_ARG) ++{ ++ static const reiser4_key FORMAT40_ROOT_DIR_KEY = { ++ .el = { ++ __constant_cpu_to_le64((FORMAT40_ROOT_LOCALITY << 4) | ++ KEY_SD_MINOR), ++#if REISER4_LARGE_KEY ++ ON_LARGE_KEY(0ull,) ++#endif ++ __constant_cpu_to_le64(FORMAT40_ROOT_OBJECTID), ++ 0ull ++ } ++ }; ++ return &FORMAT40_ROOT_DIR_KEY; ++} ++ ++/** ++ * ->check_open() method of disk_format40 plugin ++ * Check the opened object for validness. ++ * For now it checks for the valid oid & locality only, ++ * can be improved later and it its work may depend on ++ * the mount options ++ */ ++int check_open_format40(const struct inode *object) ++{ ++ oid_t max, oid; ++ ++ max = oid_next(object->i_sb) - 1; ++ /* ++ * Check the oid ++ */ ++ oid = get_inode_oid(object); ++ if (oid > max) { ++ warning("vpf-1360", "The object with the oid %llu " ++ "greater then the max used oid %llu found.", ++ (unsigned long long)oid, (unsigned long long)max); ++ ++ return RETERR(-EIO); ++ } ++ /* ++ * Check the locality ++ */ ++ oid = reiser4_inode_data(object)->locality_id; ++ if (oid > max) { ++ warning("vpf-1361", "The object with the locality %llu " ++ "greater then the max used oid %llu found.", ++ (unsigned long long)oid, (unsigned long long)max); ++ ++ return RETERR(-EIO); ++ } ++ return 0; ++} ++ ++static int version_update_common(struct super_block *super, ++ reiser4_subvol *subv, int major) ++{ ++ int ret; ++ lock_handle lh; ++ ++ if (sb_rdonly(super) || subv->version >= get_release_number_minor()) ++ return 0; ++ ++ printk("reiser4 (%s): upgrading disk format to %d.%d.%d.\n", ++ subv->name, ++ get_format_number_principal(major), ++ major, ++ get_release_number_minor()); ++ ++ printk("reiser4 (%s): use 'fsck.reiser4 --fix' " ++ "to complete disk format upgrade.\n", subv->name); ++ /* ++ * Mark the uber znode dirty to call ->log_super() on write_logs ++ */ ++ init_lh(&lh); ++ ret = get_uber_znode(&subv->tree, ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_HIPRI, &lh); ++ if (ret) { ++ BUG_ON(ret > 0); ++ return ret; ++ } ++ znode_make_dirty(lh.node); ++ done_lh(&lh); ++ /* ++ * Backup blocks stuff in fsck makes me queasy - Edward. ++ */ ++ return 1; ++} ++ ++int version_update_format40(struct super_block *super, reiser4_subvol *subv) ++{ ++ return version_update_common(super, subv, 0); ++} ++ ++int version_update_format41(struct super_block *super, reiser4_subvol *subv) ++{ ++ return version_update_common(super, subv, 1); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format40.h linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format40.h +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format40.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format40.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,123 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* ++ * Objects of Standard Disk Layout for simple volumes (i.e. volumes ++ * associated with a single physical, or logical (RAID, LVM) device. ++ */ ++ ++#ifndef __DISK_FORMAT40_H__ ++#define __DISK_FORMAT40_H__ ++ ++/* magic for default reiser4 layout */ ++#define FORMAT40_MAGIC "ReIsEr40FoRmAt" ++#define FORMAT40_OFFSET (REISER4_MASTER_OFFSET + PAGE_SIZE) ++ ++#include "../../dformat.h" ++#include ++ ++typedef enum { ++ FORMAT40_LARGE_KEYS, ++ FORMAT40_UNBALANCED_VOLUME, ++ FORMAT40_HAS_DATA_ROOM, ++ FORMAT40_TO_BE_REMOVED, ++ FORMAT40_PLANB_KEY_ALLOC, ++ FORMAT40_IS_PROXY, ++} format40_flags; ++ ++/* ondisk super block for format 40. It is 512 bytes long */ ++typedef struct format40_disk_super_block { ++ /* 0 */ d64 block_count; ++ /* number of block in a filesystem */ ++ /* 8 */ d64 free_blocks; ++ /* number of free blocks */ ++ /* 16 */ d64 root_block; ++ /* filesystem tree root block */ ++ /* 24 */ d64 oid; ++ /* smallest free objectid */ ++ /* 32 */ d64 file_count; ++ /* number of files in a filesystem */ ++ /* 40 */ d64 flushes; ++ /* number of times super block was ++ flushed. Needed if format 40 ++ will have few super blocks */ ++ /* 48 */ d32 mkfs_id; ++ /* unique identifier of fs */ ++ /* 52 */ char magic[16]; ++ /* magic string ReIsEr40FoRmAt */ ++ /* 68 */ d16 tree_height; ++ /* height of filesystem tree */ ++ /* 70 */ d16 formatting_policy; ++ /* not used anymore */ ++ /* 72 */ d64 flags; ++ /* 80 */ d32 version; ++ /* on-disk format version number ++ initially assigned by mkfs as the greatest format40 ++ version number supported by reiser4progs and updated ++ in mount time in accordance with the greatest format40 ++ version number supported by kernel. ++ Is used by fsck to catch possible corruption and ++ for various compatibility issues */ ++ /* 84 */ d32 node_pid; /* formatted node plugin id */ ++ ++ /* Reiser5 fields */ ++ /* 88 */ d64 origin_id; /* internal ID of the subvolume. It gets assigned ++ once and never changes */ ++ /* 96 */ d64 nr_origins; /* total number of original subvolumes in LV */ ++ /* 104 */ d64 data_capacity;/* weight of the brick in data storage array */ ++ /* 112 */ d64 volinfo_loc; /* location of the first block of system LV info */ ++ /* 120 */ d8 num_sgs_bits; /* logarithm of total number of the hash-space ++ segments */ ++ /* 121 */ d64 nr_mslots; /* number of mslots (== maximal brick ID + 1) */ ++ /* 129 */ d64 min_occup; /* mimimal possible number of occupied blocks on ++ * the partition (reserved area at the beginning ++ * of the partition + 2 super-blocks + 1 journal ++ * footer + 1 journal header + backup blocks that ++ * kernel is not aware of, etc). This is set by ++ * mkfs.reiser4 utility and never gets changed */ ++ char not_used[375]; ++} __attribute__((packed)) format40_disk_super_block; ++ ++/* Defines for journal header and footer respectively. */ ++#define FORMAT40_JOURNAL_HEADER_BLOCKNR \ ++ ((REISER4_MASTER_OFFSET / PAGE_SIZE) + 3) ++ ++#define FORMAT40_JOURNAL_FOOTER_BLOCKNR \ ++ ((REISER4_MASTER_OFFSET / PAGE_SIZE) + 4) ++ ++#define FORMAT40_STATUS_BLOCKNR \ ++ ((REISER4_MASTER_OFFSET / PAGE_SIZE) + 5) ++ ++/* Diskmap declarations */ ++#define FORMAT40_PLUGIN_DISKMAP_ID ((REISER4_FORMAT_PLUGIN_TYPE<<16) | (FORMAT40_ID)) ++#define FORMAT40_SUPER 1 ++#define FORMAT40_JH 2 ++#define FORMAT40_JF 3 ++ ++/* ++ * declarations of functions implementing methods of layout plugin ++ * for format40. The functions theirself are in disk_format40.c ++ */ ++extern int extract_subvol_id_format40(struct block_device *bdev, u64 *subv_id); ++extern int extract_subvol_id_format41(struct block_device *bdev, u64 *subv_id); ++extern int init_format_format40(struct super_block *, reiser4_subvol *); ++extern int init_format_format41(struct super_block *, reiser4_subvol *); ++extern const reiser4_key *root_dir_key_format40(const struct super_block *); ++extern int release_format40(struct super_block *s, reiser4_subvol *); ++extern jnode *log_super_format40(struct super_block *s, reiser4_subvol *); ++extern int check_open_format40(const struct inode *object); ++extern int version_update_format40(struct super_block *super, reiser4_subvol *); ++extern int version_update_format41(struct super_block *super, reiser4_subvol *); ++ ++/* __DISK_FORMAT40_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format41.c linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format41.c +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format41.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format41.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,10 @@ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format41.h linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format41.h +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format41.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format41.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,15 @@ ++#ifndef __DISK_FORMAT41_H__ ++#define __DISK_FORMAT41_H__ ++ ++#endif /* __DISK_FORMAT41_H__ */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format.c linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format.c +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,56 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../debug.h" ++#include "../plugin_header.h" ++#include "disk_format40.h" ++#include "disk_format.h" ++#include "../plugin.h" ++ ++/* initialization of disk layout plugins */ ++disk_format_plugin format_plugins[LAST_FORMAT_ID] = { ++ [FORMAT40_ID] = { ++ .h = { ++ .type_id = REISER4_FORMAT_PLUGIN_TYPE, ++ .id = FORMAT40_ID, ++ .pops = NULL, ++ .label = "format40", ++ .desc = "standard disk layout for simple volumes", ++ .linkage = {NULL, NULL} ++ }, ++ .extract_subvol_id = extract_subvol_id_format40, ++ .init_format = init_format_format40, ++ .root_dir_key = root_dir_key_format40, ++ .release_format = release_format40, ++ .log_super = log_super_format40, ++ .check_open = check_open_format40, ++ .version_update = version_update_format40, ++ }, ++ [FORMAT41_ID] = { ++ .h = { ++ .type_id = REISER4_FORMAT_PLUGIN_TYPE, ++ .id = FORMAT41_ID, ++ .pops = NULL, ++ .label = "format41", ++ .desc = "standard disk layout for compound volumes", ++ .linkage = {NULL, NULL} ++ }, ++ .extract_subvol_id = extract_subvol_id_format41, ++ .init_format = init_format_format41, ++ .root_dir_key = root_dir_key_format40, ++ .release_format = release_format40, ++ .log_super = log_super_format40, ++ .check_open = check_open_format40, ++ .version_update = version_update_format41, ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format.h linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format.h +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/disk_format.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/disk_format.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,28 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* identifiers for disk layouts, they are also used as indexes in array of disk ++ plugins */ ++ ++#if !defined( __REISER4_DISK_FORMAT_H__ ) ++#define __REISER4_DISK_FORMAT_H__ ++ ++typedef enum { ++ /* standard reiser4 disk layout plugin id */ ++ FORMAT40_ID, ++ FORMAT41_ID, ++ LAST_FORMAT_ID ++} disk_format_id; ++ ++/* __REISER4_DISK_FORMAT_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/disk_format/Makefile linux-5.10.2/fs/reiser4/plugin/disk_format/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/disk_format/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/disk_format/Makefile 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,5 @@ ++obj-$(CONFIG_REISER4_FS) += df_plugins.o ++ ++df_plugins-objs := \ ++ disk_format40.o \ ++ disk_format.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/dst.c linux-5.10.2/fs/reiser4/plugin/dst/dst.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/dst.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/dst.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,90 @@ ++/* ++ Copyright (c) 2014-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include ++#include ++#include "../../debug.h" ++#include "../../inode.h" ++#include "../plugin.h" ++#include "../volume/volume.h" ++#include "dst.h" ++ ++static u64 lookup_triv(reiser4_dcx *rdcx, const struct inode *inode, ++ const char *str, int len, u32 seed, void *tab) ++{ ++ return METADATA_SUBVOL_ID; ++} ++ ++distribution_plugin distribution_plugins[LAST_DISTRIB_ID] = { ++ [TRIV_DISTRIB_ID] = { ++ .h = { ++ .type_id = REISER4_DISTRIBUTION_PLUGIN_TYPE, ++ .id = TRIV_DISTRIB_ID, ++ .pops = NULL, ++ .label = "triv", ++ .desc = "Trivial Distribution", ++ .linkage = {NULL, NULL} ++ }, ++ .seg_bits = 0, ++ .r = { ++ .init = NULL, ++ .lookup = lookup_triv, ++ .done = NULL, ++ }, ++ .v = { ++ .init = NULL, ++ .done = NULL, ++ .inc = NULL, ++ .dec = NULL, ++ .spl = NULL, ++ .pack = NULL, ++ .unpack = NULL, ++ .dump = NULL, ++ } ++ }, ++ [FSX32M_DISTRIB_ID] = { ++ .h = { ++ .type_id = REISER4_DISTRIBUTION_PLUGIN_TYPE, ++ .id = FSX32M_DISTRIB_ID, ++ .pops = NULL, ++ .label = "fsx32m", ++ .desc = "Fiber-Striping over 32-bit Murmur hash", ++ .linkage = {NULL, NULL} ++ }, ++ .seg_bits = 2, /* (log(sizeof u32)) */ ++ .r = { ++ .init = initr_fsx32, ++ .lookup = lookup_fsx32m, ++ .replace = replace_fsx32, ++ .free = free_fsx32, ++ .done = doner_fsx32 ++ }, ++ .v = { ++ .init = initv_fsx32, ++ .done = donev_fsx32, ++ .inc = inc_fsx32, ++ .dec = dec_fsx32, ++ .spl = spl_fsx32, ++ .pack = pack_fsx32, ++ .unpack = unpack_fsx32, ++ .dump = dump_fsx32, ++ } ++ }, ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/dst.h linux-5.10.2/fs/reiser4/plugin/dst/dst.h +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/dst.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/dst.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,21 @@ ++#ifndef DST_H ++#define DST_H ++ ++#include "fsx32.h" ++ ++union reiser4_dcx { ++ struct fsx32_dcx fsx32; ++}; ++ ++#endif /* DST_H */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/fsx32.c linux-5.10.2/fs/reiser4/plugin/dst/fsx32.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/fsx32.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/fsx32.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,975 @@ ++/* ++ Balanced Fiber-Striped eXtendable array with Weights. ++ Inventor, Author: Eduard O. Shishkin ++ Implementation over 32-bit hash. ++ Adapted for use in Reiser4. ++ ++ Copyright (c) 2014-2020 Eduard O. Shishkin ++*/ ++ ++#include ++#include ++#include "../../debug.h" ++#include "../../inode.h" ++#include "../plugin.h" ++#include "dst.h" ++ ++#define MIN_SGS_BITS 10 ++#define MAX_SGS_BITS 20 ++#define MAX_BUCKETS (1u << MAX_SGS_BITS) ++#define MAX_DIFFER_BITS 19 ++#define MAX_DATA_CAPACITY 0xffffffffffffffffull ++ ++static inline void *fsx32_alloc(u64 len) ++{ ++ void *result = reiser4_vmalloc(len * sizeof(u32)); ++ if (result) ++ memset(result, 0, len * sizeof(u32)); ++ return result; ++} ++ ++static inline void *fsx64_alloc(u64 len) ++{ ++ void *result = reiser4_vmalloc(len * sizeof(u64)); ++ if (result) ++ memset(result, 0, len * sizeof(u64)); ++ return result; ++} ++ ++static inline void fsx_free(void *p) ++{ ++ vfree(p); ++} ++ ++static inline struct fsx32_dcx *fsx32_private(reiser4_dcx *dcx) ++{ ++ return &dcx->fsx32; ++} ++ ++static void init_apxs_by_tab(u32 numb, ++ u32 nums_bits, ++ u32 *tab, ++ bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ u32 (*id2idx)(u64 id), ++ u32 *weights) ++{ ++ u32 i; ++ u32 nums = 1 << nums_bits; ++ ++ for(i = 0; i < numb; i++) ++ weights[i] = 0; ++ ++ for(i = 0; i < nums; i++) { ++ u32 *apx; ++ ++ apx = apx_at(vec, id2idx(tab[i])); ++ apx[(weights[id2idx(tab[i])])++] = i; ++ } ++} ++ ++static void init_tab_by_apxs(u32 numb, ++ u32 *tab, ++ bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ u64 (*idx2id)(u32 idx), ++ u32 *weights) ++{ ++ u32 i, j; ++ ++ for(i = 0; i < numb; i++) ++ for (j = 0; j < weights[i]; j++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ tab[apx[j]] = idx2id(i); ++ } ++} ++ ++u32 *init_tab_from_scratch(u32 *weights, u32 numb, u32 nums_bits, ++ u64 (*idx2id)(u32 idx)) ++{ ++ u32 i, j, k; ++ u32 *tab; ++ u32 nums = 1 << nums_bits; ++ ++ tab = fsx32_alloc(nums); ++ if (!tab) ++ return NULL; ++ for (i = 0, k = 0; i < numb; i++) ++ for (j = 0; j < weights[i]; j++) ++ tab[k++] = idx2id(i); ++ return tab; ++} ++ ++static void calibrate(u64 num, u64 val, ++ bucket_t *vec, u64 (*vec_el_get)(bucket_t *vec, u64 idx), ++ void *ret, u64 (*ret_el_get)(void *ret, u64 idx), ++ void (ret_el_set)(void *ret, u64 idx, u64 value)) ++{ ++ u64 i; ++ u64 rest; ++ u64 sum_scaled = 0; ++ u64 sum_not_scaled = 0; ++ ++ for (i = 0; i < num; i++) ++ sum_not_scaled += vec_el_get(vec, i); ++ for (i = 0; i < num; i++) { ++ u64 q; ++ u64 result; ++ ++ q = val * vec_el_get(vec, i); ++ result = div64_u64(q, sum_not_scaled); ++ ret_el_set(ret, i, result); ++ sum_scaled += result; ++ } ++ rest = val - sum_scaled; ++ ++ for (i = 0; i < rest; i++) ++ ret_el_set(ret, i, ret_el_get(ret, i) + 1); ++ return; ++} ++ ++static u64 array32_el_get(void *array, u64 idx) ++{ ++ return ((u32 *)array)[idx]; ++} ++ ++static void array32_el_set(void *array, u64 idx, u64 val) ++{ ++ ((u32 *)array)[idx] = val; ++} ++ ++static u64 array64_el_get(void *array, u64 idx) ++{ ++ return ((u64 *)array)[idx]; ++} ++ ++static void array64_el_set(void *array, u64 idx, u64 val) ++{ ++ ((u64 *)array)[idx] = val; ++} ++ ++static void calibrate32(u32 num, u32 val, bucket_t *vec, ++ u64 (*vec_el_get)(bucket_t *vec, u64 idx), ++ u32 *ret) ++{ ++ calibrate(num, val, vec, vec_el_get, ++ ret, array32_el_get, array32_el_set); ++} ++ ++static void calibrate64(u64 num, u64 val, bucket_t *vec, ++ u64 (*vec_el_get)(bucket_t *vec, u64 idx), ++ u64 *ret) ++{ ++ calibrate(num, val, vec, vec_el_get, ++ ret, array64_el_get, array64_el_set); ++} ++ ++int create_systab(u32 nums_bits, u32 **tab, ++ u32 numb, u32 *weights, bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ u64 (*idx2id)(u32 idx)) ++{ ++ u32 nums = 1 << nums_bits; ++ ++ *tab = fsx32_alloc(nums); ++ if (!tab) ++ return -ENOMEM; ++ ++ init_tab_by_apxs(numb, *tab, vec, apx_at, idx2id, weights); ++ return 0; ++} ++ ++static int clone_systab(struct fsx32_dcx *dcx, const void *tab) ++{ ++ assert("edward-2169", dcx != NULL); ++ assert("edward-2170", tab != NULL); ++ assert("edward-2171", dcx->tab == NULL); ++ ++ dcx->tab = fsx32_alloc(1 << dcx->nums_bits); ++ if (!dcx->tab) ++ return -ENOMEM; ++ memcpy(dcx->tab, tab, (1 << dcx->nums_bits) * sizeof(u32)); ++ return 0; ++} ++ ++static void free_cloned_systab(struct fsx32_dcx *dcx) ++{ ++ if (dcx->tab) { ++ fsx_free(dcx->tab); ++ dcx->tab = NULL; ++ } ++} ++ ++static int create_apxs(u32 nums_bits, u32 *tab, ++ u32 numb, u32 *weights, bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ void (*apx_set_at)(bucket_t *vec, u64 idx, void *apx), ++ u64 *(*apx_lenp_at)(bucket_t *vec, u64 idx), ++ u32 (*id2idx)(u64 id)) ++{ ++ u32 i; ++ for(i = 0; i < numb; i++) { ++ u32 *apx; ++ u64 *apx_lenp; ++ ++ apx = fsx32_alloc(weights[i]); ++ if (!apx) ++ return RETERR(-ENOMEM); ++ apx_set_at(vec, i, apx); ++ apx_lenp = apx_lenp_at(vec, i); ++ *apx_lenp = weights[i]; ++ } ++ init_apxs_by_tab(numb, ++ nums_bits, tab, vec, apx_at, id2idx, weights); ++ ++ for (i = 0; i < numb; i++) ++ assert("edward-1901", ++ weights[i] == *(apx_lenp_at(vec, i))); ++ return 0; ++} ++ ++#if REISER4_DEBUG ++void print_apx(u32 id, bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ u64 *(*apx_lenp_at)(bucket_t *vec, u64 idx)) ++{ ++ u32 i; ++ u32 *apx = apx_at(vec, id); ++ u32 apx_len = *apx_lenp_at(vec, id); ++ ++ printk("apx %d (len %d):", id, apx_len); ++ for (i = 0; i < apx_len; i++) ++ printk("%d", apx[i]); ++ printk("end of apx %d", id); ++ return; ++} ++#endif ++ ++static void release_apxs(u32 numb, bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ void (*apx_set_at)(bucket_t *vec, u64 idx, ++ void *apx)) ++{ ++ u32 i; ++ ++ for(i = 0; i < numb; i++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ fsx_free(apx); ++ apx_set_at(vec, i, NULL); ++ } ++} ++ ++static int replace_apxs(u32 nums_bits, u32 *tab, ++ u32 old_numb, u32 new_numb, ++ u32 *weights, bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ void (*apx_set_at)(bucket_t *vec, u64 idx, void *apx), ++ u64 *(*apx_lenp_at)(bucket_t *vec, u64 idx), ++ u32 (*id2idx)(u64 id)) ++{ ++ release_apxs(old_numb, vec, apx_at, apx_set_at); ++ return create_apxs(nums_bits, tab, new_numb, weights, vec, ++ apx_at, apx_set_at, apx_lenp_at, id2idx); ++} ++ ++/** ++ * @vec: new array of abstract buckets ++ * @new: a bucket to be added ++ * @target_pos: index of @new in the @vec ++ */ ++static int balance_inc(struct fsx32_dcx *dcx, ++ u32 new_numb, u32 *tab, ++ u32 *old_weights, u32 *new_weights, ++ u32 target_pos, ++ bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ u64 (*idx2id)(u32 idx), ++ bucket_t new) ++{ ++ int ret = 0; ++ u32 i, j; ++ u32 *exc = NULL; ++ ++ exc = fsx32_alloc(new_numb); ++ if (!exc) { ++ ret = -ENOMEM; ++ goto exit; ++ } ++ dcx->exc = exc; ++ ++ for (i = 0; i < target_pos; i++) ++ exc[i] = old_weights[i] - new_weights[i]; ++ ++ for(i = target_pos + 1; i < new_numb; i++) { ++ if (new) ++ exc[i] = old_weights[i-1] - new_weights[i]; ++ else ++ exc[i] = old_weights[i] - new_weights[i]; ++ } ++ assert("edward-1910", exc[target_pos] == 0); ++ ++ for(i = 0; i < target_pos; i++) ++ for(j = 0; j < exc[i]; j++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ ++ assert("edward-1902", ++ tab[apx[new_weights[i] + j]] == idx2id(i)); ++ ++ tab[apx[new_weights[i] + j]] = idx2id(target_pos); ++ } ++ ++ for(i = target_pos + 1; i < new_numb; i++) { ++ for(j = 0; j < new_weights[i]; j++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ assert("edward-1913", tab[apx[j]] == idx2id(i)); ++ } ++ for(j = 0; j < exc[i]; j++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ assert("edward-1914", ++ tab[apx[new_weights[i] + j]] == idx2id(i)); ++ tab[apx[new_weights[i] + j]] = idx2id(target_pos); ++ } ++ } ++ exit: ++ if (exc) ++ fsx_free(exc); ++ return ret; ++} ++ ++/** ++ * @vec: new array of abstract buckets ++ * @removeme: bucket to be removed ++ * @target_pos: index (in @vec) of @removeme ++ */ ++static int balance_dec(struct fsx32_dcx *dcx, ++ u32 new_numb, u32 *tab, ++ u32 *old_weights, u32 *new_weights, ++ u32 target_pos, ++ bucket_t *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ void *(*apx_of)(bucket_t bucket), ++ u64 (*idx2id)(u32 idx), ++ bucket_t removeme) ++{ ++ int ret = 0; ++ u32 i, j; ++ u32 off_in_target = 0; ++ u32 *sho; ++ u32 *target; ++ ++ sho = fsx32_alloc(new_numb); ++ if (!sho) { ++ ret = -ENOMEM; ++ goto exit; ++ } ++ dcx->sho = sho; ++ ++ for(i = 0; i < target_pos; i++) ++ sho[i] = new_weights[i] - old_weights[i]; ++ ++ for(i = target_pos; i < new_numb; i++) { ++ if (removeme) ++ sho[i] = new_weights[i] - old_weights[i+1]; ++ else ++ sho[i] = new_weights[i] - old_weights[i]; ++ } ++ ++ if (removeme) { ++ target = apx_of(removeme); ++ off_in_target = 0; ++ } else { ++ target = apx_at(vec, target_pos); ++ off_in_target = new_weights[target_pos]; ++ } ++ /* ++ * distribute segments among all apxs to the left of target_pos ++ */ ++ for(i = 0; i < target_pos; i++) ++ for(j = 0; j < sho[i]; j++) { ++ tab[target[off_in_target ++]] = idx2id(i); ++ } ++ /* ++ * distribute segments among all apxs to the right of target_pos ++ */ ++ if (removeme) ++ for(i = target_pos; i < new_numb; i++) { ++ for(j = 0; j < sho[i]; j++) { ++ tab[target[off_in_target ++]] = idx2id(i); ++ } ++ } ++ else ++ for(i = target_pos + 1; i < new_numb; i++) { ++ for(j = 0; j < sho[i]; j++) { ++ tab[target[off_in_target ++]] = idx2id(i); ++ } ++ } ++ exit: ++ if (sho) ++ fsx_free(sho); ++ return ret; ++} ++ ++static int balance_spl(u32 numb, u32 nums_bits, ++ const u32 *old_tab, ++ u32 **result, ++ u32 *old_weights, u32 *new_weights, ++ u32 fact_bits, ++ void *vec, ++ void *(*apx_at)(bucket_t *vec, u64 idx), ++ void (*apx_set_at)(bucket_t *vec, ++ u64 idx, void *apx), ++ u64 *(*apx_lenp_at)(bucket_t *vec, u64 idx), ++ u32 (*id2idx)(u64 id), u64 (*idx2id)(u32 idx)) ++{ ++ u32 ret = 0; ++ u32 i,j,k = 0; ++ u32 nums; ++ ++ u32 *tab = NULL; ++ u32 *exc = NULL; ++ u32 num_exc; ++ u32 *sho = NULL; ++ u32 num_sho; ++ u32 *reloc = NULL; ++ u32 num_reloc; ++ u32 factor; ++ ++ assert("edward-1904", numb <= MAX_BUCKETS); ++ ++ if (nums_bits + fact_bits > MAX_SGS_BITS) { ++ warning("edward-2399", ++ "Scale factor %u is too large", 1 << fact_bits); ++ return -EINVAL; ++ } ++ ++ nums = 1 << nums_bits; ++ factor = 1 << fact_bits; ++ ++ num_exc = (nums * factor) % numb; ++ num_sho = numb - num_exc; ++ ++ if (num_exc) { ++ exc = fsx32_alloc(numb); ++ if (!exc) ++ goto error; ++ ++ sho = exc + num_exc; ++ ++ for(i = 0; i < num_exc; i++) { ++ assert("edward-2400", ++ factor * old_weights[i] >= new_weights[i]); ++ ++ exc[i] = factor * old_weights[i] - new_weights[i]; ++ } ++ for(i = 0; i < num_sho; i++) { ++ assert("edward-2401", ++ new_weights[i + num_exc] >= ++ factor * old_weights[i + num_exc]); ++ ++ sho[i] = new_weights[i + num_exc] - ++ factor * old_weights[i + num_exc]; ++ } ++ } ++ tab = fsx32_alloc(nums * factor); ++ if (!tab) { ++ ret = -ENOMEM; ++ goto error; ++ } ++ for(i = 0; i < nums; i++) ++ for(j = 0; j < factor; j++) ++ tab[i * factor + j] = old_tab[i]; ++ if (!num_exc) ++ goto release; ++ ++ for (i = 0; i < numb; i++) ++ old_weights[i] *= factor; ++ ++ ret = replace_apxs(nums_bits + fact_bits, tab, ++ numb, numb, old_weights, vec, ++ apx_at, apx_set_at, apx_lenp_at, id2idx); ++ if (ret) ++ goto error; ++ ++ for (i = 0, num_reloc = 0; i < num_exc; i++) ++ num_reloc += exc[i]; ++ ++ if (num_reloc == 0) ++ goto release; ++ ++ reloc = fsx32_alloc(num_reloc); ++ if (!reloc) { ++ ret = RETERR(-EINVAL); ++ goto error; ++ } ++ for (i = 0, k = 0; i < num_exc; i++) ++ for (j = 0; j < exc[i]; j++) { ++ u32 *apx; ++ apx = apx_at(vec, i); ++ reloc[k++] = apx[new_weights[i] + j]; ++ } ++ for (i = 0, k = 0; i < num_sho; i++) ++ for (j = 0; j < sho[i]; j++) ++ tab[reloc[k++]] = idx2id(num_exc + i); ++ release: ++ release_apxs(numb, vec, apx_at, apx_set_at); ++ *result = tab; ++ goto exit; ++ error: ++ if (tab) ++ fsx_free(tab); ++ exit: ++ if (exc) ++ fsx_free(exc); ++ if (reloc) ++ fsx_free(reloc); ++ return ret; ++} ++ ++void donev_fsx32(reiser4_dcx *rdcx) ++{ ++ struct fsx32_dcx *dcx; ++ ++ dcx = fsx32_private(rdcx); ++ ++ if (dcx->weights != NULL) { ++ fsx_free(dcx->weights); ++ dcx->weights = NULL; ++ } ++} ++ ++/** ++ * Set newly created distribution table to @target ++ */ ++void replace_fsx32(reiser4_dcx *rdcx, void **target) ++{ ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ ++ assert("edward-2236", target != NULL); ++ assert("edward-2237", *target == NULL); ++ ++ *target = dcx->tab; ++ dcx->tab = NULL; ++} ++ ++void free_fsx32(void *tab) ++{ ++ assert("edward-2238", tab != NULL); ++ fsx_free(tab); ++} ++ ++/** ++ * Initialize distribution context for regular file operations ++ */ ++int initr_fsx32(reiser4_dcx *rdcx, void **tab, int nums_bits) ++{ ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ ++ if (*tab != NULL) ++ return 0; ++ ++ if (nums_bits < MIN_SGS_BITS) { ++ warning("edward-1953", ++ "Bad number of hash space segments (%llu). " ++ "It should be not less than %llu", ++ 1ull << nums_bits, 1ull << MIN_SGS_BITS); ++ return -EINVAL; ++ } ++ *tab = fsx32_alloc(1 << nums_bits); ++ if (*tab == NULL) ++ return -ENOMEM; ++ ++ dcx->nums_bits = nums_bits; ++ return 0; ++} ++ ++void doner_fsx32(void **tab) ++{ ++ assert("edward-2260", tab != NULL); ++ ++ if (*tab) { ++ fsx_free(*tab); ++ *tab = NULL; ++ } ++} ++ ++/** ++ * Initialize distribution context for volume operations ++ * ++ * @buckets: set of abstract buckets; ++ * @ops: operations to access the buckets; ++ * @rdcx: distribution context to be initialized. ++ */ ++int initv_fsx32(void **tab, u64 numb, int nums_bits, ++ reiser4_dcx *rdcx) ++{ ++ int ret = -ENOMEM; ++ u32 nums; ++ struct fsx32_dcx *dcx; ++ struct bucket_ops *ops = current_bucket_ops(); ++ ++ if (numb == 0 || nums_bits >= MAX_SGS_BITS) ++ return -EINVAL; ++ ++ nums = 1 << nums_bits; ++ if (numb >= nums) ++ return -EINVAL; ++ ++ dcx = fsx32_private(rdcx); ++ ++ assert("edward-2172", dcx->tab == NULL); ++ assert("edward-1922", dcx->weights == NULL); ++ assert("edward-2261", tab != NULL); ++ assert("edward-2336", current_buckets() != NULL); ++ ++ dcx->numb = numb; ++ dcx->weights = fsx32_alloc(numb); ++ if (!dcx->weights) ++ goto error; ++ ++ calibrate32(numb, nums, current_buckets(), ++ ops->cap_at, dcx->weights); ++ ++ if (*tab == NULL) { ++ u32 i; ++ assert("edward-2201", numb == 1); ++ ++ ret = initr_fsx32(rdcx, tab, nums_bits); ++ if (ret) ++ goto error; ++ for (i = 0; i < nums; i++) ++ (*(u32 **)tab)[i] = ops->idx2id(0); ++ } ++ assert("edward-2173", *tab != NULL); ++ ++ ret = create_apxs(nums_bits, *tab, ++ numb, dcx->weights, current_buckets(), ++ ops->apx_at, ++ ops->apx_set_at, ++ ops->apx_lenp_at, ++ ops->id2idx); ++ if (ret) ++ goto error; ++ return 0; ++ error: ++ doner_fsx32(tab); ++ donev_fsx32(rdcx); ++ return ret; ++} ++ ++u64 lookup_fsx32m(reiser4_dcx *rdcx, const struct inode *inode, ++ const char *str, int len, u32 seed, void *tab) ++{ ++ u32 hash; ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ ++ hash = murmur3_x86_32(str, len, seed); ++ return ((u32 *)tab)[hash >> (32 - dcx->nums_bits)]; ++} ++ ++static int check_maxdiff(reiser4_dcx *rdcx, u64 numb) ++{ ++ u64 i; ++ u64 min = MAX_DATA_CAPACITY; ++ u64 max = 0; ++ bucket_t *vec = current_buckets(); ++ struct bucket_ops *ops = current_bucket_ops(); ++ ++ assert("edward-2390", numb >= 1); ++ ++ for (i = 0; i < numb; i++) { ++ if (min > ops->cap_at(vec, i)) ++ min = ops->cap_at(vec, i); ++ if (max < ops->cap_at(vec, i)) ++ max = ops->cap_at(vec, i); ++ } ++ assert("edward-2391", min != 0); ++ ++ if ((div64_u64(max, min)) >> MAX_DIFFER_BITS != 0) { ++ warning("edward-2392", ++ "Capacities %llu and %llu differ too much", ++ min, max); ++ return RETERR(-EINVAL); ++ } ++ return 0; ++} ++ ++int inc_fsx32(reiser4_dcx *rdcx, const void *tab, u64 target_pos, bucket_t new) ++{ ++ int ret = 0; ++ u32 *new_weights; ++ u32 old_numb, new_numb, nums; ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ struct bucket_ops *ops = current_bucket_ops(); ++ ++ new_numb = old_numb = dcx->numb; ++ if (new) { ++ if (old_numb == MAX_BUCKETS) ++ return -EINVAL; ++ new_numb ++; ++ } ++ nums = 1 << dcx->nums_bits; ++ if (new_numb > nums) { ++ warning("edward-2337", ++ "Can not add bucket: current limit (%u) reached", ++ nums); ++ return -EINVAL; ++ } ++ ret = check_maxdiff(rdcx, new_numb); ++ if (ret) ++ return ret; ++ new_weights = fsx32_alloc(new_numb); ++ if (!new_weights) { ++ ret = -ENOMEM; ++ goto error; ++ } ++ dcx->new_weights = new_weights; ++ ++ ret = clone_systab(dcx, tab); ++ if (ret) ++ goto error; ++ ++ calibrate32(new_numb, nums, ++ current_buckets(), ops->cap_at, new_weights); ++ ret = balance_inc(dcx, ++ new_numb, dcx->tab, ++ dcx->weights, new_weights, target_pos, ++ current_buckets(), ops->apx_at, ++ ops->idx2id, new); ++ if (ret) ++ goto error; ++ ++ release_apxs(new_numb, current_buckets(), ++ ops->apx_at, ops->apx_set_at); ++ ++ fsx_free(dcx->weights); ++ dcx->weights = new_weights; ++ dcx->numb = new_numb; ++ ++ return 0; ++ error: ++ if (new_weights) ++ fsx_free(new_weights); ++ free_cloned_systab(dcx); ++ return ret; ++} ++ ++/** ++ * Check if there is enough capacity on abstract buckets ++ * for successful completion of an operation. ++ * ++ * @numb: number of buckets upon succesfull completion. ++ * @occ: total amount of space occupied on all buckets ++ */ ++static int check_leftovers(reiser4_dcx *rdcx, u64 numb, u64 occ) ++{ ++ u64 i; ++ int ret = 0; ++ u64 *vec_new_occ; ++ bucket_t *vec = current_buckets(); ++ struct bucket_ops *ops = current_bucket_ops(); ++ /* ++ * For each bucket calculate how much space will be ++ * occupied on that bucket after successful completion ++ * of the volume operation and compare it with the ++ * bucket's capacity ++ */ ++ vec_new_occ = fsx64_alloc(numb); ++ if (!vec_new_occ) ++ return -ENOMEM; ++ ++ calibrate64(numb, occ, vec, ops->cap_at, vec_new_occ); ++ ++ for (i = 0; i < numb; i++) { ++ u64 cap; ++ ON_DEBUG(notice("edward-2145", ++ "Brick %llu: data capacity: %llu, min required: %llu", ++ i, ops->cap_at(vec, i), vec_new_occ[i])); ++ ++ cap = ops->cap_at(vec, i); ++ cap -= (cap * 5)/100; /* deduct 5% reservation */ ++ if (cap < vec_new_occ[i]) { ++ warning("edward-2070", ++ "Not enough data capacity (%llu) of brick %llu (required %llu)", ++ cap, ++ i, ++ vec_new_occ[i]); ++ ret = -ENOSPC; ++ break; ++ } else { ++ ON_DEBUG(notice("edward-2145", ++ "Brick %llu: data capacity: %llu, min required: %llu", ++ i, cap, vec_new_occ[i])); ++ } ++ } ++ fsx_free(vec_new_occ); ++ return ret; ++} ++ ++int dec_fsx32(reiser4_dcx *rdcx, const void *tab, u64 target_pos, ++ bucket_t removeme) ++{ ++ int ret = 0; ++ u32 nums; ++ u32 new_numb; ++ u32 *new_weights = NULL; ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ struct bucket_ops *ops = current_bucket_ops(); ++ ++ assert("edward-1908", dcx->numb >= 1); ++ assert("edward-1909", dcx->numb <= MAX_BUCKETS); ++ assert("edward-1927", dcx->numb > 1); ++ ++ new_numb = dcx->numb; ++ if (removeme) ++ new_numb --; ++ else { ++ ret = check_maxdiff(rdcx, new_numb); ++ if (ret) ++ return ret; ++ } ++ ret = check_leftovers(rdcx, new_numb, ops->space_occupied()); ++ if (ret) ++ return ret; ++ ++ nums = 1 << dcx->nums_bits; ++ new_weights = fsx32_alloc(new_numb); ++ if (!new_weights) { ++ ret = -ENOMEM; ++ goto error; ++ } ++ dcx->new_weights = new_weights; ++ ++ ret = clone_systab(dcx, tab); ++ if (ret) ++ goto error; ++ ++ calibrate32(new_numb, nums, ++ current_buckets(), ops->cap_at, new_weights); ++ ++ ret = balance_dec(dcx, ++ new_numb, dcx->tab, ++ dcx->weights, new_weights, target_pos, ++ current_buckets(), ops->apx_at, ++ ops->apx_of, ops->idx2id, ++ removeme); ++ if (ret) ++ goto error; ++ ++ release_apxs(new_numb, ++ current_buckets(), ops->apx_at, ++ ops->apx_set_at); ++ if (removeme) ++ release_apxs(1, ++ &removeme, ops->apx_at, ++ ops->apx_set_at); ++ fsx_free(dcx->weights); ++ dcx->weights = new_weights; ++ dcx->numb = new_numb; ++ return 0; ++ error: ++ if (new_weights) ++ fsx_free(new_weights); ++ free_cloned_systab(dcx); ++ return ret; ++} ++ ++int spl_fsx32(reiser4_dcx *rdcx, const void *tab, u32 fact_bits) ++{ ++ int ret = 0; ++ u32 *new_weights; ++ u32 new_nums; ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ struct bucket_ops *ops = current_bucket_ops(); ++ ++ if (dcx->nums_bits + fact_bits > MAX_SGS_BITS) ++ return -EINVAL; ++ ++ new_nums = 1 << (dcx->nums_bits + fact_bits); ++ ++ new_weights = fsx32_alloc(dcx->numb); ++ if (!new_weights) { ++ ret = -ENOMEM; ++ goto error; ++ } ++ calibrate32(dcx->numb, new_nums, ++ current_buckets(), ops->cap_at, new_weights); ++ ret = balance_spl(dcx->numb, dcx->nums_bits, ++ tab, ++ &dcx->tab, ++ dcx->weights, ++ new_weights, ++ fact_bits, ++ current_buckets(), ++ ops->apx_at, ++ ops->apx_set_at, ++ ops->apx_lenp_at, ++ ops->id2idx, ++ ops->idx2id); ++ if (ret) ++ goto error; ++ fsx_free(dcx->weights); ++ dcx->weights = new_weights; ++ dcx->nums_bits += fact_bits; ++ return 0; ++ error: ++ if (new_weights) ++ fsx_free(new_weights); ++ return ret; ++} ++ ++void pack_fsx32(reiser4_dcx *rdcx, char *to, u64 src_off, u64 count) ++{ ++ u64 i; ++ u32 *src; ++ struct fsx32_dcx *dcx = fsx32_private(rdcx); ++ ++ assert("edward-1923", to != NULL); ++ assert("edward-1924", dcx->tab != NULL); ++ ++ src = dcx->tab + src_off; ++ ++ for (i = 0; i < count; i++) { ++ put_unaligned(cpu_to_le32(*src), (d32 *)to); ++ to += sizeof(u32); ++ src ++; ++ } ++} ++ ++void unpack_fsx32(reiser4_dcx *rdcx, void *tab, ++ char *from, u64 dst_off, u64 count) ++{ ++ u64 i; ++ u32 *dst; ++ ++ assert("edward-1925", from != NULL); ++ assert("edward-1926", tab != NULL); ++ ++ dst = (u32 *)tab + dst_off; ++ ++ for (i = 0; i < count; i++) { ++ *dst = le32_to_cpu(get_unaligned((d32 *)from)); ++ from += sizeof(u32); ++ dst ++; ++ } ++} ++ ++void dump_fsx32(reiser4_dcx *rdcx, void *tab, char *to, u64 offset, u32 size) ++{ ++ memcpy(to, (u32 *)tab + offset, size); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/fsx32.h linux-5.10.2/fs/reiser4/plugin/dst/fsx32.h +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/fsx32.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/fsx32.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,53 @@ ++/* ++ Copyright (c) 2014-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#ifndef FSX32_H ++#define FSX32_H ++ ++struct fsx32_dcx { ++ u64 numb; /* number of abstract buckets */ ++ u32 nums_bits; /* logarithm of number of hash space segments */ ++ u32 *tab; /* system table */ ++ u32 *weights; /* array of weights */ ++ u32 *new_weights; ++ u32 *sho; ++ u32 *exc; ++}; ++ ++extern u32 murmur3_x86_32(const char *data, int len, int seed); ++ ++extern int initr_fsx32(reiser4_dcx *rdcx, void **tab, int nums_bits); ++extern reiser4_subvol *dst_builtin(const struct inode *inode, loff_t offset); ++extern void replace_fsx32(reiser4_dcx *rdcx, void **target); ++extern void free_fsx32(void *tab); ++extern void doner_fsx32(void **tab); ++extern int initv_fsx32(void **tab, u64 numb, int nums_bits, reiser4_dcx *rdcx); ++extern void donev_fsx32(reiser4_dcx *rdcx); ++extern u64 lookup_fsx32m(reiser4_dcx *rdcx, const struct inode *inode, ++ const char *str, int len, u32 seed, void *tab); ++extern int inc_fsx32(reiser4_dcx *rdcx, const void *tab, u64 pos, bucket_t new); ++extern int dec_fsx32(reiser4_dcx *rdcx, const void *tab, u64 pos, bucket_t victim); ++extern int spl_fsx32(reiser4_dcx *rdcx, const void *tab, u32 fact_bits); ++extern void pack_fsx32(reiser4_dcx *rdcx, char *to, u64 src_off, u64 count); ++extern void unpack_fsx32(reiser4_dcx *rdcx, void *tab, ++ char *from, u64 dst_off, u64 count); ++extern void dump_fsx32(reiser4_dcx *rdcx, void *tab, ++ char *to, u64 offset, u32 size); ++#endif /* FSX32_H */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/hash.c linux-5.10.2/fs/reiser4/plugin/dst/hash.c +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/hash.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/hash.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,96 @@ ++/* ++ * Adopted for using by Reiser4 distribution plugin ++ * ++ * MurmurHash3 was written by Austin Appleby, and is placed in the public ++ * domain. The author hereby disclaims copyright to this source code. ++ */ ++ ++#include ++ ++inline u32 rotl32 ( u32 x, s8 r ) ++{ ++ return (x << r) | (x >> (32 - r)); ++} ++ ++inline u64 rotl64 ( u64 x, s8 r ) ++{ ++ return (x << r) | (x >> (64 - r)); ++} ++ ++#define ROTL32(x,y) rotl32(x,y) ++#define ROTL64(x,y) rotl64(x,y) ++ ++//----------------------------------------------------------------------------- ++// Finalization mix - force all bits of a hash block to avalanche ++ ++static inline u32 fmix ( u32 h ) ++{ ++ h ^= h >> 16; ++ h *= 0x85ebca6b; ++ h ^= h >> 13; ++ h *= 0xc2b2ae35; ++ h ^= h >> 16; ++ ++ return h; ++} ++ ++//----------------------------------------------------------------------------- ++ ++u32 murmur3_x86_32(const void * key, int len, u32 seed) ++{ ++ const u8 * data = (const u8*)key; ++ const int nblocks = len / 4; ++ ++ u32 h1 = seed; ++ ++ u32 c1 = 0xcc9e2d51; ++ u32 c2 = 0x1b873593; ++ ++ /* body */ ++ ++ const u8 * tail; ++ u32 k1; ++ const u32 * blocks = (const u32 *)(data + nblocks*4); ++ int i; ++ ++ for(i = -nblocks; i; i++) { ++ u32 k = blocks[i]; ++ ++ k *= c1; ++ k = ROTL32(k,15); ++ k *= c2; ++ ++ h1 ^= k; ++ h1 = ROTL32(h1,13); ++ h1 = h1*5+0xe6546b64; ++ } ++ ++ /* tail */ ++ ++ tail = (const u8*)(data + nblocks*4); ++ ++ k1 = 0; ++ ++ switch(len & 3) { ++ case 3: ++ k1 ^= tail[2] << 16; ++ /* fall through */ ++ case 2: ++ k1 ^= tail[1] << 8; ++ /* fall through */ ++ case 1: ++ k1 ^= tail[0]; ++ k1 *= c1; ++ k1 = ROTL32(k1,15); ++ k1 *= c2; ++ h1 ^= k1; ++ }; ++ ++ /* finalization */ ++ ++ h1 ^= len; ++ ++ h1 = fmix(h1); ++ ++ return h1; ++} +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/dst/Makefile linux-5.10.2/fs/reiser4/plugin/dst/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/dst/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/dst/Makefile 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,5 @@ ++obj-$(CONFIG_REISER4_FS) += distribution_plugins.o ++ ++distribution_plugins-objs := \ ++ hash.o \ ++ fsx32.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/fibration.c linux-5.10.2/fs/reiser4/plugin/fibration.c +--- linux-5.10.2.orig/fs/reiser4/plugin/fibration.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/fibration.c 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,175 @@ ++/* Copyright 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Directory fibrations */ ++ ++/* ++ * Suppose we have a directory tree with sources of some project. During ++ * compilation .o files are created within this tree. This makes access ++ * to the original source files less efficient, because source files are ++ * now "diluted" by object files: default directory plugin uses prefix ++ * of a file name as a part of the key for directory entry (and this ++ * part is also inherited by the key of file body). This means that ++ * foo.o will be located close to foo.c and foo.h in the tree. ++ * ++ * To avoid this effect directory plugin fill highest 7 (unused ++ * originally) bits of the second component of the directory entry key ++ * by bit-pattern depending on the file name (see ++ * fs/reiser4/kassign.c:build_entry_key_common()). These bits are called ++ * "fibre". Fibre of the file name key is inherited by key of stat data ++ * and keys of file body (in the case of REISER4_LARGE_KEY). ++ * ++ * Fibre for a given file is chosen by per-directory fibration ++ * plugin. Names within given fibre are ordered lexicographically. ++ */ ++ ++#include "../debug.h" ++#include "plugin_header.h" ++#include "plugin.h" ++#include "../super.h" ++#include "../inode.h" ++ ++#include ++ ++static const int fibre_shift = 57; ++ ++#define FIBRE_NO(n) (((__u64)(n)) << fibre_shift) ++ ++/* ++ * Trivial fibration: all files of directory are just ordered ++ * lexicographically. ++ */ ++static __u64 fibre_trivial(const struct inode *dir, const char *name, int len) ++{ ++ return FIBRE_NO(0); ++} ++ ++/* ++ * dot-o fibration: place .o files after all others. ++ */ ++static __u64 fibre_dot_o(const struct inode *dir, const char *name, int len) ++{ ++ /* special treatment for .*\.o */ ++ if (len > 2 && name[len - 1] == 'o' && name[len - 2] == '.') ++ return FIBRE_NO(1); ++ else ++ return FIBRE_NO(0); ++} ++ ++/* ++ * ext.1 fibration: subdivide directory into 128 fibrations one for each ++ * 7bit extension character (file "foo.h" goes into fibre "h"), plus ++ * default fibre for the rest. ++ */ ++static __u64 fibre_ext_1(const struct inode *dir, const char *name, int len) ++{ ++ if (len > 2 && name[len - 2] == '.') ++ return FIBRE_NO(name[len - 1]); ++ else ++ return FIBRE_NO(0); ++} ++ ++/* ++ * ext.3 fibration: try to separate files with different 3-character ++ * extensions from each other. ++ */ ++static __u64 fibre_ext_3(const struct inode *dir, const char *name, int len) ++{ ++ if (len > 4 && name[len - 4] == '.') ++ return FIBRE_NO(name[len - 3] + name[len - 2] + name[len - 1]); ++ else ++ return FIBRE_NO(0); ++} ++ ++static int change_fibration(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ int result; ++ ++ assert("nikita-3503", inode != NULL); ++ assert("nikita-3504", plugin != NULL); ++ ++ assert("nikita-3505", is_reiser4_inode(inode)); ++ assert("nikita-3506", inode_dir_plugin(inode) != NULL); ++ assert("nikita-3507", ++ plugin->h.type_id == REISER4_FIBRATION_PLUGIN_TYPE); ++ ++ result = 0; ++ if (inode_fibration_plugin(inode) == NULL || ++ inode_fibration_plugin(inode)->h.id != plugin->h.id) { ++ if (is_dir_empty(inode) == 0) ++ result = aset_set_unsafe(&reiser4_inode_data(inode)->pset, ++ PSET_FIBRATION, plugin); ++ else ++ result = RETERR(-ENOTEMPTY); ++ ++ } ++ return result; ++} ++ ++static reiser4_plugin_ops fibration_plugin_ops = { ++ .init = NULL, ++ .load = NULL, ++ .save_len = NULL, ++ .save = NULL, ++ .change = change_fibration ++}; ++ ++/* fibration plugins */ ++fibration_plugin fibration_plugins[LAST_FIBRATION_ID] = { ++ [FIBRATION_LEXICOGRAPHIC] = { ++ .h = { ++ .type_id = REISER4_FIBRATION_PLUGIN_TYPE, ++ .id = FIBRATION_LEXICOGRAPHIC, ++ .pops = &fibration_plugin_ops, ++ .label = "lexicographic", ++ .desc = "no fibration", ++ .linkage = {NULL, NULL} ++ }, ++ .fibre = fibre_trivial ++ }, ++ [FIBRATION_DOT_O] = { ++ .h = { ++ .type_id = REISER4_FIBRATION_PLUGIN_TYPE, ++ .id = FIBRATION_DOT_O, ++ .pops = &fibration_plugin_ops, ++ .label = "dot-o", ++ .desc = "fibrate .o files separately", ++ .linkage = {NULL, NULL} ++ }, ++ .fibre = fibre_dot_o ++ }, ++ [FIBRATION_EXT_1] = { ++ .h = { ++ .type_id = REISER4_FIBRATION_PLUGIN_TYPE, ++ .id = FIBRATION_EXT_1, ++ .pops = &fibration_plugin_ops, ++ .label = "ext-1", ++ .desc = "fibrate file by single character extension", ++ .linkage = {NULL, NULL} ++ }, ++ .fibre = fibre_ext_1 ++ }, ++ [FIBRATION_EXT_3] = { ++ .h = { ++ .type_id = REISER4_FIBRATION_PLUGIN_TYPE, ++ .id = FIBRATION_EXT_3, ++ .pops = &fibration_plugin_ops, ++ .label = "ext-3", ++ .desc = "fibrate file by three character extension", ++ .linkage = {NULL, NULL} ++ }, ++ .fibre = fibre_ext_3 ++ } ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/fibration.h linux-5.10.2/fs/reiser4/plugin/fibration.h +--- linux-5.10.2.orig/fs/reiser4/plugin/fibration.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/fibration.h 2020-12-23 16:07:46.122813187 +0100 +@@ -0,0 +1,37 @@ ++/* Copyright 2004 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Fibration plugin used by hashed directory plugin to segment content ++ * of directory. See fs/reiser4/plugin/fibration.c for more on this. */ ++ ++#if !defined(__FS_REISER4_PLUGIN_FIBRATION_H__) ++#define __FS_REISER4_PLUGIN_FIBRATION_H__ ++ ++#include "plugin_header.h" ++ ++typedef struct fibration_plugin { ++ /* generic fields */ ++ plugin_header h; ++ ++ __u64(*fibre) (const struct inode *dir, const char *name, int len); ++} fibration_plugin; ++ ++typedef enum { ++ FIBRATION_LEXICOGRAPHIC, ++ FIBRATION_DOT_O, ++ FIBRATION_EXT_1, ++ FIBRATION_EXT_3, ++ LAST_FIBRATION_ID ++} reiser4_fibration_id; ++ ++/* __FS_REISER4_PLUGIN_FIBRATION_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/cryptcompress.c linux-5.10.2/fs/reiser4/plugin/file/cryptcompress.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/cryptcompress.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/cryptcompress.c 2020-12-23 16:07:46.123813202 +0100 +@@ -0,0 +1,3821 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ reiser4/README */ ++/* ++ * Written by Edward Shishkin. ++ * ++ * Implementations of inode/file/address_space operations ++ * specific for cryptcompress file plugin which manages ++ * regular files built of compressed and(or) encrypted bodies. ++ * See http://dev.namesys.com/CryptcompressPlugin for details. ++ */ ++ ++#include "../../inode.h" ++#include "../cluster.h" ++#include "../object.h" ++#include "../../tree_walk.h" ++#include "cryptcompress.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* ++ Managing primary and secondary caches by Reiser4 ++ cryptcompress file plugin. Synchronization scheme. ++ ++ ++ +------------------+ ++ +------------------->| tfm stream | ++ | | (compressed data)| ++ flush | +------------------+ ++ +-----------------+ | ++ |(->)longterm lock| V ++--+ writepages() | | +-***-+ reiser4 +---+ ++ | | +--+ | *** | storage tree | | ++ | | | +-***-+ (primary cache)| | ++u | write() (secondary| cache) V / | \ | | ++s | ----> +----+ +----+ +----+ +----+ +-***** ******* **----+ ----> | d | ++e | | | |page cluster | | | **disk cluster** | | i | ++r | <---- +----+ +----+ +----+ +----+ +-***** **********----+ <---- | s | ++ | read() ^ ^ | | k | ++ | | (->)longterm lock| | page_io()| | ++ | | +------+ | | ++--+ readpages() | | +---+ ++ | V ++ | +------------------+ ++ +--------------------| tfm stream | ++ | (plain text) | ++ +------------------+ ++*/ ++ ++/* get cryptcompress specific portion of inode */ ++struct cryptcompress_info *cryptcompress_inode_data(const struct inode *inode) ++{ ++ return &reiser4_inode_data(inode)->file_plugin_data.cryptcompress_info; ++} ++ ++void init_inode_data_cryptcompress(struct inode *inode, ++ reiser4_object_create_data * crd, ++ const reiser4_key *sd_key, int create) ++{ ++ struct cryptcompress_info *data; ++ ++ data = cryptcompress_inode_data(inode); ++ assert("edward-685", data != NULL); ++ ++ memset(data, 0, sizeof(*data)); ++ ++ mutex_init(&data->checkin_mutex); ++ data->trunc_index = ULONG_MAX; ++ turn_on_compression(data); ++ set_lattice_factor(data, MIN_LATTICE_FACTOR); ++ init_inode_ordering(inode, crd, sd_key, create); ++} ++ ++/* The following is a part of reiser4 cipher key manager ++ which is called when opening/creating a cryptcompress file */ ++ ++/* get/set cipher key info */ ++struct reiser4_crypto_info * inode_crypto_info (struct inode * inode) ++{ ++ assert("edward-90", inode != NULL); ++ assert("edward-91", reiser4_inode_data(inode) != NULL); ++ return cryptcompress_inode_data(inode)->crypt; ++} ++ ++static void set_inode_crypto_info (struct inode * inode, ++ struct reiser4_crypto_info * info) ++{ ++ cryptcompress_inode_data(inode)->crypt = info; ++} ++ ++/* allocate a cipher key info */ ++struct reiser4_crypto_info * reiser4_alloc_crypto_info (struct inode * inode) ++{ ++ struct reiser4_crypto_info *info; ++ int fipsize; ++ ++ info = kzalloc(sizeof(*info), reiser4_ctx_gfp_mask_get()); ++ if (!info) ++ return ERR_PTR(-ENOMEM); ++ ++ fipsize = inode_digest_plugin(inode)->fipsize; ++ info->keyid = kmalloc(fipsize, reiser4_ctx_gfp_mask_get()); ++ if (!info->keyid) { ++ kfree(info); ++ return ERR_PTR(-ENOMEM); ++ } ++ info->host = inode; ++ return info; ++} ++ ++#if 0 ++/* allocate/free low-level info for cipher and digest ++ transforms */ ++static int alloc_crypto_tfms(struct reiser4_crypto_info * info) ++{ ++ struct crypto_blkcipher * ctfm = NULL; ++ struct crypto_hash * dtfm = NULL; ++ cipher_plugin * cplug = inode_cipher_plugin(info->host); ++ digest_plugin * dplug = inode_digest_plugin(info->host); ++ ++ if (cplug->alloc) { ++ ctfm = cplug->alloc(); ++ if (IS_ERR(ctfm)) { ++ warning("edward-1364", ++ "Can not allocate info for %s\n", ++ cplug->h.desc); ++ return RETERR(PTR_ERR(ctfm)); ++ } ++ } ++ info_set_cipher(info, ctfm); ++ if (dplug->alloc) { ++ dtfm = dplug->alloc(); ++ if (IS_ERR(dtfm)) { ++ warning("edward-1365", ++ "Can not allocate info for %s\n", ++ dplug->h.desc); ++ goto unhappy_with_digest; ++ } ++ } ++ info_set_digest(info, dtfm); ++ return 0; ++ unhappy_with_digest: ++ if (cplug->free) { ++ cplug->free(ctfm); ++ info_set_cipher(info, NULL); ++ } ++ return RETERR(PTR_ERR(dtfm)); ++} ++#endif ++ ++static void ++free_crypto_tfms(struct reiser4_crypto_info * info) ++{ ++ assert("edward-1366", info != NULL); ++ if (!info_get_cipher(info)) { ++ assert("edward-1601", !info_get_digest(info)); ++ return; ++ } ++ inode_cipher_plugin(info->host)->free(info_get_cipher(info)); ++ info_set_cipher(info, NULL); ++ inode_digest_plugin(info->host)->free(info_get_digest(info)); ++ info_set_digest(info, NULL); ++ return; ++} ++ ++#if 0 ++/* create a key fingerprint for disk stat-data */ ++static int create_keyid (struct reiser4_crypto_info * info, ++ struct reiser4_crypto_data * data) ++{ ++ int ret = -ENOMEM; ++ size_t blk, pad; ++ __u8 * dmem; ++ __u8 * cmem; ++ struct hash_desc ddesc; ++ struct blkcipher_desc cdesc; ++ struct scatterlist sg; ++ ++ assert("edward-1367", info != NULL); ++ assert("edward-1368", info->keyid != NULL); ++ ++ ddesc.tfm = info_get_digest(info); ++ ddesc.flags = 0; ++ cdesc.tfm = info_get_cipher(info); ++ cdesc.flags = 0; ++ ++ dmem = kmalloc((size_t)crypto_hash_digestsize(ddesc.tfm), ++ reiser4_ctx_gfp_mask_get()); ++ if (!dmem) ++ goto exit1; ++ ++ blk = crypto_blkcipher_blocksize(cdesc.tfm); ++ ++ pad = data->keyid_size % blk; ++ pad = (pad ? blk - pad : 0); ++ ++ cmem = kmalloc((size_t)data->keyid_size + pad, ++ reiser4_ctx_gfp_mask_get()); ++ if (!cmem) ++ goto exit2; ++ memcpy(cmem, data->keyid, data->keyid_size); ++ memset(cmem + data->keyid_size, 0, pad); ++ ++ sg_init_one(&sg, cmem, data->keyid_size + pad); ++ ++ ret = crypto_blkcipher_encrypt(&cdesc, &sg, &sg, ++ data->keyid_size + pad); ++ if (ret) { ++ warning("edward-1369", ++ "encryption failed flags=%x\n", cdesc.flags); ++ goto exit3; ++ } ++ ret = crypto_hash_digest(&ddesc, &sg, sg.length, dmem); ++ if (ret) { ++ warning("edward-1602", ++ "digest failed flags=%x\n", ddesc.flags); ++ goto exit3; ++ } ++ memcpy(info->keyid, dmem, inode_digest_plugin(info->host)->fipsize); ++ exit3: ++ kfree(cmem); ++ exit2: ++ kfree(dmem); ++ exit1: ++ return ret; ++} ++#endif ++ ++static void destroy_keyid(struct reiser4_crypto_info * info) ++{ ++ assert("edward-1370", info != NULL); ++ assert("edward-1371", info->keyid != NULL); ++ kfree(info->keyid); ++ return; ++} ++ ++static void __free_crypto_info (struct inode * inode) ++{ ++ struct reiser4_crypto_info * info = inode_crypto_info(inode); ++ assert("edward-1372", info != NULL); ++ ++ free_crypto_tfms(info); ++ destroy_keyid(info); ++ kfree(info); ++} ++ ++#if 0 ++static void instantiate_crypto_info(struct reiser4_crypto_info * info) ++{ ++ assert("edward-1373", info != NULL); ++ assert("edward-1374", info->inst == 0); ++ info->inst = 1; ++} ++#endif ++ ++static void uninstantiate_crypto_info(struct reiser4_crypto_info * info) ++{ ++ assert("edward-1375", info != NULL); ++ info->inst = 0; ++} ++ ++#if 0 ++static int is_crypto_info_instantiated(struct reiser4_crypto_info * info) ++{ ++ return info->inst; ++} ++ ++static int inode_has_cipher_key(struct inode * inode) ++{ ++ assert("edward-1376", inode != NULL); ++ return inode_crypto_info(inode) && ++ is_crypto_info_instantiated(inode_crypto_info(inode)); ++} ++#endif ++ ++static void free_crypto_info (struct inode * inode) ++{ ++ uninstantiate_crypto_info(inode_crypto_info(inode)); ++ __free_crypto_info(inode); ++} ++ ++static int need_cipher(struct inode * inode) ++{ ++ return inode_cipher_plugin(inode) != ++ cipher_plugin_by_id(NONE_CIPHER_ID); ++} ++ ++/* Parse @data which contains a (uninstantiated) cipher key imported ++ from user space, create a low-level cipher info and attach it to ++ the @object. If success, then info contains an instantiated key */ ++#if 0 ++struct reiser4_crypto_info * create_crypto_info(struct inode * object, ++ struct reiser4_crypto_data * data) ++{ ++ int ret; ++ struct reiser4_crypto_info * info; ++ ++ assert("edward-1377", data != NULL); ++ assert("edward-1378", need_cipher(object)); ++ ++ if (inode_file_plugin(object) != ++ file_plugin_by_id(DIRECTORY_FILE_PLUGIN_ID)) ++ return ERR_PTR(-EINVAL); ++ ++ info = reiser4_alloc_crypto_info(object); ++ if (IS_ERR(info)) ++ return info; ++ ret = alloc_crypto_tfms(info); ++ if (ret) ++ goto err; ++ /* instantiating a key */ ++ ret = crypto_blkcipher_setkey(info_get_cipher(info), ++ data->key, ++ data->keysize); ++ if (ret) { ++ warning("edward-1379", ++ "setkey failed flags=%x", ++ crypto_blkcipher_get_flags(info_get_cipher(info))); ++ goto err; ++ } ++ info->keysize = data->keysize; ++ ret = create_keyid(info, data); ++ if (ret) ++ goto err; ++ instantiate_crypto_info(info); ++ return info; ++ err: ++ __free_crypto_info(object); ++ return ERR_PTR(ret); ++} ++#endif ++ ++/* increment/decrement a load counter when ++ attaching/detaching the crypto-stat to any object */ ++static void load_crypto_info(struct reiser4_crypto_info * info) ++{ ++ assert("edward-1380", info != NULL); ++ inc_keyload_count(info); ++} ++ ++static void unload_crypto_info(struct inode * inode) ++{ ++ struct reiser4_crypto_info * info = inode_crypto_info(inode); ++ assert("edward-1381", info->keyload_count > 0); ++ ++ dec_keyload_count(inode_crypto_info(inode)); ++ if (info->keyload_count == 0) ++ /* final release */ ++ free_crypto_info(inode); ++} ++ ++/* attach/detach an existing crypto-stat */ ++void reiser4_attach_crypto_info(struct inode * inode, ++ struct reiser4_crypto_info * info) ++{ ++ assert("edward-1382", inode != NULL); ++ assert("edward-1383", info != NULL); ++ assert("edward-1384", inode_crypto_info(inode) == NULL); ++ ++ set_inode_crypto_info(inode, info); ++ load_crypto_info(info); ++} ++ ++/* returns true, if crypto stat can be attached to the @host */ ++#if REISER4_DEBUG ++static int host_allows_crypto_info(struct inode * host) ++{ ++ int ret; ++ file_plugin * fplug = inode_file_plugin(host); ++ ++ switch (fplug->h.id) { ++ case CRYPTCOMPRESS_FILE_PLUGIN_ID: ++ ret = 1; ++ break; ++ default: ++ ret = 0; ++ } ++ return ret; ++} ++#endif /* REISER4_DEBUG */ ++ ++static void reiser4_detach_crypto_info(struct inode * inode) ++{ ++ assert("edward-1385", inode != NULL); ++ assert("edward-1386", host_allows_crypto_info(inode)); ++ ++ if (inode_crypto_info(inode)) ++ unload_crypto_info(inode); ++ set_inode_crypto_info(inode, NULL); ++} ++ ++#if 0 ++ ++/* compare fingerprints of @child and @parent */ ++static int keyid_eq(struct reiser4_crypto_info * child, ++ struct reiser4_crypto_info * parent) ++{ ++ return !memcmp(child->keyid, ++ parent->keyid, ++ info_digest_plugin(parent)->fipsize); ++} ++ ++/* check if a crypto-stat (which is bound to @parent) can be inherited */ ++int can_inherit_crypto_cryptcompress(struct inode *child, struct inode *parent) ++{ ++ if (!need_cipher(child)) ++ return 0; ++ /* the child is created */ ++ if (!inode_crypto_info(child)) ++ return 1; ++ /* the child is looked up */ ++ if (!inode_crypto_info(parent)) ++ return 0; ++ return (inode_cipher_plugin(child) == inode_cipher_plugin(parent) && ++ inode_digest_plugin(child) == inode_digest_plugin(parent) && ++ inode_crypto_info(child)->keysize == ++ inode_crypto_info(parent)->keysize && ++ keyid_eq(inode_crypto_info(child), inode_crypto_info(parent))); ++} ++#endif ++ ++/* helper functions for ->create() method of the cryptcompress plugin */ ++static int inode_set_crypto(struct inode * object) ++{ ++ reiser4_inode * info; ++ if (!inode_crypto_info(object)) { ++ if (need_cipher(object)) ++ return RETERR(-EINVAL); ++ /* the file is not to be encrypted */ ++ return 0; ++ } ++ info = reiser4_inode_data(object); ++ info->extmask |= (1 << CRYPTO_STAT); ++ return 0; ++} ++ ++static int inode_init_compression(struct inode * object) ++{ ++ int result = 0; ++ assert("edward-1461", object != NULL); ++ if (inode_compression_plugin(object)->init) ++ result = inode_compression_plugin(object)->init(); ++ return result; ++} ++ ++static int inode_check_cluster(struct inode * object) ++{ ++ assert("edward-696", object != NULL); ++ ++ if (unlikely(inode_cluster_size(object) < PAGE_SIZE)) { ++ warning("edward-1320", "Can not support '%s' " ++ "logical clusters (less then page size)", ++ inode_cluster_plugin(object)->h.label); ++ return RETERR(-EINVAL); ++ } ++ if (unlikely(inode_cluster_shift(object)) >= BITS_PER_BYTE*sizeof(int)){ ++ warning("edward-1463", "Can not support '%s' " ++ "logical clusters (too big for transform)", ++ inode_cluster_plugin(object)->h.label); ++ return RETERR(-EINVAL); ++ } ++ return 0; ++} ++ ++/* plugin->destroy_inode() */ ++void destroy_inode_cryptcompress(struct inode * inode) ++{ ++ assert("edward-1464", INODE_PGCOUNT(inode) == 0); ++ reiser4_detach_crypto_info(inode); ++ return; ++} ++ ++/* plugin->create_object(): ++. install plugins ++. attach crypto info if specified ++. attach compression info if specified ++. attach cluster info ++*/ ++int create_object_cryptcompress(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *data, oid_t *oid) ++{ ++ int result; ++ reiser4_inode *info; ++ ++ assert("edward-23", object != NULL); ++ assert("edward-24", parent != NULL); ++ assert("edward-30", data != NULL); ++ assert("edward-26", reiser4_inode_get_flag(object, REISER4_NO_SD)); ++ assert("edward-27", data->id == CRYPTCOMPRESS_FILE_PLUGIN_ID); ++ ++ info = reiser4_inode_data(object); ++ ++ assert("edward-29", info != NULL); ++ ++ /* set file bit */ ++ info->plugin_mask |= (1 << PSET_FILE); ++ ++ /* set crypto */ ++ result = inode_set_crypto(object); ++ if (result) ++ goto error; ++ /* set compression */ ++ result = inode_init_compression(object); ++ if (result) ++ goto error; ++ /* set cluster */ ++ result = inode_check_cluster(object); ++ if (result) ++ goto error; ++ ++ /* save everything in disk stat-data */ ++ result = write_sd_by_inode_common(object, oid); ++ if (!result) ++ return 0; ++ error: ++ reiser4_detach_crypto_info(object); ++ return result; ++} ++ ++/* plugin->open() */ ++int open_cryptcompress(struct inode * inode, struct file * file) ++{ ++ return 0; ++} ++ ++#if REISER4_CRYPTO ++/* returns a blocksize, the attribute of a cipher algorithm */ ++static unsigned int ++cipher_blocksize(struct inode * inode) ++{ ++ assert("edward-758", need_cipher(inode)); ++ assert("edward-1400", inode_crypto_info(inode) != NULL); ++ return crypto_blkcipher_blocksize ++ (info_get_cipher(inode_crypto_info(inode))); ++} ++ ++/* returns offset translated by scale factor of the crypto-algorithm */ ++static loff_t inode_scaled_offset (struct inode * inode, ++ const loff_t src_off /* input offset */) ++{ ++ assert("edward-97", inode != NULL); ++ ++ if (!need_cipher(inode) || ++ src_off == get_key_offset(reiser4_min_key()) || ++ src_off == get_key_offset(reiser4_max_key())) ++ return src_off; ++ ++ return inode_cipher_plugin(inode)->scale(inode, ++ cipher_blocksize(inode), ++ src_off); ++} ++#else ++#define inode_scaled_offset(__inode, __off) __off ++#endif ++ ++/* returns disk cluster size */ ++size_t inode_scaled_cluster_size(struct inode * inode) ++{ ++ assert("edward-110", inode != NULL); ++ ++ return inode_scaled_offset(inode, inode_cluster_size(inode)); ++} ++ ++/* set number of cluster pages */ ++static void set_cluster_nrpages(struct cluster_handle * clust, ++ struct inode *inode) ++{ ++ struct reiser4_slide * win; ++ ++ assert("edward-180", clust != NULL); ++ assert("edward-1040", inode != NULL); ++ ++ clust->old_nrpages = size_in_pages(lbytes(clust->index, inode)); ++ win = clust->win; ++ if (!win) { ++ clust->nr_pages = size_in_pages(lbytes(clust->index, inode)); ++ return; ++ } ++ assert("edward-1176", clust->op != LC_INVAL); ++ assert("edward-1064", win->off + win->count + win->delta != 0); ++ ++ if (win->stat == HOLE_WINDOW && ++ win->off == 0 && win->count == inode_cluster_size(inode)) { ++ /* special case: writing a "fake" logical cluster */ ++ clust->nr_pages = 0; ++ return; ++ } ++ clust->nr_pages = size_in_pages(max(win->off + win->count + win->delta, ++ lbytes(clust->index, inode))); ++ return; ++} ++ ++/** ++ * build key of a disk cluster (item group) ++ */ ++int build_body_key_cryptcompress(struct inode *inode, loff_t off, ++ reiser4_key *key) ++{ ++ assert("edward-64", inode != 0); ++ ++ if (likely(off != get_key_offset(reiser4_max_key()))) ++ off = off_to_clust_to_off(off, inode); ++ if (inode_crypto_info(inode)) ++ off = inode_scaled_offset(inode, off); ++ ++ build_body_key_unix_file(inode, off, key); ++ return 0; ++} ++ ++int flow_by_inode_cryptcompress(struct inode *inode, const char __user * buf, ++ int user, /* 1: @buf is of user space, ++ 0: kernel space */ ++ loff_t size, /* @buf size */ ++ loff_t off, /* offset to start io from */ ++ rw_op op, /* READ or WRITE */ ++ flow_t * f /* resulting flow */) ++{ ++ assert("edward-436", f != NULL); ++ assert("edward-149", inode != NULL); ++ assert("edward-150", inode_file_plugin(inode) != NULL); ++ assert("edward-1465", user == 0); /* we use flow to read/write ++ disk clusters located in ++ kernel space */ ++ f->length = size; ++ memcpy(&f->data, &buf, sizeof(buf)); ++ f->user = user; ++ f->op = op; ++ return build_body_key_cryptcompress(inode, off, &f->key); ++} ++ ++static int cryptcompress_hint_validate(hint_t *hint, reiser4_tree *tree, ++ const reiser4_key * key, ++ znode_lock_mode lock_mode) ++{ ++ coord_t *coord; ++ ++ assert("edward-704", hint != NULL); ++ assert("edward-1089", !hint_is_valid(hint)); ++ assert("edward-706", hint->lh.owner == NULL); ++ ++ coord = &hint->ext_coord.coord; ++ ++ if (!hint || !hint_is_set(hint) || hint->mode != lock_mode) ++ /* hint either not set or set by different operation */ ++ return RETERR(-E_REPEAT); ++ ++ if (get_key_offset(key) != hint->offset) ++ /* hint is set for different key */ ++ return RETERR(-E_REPEAT); ++ ++ assert("edward-707", reiser4_schedulable()); ++ ++ return reiser4_seal_validate(&hint->seal, tree, &hint->ext_coord.coord, ++ key, &hint->lh, lock_mode, ++ ZNODE_LOCK_LOPRI); ++} ++ ++/* reserve disk space when writing a logical cluster */ ++static int reserve4cluster(struct inode *inode, struct cluster_handle *clust) ++{ ++ int result = 0; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ assert("edward-965", reiser4_schedulable()); ++ assert("edward-439", inode != NULL); ++ assert("edward-440", clust != NULL); ++ assert("edward-441", clust->pages != NULL); ++ ++ if (clust->nr_pages == 0) { ++ assert("edward-1152", clust->win != NULL); ++ assert("edward-1153", clust->win->stat == HOLE_WINDOW); ++ /* don't reserve disk space for fake logical cluster */ ++ return 0; ++ } ++ assert("edward-442", jprivate(clust->pages[0]) != NULL); ++ ++ result = reiser4_grab_space_force(estimate_insert_cluster(inode) + ++ estimate_update_cluster(inode), ++ BA_CAN_COMMIT, subv); ++ if (result) ++ return result; ++ clust->reserved = 1; ++ grabbed2cluster_reserved(estimate_insert_cluster(inode) + ++ estimate_update_cluster(inode), subv); ++#if REISER4_DEBUG ++ clust->reserved_prepped = estimate_update_cluster(inode); ++ clust->reserved_unprepped = estimate_insert_cluster(inode); ++#endif ++ /* there can be space grabbed by txnmgr_force_commit_all */ ++ return 0; ++} ++ ++/* free reserved disk space if writing a logical cluster fails */ ++static void free_reserved4cluster(struct inode *inode, ++ struct cluster_handle *ch, int count) ++{ ++ assert("edward-967", ch->reserved == 1); ++ ++ cluster_reserved2free(count, get_meta_subvol()); ++ ch->reserved = 0; ++} ++ ++/* ++ * The core search procedure of the cryptcompress plugin. ++ * If returned value is not cbk_errored, then current position ++ * is locked. ++ */ ++static int find_cluster_item(hint_t * hint, ++ const reiser4_key * key, /* key of the item we are ++ looking for */ ++ znode_lock_mode lock_mode /* which lock */ , ++ ra_info_t * ra_info, lookup_bias bias, __u32 flags, ++ reiser4_subvol *subv) ++{ ++ int result; ++ reiser4_key ikey; ++ coord_t *coord = &hint->ext_coord.coord; ++ coord_t orig = *coord; ++ ++ assert("edward-152", hint != NULL); ++ ++ if (!hint_is_valid(hint)) { ++ result = cryptcompress_hint_validate(hint, &subv->tree, ++ key, lock_mode); ++ if (result == -E_REPEAT) ++ goto traverse_tree; ++ else if (result) { ++ assert("edward-1216", 0); ++ return result; ++ } ++ hint_set_valid(hint); ++ } ++ assert("edward-709", znode_is_any_locked(coord->node)); ++ /* ++ * Hint is valid, so we perform in-place lookup. ++ * It means we just need to check if the next item in ++ * the tree (relative to the current position @coord) ++ * has key @key. ++ * ++ * Valid hint means in particular, that node is not ++ * empty and at least one its item has been processed ++ */ ++ if (equal_to_rdk(coord->node, key)) { ++ /* ++ * Look for the item in the right neighbor ++ */ ++ lock_handle lh_right; ++ ++ init_lh(&lh_right); ++ result = reiser4_get_right_neighbor(&lh_right, coord->node, ++ znode_is_wlocked(coord->node) ? ++ ZNODE_WRITE_LOCK : ZNODE_READ_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result) { ++ done_lh(&lh_right); ++ reiser4_unset_hint(hint); ++ if (result == -E_NO_NEIGHBOR) ++ return RETERR(-EIO); ++ return result; ++ } ++ assert("edward-1218", ++ equal_to_ldk(lh_right.node, key)); ++ result = zload(lh_right.node); ++ if (result) { ++ done_lh(&lh_right); ++ reiser4_unset_hint(hint); ++ return result; ++ } ++ coord_init_first_unit_nocheck(coord, lh_right.node); ++ ++ if (!coord_is_existing_item(coord)) { ++ zrelse(lh_right.node); ++ done_lh(&lh_right); ++ goto traverse_tree; ++ } ++ item_key_by_coord(coord, &ikey); ++ zrelse(coord->node); ++ if (unlikely(!keyeq(key, &ikey))) { ++ warning("edward-1608", ++ "Expected item not found. Fsck?"); ++ done_lh(&lh_right); ++ goto not_found; ++ } ++ /* ++ * item has been found in the right neighbor; ++ * move lock to the right ++ */ ++ done_lh(&hint->lh); ++ move_lh(&hint->lh, &lh_right); ++ ++ dclust_inc_extension_ncount(hint); ++ ++ return CBK_COORD_FOUND; ++ } else { ++ /* ++ * Look for the item in the current node ++ */ ++ coord->item_pos++; ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ ++ result = zload(coord->node); ++ if (result) { ++ done_lh(&hint->lh); ++ return result; ++ } ++ if (!coord_is_existing_item(coord)) { ++ zrelse(coord->node); ++ goto not_found; ++ } ++ item_key_by_coord(coord, &ikey); ++ zrelse(coord->node); ++ if (!keyeq(key, &ikey)) ++ goto not_found; ++ /* ++ * item has been found in the current node ++ */ ++ dclust_inc_extension_ncount(hint); ++ ++ return CBK_COORD_FOUND; ++ } ++ not_found: ++ /* ++ * The tree doesn't contain an item with @key; ++ * roll back the coord ++ */ ++ *coord = orig; ++ ON_DEBUG(coord_update_v(coord)); ++ return CBK_COORD_NOTFOUND; ++ ++ traverse_tree: ++ ++ reiser4_unset_hint(hint); ++ dclust_init_extension(hint); ++ coord_init_zero(coord); ++ ++ assert("edward-713", hint->lh.owner == NULL); ++ assert("edward-714", reiser4_schedulable()); ++ ++ result = coord_by_key(&subv->tree, ++ key, coord, &hint->lh, ++ lock_mode, bias, LEAF_LEVEL, LEAF_LEVEL, ++ CBK_UNIQUE | flags, ra_info); ++ if (cbk_errored(result)) ++ return result; ++ if(result == CBK_COORD_FOUND) ++ dclust_inc_extension_ncount(hint); ++ hint_set_valid(hint); ++ return result; ++} ++ ++#if REISER4_CRYPTO ++ ++/* This function is called by deflate[inflate] manager when ++ creating a transformed/plain stream to check if we should ++ create/cut some overhead. If this returns true, then @oh ++ contains the size of this overhead. ++ */ ++static int need_cut_or_align(struct inode * inode, ++ struct cluster_handle * ch, rw_op rw, int * oh) ++{ ++ struct tfm_cluster * tc = &ch->tc; ++ switch (rw) { ++ case WRITE_OP: /* estimate align */ ++ *oh = tc->len % cipher_blocksize(inode); ++ if (*oh != 0) ++ return 1; ++ break; ++ case READ_OP: /* estimate cut */ ++ *oh = *(tfm_output_data(ch) + tc->len - 1); ++ break; ++ default: ++ impossible("edward-1401", "bad option"); ++ } ++ return (tc->len != tc->lsize); ++} ++ ++/* create/cut an overhead of transformed/plain stream */ ++static void align_or_cut_overhead(struct inode * inode, ++ struct cluster_handle * ch, rw_op rw) ++{ ++ unsigned int oh; ++ cipher_plugin * cplug = inode_cipher_plugin(inode); ++ ++ assert("edward-1402", need_cipher(inode)); ++ ++ if (!need_cut_or_align(inode, ch, rw, &oh)) ++ return; ++ switch (rw) { ++ case WRITE_OP: /* do align */ ++ ch->tc.len += ++ cplug->align_stream(tfm_input_data(ch) + ++ ch->tc.len, ch->tc.len, ++ cipher_blocksize(inode)); ++ *(tfm_input_data(ch) + ch->tc.len - 1) = ++ cipher_blocksize(inode) - oh; ++ break; ++ case READ_OP: /* do cut */ ++ assert("edward-1403", oh <= cipher_blocksize(inode)); ++ ch->tc.len -= oh; ++ break; ++ default: ++ impossible("edward-1404", "bad option"); ++ } ++ return; ++} ++ ++static unsigned max_cipher_overhead(struct inode * inode) ++{ ++ if (!need_cipher(inode) || !inode_cipher_plugin(inode)->align_stream) ++ return 0; ++ return cipher_blocksize(inode); ++} ++#else ++#define max_cipher_overhead(_inode) 0 ++#endif ++ ++static int deflate_overhead(struct inode *inode) ++{ ++ return (inode_compression_plugin(inode)-> ++ checksum ? DC_CHECKSUM_SIZE : 0); ++} ++ ++static unsigned deflate_overrun(struct inode * inode, int ilen) ++{ ++ return coa_overrun(inode_compression_plugin(inode), ilen); ++} ++ ++static bool is_all_zero(char const* mem, size_t size) ++{ ++ while (size-- > 0) ++ if (*mem++) ++ return false; ++ return true; ++} ++ ++static inline bool should_punch_hole(struct tfm_cluster *tc) ++{ ++ if (0 && ++ !reiser4_is_set(reiser4_get_current_sb(), REISER4_DONT_PUNCH_HOLES) ++ && is_all_zero(tfm_stream_data(tc, INPUT_STREAM), tc->lsize)) { ++ ++ tc->hole = 1; ++ return true; ++ } ++ return false; ++} ++ ++/* Estimating compressibility of a logical cluster by various ++ policies represented by compression mode plugin. ++ If this returns false, then compressor won't be called for ++ the cluster of index @index. ++*/ ++static int should_compress(struct tfm_cluster *tc, cloff_t index, ++ struct inode *inode) ++{ ++ compression_plugin *cplug = inode_compression_plugin(inode); ++ compression_mode_plugin *mplug = inode_compression_mode_plugin(inode); ++ ++ assert("edward-1321", tc->len != 0); ++ assert("edward-1322", cplug != NULL); ++ assert("edward-1323", mplug != NULL); ++ ++ if (should_punch_hole(tc)) ++ /* ++ * we are about to punch a hole, ++ * so don't compress data ++ */ ++ return 0; ++ return /* estimate by size */ ++ (cplug->min_size_deflate ? ++ tc->len >= cplug->min_size_deflate() : ++ 1) && ++ /* estimate by compression mode plugin */ ++ (mplug->should_deflate ? ++ mplug->should_deflate(inode, index) : ++ 1); ++} ++ ++/* Evaluating results of compression transform. ++ Returns true, if we need to accept this results */ ++static int save_compressed(int size_before, int size_after, struct inode *inode) ++{ ++ return (size_after + deflate_overhead(inode) + ++ max_cipher_overhead(inode) < size_before); ++} ++ ++/* Guess result of the evaluation above */ ++static int need_inflate(struct cluster_handle * ch, struct inode * inode, ++ int encrypted /* is cluster encrypted */ ) ++{ ++ struct tfm_cluster * tc = &ch->tc; ++ ++ assert("edward-142", tc != 0); ++ assert("edward-143", inode != NULL); ++ ++ return tc->len < ++ (encrypted ? ++ inode_scaled_offset(inode, tc->lsize) : ++ tc->lsize); ++} ++ ++/* If results of compression were accepted, then we add ++ a checksum to catch possible disk cluster corruption. ++ The following is a format of the data stored in disk clusters: ++ ++ data This is (transformed) logical cluster. ++ cipher_overhead This is created by ->align() method ++ of cipher plugin. May be absent. ++ checksum (4) This is created by ->checksum method ++ of compression plugin to check ++ integrity. May be absent. ++ ++ Crypto overhead format: ++ ++ data ++ control_byte (1) contains aligned overhead size: ++ 1 <= overhead <= cipher_blksize ++*/ ++/* Append a checksum at the end of a transformed stream */ ++static void dc_set_checksum(compression_plugin * cplug, struct tfm_cluster * tc) ++{ ++ __u32 checksum; ++ ++ assert("edward-1309", tc != NULL); ++ assert("edward-1310", tc->len > 0); ++ assert("edward-1311", cplug->checksum != NULL); ++ ++ checksum = cplug->checksum(tfm_stream_data(tc, OUTPUT_STREAM), tc->len); ++ put_unaligned(cpu_to_le32(checksum), ++ (d32 *)(tfm_stream_data(tc, OUTPUT_STREAM) + tc->len)); ++ tc->len += (int)DC_CHECKSUM_SIZE; ++} ++ ++/* Check a disk cluster checksum. ++ Returns 0 if checksum is correct, otherwise returns 1 */ ++static int dc_check_checksum(compression_plugin * cplug, struct tfm_cluster * tc) ++{ ++ assert("edward-1312", tc != NULL); ++ assert("edward-1313", tc->len > (int)DC_CHECKSUM_SIZE); ++ assert("edward-1314", cplug->checksum != NULL); ++ ++ if (cplug->checksum(tfm_stream_data(tc, INPUT_STREAM), ++ tc->len - (int)DC_CHECKSUM_SIZE) != ++ le32_to_cpu(get_unaligned((d32 *) ++ (tfm_stream_data(tc, INPUT_STREAM) ++ + tc->len - (int)DC_CHECKSUM_SIZE)))) { ++ warning("edward-156", ++ "Bad disk cluster checksum %d, (should be %d) Fsck?\n", ++ (int)le32_to_cpu ++ (get_unaligned((d32 *) ++ (tfm_stream_data(tc, INPUT_STREAM) + ++ tc->len - (int)DC_CHECKSUM_SIZE))), ++ (int)cplug->checksum ++ (tfm_stream_data(tc, INPUT_STREAM), ++ tc->len - (int)DC_CHECKSUM_SIZE)); ++ return 1; ++ } ++ tc->len -= (int)DC_CHECKSUM_SIZE; ++ return 0; ++} ++ ++/* get input/output stream for some transform action */ ++int grab_tfm_stream(struct inode * inode, struct tfm_cluster * tc, ++ tfm_stream_id id) ++{ ++ size_t size = inode_scaled_cluster_size(inode); ++ ++ assert("edward-901", tc != NULL); ++ assert("edward-1027", inode_compression_plugin(inode) != NULL); ++ ++ if (cluster_get_tfm_act(tc) == TFMA_WRITE) ++ size += deflate_overrun(inode, inode_cluster_size(inode)); ++ ++ if (!get_tfm_stream(tc, id) && id == INPUT_STREAM) ++ alternate_streams(tc); ++ if (!get_tfm_stream(tc, id)) ++ return alloc_tfm_stream(tc, size, id); ++ ++ assert("edward-902", tfm_stream_is_set(tc, id)); ++ ++ if (tfm_stream_size(tc, id) < size) ++ return realloc_tfm_stream(tc, size, id); ++ return 0; ++} ++ ++/* Common deflate manager */ ++int reiser4_deflate_cluster(struct cluster_handle * clust, struct inode * inode) ++{ ++ int result = 0; ++ int compressed = 0; ++ int encrypted = 0; ++ struct tfm_cluster * tc = &clust->tc; ++ compression_plugin * coplug; ++ ++ assert("edward-401", inode != NULL); ++ assert("edward-903", tfm_stream_is_set(tc, INPUT_STREAM)); ++ assert("edward-1348", cluster_get_tfm_act(tc) == TFMA_WRITE); ++ assert("edward-498", !tfm_cluster_is_uptodate(tc)); ++ ++ coplug = inode_compression_plugin(inode); ++ if (should_compress(tc, clust->index, inode)) { ++ /* try to compress, discard bad results */ ++ size_t dst_len; ++ compression_mode_plugin * mplug = ++ inode_compression_mode_plugin(inode); ++ assert("edward-602", coplug != NULL); ++ assert("edward-1423", coplug->compress != NULL); ++ ++ result = grab_coa(tc, coplug); ++ if (result) ++ /* ++ * can not allocate memory to perform ++ * compression, leave data uncompressed ++ */ ++ goto cipher; ++ result = grab_tfm_stream(inode, tc, OUTPUT_STREAM); ++ if (result) { ++ warning("edward-1425", ++ "alloc stream failed with ret=%d, skipped compression", ++ result); ++ goto cipher; ++ } ++ dst_len = tfm_stream_size(tc, OUTPUT_STREAM); ++ coplug->compress(get_coa(tc, coplug->h.id, tc->act), ++ tfm_input_data(clust), tc->len, ++ tfm_output_data(clust), &dst_len); ++ /* make sure we didn't overwrite extra bytes */ ++ assert("edward-603", ++ dst_len <= tfm_stream_size(tc, OUTPUT_STREAM)); ++ ++ /* evaluate results of compression transform */ ++ if (save_compressed(tc->len, dst_len, inode)) { ++ /* good result, accept */ ++ tc->len = dst_len; ++ if (mplug->accept_hook != NULL) { ++ result = mplug->accept_hook(inode, clust->index); ++ if (result) ++ warning("edward-1426", ++ "accept_hook failed with ret=%d", ++ result); ++ } ++ compressed = 1; ++ } ++ else { ++ /* bad result, discard */ ++#if 0 ++ if (cluster_is_complete(clust, inode)) ++ warning("edward-1496", ++ "incompressible cluster %lu (inode %llu)", ++ clust->index, ++ (unsigned long long)get_inode_oid(inode)); ++#endif ++ if (mplug->discard_hook != NULL && ++ cluster_is_complete(clust, inode)) { ++ result = mplug->discard_hook(inode, ++ clust->index); ++ if (result) ++ warning("edward-1427", ++ "discard_hook failed with ret=%d", ++ result); ++ } ++ } ++ } ++ cipher: ++#if REISER4_CRYPTO ++ if (need_cipher(inode)) { ++ cipher_plugin * ciplug; ++ struct blkcipher_desc desc; ++ struct scatterlist src; ++ struct scatterlist dst; ++ ++ ciplug = inode_cipher_plugin(inode); ++ desc.tfm = info_get_cipher(inode_crypto_info(inode)); ++ desc.flags = 0; ++ if (compressed) ++ alternate_streams(tc); ++ result = grab_tfm_stream(inode, tc, OUTPUT_STREAM); ++ if (result) ++ return result; ++ ++ align_or_cut_overhead(inode, clust, WRITE_OP); ++ sg_init_one(&src, tfm_input_data(clust), tc->len); ++ sg_init_one(&dst, tfm_output_data(clust), tc->len); ++ ++ result = crypto_blkcipher_encrypt(&desc, &dst, &src, tc->len); ++ if (result) { ++ warning("edward-1405", ++ "encryption failed flags=%x\n", desc.flags); ++ return result; ++ } ++ encrypted = 1; ++ } ++#endif ++ if (compressed && coplug->checksum != NULL) ++ dc_set_checksum(coplug, tc); ++ if (!compressed && !encrypted) ++ alternate_streams(tc); ++ return result; ++} ++ ++/* Common inflate manager. */ ++int reiser4_inflate_cluster(struct cluster_handle * clust, struct inode * inode) ++{ ++ int result = 0; ++ int transformed = 0; ++ struct tfm_cluster * tc = &clust->tc; ++ compression_plugin * coplug; ++ ++ assert("edward-905", inode != NULL); ++ assert("edward-1178", clust->dstat == PREP_DISK_CLUSTER); ++ assert("edward-906", tfm_stream_is_set(&clust->tc, INPUT_STREAM)); ++ assert("edward-1349", tc->act == TFMA_READ); ++ assert("edward-907", !tfm_cluster_is_uptodate(tc)); ++ ++ /* Handle a checksum (if any) */ ++ coplug = inode_compression_plugin(inode); ++ if (need_inflate(clust, inode, need_cipher(inode)) && ++ coplug->checksum != NULL) { ++ result = dc_check_checksum(coplug, tc); ++ if (unlikely(result)) { ++ warning("edward-1460", ++ "Inode %llu: disk cluster %lu looks corrupted", ++ (unsigned long long)get_inode_oid(inode), ++ clust->index); ++ return RETERR(-EIO); ++ } ++ } ++#if REISER4_CRYPTO ++ if (need_cipher(inode)) { ++ cipher_plugin * ciplug; ++ struct blkcipher_desc desc; ++ struct scatterlist src; ++ struct scatterlist dst; ++ ++ ciplug = inode_cipher_plugin(inode); ++ desc.tfm = info_get_cipher(inode_crypto_info(inode)); ++ desc.flags = 0; ++ result = grab_tfm_stream(inode, tc, OUTPUT_STREAM); ++ if (result) ++ return result; ++ assert("edward-909", tfm_cluster_is_set(tc)); ++ ++ sg_init_one(&src, tfm_input_data(clust), tc->len); ++ sg_init_one(&dst, tfm_output_data(clust), tc->len); ++ ++ result = crypto_blkcipher_decrypt(&desc, &dst, &src, tc->len); ++ if (result) { ++ warning("edward-1600", "decrypt failed flags=%x\n", ++ desc.flags); ++ return result; ++ } ++ align_or_cut_overhead(inode, clust, READ_OP); ++ transformed = 1; ++ } ++#endif ++ if (need_inflate(clust, inode, 0)) { ++ size_t dst_len = inode_cluster_size(inode); ++ if(transformed) ++ alternate_streams(tc); ++ ++ result = grab_tfm_stream(inode, tc, OUTPUT_STREAM); ++ if (result) ++ return result; ++ assert("edward-1305", coplug->decompress != NULL); ++ assert("edward-910", tfm_cluster_is_set(tc)); ++ ++ coplug->decompress(get_coa(tc, coplug->h.id, tc->act), ++ tfm_input_data(clust), tc->len, ++ tfm_output_data(clust), &dst_len); ++ /* check length */ ++ tc->len = dst_len; ++ assert("edward-157", dst_len == tc->lsize); ++ transformed = 1; ++ } ++ if (!transformed) ++ alternate_streams(tc); ++ return result; ++} ++ ++/* This is implementation of readpage method of struct ++ address_space_operations for cryptcompress plugin. */ ++int readpage_cryptcompress(struct file *file, struct page *page) ++{ ++ reiser4_context *ctx; ++ struct cluster_handle clust; ++ int result; ++ ++ assert("edward-88", PageLocked(page)); ++ assert("vs-976", !PageUptodate(page)); ++ assert("edward-89", page->mapping && page->mapping->host); ++ ++ ctx = reiser4_init_context(page->mapping->host->i_sb); ++ if (IS_ERR(ctx)) { ++ unlock_page(page); ++ return PTR_ERR(ctx); ++ } ++ assert("edward-113", ++ ergo(file != NULL, ++ page->mapping == file_inode(file)->i_mapping)); ++ ++ if (PageUptodate(page)) { ++ warning("edward-1338", "page is already uptodate\n"); ++ unlock_page(page); ++ reiser4_exit_context(ctx); ++ return 0; ++ } ++ cluster_init_read(&clust, NULL); ++ clust.file = file; ++ ++ result = readpage_ctail(&clust, page); ++ ++ put_cluster_handle(&clust); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* number of pages to check in */ ++static int get_new_nrpages(struct cluster_handle * clust) ++{ ++ switch (clust->op) { ++ case LC_APPOV: ++ case LC_EXPAND: ++ return clust->nr_pages; ++ case LC_SHRINK: ++ assert("edward-1179", clust->win != NULL); ++ return size_in_pages(clust->win->off + clust->win->count); ++ default: ++ impossible("edward-1180", "bad page cluster option"); ++ return 0; ++ } ++} ++ ++static void set_cluster_pages_dirty(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ int i; ++ struct page *pg; ++ int nrpages = get_new_nrpages(clust); ++ ++ for (i = 0; i < nrpages; i++) { ++ ++ pg = clust->pages[i]; ++ assert("edward-968", pg != NULL); ++ lock_page(pg); ++ assert("edward-1065", PageUptodate(pg)); ++ set_page_dirty_notag(pg); ++ unlock_page(pg); ++ mark_page_accessed(pg); ++ } ++} ++ ++/* Grab a page cluster for read/write operations. ++ Attach a jnode for write operations (when preparing for modifications, which ++ are supposed to be committed). ++ ++ We allocate only one jnode per page cluster; this jnode is binded to the ++ first page of this cluster, so we have an extra-reference that will be put ++ as soon as jnode is evicted from memory), other references will be cleaned ++ up in flush time (assume that check in page cluster was successful). ++*/ ++int grab_page_cluster(struct inode * inode, ++ struct cluster_handle * clust, rw_op rw) ++{ ++ int i; ++ int result = 0; ++ jnode *node = NULL; ++ ++ assert("edward-182", clust != NULL); ++ assert("edward-183", clust->pages != NULL); ++ assert("edward-1466", clust->node == NULL); ++ assert("edward-1428", inode != NULL); ++ assert("edward-1429", inode->i_mapping != NULL); ++ assert("edward-184", clust->nr_pages <= cluster_nrpages(inode)); ++ ++ if (clust->nr_pages == 0) ++ return 0; ++ ++ for (i = 0; i < clust->nr_pages; i++) { ++ ++ assert("edward-1044", clust->pages[i] == NULL); ++ ++ clust->pages[i] = ++ find_or_create_page(inode->i_mapping, ++ clust_to_pg(clust->index, inode) + i, ++ reiser4_ctx_gfp_mask_get()); ++ if (!clust->pages[i]) { ++ result = RETERR(-ENOMEM); ++ break; ++ } ++ if (i == 0 && rw == WRITE_OP) { ++ node = jnode_of_page(clust->pages[i]); ++ if (IS_ERR(node)) { ++ result = PTR_ERR(node); ++ unlock_page(clust->pages[i]); ++ break; ++ } ++ JF_SET(node, JNODE_CLUSTER_PAGE); ++ assert("edward-920", jprivate(clust->pages[0])); ++ /* ++ * this jnode doesn't participate in IO - ++ * we need it only to track transactions. ++ * We'll make it dirty and respectively ++ * need to reserve disk space for that. ++ * By design we reserve space on meta-data ++ * subvolume. So we set meta-data subvolume ++ * for reservation issues. ++ */ ++ if (node->subvol == NULL) ++ node->subvol = get_meta_subvol(); ++ else ++ assert("edward-2225", ++ node->subvol == get_meta_subvol()); ++ } ++ INODE_PGCOUNT_INC(inode); ++ unlock_page(clust->pages[i]); ++ } ++ if (unlikely(result)) { ++ while (i) { ++ put_cluster_page(clust->pages[--i]); ++ INODE_PGCOUNT_DEC(inode); ++ } ++ if (node && !IS_ERR(node)) ++ jput(node); ++ return result; ++ } ++ clust->node = node; ++ return 0; ++} ++ ++static void truncate_page_cluster_range(struct inode * inode, ++ struct page ** pages, ++ cloff_t index, ++ int from, int count, ++ int even_cows) ++{ ++ assert("edward-1467", count > 0); ++ reiser4_invalidate_pages(inode->i_mapping, ++ clust_to_pg(index, inode) + from, ++ count, even_cows); ++} ++ ++/* Put @count pages starting from @from offset */ ++void __put_page_cluster(int from, int count, ++ struct page ** pages, struct inode * inode) ++{ ++ int i; ++ assert("edward-1468", pages != NULL); ++ assert("edward-1469", inode != NULL); ++ assert("edward-1470", from >= 0 && count >= 0); ++ ++ for (i = 0; i < count; i++) { ++ assert("edward-1471", pages[from + i] != NULL); ++ assert("edward-1472", ++ pages[from + i]->index == pages[from]->index + i); ++ ++ put_cluster_page(pages[from + i]); ++ INODE_PGCOUNT_DEC(inode); ++ } ++} ++ ++/* ++ * This is dual to grab_page_cluster, ++ * however if @rw == WRITE_OP, then we call this function ++ * only if something is failed before checkin page cluster. ++ */ ++void put_page_cluster(struct cluster_handle * clust, ++ struct inode * inode, rw_op rw) ++{ ++ assert("edward-445", clust != NULL); ++ assert("edward-922", clust->pages != NULL); ++ assert("edward-446", ++ ergo(clust->nr_pages != 0, clust->pages[0] != NULL)); ++ ++ __put_page_cluster(0, clust->nr_pages, clust->pages, inode); ++ if (rw == WRITE_OP) { ++ if (unlikely(clust->node)) { ++ assert("edward-447", ++ clust->node == jprivate(clust->pages[0])); ++ jput(clust->node); ++ clust->node = NULL; ++ } ++ } ++} ++ ++#if REISER4_DEBUG ++int cryptcompress_inode_ok(struct inode *inode) ++{ ++ if (!(reiser4_inode_data(inode)->plugin_mask & (1 << PSET_FILE))) ++ return 0; ++ if (!cluster_shift_ok(inode_cluster_shift(inode))) ++ return 0; ++ return 1; ++} ++ ++static int window_ok(struct reiser4_slide * win, struct inode *inode) ++{ ++ assert("edward-1115", win != NULL); ++ assert("edward-1116", ergo(win->delta, win->stat == HOLE_WINDOW)); ++ ++ return (win->off != inode_cluster_size(inode)) && ++ (win->off + win->count + win->delta <= inode_cluster_size(inode)); ++} ++ ++static int cluster_ok(struct cluster_handle * clust, struct inode *inode) ++{ ++ assert("edward-279", clust != NULL); ++ ++ if (!clust->pages) ++ return 0; ++ return (clust->win ? window_ok(clust->win, inode) : 1); ++} ++#if 0 ++static int pages_truncate_ok(struct inode *inode, pgoff_t start) ++{ ++ int found; ++ struct page * page; ++ ++ found = find_get_pages(inode->i_mapping, &start, 1, &page); ++ if (found) ++ put_cluster_page(page); ++ return !found; ++} ++#else ++#define pages_truncate_ok(inode, start) 1 ++#endif ++ ++static int jnode_truncate_ok(struct inode *inode, cloff_t index) ++{ ++ jnode *node; ++ node = jlookup(get_inode_oid(inode), clust_to_pg(index, inode)); ++ if (likely(!node)) ++ return 1; ++ jput(node); ++ return 0; ++} ++#endif ++ ++/* guess next window stat */ ++static inline window_stat next_window_stat(struct reiser4_slide * win) ++{ ++ assert("edward-1130", win != NULL); ++ return ((win->stat == HOLE_WINDOW && win->delta == 0) ? ++ HOLE_WINDOW : DATA_WINDOW); ++} ++ ++/* guess and set next cluster index and window params */ ++static void move_update_window(struct inode * inode, ++ struct cluster_handle * clust, ++ loff_t file_off, loff_t to_file) ++{ ++ struct reiser4_slide * win; ++ ++ assert("edward-185", clust != NULL); ++ assert("edward-438", clust->pages != NULL); ++ assert("edward-281", cluster_ok(clust, inode)); ++ ++ win = clust->win; ++ if (!win) ++ return; ++ ++ switch (win->stat) { ++ case DATA_WINDOW: ++ /* increment */ ++ clust->index++; ++ win->stat = DATA_WINDOW; ++ win->off = 0; ++ win->count = min((loff_t)inode_cluster_size(inode), to_file); ++ break; ++ case HOLE_WINDOW: ++ switch (next_window_stat(win)) { ++ case HOLE_WINDOW: ++ /* skip */ ++ clust->index = off_to_clust(file_off, inode); ++ win->stat = HOLE_WINDOW; ++ win->off = 0; ++ win->count = off_to_cloff(file_off, inode); ++ win->delta = min((loff_t)(inode_cluster_size(inode) - ++ win->count), to_file); ++ break; ++ case DATA_WINDOW: ++ /* stay */ ++ win->stat = DATA_WINDOW; ++ /* off+count+delta=inv */ ++ win->off = win->off + win->count; ++ win->count = win->delta; ++ win->delta = 0; ++ break; ++ default: ++ impossible("edward-282", "wrong next window state"); ++ } ++ break; ++ default: ++ impossible("edward-283", "wrong current window state"); ++ } ++ assert("edward-1068", cluster_ok(clust, inode)); ++} ++ ++static int update_sd_cryptcompress(struct inode *inode) ++{ ++ int result = 0; ++ ++ assert("edward-978", reiser4_schedulable()); ++ /* ++ * Reserve space for stat-data update ++ */ ++ result = reiser4_grab_space_force(estimate_update_common(inode), ++ BA_CAN_COMMIT, ++ get_meta_subvol()); ++ if (result) ++ return result; ++ if (!IS_NOCMTIME(inode)) ++ inode->i_ctime = inode->i_mtime = current_time(inode); ++ ++ result = reiser4_update_sd(inode); ++ ++ if (unlikely(result != 0)) ++ warning("edward-1573", ++ "Can not update stat-data: %i. FSCK?", ++ result); ++ return result; ++} ++ ++static void uncapture_cluster_jnode(jnode * node) ++{ ++ txn_atom *atom; ++ ++ assert_spin_locked(&(node->guard)); ++ ++ atom = jnode_get_atom(node); ++ if (atom == NULL) { ++ assert("jmacd-7111", !JF_ISSET(node, JNODE_DIRTY)); ++ spin_unlock_jnode(node); ++ return; ++ } ++ reiser4_uncapture_block(node); ++ spin_unlock_atom(atom); ++ jput(node); ++} ++ ++static void put_found_pages(struct page **pages, int nr) ++{ ++ int i; ++ for (i = 0; i < nr; i++) { ++ assert("edward-1045", pages[i] != NULL); ++ put_cluster_page(pages[i]); ++ } ++} ++ ++/* Lifecycle of a logical cluster in the system. ++ * ++ * ++ * Logical cluster of a cryptcompress file is represented in the system by ++ * . page cluster (in memory, primary cache, contains plain text); ++ * . disk cluster (in memory, secondary cache, contains transformed text). ++ * Primary cache is to reduce number of transform operations (compression, ++ * encryption), i.e. to implement transform-caching strategy. ++ * Secondary cache is to reduce number of I/O operations, i.e. for usual ++ * write-caching strategy. Page cluster is a set of pages, i.e. mapping of ++ * a logical cluster to the primary cache. Disk cluster is a set of items ++ * of the same type defined by some reiser4 item plugin id. ++ * ++ * 1. Performing modifications ++ * ++ * Every modification of a cryptcompress file is considered as a set of ++ * operations performed on file's logical clusters. Every such "atomic" ++ * modification is truncate, append and(or) overwrite some bytes of a ++ * logical cluster performed in the primary cache with the following ++ * synchronization with the secondary cache (in flush time). Disk clusters, ++ * which live in the secondary cache, are supposed to be synchronized with ++ * disk. The mechanism of synchronization of primary and secondary caches ++ * includes so-called checkin/checkout technique described below. ++ * ++ * 2. Submitting modifications ++ * ++ * Each page cluster has associated jnode (a special in-memory header to ++ * keep a track of transactions in reiser4), which is attached to its first ++ * page when grabbing page cluster for modifications (see grab_page_cluster). ++ * Submitting modifications (see checkin_logical_cluster) is going per logical ++ * cluster and includes: ++ * . checkin_cluster_size; ++ * . checkin_page_cluster. ++ * checkin_cluster_size() is resolved to file size update (which completely ++ * defines new size of logical cluster (number of file's bytes in a logical ++ * cluster). ++ * checkin_page_cluster() captures jnode of a page cluster and installs ++ * jnode's dirty flag (if needed) to indicate that modifications are ++ * successfully checked in. ++ * ++ * 3. Checking out modifications ++ * ++ * Is going per logical cluster in flush time (see checkout_logical_cluster). ++ * This is the time of synchronizing primary and secondary caches. ++ * checkout_logical_cluster() includes: ++ * . checkout_page_cluster (retrieving checked in pages). ++ * . uncapture jnode (including clear dirty flag and unlock) ++ * ++ * 4. Committing modifications ++ * ++ * Proceeding a synchronization of primary and secondary caches. When checking ++ * out page cluster (the phase above) pages are locked/flushed/unlocked ++ * one-by-one in ascending order of their indexes to contiguous stream, which ++ * is supposed to be transformed (compressed, encrypted), chopped up into items ++ * and committed to disk as a disk cluster. ++ * ++ * 5. Managing page references ++ * ++ * Every checked in page have a special additional "control" reference, ++ * which is dropped at checkout. We need this to avoid unexpected evicting ++ * pages from memory before checkout. Control references are managed so ++ * they are not accumulated with every checkin: ++ * ++ * 0 ++ * checkin -> 1 ++ * 0 -> checkout ++ * checkin -> 1 ++ * checkin -> 1 ++ * checkin -> 1 ++ * 0 -> checkout ++ * ... ++ * ++ * Every page cluster has its own unique "cluster lock". Update/drop ++ * references are serialized via this lock. Number of checked in cluster ++ * pages is calculated by i_size under cluster lock. File size is updated ++ * at every checkin action also under cluster lock (except cases of ++ * appending/truncating fake logical clusters). ++ * ++ * Proof of correctness: ++ * ++ * Since we update file size under cluster lock, in the case of non-fake ++ * logical cluster with its lock held we do have expected number of checked ++ * in pages. On the other hand, append/truncate of fake logical clusters ++ * doesn't change number of checked in pages of any cluster. ++ * ++ * NOTE-EDWARD: As cluster lock we use guard (spinlock_t) of its jnode. ++ * Currently, I don't see any reason to create a special lock for those ++ * needs. ++ */ ++ ++static inline void lock_cluster(jnode * node) ++{ ++ spin_lock_jnode(node); ++} ++ ++static inline void unlock_cluster(jnode * node) ++{ ++ spin_unlock_jnode(node); ++} ++ ++static inline void unlock_cluster_uncapture(jnode * node) ++{ ++ uncapture_cluster_jnode(node); ++} ++ ++/* Set new file size by window. Cluster lock is required. */ ++static void checkin_file_size(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ loff_t new_size; ++ struct reiser4_slide * win; ++ ++ assert("edward-1181", clust != NULL); ++ assert("edward-1182", inode != NULL); ++ assert("edward-1473", clust->pages != NULL); ++ assert("edward-1474", clust->pages[0] != NULL); ++ assert("edward-1475", jprivate(clust->pages[0]) != NULL); ++ assert_spin_locked(&(jprivate(clust->pages[0])->guard)); ++ ++ ++ win = clust->win; ++ assert("edward-1183", win != NULL); ++ ++ new_size = clust_to_off(clust->index, inode) + win->off; ++ ++ switch (clust->op) { ++ case LC_APPOV: ++ case LC_EXPAND: ++ if (new_size + win->count <= i_size_read(inode)) ++ /* overwrite only */ ++ return; ++ new_size += win->count; ++ break; ++ case LC_SHRINK: ++ break; ++ default: ++ impossible("edward-1184", "bad page cluster option"); ++ break; ++ } ++ inode_check_scale_nolock(inode, i_size_read(inode), new_size); ++ i_size_write(inode, new_size); ++ return; ++} ++ ++static inline void checkin_cluster_size(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ if (clust->win) ++ checkin_file_size(clust, inode); ++} ++ ++static int checkin_page_cluster(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ int result; ++ jnode * node; ++ int old_nrpages = clust->old_nrpages; ++ int new_nrpages = get_new_nrpages(clust); ++ ++ node = clust->node; ++ ++ assert("edward-221", node != NULL); ++ assert("edward-971", clust->reserved == 1); ++ assert("edward-1263", ++ clust->reserved_prepped == estimate_update_cluster(inode)); ++ assert("edward-1264", clust->reserved_unprepped == 0); ++ ++ if (JF_ISSET(node, JNODE_DIRTY)) { ++ /* ++ * page cluster was checked in, but not yet ++ * checked out, so release related resources ++ */ ++ free_reserved4cluster(inode, clust, ++ estimate_update_cluster(inode)); ++ __put_page_cluster(0, clust->old_nrpages, ++ clust->pages, inode); ++ } else { ++ result = capture_cluster_jnode(node); ++ if (unlikely(result)) { ++ unlock_cluster(node); ++ return result; ++ } ++ jnode_make_dirty_locked(node); ++ clust->reserved = 0; ++ } ++ unlock_cluster(node); ++ ++ if (new_nrpages < old_nrpages) { ++ /* truncate >= 1 complete pages */ ++ __put_page_cluster(new_nrpages, ++ old_nrpages - new_nrpages, ++ clust->pages, inode); ++ truncate_page_cluster_range(inode, ++ clust->pages, clust->index, ++ new_nrpages, ++ old_nrpages - new_nrpages, ++ 0); ++ } ++#if REISER4_DEBUG ++ clust->reserved_prepped -= estimate_update_cluster(inode); ++#endif ++ return 0; ++} ++ ++/* Submit modifications of a logical cluster */ ++static int checkin_logical_cluster(struct cluster_handle * clust, ++ struct inode *inode) ++{ ++ int result = 0; ++ jnode * node; ++ ++ node = clust->node; ++ ++ assert("edward-1035", node != NULL); ++ assert("edward-1029", clust != NULL); ++ assert("edward-1030", clust->reserved == 1); ++ assert("edward-1031", clust->nr_pages != 0); ++ assert("edward-1032", clust->pages != NULL); ++ assert("edward-1033", clust->pages[0] != NULL); ++ assert("edward-1446", jnode_is_cluster_page(node)); ++ assert("edward-1476", node == jprivate(clust->pages[0])); ++ ++ lock_cluster(node); ++ checkin_cluster_size(clust, inode); ++ /* ++ * this will unlock the cluster ++ */ ++ result = checkin_page_cluster(clust, inode); ++ jput(node); ++ clust->node = NULL; ++ return result; ++} ++ ++/* ++ * Retrieve size of logical cluster that was checked in at ++ * the latest modifying session (cluster lock is required) ++ */ ++static inline void checkout_cluster_size(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ struct tfm_cluster *tc = &clust->tc; ++ ++ tc->len = lbytes(clust->index, inode); ++ assert("edward-1478", tc->len != 0); ++} ++ ++/* ++ * Retrieve a page cluster with the latest submitted modifications ++ * and flush its pages to previously allocated contiguous stream. ++ */ ++static void checkout_page_cluster(struct cluster_handle * clust, ++ jnode * node, struct inode * inode) ++{ ++ int i; ++ int found; ++ int to_put; ++ pgoff_t page_index = clust_to_pg(clust->index, inode); ++ struct tfm_cluster *tc = &clust->tc; ++ ++ /* find and put checked in pages: cluster is locked, ++ * so we must get expected number (to_put) of pages ++ */ ++ to_put = size_in_pages(lbytes(clust->index, inode)); ++ found = find_get_pages(inode->i_mapping, &page_index, ++ to_put, clust->pages); ++ BUG_ON(found != to_put); ++ ++ __put_page_cluster(0, to_put, clust->pages, inode); ++ unlock_cluster_uncapture(node); ++ ++ /* Flush found pages. ++ * ++ * Note, that we don't disable modifications while flushing, ++ * moreover, some found pages can be truncated, as we have ++ * released cluster lock. ++ */ ++ for (i = 0; i < found; i++) { ++ int in_page; ++ char * data; ++ assert("edward-1479", ++ clust->pages[i]->index == clust->pages[0]->index + i); ++ ++ lock_page(clust->pages[i]); ++ if (!PageUptodate(clust->pages[i])) { ++ /* page was truncated */ ++ assert("edward-1480", ++ i_size_read(inode) <= page_offset(clust->pages[i])); ++ assert("edward-1481", ++ clust->pages[i]->mapping != inode->i_mapping); ++ unlock_page(clust->pages[i]); ++ break; ++ } ++ /* Update the number of bytes in the logical cluster, ++ * as it could be partially truncated. Note, that only ++ * partial truncate is possible (complete truncate can ++ * not go here, as it is performed via ->kill_hook() ++ * called by cut_file_items(), and the last one must ++ * wait for znode locked with parent coord). ++ */ ++ checkout_cluster_size(clust, inode); ++ ++ /* this can be zero, as new file size is ++ checked in before truncating pages */ ++ in_page = __mbp(tc->len, i); ++ ++ data = kmap_atomic(clust->pages[i]); ++ memcpy(tfm_stream_data(tc, INPUT_STREAM) + pg_to_off(i), ++ data, in_page); ++ kunmap_atomic(data); ++ /* ++ * modifications have been checked out and will be ++ * committed later. Anyway, the dirty status of the ++ * page is no longer relevant. However, the uptodate ++ * status of the page is still relevant! ++ */ ++ if (PageDirty(clust->pages[i])) ++ cancel_dirty_page(clust->pages[i]); ++ ++ unlock_page(clust->pages[i]); ++ ++ if (in_page < PAGE_SIZE) ++ /* end of the file */ ++ break; ++ } ++ put_found_pages(clust->pages, found); /* find_get_pages */ ++ tc->lsize = tc->len; ++ return; ++} ++ ++/* Check out modifications of a logical cluster */ ++int checkout_logical_cluster(struct cluster_handle * clust, ++ jnode * node, struct inode *inode) ++{ ++ int result; ++ struct tfm_cluster *tc = &clust->tc; ++ ++ assert("edward-980", node != NULL); ++ assert("edward-236", inode != NULL); ++ assert("edward-237", clust != NULL); ++ assert("edward-240", !clust->win); ++ assert("edward-241", reiser4_schedulable()); ++ assert("edward-718", cryptcompress_inode_ok(inode)); ++ ++ result = grab_tfm_stream(inode, tc, INPUT_STREAM); ++ if (result) { ++ warning("edward-1430", "alloc stream failed with ret=%d", ++ result); ++ return RETERR(-E_REPEAT); ++ } ++ lock_cluster(node); ++ ++ if (unlikely(!JF_ISSET(node, JNODE_DIRTY))) { ++ /* race with another flush */ ++ warning("edward-982", ++ "checking out logical cluster %lu of inode %llu: " ++ "jnode is not dirty", clust->index, ++ (unsigned long long)get_inode_oid(inode)); ++ unlock_cluster(node); ++ return RETERR(-E_REPEAT); ++ } ++ cluster_reserved2grabbed(estimate_update_cluster(inode), ++ get_meta_subvol()); ++ ++ /* this will unlock cluster */ ++ checkout_page_cluster(clust, node, inode); ++ return 0; ++} ++ ++/* set hint for the cluster of the index @index */ ++static void set_hint_cluster(struct inode *inode, hint_t * hint, ++ cloff_t index, znode_lock_mode mode) ++{ ++ reiser4_key key; ++ assert("edward-722", cryptcompress_inode_ok(inode)); ++ assert("edward-723", ++ inode_file_plugin(inode) == ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); ++ ++ build_body_key_cryptcompress(inode, ++ clust_to_off(index, inode), ++ &key); ++ reiser4_seal_init(&hint->seal, &hint->ext_coord.coord, &key); ++ hint->offset = get_key_offset(&key); ++ hint->mode = mode; ++} ++ ++void invalidate_hint_cluster(struct cluster_handle * clust) ++{ ++ assert("edward-1291", clust != NULL); ++ assert("edward-1292", clust->hint != NULL); ++ ++ done_lh(&clust->hint->lh); ++ hint_clr_valid(clust->hint); ++} ++ ++static void put_hint_cluster(struct cluster_handle * clust, ++ struct inode *inode, znode_lock_mode mode) ++{ ++ assert("edward-1286", clust != NULL); ++ assert("edward-1287", clust->hint != NULL); ++ ++ set_hint_cluster(inode, clust->hint, clust->index + 1, mode); ++ invalidate_hint_cluster(clust); ++} ++ ++static int balance_dirty_page_cluster(struct cluster_handle * clust, ++ struct inode *inode, loff_t off, ++ loff_t to_file, ++ int nr_dirtied) ++{ ++ int result; ++ struct cryptcompress_info * info; ++ ++ assert("edward-724", inode != NULL); ++ assert("edward-725", cryptcompress_inode_ok(inode)); ++ assert("edward-1547", nr_dirtied <= cluster_nrpages(inode)); ++ ++ /* set next window params */ ++ move_update_window(inode, clust, off, to_file); ++ ++ result = update_sd_cryptcompress(inode); ++ if (result) ++ return result; ++ assert("edward-726", clust->hint->lh.owner == NULL); ++ info = cryptcompress_inode_data(inode); ++ ++ if (nr_dirtied == 0) ++ return 0; ++ mutex_unlock(&info->checkin_mutex); ++ reiser4_throttle_write(inode); ++ mutex_lock(&info->checkin_mutex); ++ return 0; ++} ++ ++/* ++ * Check in part of a hole within a logical cluster ++ */ ++static int write_hole(struct inode *inode, struct cluster_handle * clust, ++ loff_t file_off, loff_t to_file) ++{ ++ int result = 0; ++ unsigned cl_off, cl_count = 0; ++ unsigned to_pg, pg_off; ++ struct reiser4_slide * win; ++ ++ assert("edward-190", clust != NULL); ++ assert("edward-1069", clust->win != NULL); ++ assert("edward-191", inode != NULL); ++ assert("edward-727", cryptcompress_inode_ok(inode)); ++ assert("edward-1171", clust->dstat != INVAL_DISK_CLUSTER); ++ assert("edward-1154", ++ ergo(clust->dstat != FAKE_DISK_CLUSTER, clust->reserved == 1)); ++ ++ win = clust->win; ++ ++ assert("edward-1070", win != NULL); ++ assert("edward-201", win->stat == HOLE_WINDOW); ++ assert("edward-192", cluster_ok(clust, inode)); ++ ++ if (win->off == 0 && win->count == inode_cluster_size(inode)) { ++ /* ++ * This part of the hole occupies the whole logical ++ * cluster, so it won't be represented by any items. ++ * Nothing to submit. ++ */ ++ move_update_window(inode, clust, file_off, to_file); ++ return 0; ++ } ++ /* ++ * This part of the hole starts not at logical cluster ++ * boundary, so it has to be converted to zeros and written to disk ++ */ ++ cl_count = win->count; /* number of zeroes to write */ ++ cl_off = win->off; ++ pg_off = off_to_pgoff(win->off); ++ ++ while (cl_count) { ++ struct page *page; ++ page = clust->pages[off_to_pg(cl_off)]; ++ ++ assert("edward-284", page != NULL); ++ ++ to_pg = min((typeof(pg_off))PAGE_SIZE - pg_off, cl_count); ++ lock_page(page); ++ zero_user(page, pg_off, to_pg); ++ SetPageUptodate(page); ++ set_page_dirty_notag(page); ++ mark_page_accessed(page); ++ unlock_page(page); ++ ++ cl_off += to_pg; ++ cl_count -= to_pg; ++ pg_off = 0; ++ } ++ if (win->delta == 0) { ++ /* only zeroes in this window, try to capture ++ */ ++ result = checkin_logical_cluster(clust, inode); ++ if (result) ++ return result; ++ put_hint_cluster(clust, inode, ZNODE_WRITE_LOCK); ++ result = balance_dirty_page_cluster(clust, ++ inode, file_off, to_file, ++ win_count_to_nrpages(win)); ++ } else ++ move_update_window(inode, clust, file_off, to_file); ++ return result; ++} ++ ++/* ++ The main disk search procedure for cryptcompress plugin, which ++ . scans all items of disk cluster with the lock mode @mode ++ . maybe reads each one (if @read) ++ . maybe makes its znode dirty (if write lock mode was specified) ++ ++ NOTE-EDWARD: Callers should handle the case when disk cluster ++ is incomplete (-EIO) ++*/ ++int find_disk_cluster(struct cluster_handle * clust, ++ struct inode *inode, int read, znode_lock_mode mode) ++{ ++ flow_t f; ++ hint_t *hint; ++ int result = 0; ++ int was_grabbed; ++ ra_info_t ra_info; ++ file_plugin *fplug; ++ item_plugin *iplug; ++ struct tfm_cluster *tc; ++ struct cryptcompress_info *info; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ assert("edward-138", clust != NULL); ++ assert("edward-728", clust->hint != NULL); ++ assert("edward-226", reiser4_schedulable()); ++ assert("edward-137", inode != NULL); ++ assert("edward-729", cryptcompress_inode_ok(inode)); ++ ++ hint = clust->hint; ++ fplug = inode_file_plugin(inode); ++ was_grabbed = ctx_subvol_grabbed(get_current_context(), subv->id); ++ info = cryptcompress_inode_data(inode); ++ tc = &clust->tc; ++ ++ assert("edward-462", !tfm_cluster_is_uptodate(tc)); ++ assert("edward-461", ergo(read, tfm_stream_is_set(tc, INPUT_STREAM))); ++ ++ dclust_init_extension(hint); ++ ++ /* ++ * set key of the first disk cluster item ++ */ ++ flow_by_inode_cryptcompress(inode, ++ (read ? (char __user *)tfm_stream_data(tc, INPUT_STREAM) : NULL), ++ 0 /* kernel space */ , ++ inode_scaled_cluster_size(inode), ++ clust_to_off(clust->index, inode), READ_OP, &f); ++ ++ if (mode == ZNODE_WRITE_LOCK) { ++ /* ++ * reserve for flush to make dirty all the leaf nodes ++ * which contain disk cluster ++ */ ++ result = reiser4_grab_space_force(estimate_dirty_cluster(inode), ++ BA_CAN_COMMIT, subv); ++ if (result) ++ goto out; ++ } ++ ++ ra_info.key_to_stop = f.key; ++ set_key_offset(&ra_info.key_to_stop, get_key_offset(reiser4_max_key())); ++ ++ while (f.length) { ++ result = find_cluster_item(hint, &f.key, mode, ++ NULL, FIND_EXACT, ++ (mode == ZNODE_WRITE_LOCK ? ++ CBK_FOR_INSERT : 0), subv); ++ switch (result) { ++ case CBK_COORD_NOTFOUND: ++ result = 0; ++ if (inode_scaled_offset ++ (inode, clust_to_off(clust->index, inode)) == ++ get_key_offset(&f.key)) { ++ /* first item not found, this is treated ++ as disk cluster is absent */ ++ clust->dstat = FAKE_DISK_CLUSTER; ++ goto out; ++ } ++ /* we are outside the cluster, stop search here */ ++ assert("edward-146", ++ f.length != inode_scaled_cluster_size(inode)); ++ goto ok; ++ case CBK_COORD_FOUND: ++ assert("edward-148", ++ hint->ext_coord.coord.between == AT_UNIT); ++ assert("edward-460", ++ hint->ext_coord.coord.unit_pos == 0); ++ ++ coord_clear_iplug(&hint->ext_coord.coord); ++ result = zload_ra(hint->ext_coord.coord.node, &ra_info); ++ if (unlikely(result)) ++ goto out; ++ iplug = item_plugin_by_coord(&hint->ext_coord.coord); ++ assert("edward-147", ++ item_id_by_coord(&hint->ext_coord.coord) == ++ CTAIL_ID); ++ ++ result = read_ctail(NULL, &f, hint); ++ if (result) { ++ zrelse(hint->ext_coord.coord.node); ++ goto out; ++ } ++ if (mode == ZNODE_WRITE_LOCK) { ++ /* Don't make dirty more nodes then it was ++ estimated (see comments before ++ estimate_dirty_cluster). Missed nodes will be ++ read up in flush time if they are evicted from ++ memory */ ++ if (dclust_get_extension_ncount(hint) <= ++ estimate_dirty_cluster(inode)) ++ znode_make_dirty(hint->ext_coord.coord.node); ++ ++ znode_set_convertible(hint->ext_coord.coord. ++ node); ++ } ++ zrelse(hint->ext_coord.coord.node); ++ break; ++ default: ++ goto out; ++ } ++ } ++ ok: ++ /* at least one item was found */ ++ /* NOTE-EDWARD: Callers should handle the case ++ when disk cluster is incomplete (-EIO) */ ++ tc->len = inode_scaled_cluster_size(inode) - f.length; ++ tc->lsize = lbytes(clust->index, inode); ++ assert("edward-1196", tc->len > 0); ++ assert("edward-1406", tc->lsize > 0); ++ ++ if (hint_is_unprepped_dclust(clust->hint)) { ++ clust->dstat = UNPR_DISK_CLUSTER; ++ } else if (clust->index == info->trunc_index) { ++ clust->dstat = TRNC_DISK_CLUSTER; ++ } else { ++ clust->dstat = PREP_DISK_CLUSTER; ++ dclust_set_extension_dsize(clust->hint, tc->len); ++ } ++ out: ++ grabbed2free_mark(was_grabbed, subv); ++ ++ return result; ++} ++ ++int get_disk_cluster_locked(struct cluster_handle * clust, struct inode *inode, ++ znode_lock_mode lock_mode) ++{ ++ reiser4_key key; ++ ra_info_t ra_info; ++ ++ assert("edward-730", reiser4_schedulable()); ++ assert("edward-731", clust != NULL); ++ assert("edward-732", inode != NULL); ++ ++ if (hint_is_valid(clust->hint)) { ++ assert("edward-1293", clust->dstat != INVAL_DISK_CLUSTER); ++ assert("edward-1294", ++ znode_is_write_locked(clust->hint->lh.node)); ++ /* already have a valid locked position */ ++ return (clust->dstat == ++ FAKE_DISK_CLUSTER ? CBK_COORD_NOTFOUND : ++ CBK_COORD_FOUND); ++ } ++ build_body_key_cryptcompress(inode, clust_to_off(clust->index, inode), ++ &key); ++ ra_info.key_to_stop = key; ++ set_key_offset(&ra_info.key_to_stop, get_key_offset(reiser4_max_key())); ++ ++ return find_cluster_item(clust->hint, &key, lock_mode, NULL, FIND_EXACT, ++ CBK_FOR_INSERT, get_meta_subvol()); ++} ++ ++/* Read needed cluster pages before modifying. ++ If success, @clust->hint contains locked position in the tree. ++ Also: ++ . find and set disk cluster state ++ . make disk cluster dirty if its state is not FAKE_DISK_CLUSTER. ++*/ ++static int read_some_cluster_pages(struct inode * inode, ++ struct cluster_handle * clust) ++{ ++ int i; ++ int result = 0; ++ item_plugin *iplug; ++ struct reiser4_slide * win = clust->win; ++ znode_lock_mode mode = ZNODE_WRITE_LOCK; ++ ++ iplug = item_plugin_by_id(CTAIL_ID); ++ ++ assert("edward-924", !tfm_cluster_is_uptodate(&clust->tc)); ++ ++#if REISER4_DEBUG ++ if (clust->nr_pages == 0) { ++ /* start write hole from fake disk cluster */ ++ assert("edward-1117", win != NULL); ++ assert("edward-1118", win->stat == HOLE_WINDOW); ++ assert("edward-1119", new_logical_cluster(clust, inode)); ++ } ++#endif ++ if (new_logical_cluster(clust, inode)) { ++ /* ++ new page cluster is about to be written, nothing to read, ++ */ ++ assert("edward-734", reiser4_schedulable()); ++ assert("edward-735", clust->hint->lh.owner == NULL); ++ ++ if (clust->nr_pages) { ++ int off; ++ struct page * pg; ++ assert("edward-1419", clust->pages != NULL); ++ pg = clust->pages[clust->nr_pages - 1]; ++ assert("edward-1420", pg != NULL); ++ off = off_to_pgoff(win->off+win->count+win->delta); ++ if (off) { ++ lock_page(pg); ++ zero_user_segment(pg, off, PAGE_SIZE); ++ unlock_page(pg); ++ } ++ } ++ clust->dstat = FAKE_DISK_CLUSTER; ++ return 0; ++ } ++ /* ++ Here we should search for disk cluster to figure out its real state. ++ Also there is one more important reason to do disk search: we need ++ to make disk cluster _dirty_ if it exists ++ */ ++ ++ /* if windows is specified, read the only pages ++ that will be modified partially */ ++ ++ for (i = 0; i < clust->nr_pages; i++) { ++ struct page *pg = clust->pages[i]; ++ ++ lock_page(pg); ++ if (PageUptodate(pg)) { ++ unlock_page(pg); ++ continue; ++ } ++ unlock_page(pg); ++ ++ if (win && ++ i >= size_in_pages(win->off) && ++ i < off_to_pg(win->off + win->count + win->delta)) ++ /* page will be completely overwritten */ ++ continue; ++ ++ if (win && (i == clust->nr_pages - 1) && ++ /* the last page is ++ partially modified, ++ not uptodate .. */ ++ (size_in_pages(i_size_read(inode)) <= pg->index)) { ++ /* .. and appended, ++ so set zeroes to the rest */ ++ int offset; ++ lock_page(pg); ++ assert("edward-1260", ++ size_in_pages(win->off + win->count + ++ win->delta) - 1 == i); ++ ++ offset = ++ off_to_pgoff(win->off + win->count + win->delta); ++ zero_user_segment(pg, offset, PAGE_SIZE); ++ unlock_page(pg); ++ /* still not uptodate */ ++ break; ++ } ++ lock_page(pg); ++ result = do_readpage_ctail(inode, clust, pg, mode); ++ ++ assert("edward-1526", ergo(!result, PageUptodate(pg))); ++ unlock_page(pg); ++ if (result) { ++ warning("edward-219", "do_readpage_ctail failed"); ++ goto out; ++ } ++ } ++ if (!tfm_cluster_is_uptodate(&clust->tc)) { ++ /* disk cluster unclaimed, but we need to make its znodes dirty ++ * to make flush update convert its content ++ */ ++ result = find_disk_cluster(clust, inode, ++ 0 /* do not read items */, ++ mode); ++ } ++ out: ++ tfm_cluster_clr_uptodate(&clust->tc); ++ return result; ++} ++ ++static int should_create_unprepped_cluster(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ assert("edward-737", clust != NULL); ++ ++ switch (clust->dstat) { ++ case PREP_DISK_CLUSTER: ++ case UNPR_DISK_CLUSTER: ++ return 0; ++ case FAKE_DISK_CLUSTER: ++ if (clust->win && ++ clust->win->stat == HOLE_WINDOW && clust->nr_pages == 0) { ++ assert("edward-1172", ++ new_logical_cluster(clust, inode)); ++ return 0; ++ } ++ return 1; ++ default: ++ impossible("edward-1173", "bad disk cluster state"); ++ return 0; ++ } ++} ++ ++static int cryptcompress_make_unprepped_cluster(struct cluster_handle * clust, ++ struct inode *inode) ++{ ++ int result; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ assert("edward-1123", reiser4_schedulable()); ++ assert("edward-737", clust != NULL); ++ assert("edward-738", inode != NULL); ++ assert("edward-739", cryptcompress_inode_ok(inode)); ++ assert("edward-1053", clust->hint != NULL); ++ ++ if (!should_create_unprepped_cluster(clust, inode)) { ++ if (clust->reserved) { ++ cluster_reserved2free(estimate_insert_cluster(inode), ++ subv); ++#if REISER4_DEBUG ++ assert("edward-1267", ++ clust->reserved_unprepped == ++ estimate_insert_cluster(inode)); ++ clust->reserved_unprepped -= ++ estimate_insert_cluster(inode); ++#endif ++ } ++ return 0; ++ } ++ assert("edward-1268", clust->reserved); ++ cluster_reserved2grabbed(estimate_insert_cluster(inode), subv); ++#if REISER4_DEBUG ++ assert("edward-1441", ++ clust->reserved_unprepped == estimate_insert_cluster(inode)); ++ clust->reserved_unprepped -= estimate_insert_cluster(inode); ++#endif ++ result = ctail_insert_unprepped_cluster(clust, inode); ++ if (result) ++ return result; ++ ++ inode_add_bytes(inode, inode_cluster_size(inode)); ++ ++ assert("edward-743", cryptcompress_inode_ok(inode)); ++ assert("edward-744", znode_is_write_locked(clust->hint->lh.node)); ++ ++ clust->dstat = UNPR_DISK_CLUSTER; ++ return 0; ++} ++ ++/* . Grab page cluster for read, write, setattr, etc. operations; ++ * . Truncate its complete pages, if needed; ++ */ ++int prepare_page_cluster(struct inode * inode, struct cluster_handle * clust, ++ rw_op rw) ++{ ++ assert("edward-177", inode != NULL); ++ assert("edward-741", cryptcompress_inode_ok(inode)); ++ assert("edward-740", clust->pages != NULL); ++ ++ set_cluster_nrpages(clust, inode); ++ reset_cluster_pgset(clust, cluster_nrpages(inode)); ++ return grab_page_cluster(inode, clust, rw); ++} ++ ++/* Truncate complete page cluster of index @index. ++ * This is called by ->kill_hook() method of item ++ * plugin when deleting a disk cluster of such index. ++ */ ++void truncate_complete_page_cluster(struct inode *inode, cloff_t index, ++ int even_cows) ++{ ++ int found; ++ int nr_pages; ++ jnode *node; ++ pgoff_t page_index = clust_to_pg(index, inode); ++ struct page *pages[MAX_CLUSTER_NRPAGES]; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ node = jlookup(get_inode_oid(inode), clust_to_pg(index, inode)); ++ nr_pages = size_in_pages(lbytes(index, inode)); ++ assert("edward-1483", nr_pages != 0); ++ if (!node) ++ goto truncate; ++ found = find_get_pages(inode->i_mapping, &page_index, ++ cluster_nrpages(inode), pages); ++ if (!found) { ++ assert("edward-1484", jnode_truncate_ok(inode, index)); ++ return; ++ } ++ lock_cluster(node); ++ ++ if (reiser4_inode_get_flag(inode, REISER4_FILE_IN_CONVERSION) ++ && index == 0) ++ /* converting to unix_file is in progress */ ++ JF_CLR(node, JNODE_CLUSTER_PAGE); ++ if (JF_ISSET(node, JNODE_DIRTY)) { ++ /* ++ * @nr_pages were checked in, but not yet checked out - ++ * we need to release them. (also there can be pages ++ * attached to page cache by read(), etc. - don't take ++ * them into account). ++ */ ++ assert("edward-1198", found >= nr_pages); ++ ++ /* free disk space grabbed for disk cluster converting */ ++ cluster_reserved2grabbed(estimate_update_cluster(inode), subv); ++ grabbed2free(get_current_context(), ++ get_current_super_private(), ++ estimate_update_cluster(inode), subv); ++ __put_page_cluster(0, nr_pages, pages, inode); ++ ++ /* This will clear dirty bit, uncapture and unlock jnode */ ++ unlock_cluster_uncapture(node); ++ } else ++ unlock_cluster(node); ++ jput(node); /* jlookup */ ++ put_found_pages(pages, found); /* find_get_pages */ ++ truncate: ++ if (reiser4_inode_get_flag(inode, REISER4_FILE_IN_CONVERSION) && ++ index == 0) ++ return; ++ truncate_page_cluster_range(inode, pages, index, 0, ++ cluster_nrpages(inode), ++ even_cows); ++ assert("edward-1201", ++ ergo(!reiser4_inode_get_flag(inode, ++ REISER4_FILE_IN_CONVERSION), ++ jnode_truncate_ok(inode, index))); ++ return; ++} ++ ++/* ++ * Set cluster handle @clust of a logical cluster before ++ * modifications which are supposed to be committed. ++ * ++ * . grab cluster pages; ++ * . reserve disk space; ++ * . maybe read pages from disk and set the disk cluster dirty; ++ * . maybe write hole and check in (partially zeroed) logical cluster; ++ * . create 'unprepped' disk cluster for new or fake logical one. ++ */ ++static int prepare_logical_cluster(struct inode *inode, ++ loff_t file_off, /* write position ++ in the file */ ++ loff_t to_file, /* bytes of users data ++ to write to the file */ ++ struct cluster_handle * clust, ++ logical_cluster_op op) ++{ ++ int result = 0; ++ struct reiser4_slide * win = clust->win; ++ ++ reset_cluster_params(clust); ++ cluster_set_tfm_act(&clust->tc, TFMA_READ); ++#if REISER4_DEBUG ++ clust->ctx = get_current_context(); ++#endif ++ assert("edward-1190", op != LC_INVAL); ++ ++ clust->op = op; ++ ++ result = prepare_page_cluster(inode, clust, WRITE_OP); ++ if (result) ++ return result; ++ assert("edward-1447", ++ ergo(clust->nr_pages != 0, jprivate(clust->pages[0]))); ++ assert("edward-1448", ++ ergo(clust->nr_pages != 0, ++ jnode_is_cluster_page(jprivate(clust->pages[0])))); ++ ++ result = reserve4cluster(inode, clust); ++ if (result) ++ goto out; ++ ++ result = read_some_cluster_pages(inode, clust); ++ ++ if (result || ++ /* ++ * don't submit data modifications ++ * when expanding or shrinking holes ++ */ ++ (op == LC_SHRINK && clust->dstat == FAKE_DISK_CLUSTER) || ++ (op == LC_EXPAND && clust->dstat == FAKE_DISK_CLUSTER)){ ++ free_reserved4cluster(inode, ++ clust, ++ estimate_update_cluster(inode) + ++ estimate_insert_cluster(inode)); ++ goto out; ++ } ++ assert("edward-1124", clust->dstat != INVAL_DISK_CLUSTER); ++ ++ result = cryptcompress_make_unprepped_cluster(clust, inode); ++ if (result) ++ goto error; ++ if (win && win->stat == HOLE_WINDOW) { ++ result = write_hole(inode, clust, file_off, to_file); ++ if (result) ++ goto error; ++ } ++ return 0; ++ error: ++ free_reserved4cluster(inode, clust, ++ estimate_update_cluster(inode)); ++ out: ++ put_page_cluster(clust, inode, WRITE_OP); ++ return result; ++} ++ ++/* set window by two offsets */ ++static void set_window(struct cluster_handle * clust, ++ struct reiser4_slide * win, struct inode *inode, ++ loff_t o1, loff_t o2) ++{ ++ assert("edward-295", clust != NULL); ++ assert("edward-296", inode != NULL); ++ assert("edward-1071", win != NULL); ++ assert("edward-297", o1 <= o2); ++ ++ clust->index = off_to_clust(o1, inode); ++ ++ win->off = off_to_cloff(o1, inode); ++ win->count = min((loff_t)(inode_cluster_size(inode) - win->off), ++ o2 - o1); ++ win->delta = 0; ++ ++ clust->win = win; ++} ++ ++static int set_window_and_cluster(struct inode *inode, ++ struct cluster_handle * clust, ++ struct reiser4_slide * win, size_t length, ++ loff_t file_off) ++{ ++ int result; ++ ++ assert("edward-197", clust != NULL); ++ assert("edward-1072", win != NULL); ++ assert("edward-198", inode != NULL); ++ ++ result = alloc_cluster_pgset(clust, cluster_nrpages(inode)); ++ if (result) ++ return result; ++ ++ if (file_off > i_size_read(inode)) { ++ /* Uhmm, hole in cryptcompress file... */ ++ loff_t hole_size; ++ hole_size = file_off - inode->i_size; ++ ++ set_window(clust, win, inode, inode->i_size, file_off); ++ win->stat = HOLE_WINDOW; ++ if (win->off + hole_size < inode_cluster_size(inode)) ++ /* there is also user's data to append to the hole */ ++ win->delta = min(inode_cluster_size(inode) - ++ (win->off + win->count), length); ++ return 0; ++ } ++ set_window(clust, win, inode, file_off, file_off + length); ++ win->stat = DATA_WINDOW; ++ return 0; ++} ++ ++int set_cluster_by_page(struct cluster_handle * clust, struct page * page, ++ int count) ++{ ++ int result = 0; ++ int (*setting_actor)(struct cluster_handle * clust, int count); ++ ++ assert("edward-1358", clust != NULL); ++ assert("edward-1359", page != NULL); ++ assert("edward-1360", page->mapping != NULL); ++ assert("edward-1361", page->mapping->host != NULL); ++ ++ setting_actor = ++ (clust->pages ? reset_cluster_pgset : alloc_cluster_pgset); ++ result = setting_actor(clust, count); ++ clust->index = pg_to_clust(page->index, page->mapping->host); ++ return result; ++} ++ ++/* reset all the params that not get updated */ ++void reset_cluster_params(struct cluster_handle * clust) ++{ ++ assert("edward-197", clust != NULL); ++ ++ clust->dstat = INVAL_DISK_CLUSTER; ++ clust->tc.uptodate = 0; ++ clust->tc.len = 0; ++} ++ ++/* the heart of write_cryptcompress */ ++static loff_t do_write_cryptcompress(struct file *file, struct inode *inode, ++ const char __user *buf, size_t to_write, ++ loff_t pos, struct dispatch_context *cont) ++{ ++ int i; ++ hint_t *hint; ++ int result = 0; ++ size_t count; ++ struct reiser4_slide win; ++ struct cluster_handle clust; ++ struct cryptcompress_info * info; ++ ++ assert("edward-154", buf != NULL); ++ assert("edward-161", reiser4_schedulable()); ++ assert("edward-748", cryptcompress_inode_ok(inode)); ++ assert("edward-159", current_blocksize == PAGE_SIZE); ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) ++ return RETERR(-ENOMEM); ++ ++ result = load_file_hint(file, hint); ++ if (result) { ++ kfree(hint); ++ return result; ++ } ++ count = to_write; ++ ++ reiser4_slide_init(&win); ++ cluster_init_read(&clust, &win); ++ clust.hint = hint; ++ info = cryptcompress_inode_data(inode); ++ ++ mutex_lock(&info->checkin_mutex); ++ ++ result = set_window_and_cluster(inode, &clust, &win, to_write, pos); ++ if (result) ++ goto out; ++ ++ if (next_window_stat(&win) == HOLE_WINDOW) { ++ /* write hole in this iteration ++ separated from the loop below */ ++ result = write_dispatch_hook(file, inode, ++ pos, &clust, cont); ++ if (result) ++ goto out; ++ result = prepare_logical_cluster(inode, pos, count, &clust, ++ LC_APPOV); ++ if (result) ++ goto out; ++ } ++ do { ++ const char __user * src; ++ unsigned page_off, to_page; ++ ++ assert("edward-750", reiser4_schedulable()); ++ ++ result = write_dispatch_hook(file, inode, ++ pos + to_write - count, ++ &clust, cont); ++ if (result) ++ goto out; ++ if (cont->state == DISPATCH_ASSIGNED_NEW) ++ /* done_lh was called in write_dispatch_hook */ ++ goto out_no_longterm_lock; ++ ++ result = prepare_logical_cluster(inode, pos, count, &clust, ++ LC_APPOV); ++ if (result) ++ goto out; ++ ++ assert("edward-751", cryptcompress_inode_ok(inode)); ++ assert("edward-204", win.stat == DATA_WINDOW); ++ assert("edward-1288", hint_is_valid(clust.hint)); ++ assert("edward-752", ++ znode_is_write_locked(hint->ext_coord.coord.node)); ++ put_hint_cluster(&clust, inode, ZNODE_WRITE_LOCK); ++ ++ /* set write position in page */ ++ page_off = off_to_pgoff(win.off); ++ ++ /* copy user's data to cluster pages */ ++ for (i = off_to_pg(win.off), src = buf; ++ i < size_in_pages(win.off + win.count); ++ i++, src += to_page) { ++ to_page = __mbp(win.off + win.count, i) - page_off; ++ assert("edward-1039", ++ page_off + to_page <= PAGE_SIZE); ++ assert("edward-287", clust.pages[i] != NULL); ++ ++ fault_in_pages_readable(src, to_page); ++ ++ lock_page(clust.pages[i]); ++ result = ++ __copy_from_user((char *)kmap(clust.pages[i]) + ++ page_off, src, to_page); ++ kunmap(clust.pages[i]); ++ if (unlikely(result)) { ++ unlock_page(clust.pages[i]); ++ result = -EFAULT; ++ goto err2; ++ } ++ SetPageUptodate(clust.pages[i]); ++ set_page_dirty_notag(clust.pages[i]); ++ flush_dcache_page(clust.pages[i]); ++ mark_page_accessed(clust.pages[i]); ++ unlock_page(clust.pages[i]); ++ page_off = 0; ++ } ++ assert("edward-753", cryptcompress_inode_ok(inode)); ++ ++ result = checkin_logical_cluster(&clust, inode); ++ if (result) ++ goto err2; ++ ++ buf += win.count; ++ count -= win.count; ++ ++ result = balance_dirty_page_cluster(&clust, inode, 0, count, ++ win_count_to_nrpages(&win)); ++ if (result) ++ goto err1; ++ assert("edward-755", hint->lh.owner == NULL); ++ reset_cluster_params(&clust); ++ continue; ++ err2: ++ put_page_cluster(&clust, inode, WRITE_OP); ++ err1: ++ if (clust.reserved) ++ free_reserved4cluster(inode, ++ &clust, ++ estimate_update_cluster(inode)); ++ break; ++ } while (count); ++ out: ++ done_lh(&hint->lh); ++ save_file_hint(file, hint); ++ out_no_longterm_lock: ++ mutex_unlock(&info->checkin_mutex); ++ kfree(hint); ++ put_cluster_handle(&clust); ++ assert("edward-195", ++ ergo((to_write == count), ++ (result < 0 || cont->state == DISPATCH_ASSIGNED_NEW))); ++ return (to_write - count) ? (to_write - count) : result; ++} ++ ++/** ++ * plugin->write() ++ * @file: file to write to ++ * @buf: address of user-space buffer ++ * @read_amount: number of bytes to write ++ * @off: position in file to write to ++ */ ++ssize_t write_cryptcompress(struct file *file, const char __user *buf, ++ size_t count, loff_t *off, ++ struct dispatch_context *cont) ++{ ++ ssize_t result; ++ struct inode *inode; ++ reiser4_context *ctx; ++ loff_t pos = *off; ++ struct cryptcompress_info *info; ++ ++ assert("edward-1449", cont->state == DISPATCH_INVAL_STATE); ++ ++ inode = file_inode(file); ++ assert("edward-196", cryptcompress_inode_ok(inode)); ++ ++ info = cryptcompress_inode_data(inode); ++ ctx = get_current_context(); ++ ++ result = file_remove_privs(file); ++ if (unlikely(result != 0)) { ++ context_set_commit_async(ctx); ++ return result; ++ } ++ /* remove_suid might create a transaction */ ++ reiser4_txn_restart(ctx); ++ ++ result = do_write_cryptcompress(file, inode, buf, count, pos, cont); ++ ++ if (unlikely(result < 0)) { ++ context_set_commit_async(ctx); ++ return result; ++ } ++ /* update position in a file */ ++ *off = pos + result; ++ return result; ++} ++ ++/* plugin->readpages */ ++int readpages_cryptcompress(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages) ++{ ++ reiser4_context * ctx; ++ int ret; ++ ++ ctx = reiser4_init_context(mapping->host->i_sb); ++ if (IS_ERR(ctx)) { ++ ret = PTR_ERR(ctx); ++ goto err; ++ } ++ /* cryptcompress file can be built of ctail items only */ ++ ret = readpages_ctail(file, mapping, pages); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ if (ret) { ++err: ++ put_pages_list(pages); ++ } ++ return ret; ++} ++ ++static reiser4_block_nr cryptcompress_estimate_read(struct inode *inode) ++{ ++ /* reserve one block to update stat data item */ ++ assert("edward-1193", ++ inode_file_plugin(inode)->estimate.update == ++ estimate_update_common); ++ return estimate_update_common(inode); ++} ++ ++/** ++ * plugin->read ++ * @file: file to read from ++ * @buf: address of user-space buffer ++ * @read_amount: number of bytes to read ++ * @off: position in file to read from ++ */ ++ssize_t read_cryptcompress(struct file * file, char __user *buf, size_t size, ++ loff_t * off) ++{ ++ ssize_t result; ++ struct inode *inode; ++ reiser4_context *ctx; ++ struct cryptcompress_info *info; ++ reiser4_block_nr needed; ++ ++ inode = file_inode(file); ++ assert("edward-1194", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ info = cryptcompress_inode_data(inode); ++ needed = cryptcompress_estimate_read(inode); ++ ++ result = reiser4_grab_space(needed, BA_CAN_COMMIT, get_meta_subvol()); ++ if (result != 0) { ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ result = new_sync_read(file, buf, size, off); ++ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ ++ return result; ++} ++ ++/* Set left coord when unit is not found after node_lookup() ++ This takes into account that there can be holes in a sequence ++ of disk clusters */ ++ ++static void adjust_left_coord(coord_t * left_coord) ++{ ++ switch (left_coord->between) { ++ case AFTER_UNIT: ++ left_coord->between = AFTER_ITEM; ++ case AFTER_ITEM: ++ case BEFORE_UNIT: ++ break; ++ default: ++ impossible("edward-1204", "bad left coord to cut"); ++ } ++ return; ++} ++ ++#define CRC_CUT_TREE_MIN_ITERATIONS 64 ++ ++/* plugin->cut_tree_worker */ ++int cut_tree_worker_cryptcompress(tap_t * tap, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed, ++ struct inode *object, int truncate, ++ int *progress) ++{ ++ lock_handle next_node_lock; ++ coord_t left_coord; ++ int result; ++ ++ assert("edward-1158", tap->coord->node != NULL); ++ assert("edward-1159", znode_is_write_locked(tap->coord->node)); ++ assert("edward-1160", znode_get_level(tap->coord->node) == LEAF_LEVEL); ++ ++ *progress = 0; ++ init_lh(&next_node_lock); ++ ++ while (1) { ++ znode *node; /* node from which items are cut */ ++ node_plugin *nplug; /* node plugin for @node */ ++ ++ node = tap->coord->node; ++ ++ /* Move next_node_lock to the next node on the left. */ ++ result = ++ reiser4_get_left_neighbor(&next_node_lock, node, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result != 0 && result != -E_NO_NEIGHBOR) ++ break; ++ /* FIXME-EDWARD: Check can we delete the node as a whole. */ ++ result = reiser4_tap_load(tap); ++ if (result) ++ return result; ++ ++ /* Prepare the second (right) point for cut_node() */ ++ if (*progress) ++ coord_init_last_unit(tap->coord, node); ++ ++ else if (item_plugin_by_coord(tap->coord)->b.lookup == NULL) ++ /* set rightmost unit for the items without lookup method */ ++ tap->coord->unit_pos = coord_last_unit_pos(tap->coord); ++ ++ nplug = node->nplug; ++ ++ assert("edward-1161", nplug); ++ assert("edward-1162", nplug->lookup); ++ ++ /* left_coord is leftmost unit cut from @node */ ++ result = nplug->lookup(node, from_key, FIND_EXACT, &left_coord); ++ ++ if (IS_CBKERR(result)) ++ break; ++ ++ if (result == CBK_COORD_NOTFOUND) ++ adjust_left_coord(&left_coord); ++ ++ /* adjust coordinates so that they are set to existing units */ ++ if (coord_set_to_right(&left_coord) ++ || coord_set_to_left(tap->coord)) { ++ result = 0; ++ break; ++ } ++ ++ if (coord_compare(&left_coord, tap->coord) == ++ COORD_CMP_ON_RIGHT) { ++ /* keys from @from_key to @to_key are not in the tree */ ++ result = 0; ++ break; ++ } ++ ++ /* cut data from one node */ ++ *smallest_removed = *reiser4_min_key(); ++ result = kill_node_content(&left_coord, ++ tap->coord, ++ from_key, ++ to_key, ++ smallest_removed, ++ next_node_lock.node, ++ object, truncate); ++ reiser4_tap_relse(tap); ++ ++ if (result) ++ break; ++ ++ ++(*progress); ++ ++ /* Check whether all items with keys >= from_key were removed ++ * from the tree. */ ++ if (keyle(smallest_removed, from_key)) ++ /* result = 0; */ ++ break; ++ ++ if (next_node_lock.node == NULL) ++ break; ++ ++ result = reiser4_tap_move(tap, &next_node_lock); ++ done_lh(&next_node_lock); ++ if (result) ++ break; ++ ++ /* Break long cut_tree operation (deletion of a large file) if ++ * atom requires commit. */ ++ if (*progress > CRC_CUT_TREE_MIN_ITERATIONS ++ && current_atom_should_commit()) { ++ result = -E_REPEAT; ++ break; ++ } ++ } ++ done_lh(&next_node_lock); ++ return result; ++} ++ ++static int expand_cryptcompress(struct inode *inode /* old size */, ++ loff_t new_size) ++{ ++ int result = 0; ++ hint_t *hint; ++ lock_handle *lh; ++ loff_t hole_size; ++ int nr_zeroes; ++ struct reiser4_slide win; ++ struct cluster_handle clust; ++ ++ assert("edward-1133", inode->i_size < new_size); ++ assert("edward-1134", reiser4_schedulable()); ++ assert("edward-1135", cryptcompress_inode_ok(inode)); ++ assert("edward-1136", current_blocksize == PAGE_SIZE); ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) ++ return RETERR(-ENOMEM); ++ hint_init_zero(hint); ++ lh = &hint->lh; ++ ++ reiser4_slide_init(&win); ++ cluster_init_read(&clust, &win); ++ clust.hint = hint; ++ ++ if (off_to_cloff(inode->i_size, inode) == 0) ++ goto append_hole; ++ /* ++ * It can happen that ++ * a part of the hole will be converted ++ * to zeros. If so, it should be submitted ++ */ ++ result = alloc_cluster_pgset(&clust, cluster_nrpages(inode)); ++ if (result) ++ goto out; ++ hole_size = new_size - inode->i_size; ++ nr_zeroes = inode_cluster_size(inode) - ++ off_to_cloff(inode->i_size, inode); ++ if (nr_zeroes > hole_size) ++ nr_zeroes = hole_size; ++ ++ set_window(&clust, &win, inode, inode->i_size, ++ inode->i_size + nr_zeroes); ++ win.stat = HOLE_WINDOW; ++ ++ assert("edward-1137", ++ clust.index == off_to_clust(inode->i_size, inode)); ++ ++ result = prepare_logical_cluster(inode, 0, 0, &clust, LC_EXPAND); ++ if (result) ++ goto out; ++ assert("edward-1139", ++ clust.dstat == PREP_DISK_CLUSTER || ++ clust.dstat == UNPR_DISK_CLUSTER || ++ clust.dstat == FAKE_DISK_CLUSTER); ++ ++ assert("edward-1431", hole_size >= nr_zeroes); ++ ++ append_hole: ++ INODE_SET_SIZE(inode, new_size); ++ out: ++ done_lh(lh); ++ kfree(hint); ++ put_cluster_handle(&clust); ++ return result; ++} ++ ++static int update_size_actor(struct inode *inode, ++ loff_t new_size, int update_sd) ++{ ++ if (new_size & ((loff_t) (inode_cluster_size(inode)) - 1)) ++ /* ++ * cut not at logical cluster boundary, ++ * size will be updated by write_hole() ++ */ ++ return 0; ++ else ++ return reiser4_update_file_size(inode, new_size, update_sd); ++} ++ ++static int prune_cryptcompress(struct inode *inode, ++ loff_t new_size, int update_sd) ++{ ++ int result = 0; ++ unsigned nr_zeros; ++ loff_t to_prune; ++ loff_t old_size; ++ cloff_t from_idx; ++ cloff_t to_idx; ++ ++ hint_t *hint; ++ lock_handle *lh; ++ struct reiser4_slide win; ++ struct cluster_handle clust; ++ ++ assert("edward-1140", inode->i_size >= new_size); ++ assert("edward-1141", reiser4_schedulable()); ++ assert("edward-1142", cryptcompress_inode_ok(inode)); ++ assert("edward-1143", current_blocksize == PAGE_SIZE); ++ ++ old_size = inode->i_size; ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) ++ return RETERR(-ENOMEM); ++ hint_init_zero(hint); ++ lh = &hint->lh; ++ ++ reiser4_slide_init(&win); ++ cluster_init_read(&clust, &win); ++ clust.hint = hint; ++ ++ /* ++ * index of the leftmost logical cluster ++ * that will be completely truncated ++ */ ++ from_idx = size_in_lc(new_size, inode); ++ to_idx = size_in_lc(inode->i_size, inode); ++ /* ++ * truncate all complete disk clusters starting from @from_idx ++ */ ++ assert("edward-1174", from_idx <= to_idx); ++ ++ old_size = inode->i_size; ++ if (from_idx != to_idx) { ++ struct cryptcompress_info *info; ++ info = cryptcompress_inode_data(inode); ++ ++ result = cut_file_items(inode, ++ clust_to_off(from_idx, inode), ++ update_sd, ++ clust_to_off(to_idx, inode), ++ update_size_actor); ++ info->trunc_index = ULONG_MAX; ++ if (unlikely(result == CBK_COORD_NOTFOUND)) ++ result = 0; ++ if (unlikely(result)) ++ goto out; ++ } ++ if (off_to_cloff(new_size, inode) == 0) ++ goto truncate_hole; ++ ++ assert("edward-1146", new_size < inode->i_size); ++ ++ to_prune = inode->i_size - new_size; ++ /* ++ * Partial truncate of the last logical cluster. ++ * Partial hole will be converted to zeros. The resulted ++ * logical cluster will be captured and submitted to disk ++ */ ++ result = alloc_cluster_pgset(&clust, cluster_nrpages(inode)); ++ if (result) ++ goto out; ++ ++ nr_zeros = off_to_pgoff(new_size); ++ if (nr_zeros) ++ nr_zeros = PAGE_SIZE - nr_zeros; ++ ++ set_window(&clust, &win, inode, new_size, new_size + nr_zeros); ++ win.stat = HOLE_WINDOW; ++ ++ assert("edward-1149", clust.index == from_idx - 1); ++ ++ result = prepare_logical_cluster(inode, 0, 0, &clust, LC_SHRINK); ++ if (result) ++ goto out; ++ assert("edward-1151", ++ clust.dstat == PREP_DISK_CLUSTER || ++ clust.dstat == UNPR_DISK_CLUSTER || ++ clust.dstat == FAKE_DISK_CLUSTER); ++ truncate_hole: ++ /* ++ * drop all the pages that don't have jnodes (i.e. pages ++ * which can not be truncated by cut_file_items() because ++ * of holes represented by fake disk clusters) including ++ * the pages of partially truncated cluster which was ++ * released by prepare_logical_cluster() ++ */ ++ INODE_SET_SIZE(inode, new_size); ++ truncate_inode_pages(inode->i_mapping, new_size); ++ out: ++ assert("edward-1497", ++ pages_truncate_ok(inode, size_in_pages(new_size))); ++ ++ done_lh(lh); ++ kfree(hint); ++ put_cluster_handle(&clust); ++ return result; ++} ++ ++/** ++ * Capture a pager cluster. ++ * @clust must be set up by a caller. ++ */ ++static int capture_page_cluster(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ int result; ++ ++ assert("edward-1073", clust != NULL); ++ assert("edward-1074", inode != NULL); ++ assert("edward-1075", clust->dstat == INVAL_DISK_CLUSTER); ++ ++ result = prepare_logical_cluster(inode, 0, 0, clust, LC_APPOV); ++ if (result) ++ return result; ++ ++ set_cluster_pages_dirty(clust, inode); ++ result = checkin_logical_cluster(clust, inode); ++ put_hint_cluster(clust, inode, ZNODE_WRITE_LOCK); ++ if (unlikely(result)) ++ put_page_cluster(clust, inode, WRITE_OP); ++ return result; ++} ++ ++/* Starting from @index find tagged pages of the same page cluster. ++ * Clear the tag for each of them. Return number of found pages. ++ */ ++static int find_anon_page_cluster(struct address_space * mapping, ++ pgoff_t * index, struct page ** pages) ++{ ++ int i = 0; ++ int found; ++ xa_lock_irq(&mapping->i_pages); ++ do { ++ /* looking for one page */ ++ found = radix_tree_gang_lookup_tag(&mapping->i_pages, ++ (void **)&pages[i], ++ *index, 1, ++ PAGECACHE_TAG_REISER4_MOVED); ++ if (!found) ++ break; ++ if (!same_page_cluster(pages[0], pages[i])) ++ break; ++ ++ /* found */ ++ get_page(pages[i]); ++ *index = pages[i]->index + 1; ++ ++ radix_tree_tag_clear(&mapping->i_pages, ++ pages[i]->index, ++ PAGECACHE_TAG_REISER4_MOVED); ++ if (last_page_in_cluster(pages[i++])) ++ break; ++ } while (1); ++ xa_unlock_irq(&mapping->i_pages); ++ return i; ++} ++ ++#define MAX_PAGES_TO_CAPTURE (1024) ++ ++/* Capture anonymous page clusters */ ++static int capture_anon_pages(struct address_space * mapping, pgoff_t * index, ++ int to_capture) ++{ ++ int count = 0; ++ int found = 0; ++ int result = 0; ++ hint_t *hint; ++ lock_handle *lh; ++ struct inode * inode; ++ struct cluster_handle clust; ++ struct page * pages[MAX_CLUSTER_NRPAGES]; ++ ++ assert("edward-1127", mapping != NULL); ++ assert("edward-1128", mapping->host != NULL); ++ assert("edward-1440", mapping->host->i_mapping == mapping); ++ ++ inode = mapping->host; ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) ++ return RETERR(-ENOMEM); ++ hint_init_zero(hint); ++ lh = &hint->lh; ++ ++ cluster_init_read(&clust, NULL /* no sliding window */); ++ clust.hint = hint; ++ ++ result = alloc_cluster_pgset(&clust, cluster_nrpages(inode)); ++ if (result) ++ goto out; ++ ++ while (to_capture > 0) { ++ found = find_anon_page_cluster(mapping, index, pages); ++ if (!found) { ++ *index = (pgoff_t) - 1; ++ break; ++ } ++ move_cluster_forward(&clust, inode, pages[0]->index); ++ result = capture_page_cluster(&clust, inode); ++ ++ put_found_pages(pages, found); /* find_anon_page_cluster */ ++ if (result) ++ break; ++ to_capture -= clust.nr_pages; ++ count += clust.nr_pages; ++ } ++ if (result) { ++ warning("edward-1077", ++ "Capture failed (inode %llu, result=%i, captured=%d)\n", ++ (unsigned long long)get_inode_oid(inode), result, count); ++ } else { ++ assert("edward-1078", ergo(found > 0, count > 0)); ++ if (to_capture <= 0) ++ /* there may be left more pages */ ++ __mark_inode_dirty(inode, I_DIRTY_PAGES); ++ result = count; ++ } ++ out: ++ done_lh(lh); ++ kfree(hint); ++ put_cluster_handle(&clust); ++ return result; ++} ++ ++/* Returns true if inode's mapping has dirty pages ++ which do not belong to any atom */ ++static int cryptcompress_inode_has_anon_pages(struct inode *inode) ++{ ++ int result; ++ xa_lock_irq(&inode->i_mapping->i_pages); ++ result = radix_tree_tagged(&inode->i_mapping->i_pages, ++ PAGECACHE_TAG_REISER4_MOVED); ++ xa_unlock_irq(&inode->i_mapping->i_pages); ++ return result; ++} ++ ++/* plugin->writepages */ ++int writepages_cryptcompress(struct address_space *mapping, ++ struct writeback_control *wbc) ++{ ++ int result = 0; ++ long to_capture; ++ pgoff_t nrpages; ++ pgoff_t index = 0; ++ struct inode *inode; ++ struct cryptcompress_info *info; ++ ++ inode = mapping->host; ++ if (!cryptcompress_inode_has_anon_pages(inode)) ++ goto end; ++ info = cryptcompress_inode_data(inode); ++ nrpages = size_in_pages(i_size_read(inode)); ++ ++ if (wbc->sync_mode != WB_SYNC_ALL) ++ to_capture = min(wbc->nr_to_write, (long)MAX_PAGES_TO_CAPTURE); ++ else ++ to_capture = MAX_PAGES_TO_CAPTURE; ++ do { ++ reiser4_context *ctx; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ result = PTR_ERR(ctx); ++ break; ++ } ++ /* avoid recursive calls to ->sync_inodes */ ++ ctx->nobalance = 1; ++ ++ assert("edward-1079", ++ lock_stack_isclean(get_current_lock_stack())); ++ ++ reiser4_txn_restart_current(); ++ ++ if (get_current_context()->entd) { ++ if (mutex_trylock(&info->checkin_mutex) == 0) { ++ /* the mutex might be occupied by ++ entd caller */ ++ result = RETERR(-EBUSY); ++ reiser4_exit_context(ctx); ++ break; ++ } ++ } else ++ mutex_lock(&info->checkin_mutex); ++ ++ result = capture_anon_pages(inode->i_mapping, &index, ++ to_capture); ++ mutex_unlock(&info->checkin_mutex); ++ ++ if (result < 0) { ++ reiser4_exit_context(ctx); ++ break; ++ } ++ wbc->nr_to_write -= result; ++ if (wbc->sync_mode != WB_SYNC_ALL) { ++ reiser4_exit_context(ctx); ++ break; ++ } ++ result = txnmgr_force_commit_all(inode->i_sb, 0); ++ reiser4_exit_context(ctx); ++ } while (result >= 0 && index < nrpages); ++ ++ end: ++ if (is_in_reiser4_context()) { ++ if (get_current_context()->nr_captured >= CAPTURE_APAGE_BURST) { ++ /* there are already pages to flush, flush them out, ++ do not delay until end of reiser4_sync_inodes */ ++ reiser4_writeout(inode->i_sb, wbc); ++ get_current_context()->nr_captured = 0; ++ } ++ } ++ return result; ++} ++ ++/* plugin->ioctl */ ++int ioctl_cryptcompress(struct file *filp, unsigned int cmd, ++ unsigned long arg) ++{ ++ return RETERR(-ENOTTY); ++} ++ ++/* plugin->mmap */ ++int mmap_cryptcompress(struct file *file, struct vm_area_struct *vma) ++{ ++ int result; ++ struct inode *inode; ++ reiser4_context *ctx; ++ ++ inode = file_inode(file); ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ /* ++ * generic_file_mmap will do update_atime. Grab space for stat data ++ * update. ++ */ ++ result = reiser4_grab_space_force ++ (inode_file_plugin(inode)->estimate.update(inode), ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (result) { ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ result = generic_file_mmap(file, vma); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* plugin->delete_object */ ++int delete_object_cryptcompress(struct inode *inode) ++{ ++ int result; ++ struct cryptcompress_info * info; ++ ++ assert("edward-429", inode->i_nlink == 0); ++ ++ reiser4_txn_restart_current(); ++ info = cryptcompress_inode_data(inode); ++ ++ mutex_lock(&info->checkin_mutex); ++ result = prune_cryptcompress(inode, 0, 0); ++ mutex_unlock(&info->checkin_mutex); ++ ++ if (result) { ++ warning("edward-430", ++ "cannot truncate cryptcompress file %lli: %i", ++ (unsigned long long)get_inode_oid(inode), ++ result); ++ } ++ /* and remove stat data */ ++ return reiser4_delete_object_common(inode); ++} ++ ++/* ++ * plugin->setattr ++ * This implements actual truncate (see comments in reiser4/page_cache.c) ++ */ ++int setattr_cryptcompress(struct dentry *dentry, struct iattr *attr) ++{ ++ int result; ++ struct inode *inode; ++ struct cryptcompress_info * info; ++ ++ inode = dentry->d_inode; ++ info = cryptcompress_inode_data(inode); ++ ++ if (attr->ia_valid & ATTR_SIZE) { ++ if (i_size_read(inode) != attr->ia_size) { ++ reiser4_context *ctx; ++ loff_t old_size; ++ ++ ctx = reiser4_init_context(dentry->d_inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ result = setattr_dispatch_hook(inode); ++ if (result) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ old_size = i_size_read(inode); ++ inode_check_scale(inode, old_size, attr->ia_size); ++ ++ mutex_lock(&info->checkin_mutex); ++ if (attr->ia_size > inode->i_size) ++ result = expand_cryptcompress(inode, ++ attr->ia_size); ++ else ++ result = prune_cryptcompress(inode, ++ attr->ia_size, ++ 1/* update sd */); ++ mutex_unlock(&info->checkin_mutex); ++ if (result) { ++ warning("edward-1192", ++ "truncate_cryptcompress failed: oid %lli, " ++ "old size %lld, new size %lld, retval %d", ++ (unsigned long long) ++ get_inode_oid(inode), old_size, ++ attr->ia_size, result); ++ } ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ } else ++ result = 0; ++ } else ++ result = reiser4_setattr_common(dentry, attr); ++ return result; ++} ++ ++/* plugin->release */ ++int release_cryptcompress(struct inode *inode, struct file *file) ++{ ++ reiser4_context *ctx = reiser4_init_context(inode->i_sb); ++ ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ reiser4_free_file_fsdata(file); ++ reiser4_exit_context(ctx); ++ return 0; ++} ++ ++/* plugin->write_begin() */ ++int write_begin_cryptcompress(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata) ++{ ++ int ret = -ENOMEM; ++ char *buf; ++ hint_t *hint; ++ struct inode *inode; ++ struct reiser4_slide *win; ++ struct cluster_handle *clust; ++ struct cryptcompress_info *info; ++ reiser4_context *ctx; ++ ++ ctx = get_current_context(); ++ inode = page->mapping->host; ++ info = cryptcompress_inode_data(inode); ++ ++ assert("edward-1564", PageLocked(page)); ++ buf = kmalloc(sizeof(*clust) + ++ sizeof(*win) + ++ sizeof(*hint), ++ reiser4_ctx_gfp_mask_get()); ++ if (!buf) ++ goto err2; ++ clust = (struct cluster_handle *)buf; ++ win = (struct reiser4_slide *)(buf + sizeof(*clust)); ++ hint = (hint_t *)(buf + sizeof(*clust) + sizeof(*win)); ++ ++ hint_init_zero(hint); ++ cluster_init_read(clust, NULL); ++ clust->hint = hint; ++ ++ mutex_lock(&info->checkin_mutex); ++ ++ ret = set_window_and_cluster(inode, clust, win, len, pos); ++ if (ret) ++ goto err1; ++ unlock_page(page); ++ ret = prepare_logical_cluster(inode, pos, len, clust, LC_APPOV); ++ done_lh(&hint->lh); ++ assert("edward-1565", lock_stack_isclean(get_current_lock_stack())); ++ lock_page(page); ++ if (ret) { ++ SetPageError(page); ++ ClearPageUptodate(page); ++ unlock_page(page); ++ goto err0; ++ } ++ /* ++ * Success. All resources (including checkin_mutex) ++ * will be released in ->write_end() ++ */ ++ ctx->locked_page = page; ++ *fsdata = (void *)buf; ++ ++ return 0; ++ err0: ++ put_cluster_handle(clust); ++ err1: ++ mutex_unlock(&info->checkin_mutex); ++ kfree(buf); ++ err2: ++ assert("edward-1568", !ret); ++ return ret; ++} ++ ++/* plugin->write_end() */ ++int write_end_cryptcompress(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata) ++{ ++ int ret; ++ hint_t *hint; ++ struct inode *inode; ++ struct cluster_handle *clust; ++ struct cryptcompress_info *info; ++ reiser4_context *ctx; ++ ++ assert("edward-1566", ++ lock_stack_isclean(get_current_lock_stack())); ++ ctx = get_current_context(); ++ inode = page->mapping->host; ++ info = cryptcompress_inode_data(inode); ++ clust = (struct cluster_handle *)fsdata; ++ hint = clust->hint; ++ ++ unlock_page(page); ++ ctx->locked_page = NULL; ++ set_cluster_pages_dirty(clust, inode); ++ ret = checkin_logical_cluster(clust, inode); ++ if (ret) { ++ SetPageError(page); ++ goto exit; ++ } ++ exit: ++ mutex_unlock(&info->checkin_mutex); ++ ++ put_cluster_handle(clust); ++ ++ if (pos + copied > inode->i_size) { ++ /* ++ * i_size has been updated in ++ * checkin_logical_cluster ++ */ ++ ret = reiser4_update_sd(inode); ++ if (unlikely(ret != 0)) ++ warning("edward-1603", ++ "Can not update stat-data: %i. FSCK?", ++ ret); ++ } ++ kfree(fsdata); ++ return ret; ++} ++ ++/* plugin->bmap */ ++sector_t bmap_cryptcompress(struct address_space *mapping, sector_t lblock) ++{ ++ return -EINVAL; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/cryptcompress.h linux-5.10.2/fs/reiser4/plugin/file/cryptcompress.h +--- linux-5.10.2.orig/fs/reiser4/plugin/file/cryptcompress.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/cryptcompress.h 2020-12-23 16:07:46.123813202 +0100 +@@ -0,0 +1,621 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* See http://www.namesys.com/cryptcompress_design.html */ ++ ++#if !defined( __FS_REISER4_CRYPTCOMPRESS_H__ ) ++#define __FS_REISER4_CRYPTCOMPRESS_H__ ++ ++#include "../../page_cache.h" ++#include "../compress/compress.h" ++#include "../crypto/cipher.h" ++ ++#include ++ ++#define MIN_CLUSTER_SHIFT PAGE_SHIFT ++#define MAX_CLUSTER_SHIFT 16 ++#define MAX_CLUSTER_NRPAGES (1U << MAX_CLUSTER_SHIFT >> PAGE_SHIFT) ++#define DC_CHECKSUM_SIZE 4 ++ ++#define MIN_LATTICE_FACTOR 1 ++#define MAX_LATTICE_FACTOR 32 ++ ++#define REISER4_CRYPTO 0 ++ ++/* this mask contains all non-standard plugins that might ++ be present in reiser4-specific part of inode managed by ++ cryptcompress file plugin */ ++#define cryptcompress_mask \ ++ ((1 << PSET_FILE) | \ ++ (1 << PSET_CLUSTER) | \ ++ (1 << PSET_CIPHER) | \ ++ (1 << PSET_DIGEST) | \ ++ (1 << PSET_COMPRESSION) | \ ++ (1 << PSET_COMPRESSION_MODE)) ++ ++#if REISER4_DEBUG ++static inline int cluster_shift_ok(int shift) ++{ ++ return (shift >= MIN_CLUSTER_SHIFT) && (shift <= MAX_CLUSTER_SHIFT); ++} ++#endif ++ ++#if REISER4_DEBUG ++#define INODE_PGCOUNT(inode) \ ++({ \ ++ assert("edward-1530", inode_file_plugin(inode) == \ ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); \ ++ atomic_read(&cryptcompress_inode_data(inode)->pgcount); \ ++ }) ++#define INODE_PGCOUNT_INC(inode) \ ++do { \ ++ assert("edward-1531", inode_file_plugin(inode) == \ ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); \ ++ atomic_inc(&cryptcompress_inode_data(inode)->pgcount); \ ++} while (0) ++#define INODE_PGCOUNT_DEC(inode) \ ++do { \ ++ if (inode_file_plugin(inode) == \ ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)) \ ++ atomic_dec(&cryptcompress_inode_data(inode)->pgcount); \ ++} while (0) ++#else ++#define INODE_PGCOUNT(inode) (0) ++#define INODE_PGCOUNT_INC(inode) ++#define INODE_PGCOUNT_DEC(inode) ++#endif /* REISER4_DEBUG */ ++ ++struct tfm_stream { ++ __u8 *data; ++ size_t size; ++}; ++ ++typedef enum { ++ INPUT_STREAM, ++ OUTPUT_STREAM, ++ LAST_STREAM ++} tfm_stream_id; ++ ++typedef struct tfm_stream * tfm_unit[LAST_STREAM]; ++ ++static inline __u8 *ts_data(struct tfm_stream * stm) ++{ ++ assert("edward-928", stm != NULL); ++ return stm->data; ++} ++ ++static inline size_t ts_size(struct tfm_stream * stm) ++{ ++ assert("edward-929", stm != NULL); ++ return stm->size; ++} ++ ++static inline void set_ts_size(struct tfm_stream * stm, size_t size) ++{ ++ assert("edward-930", stm != NULL); ++ ++ stm->size = size; ++} ++ ++static inline int alloc_ts(struct tfm_stream ** stm) ++{ ++ assert("edward-931", stm); ++ assert("edward-932", *stm == NULL); ++ ++ *stm = kzalloc(sizeof(**stm), reiser4_ctx_gfp_mask_get()); ++ if (!*stm) ++ return -ENOMEM; ++ return 0; ++} ++ ++static inline void free_ts(struct tfm_stream * stm) ++{ ++ assert("edward-933", !ts_data(stm)); ++ assert("edward-934", !ts_size(stm)); ++ ++ kfree(stm); ++} ++ ++static inline int alloc_ts_data(struct tfm_stream * stm, size_t size) ++{ ++ assert("edward-935", !ts_data(stm)); ++ assert("edward-936", !ts_size(stm)); ++ assert("edward-937", size != 0); ++ ++ stm->data = reiser4_vmalloc(size); ++ if (!stm->data) ++ return -ENOMEM; ++ set_ts_size(stm, size); ++ return 0; ++} ++ ++static inline void free_ts_data(struct tfm_stream * stm) ++{ ++ assert("edward-938", equi(ts_data(stm), ts_size(stm))); ++ ++ if (ts_data(stm)) ++ vfree(ts_data(stm)); ++ memset(stm, 0, sizeof *stm); ++} ++ ++/* Write modes for item conversion in flush convert phase */ ++typedef enum { ++ CTAIL_INVAL_CONVERT_MODE = 0, ++ CTAIL_APPEND_ITEM = 1, ++ CTAIL_OVERWRITE_ITEM = 2, ++ CTAIL_CUT_ITEM = 3 ++} ctail_convert_mode_t; ++ ++typedef enum { ++ LC_INVAL = 0, /* invalid value */ ++ LC_APPOV = 1, /* append and/or overwrite */ ++ LC_EXPAND = 2, /* expanding truncate */ ++ LC_SHRINK = 3 /* shrinking truncate */ ++} logical_cluster_op; ++ ++/* Transform cluster. ++ * Intermediate state between page cluster and disk cluster ++ * Is used for data transform (compression/encryption) ++ */ ++struct tfm_cluster { ++ coa_set coa; /* compression algorithms info */ ++ tfm_unit tun; /* plain and transformed streams */ ++ tfm_action act; ++ int uptodate; ++ int lsize; /* number of bytes in logical cluster */ ++ int len; /* length of the transform stream */ ++ unsigned int hole:1; /* should punch hole */ ++}; ++ ++static inline coa_t get_coa(struct tfm_cluster * tc, reiser4_compression_id id, ++ tfm_action act) ++{ ++ return tc->coa[id][act]; ++} ++ ++static inline void set_coa(struct tfm_cluster * tc, reiser4_compression_id id, ++ tfm_action act, coa_t coa) ++{ ++ tc->coa[id][act] = coa; ++} ++ ++static inline int alloc_coa(struct tfm_cluster * tc, compression_plugin * cplug) ++{ ++ coa_t coa; ++ ++ coa = cplug->alloc(tc->act); ++ if (IS_ERR(coa)) ++ return PTR_ERR(coa); ++ set_coa(tc, cplug->h.id, tc->act, coa); ++ return 0; ++} ++ ++static inline int ++grab_coa(struct tfm_cluster * tc, compression_plugin * cplug) ++{ ++ return (cplug->alloc && !get_coa(tc, cplug->h.id, tc->act) ? ++ alloc_coa(tc, cplug) : 0); ++} ++ ++static inline void free_coa_set(struct tfm_cluster * tc) ++{ ++ tfm_action j; ++ reiser4_compression_id i; ++ compression_plugin *cplug; ++ ++ assert("edward-810", tc != NULL); ++ ++ for (j = 0; j < TFMA_LAST; j++) ++ for (i = 0; i < LAST_COMPRESSION_ID; i++) { ++ if (!get_coa(tc, i, j)) ++ continue; ++ cplug = compression_plugin_by_id(i); ++ assert("edward-812", cplug->free != NULL); ++ cplug->free(get_coa(tc, i, j), j); ++ set_coa(tc, i, j, 0); ++ } ++ return; ++} ++ ++static inline struct tfm_stream * get_tfm_stream(struct tfm_cluster * tc, ++ tfm_stream_id id) ++{ ++ return tc->tun[id]; ++} ++ ++static inline void set_tfm_stream(struct tfm_cluster * tc, ++ tfm_stream_id id, struct tfm_stream * ts) ++{ ++ tc->tun[id] = ts; ++} ++ ++static inline __u8 *tfm_stream_data(struct tfm_cluster * tc, tfm_stream_id id) ++{ ++ return ts_data(get_tfm_stream(tc, id)); ++} ++ ++static inline void set_tfm_stream_data(struct tfm_cluster * tc, ++ tfm_stream_id id, __u8 * data) ++{ ++ get_tfm_stream(tc, id)->data = data; ++} ++ ++static inline size_t tfm_stream_size(struct tfm_cluster * tc, tfm_stream_id id) ++{ ++ return ts_size(get_tfm_stream(tc, id)); ++} ++ ++static inline void ++set_tfm_stream_size(struct tfm_cluster * tc, tfm_stream_id id, size_t size) ++{ ++ get_tfm_stream(tc, id)->size = size; ++} ++ ++static inline int ++alloc_tfm_stream(struct tfm_cluster * tc, size_t size, tfm_stream_id id) ++{ ++ assert("edward-939", tc != NULL); ++ assert("edward-940", !get_tfm_stream(tc, id)); ++ ++ tc->tun[id] = kzalloc(sizeof(struct tfm_stream), ++ reiser4_ctx_gfp_mask_get()); ++ if (!tc->tun[id]) ++ return -ENOMEM; ++ return alloc_ts_data(get_tfm_stream(tc, id), size); ++} ++ ++static inline int ++realloc_tfm_stream(struct tfm_cluster * tc, size_t size, tfm_stream_id id) ++{ ++ assert("edward-941", tfm_stream_size(tc, id) < size); ++ free_ts_data(get_tfm_stream(tc, id)); ++ return alloc_ts_data(get_tfm_stream(tc, id), size); ++} ++ ++static inline void free_tfm_stream(struct tfm_cluster * tc, tfm_stream_id id) ++{ ++ free_ts_data(get_tfm_stream(tc, id)); ++ free_ts(get_tfm_stream(tc, id)); ++ set_tfm_stream(tc, id, 0); ++} ++ ++static inline unsigned coa_overrun(compression_plugin * cplug, int ilen) ++{ ++ return (cplug->overrun != NULL ? cplug->overrun(ilen) : 0); ++} ++ ++static inline void free_tfm_unit(struct tfm_cluster * tc) ++{ ++ tfm_stream_id id; ++ for (id = 0; id < LAST_STREAM; id++) { ++ if (!get_tfm_stream(tc, id)) ++ continue; ++ free_tfm_stream(tc, id); ++ } ++} ++ ++static inline void put_tfm_cluster(struct tfm_cluster * tc) ++{ ++ assert("edward-942", tc != NULL); ++ free_coa_set(tc); ++ free_tfm_unit(tc); ++} ++ ++static inline int tfm_cluster_is_uptodate(struct tfm_cluster * tc) ++{ ++ assert("edward-943", tc != NULL); ++ assert("edward-944", tc->uptodate == 0 || tc->uptodate == 1); ++ return (tc->uptodate == 1); ++} ++ ++static inline void tfm_cluster_set_uptodate(struct tfm_cluster * tc) ++{ ++ assert("edward-945", tc != NULL); ++ assert("edward-946", tc->uptodate == 0 || tc->uptodate == 1); ++ tc->uptodate = 1; ++ return; ++} ++ ++static inline void tfm_cluster_clr_uptodate(struct tfm_cluster * tc) ++{ ++ assert("edward-947", tc != NULL); ++ assert("edward-948", tc->uptodate == 0 || tc->uptodate == 1); ++ tc->uptodate = 0; ++ return; ++} ++ ++static inline int tfm_stream_is_set(struct tfm_cluster * tc, tfm_stream_id id) ++{ ++ return (get_tfm_stream(tc, id) && ++ tfm_stream_data(tc, id) && tfm_stream_size(tc, id)); ++} ++ ++static inline int tfm_cluster_is_set(struct tfm_cluster * tc) ++{ ++ int i; ++ for (i = 0; i < LAST_STREAM; i++) ++ if (!tfm_stream_is_set(tc, i)) ++ return 0; ++ return 1; ++} ++ ++static inline void alternate_streams(struct tfm_cluster * tc) ++{ ++ struct tfm_stream *tmp = get_tfm_stream(tc, INPUT_STREAM); ++ ++ set_tfm_stream(tc, INPUT_STREAM, get_tfm_stream(tc, OUTPUT_STREAM)); ++ set_tfm_stream(tc, OUTPUT_STREAM, tmp); ++} ++ ++/* Set of states to indicate a kind of data ++ * that will be written to the window */ ++typedef enum { ++ DATA_WINDOW, /* user's data */ ++ HOLE_WINDOW /* zeroes (such kind of data can be written ++ * if we start to write from offset > i_size) */ ++} window_stat; ++ ++/* Window (of logical cluster size) discretely sliding along a file. ++ * Is used to locate hole region in a logical cluster to be properly ++ * represented on disk. ++ * We split a write to cryptcompress file into writes to its logical ++ * clusters. Before writing to a logical cluster we set a window, i.e. ++ * calculate values of the following fields: ++ */ ++struct reiser4_slide { ++ unsigned off; /* offset to write from */ ++ unsigned count; /* number of bytes to write */ ++ unsigned delta; /* number of bytes to append to the hole */ ++ window_stat stat; /* what kind of data will be written starting ++ from @off */ ++}; ++ ++/* Possible states of a disk cluster */ ++typedef enum { ++ INVAL_DISK_CLUSTER, /* unknown state */ ++ PREP_DISK_CLUSTER, /* disk cluster got converted by flush ++ * at least 1 time */ ++ UNPR_DISK_CLUSTER, /* disk cluster just created and should be ++ * converted by flush */ ++ FAKE_DISK_CLUSTER, /* disk cluster doesn't exist neither in memory ++ * nor on disk */ ++ TRNC_DISK_CLUSTER /* disk cluster is partially truncated */ ++} disk_cluster_stat; ++ ++/* The following structure represents various stages of the same logical ++ * cluster of index @index: ++ * . fixed slide ++ * . page cluster (stage in primary cache) ++ * . transform cluster (transition stage) ++ * . disk cluster (stage in secondary cache) ++ * This structure is used in transition and synchronizing operations, e.g. ++ * transform cluster is a transition state when synchronizing page cluster ++ * and disk cluster. ++ * FIXME: Encapsulate page cluster, disk cluster. ++ */ ++struct cluster_handle { ++ cloff_t index; /* offset in a file (unit is a cluster size) */ ++ int index_valid; /* for validating the index above, if needed */ ++ struct file *file; /* host file */ ++ ++ /* logical cluster */ ++ struct reiser4_slide *win; /* sliding window to locate holes */ ++ logical_cluster_op op; /* logical cluster operation (truncate or ++ append/overwrite) */ ++ /* transform cluster */ ++ struct tfm_cluster tc; /* contains all needed info to synchronize ++ page cluster and disk cluster) */ ++ /* page cluster */ ++ int nr_pages; /* number of pages of current checkin action */ ++ int old_nrpages; /* number of pages of last checkin action */ ++ struct page **pages; /* attached pages */ ++ jnode * node; /* jnode for capture */ ++ ++ /* disk cluster */ ++ hint_t *hint; /* current position in the tree */ ++ disk_cluster_stat dstat; /* state of the current disk cluster */ ++ int reserved; /* is space for disk cluster reserved */ ++#if REISER4_DEBUG ++ reiser4_context *ctx; ++ int reserved_prepped; ++ int reserved_unprepped; ++#endif ++ ++}; ++ ++static inline __u8 * tfm_input_data (struct cluster_handle * clust) ++{ ++ return tfm_stream_data(&clust->tc, INPUT_STREAM); ++} ++ ++static inline __u8 * tfm_output_data (struct cluster_handle * clust) ++{ ++ return tfm_stream_data(&clust->tc, OUTPUT_STREAM); ++} ++ ++static inline int reset_cluster_pgset(struct cluster_handle * clust, ++ int nrpages) ++{ ++ assert("edward-1057", clust->pages != NULL); ++ memset(clust->pages, 0, sizeof(*clust->pages) * nrpages); ++ return 0; ++} ++ ++static inline int alloc_cluster_pgset(struct cluster_handle * clust, ++ int nrpages) ++{ ++ assert("edward-949", clust != NULL); ++ assert("edward-1362", clust->pages == NULL); ++ assert("edward-950", nrpages != 0 && nrpages <= MAX_CLUSTER_NRPAGES); ++ ++ clust->pages = kzalloc(sizeof(*clust->pages) * nrpages, ++ reiser4_ctx_gfp_mask_get()); ++ if (!clust->pages) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++static inline void move_cluster_pgset(struct cluster_handle *clust, ++ struct page ***pages, int * nr_pages) ++{ ++ assert("edward-1545", clust != NULL && clust->pages != NULL); ++ assert("edward-1546", pages != NULL && *pages == NULL); ++ *pages = clust->pages; ++ *nr_pages = clust->nr_pages; ++ clust->pages = NULL; ++} ++ ++static inline void free_cluster_pgset(struct cluster_handle * clust) ++{ ++ assert("edward-951", clust->pages != NULL); ++ kfree(clust->pages); ++ clust->pages = NULL; ++} ++ ++static inline void put_cluster_handle(struct cluster_handle * clust) ++{ ++ assert("edward-435", clust != NULL); ++ ++ put_tfm_cluster(&clust->tc); ++ if (clust->pages) ++ free_cluster_pgset(clust); ++ memset(clust, 0, sizeof *clust); ++} ++ ++static inline void inc_keyload_count(struct reiser4_crypto_info * data) ++{ ++ assert("edward-1410", data != NULL); ++ data->keyload_count++; ++} ++ ++static inline void dec_keyload_count(struct reiser4_crypto_info * data) ++{ ++ assert("edward-1411", data != NULL); ++ assert("edward-1412", data->keyload_count > 0); ++ data->keyload_count--; ++} ++ ++static inline int capture_cluster_jnode(jnode * node) ++{ ++ return reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++} ++ ++/* cryptcompress specific part of reiser4_inode */ ++struct cryptcompress_info { ++ struct mutex checkin_mutex; /* This is to serialize ++ * checkin_logical_cluster operations */ ++ cloff_t trunc_index; /* Index of the leftmost truncated disk ++ * cluster (to resolve races with read) */ ++ struct reiser4_crypto_info *crypt; ++ /* ++ * the following 2 fields are controlled by compression mode plugin ++ */ ++ int compress_toggle; /* Current status of compressibility */ ++ int lattice_factor; /* Factor of dynamic lattice. FIXME: Have ++ * a compression_toggle to keep the factor ++ */ ++#if REISER4_DEBUG ++ atomic_t pgcount; /* number of grabbed pages */ ++#endif ++}; ++ ++static inline void set_compression_toggle (struct cryptcompress_info * info, int val) ++{ ++ info->compress_toggle = val; ++} ++ ++static inline int get_compression_toggle (struct cryptcompress_info * info) ++{ ++ return info->compress_toggle; ++} ++ ++static inline int compression_is_on(struct cryptcompress_info * info) ++{ ++ return get_compression_toggle(info) == 1; ++} ++ ++static inline void turn_on_compression(struct cryptcompress_info * info) ++{ ++ set_compression_toggle(info, 1); ++} ++ ++static inline void turn_off_compression(struct cryptcompress_info * info) ++{ ++ set_compression_toggle(info, 0); ++} ++ ++static inline void set_lattice_factor(struct cryptcompress_info * info, int val) ++{ ++ info->lattice_factor = val; ++} ++ ++static inline int get_lattice_factor(struct cryptcompress_info * info) ++{ ++ return info->lattice_factor; ++} ++ ++struct cryptcompress_info *cryptcompress_inode_data(const struct inode *); ++int equal_to_rdk(znode *, const reiser4_key *); ++int goto_right_neighbor(coord_t *, lock_handle *); ++int cryptcompress_inode_ok(struct inode *inode); ++int coord_is_unprepped_ctail(const coord_t * coord); ++extern int do_readpage_ctail(struct inode *, struct cluster_handle *, ++ struct page * page, znode_lock_mode mode); ++extern int ctail_insert_unprepped_cluster(struct cluster_handle * clust, ++ struct inode * inode); ++extern int readpages_cryptcompress(struct file*, struct address_space*, ++ struct list_head*, unsigned); ++int bind_cryptcompress(struct inode *child, struct inode *parent); ++void destroy_inode_cryptcompress(struct inode * inode); ++int grab_page_cluster(struct inode *inode, struct cluster_handle * clust, ++ rw_op rw); ++int write_dispatch_hook(struct file *file, struct inode * inode, ++ loff_t pos, struct cluster_handle * clust, ++ struct dispatch_context * cont); ++int setattr_dispatch_hook(struct inode * inode); ++struct reiser4_crypto_info * inode_crypto_info(struct inode * inode); ++void inherit_crypto_info_common(struct inode * parent, struct inode * object, ++ int (*can_inherit)(struct inode * child, ++ struct inode * parent)); ++void reiser4_attach_crypto_info(struct inode * inode, ++ struct reiser4_crypto_info * info); ++void change_crypto_info(struct inode * inode, struct reiser4_crypto_info * new); ++struct reiser4_crypto_info * reiser4_alloc_crypto_info (struct inode * inode); ++ ++static inline struct crypto_blkcipher * info_get_cipher(struct reiser4_crypto_info * info) ++{ ++ return info->cipher; ++} ++ ++static inline void info_set_cipher(struct reiser4_crypto_info * info, ++ struct crypto_blkcipher * tfm) ++{ ++ info->cipher = tfm; ++} ++ ++static inline struct crypto_hash * info_get_digest(struct reiser4_crypto_info * info) ++{ ++ return info->digest; ++} ++ ++static inline void info_set_digest(struct reiser4_crypto_info * info, ++ struct crypto_hash * tfm) ++{ ++ info->digest = tfm; ++} ++ ++static inline void put_cluster_page(struct page * page) ++{ ++ put_page(page); ++} ++ ++#endif /* __FS_REISER4_CRYPTCOMPRESS_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/file.c linux-5.10.2/fs/reiser4/plugin/file/file.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/file.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/file.c 2020-12-23 16:07:46.124813217 +0100 +@@ -0,0 +1,2916 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* ++ * this file contains implementations of inode/file/address_space/file plugin ++ * operations specific for "unix file plugin" (plugin id is ++ * UNIX_FILE_PLUGIN_ID). "Unix file" is either built of tail items only ++ * (FORMATTING_ID) or of extent items only (EXTENT40_POINTER_ID) or empty (have ++ * no items but stat data) ++ */ ++ ++#include "../../inode.h" ++#include "../../super.h" ++#include "../../tree_walk.h" ++#include "../../carry.h" ++#include "../../page_cache.h" ++#include "../object.h" ++#include "../cluster.h" ++#include "../../safe_link.h" ++ ++#include ++#include ++#include ++ ++ ++static int unpack(struct file *file, struct inode *inode, int forever); ++static void drop_access(struct unix_file_info *); ++static int hint_validate(hint_t *hint, reiser4_tree *tree, ++ const reiser4_key * key, int check_key, ++ znode_lock_mode lock_mode); ++ ++/* Get exclusive access and make sure that file is not partially ++ * converted (It may happen that another process is doing tail ++ * conversion. If so, wait until it completes) ++ */ ++static inline void get_exclusive_access_careful(struct unix_file_info * uf_info, ++ struct inode *inode) ++{ ++ do { ++ get_exclusive_access(uf_info); ++ if (!reiser4_inode_get_flag(inode, REISER4_PART_IN_CONV)) ++ break; ++ drop_exclusive_access(uf_info); ++ schedule(); ++ } while (1); ++} ++ ++/* get unix file plugin specific portion of inode */ ++struct unix_file_info *unix_file_inode_data(const struct inode *inode) ++{ ++ return &reiser4_inode_data(inode)->file_plugin_data.unix_file_info; ++} ++ ++/** ++ * equal_to_rdk - compare key and znode's right delimiting key ++ * @node: node whose right delimiting key to compare with @key ++ * @key: key to compare with @node's right delimiting key ++ * ++ * Returns true if @key is equal to right delimiting key of @node. ++ */ ++int equal_to_rdk(znode *node, const reiser4_key *key) ++{ ++ int result; ++ ++ read_lock_dk(znode_get_tree(node)); ++ result = keyeq(key, znode_get_rd_key(node)); ++ read_unlock_dk(znode_get_tree(node)); ++ return result; ++} ++ ++#if REISER4_DEBUG ++ ++/** ++ * equal_to_ldk - compare key and znode's left delimiting key ++ * @node: node whose left delimiting key to compare with @key ++ * @key: key to compare with @node's left delimiting key ++ * ++ * Returns true if @key is equal to left delimiting key of @node. ++ */ ++int equal_to_ldk(znode *node, const reiser4_key *key) ++{ ++ int result; ++ ++ read_lock_dk(znode_get_tree(node)); ++ result = keyeq(key, znode_get_ld_key(node)); ++ read_unlock_dk(znode_get_tree(node)); ++ return result; ++} ++ ++/** ++ * check_coord - check whether coord corresponds to key ++ * @coord: coord to check ++ * @key: key @coord has to correspond to ++ * ++ * Returns true if @coord is set as if it was set as result of lookup with @key ++ * in coord->node. ++ */ ++static int check_coord(const coord_t *coord, const reiser4_key *key) ++{ ++ coord_t twin; ++ ++ node_plugin_by_node(coord->node)->lookup(coord->node, key, ++ FIND_MAX_NOT_MORE_THAN, &twin); ++ return coords_equal(coord, &twin); ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++/** ++ * init_uf_coord - initialize extended coord ++ * @uf_coord: ++ * @lh: ++ * ++ * ++ */ ++void init_uf_coord(uf_coord_t *uf_coord, lock_handle *lh) ++{ ++ coord_init_zero(&uf_coord->coord); ++ coord_clear_iplug(&uf_coord->coord); ++ uf_coord->lh = lh; ++ init_lh(lh); ++ memset(&uf_coord->extension, 0, sizeof(uf_coord->extension)); ++ uf_coord->valid = 0; ++} ++ ++void validate_extended_coord(uf_coord_t *uf_coord, loff_t offset) ++{ ++ assert("vs-1333", uf_coord->valid == 0); ++ ++ if (coord_is_between_items(&uf_coord->coord)) ++ return; ++ ++ assert("vs-1348", ++ item_plugin_by_coord(&uf_coord->coord)->s.file. ++ init_coord_extension); ++ ++ item_body_by_coord(&uf_coord->coord); ++ item_plugin_by_coord(&uf_coord->coord)->s.file. ++ init_coord_extension(uf_coord, offset); ++} ++ ++/** ++ * goto_right_neighbor - lock right neighbor, drop current node lock ++ * @coord: ++ * @lh: ++ * ++ * Obtain lock on right neighbor and drop lock on current node. ++ */ ++int goto_right_neighbor(coord_t *coord, lock_handle *lh) ++{ ++ int result; ++ lock_handle lh_right; ++ ++ assert("vs-1100", znode_is_locked(coord->node)); ++ ++ init_lh(&lh_right); ++ result = reiser4_get_right_neighbor(&lh_right, coord->node, ++ znode_is_wlocked(coord->node) ? ++ ZNODE_WRITE_LOCK : ZNODE_READ_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result) { ++ done_lh(&lh_right); ++ return result; ++ } ++ ++ /* ++ * we hold two longterm locks on neighboring nodes. Unlock left of ++ * them ++ */ ++ done_lh(lh); ++ ++ coord_init_first_unit_nocheck(coord, lh_right.node); ++ move_lh(lh, &lh_right); ++ ++ return 0; ++ ++} ++ ++/** ++ * set_file_state ++ * @uf_info: ++ * @cbk_result: ++ * @level: ++ * ++ * This is to be used by find_file_item and in find_file_state to ++ * determine real state of file ++ */ ++static void set_file_state(struct unix_file_info *uf_info, int cbk_result, ++ tree_level level) ++{ ++ if (cbk_errored(cbk_result)) ++ /* error happened in find_file_item */ ++ return; ++ ++ assert("vs-1164", level == LEAF_LEVEL || level == TWIG_LEVEL); ++ ++ if (uf_info->container == UF_CONTAINER_UNKNOWN) { ++ if (cbk_result == CBK_COORD_NOTFOUND) ++ uf_info->container = UF_CONTAINER_EMPTY; ++ else if (level == LEAF_LEVEL) ++ uf_info->container = UF_CONTAINER_TAILS; ++ else ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ } else { ++ /* ++ * file state is known, check whether it is set correctly if ++ * file is not being tail converted ++ */ ++ if (!reiser4_inode_get_flag(unix_file_info_to_inode(uf_info), ++ REISER4_PART_IN_CONV)) { ++ assert("vs-1162", ++ ergo(level == LEAF_LEVEL && ++ cbk_result == CBK_COORD_FOUND, ++ uf_info->container == UF_CONTAINER_TAILS)); ++ assert("vs-1165", ++ ergo(level == TWIG_LEVEL && ++ cbk_result == CBK_COORD_FOUND, ++ uf_info->container == UF_CONTAINER_EXTENTS)); ++ } ++ } ++} ++ ++int find_file_item_nohint(coord_t *coord, lock_handle *lh, ++ const reiser4_key *key, znode_lock_mode lock_mode, ++ struct inode *inode) ++{ ++ return reiser4_object_lookup(meta_subvol_tree(), ++ inode, key, coord, lh, lock_mode, ++ FIND_MAX_NOT_MORE_THAN, ++ TWIG_LEVEL, LEAF_LEVEL, ++ (lock_mode == ZNODE_READ_LOCK) ? CBK_UNIQUE : ++ (CBK_UNIQUE | CBK_FOR_INSERT), ++ NULL /* ra_info */); ++} ++ ++/** ++ * find_file_item - look for file item in the tree ++ * @hint: provides coordinate, lock handle, seal ++ * @key: key for search ++ * @mode: mode of lock to put on returned node ++ * @ra_info: ++ * @inode: ++ * ++ * This finds position in the tree corresponding to @key. It first tries to use ++ * @hint's seal if it is set. ++ */ ++int find_file_item(hint_t *hint, const reiser4_key *key, ++ znode_lock_mode lock_mode, ++ struct inode *inode) ++{ ++ int result; ++ coord_t *coord; ++ lock_handle *lh; ++ ++ assert("nikita-3030", reiser4_schedulable()); ++ assert("vs-1707", hint != NULL); ++ assert("vs-47", inode != NULL); ++ assert("edward-2375", inode_file_plugin(inode) != ++ file_plugin_by_id(STRIPED_FILE_PLUGIN_ID)); ++ ++ coord = &hint->ext_coord.coord; ++ lh = hint->ext_coord.lh; ++ init_lh(lh); ++ ++ result = hint_validate(hint, ++ meta_subvol_tree(), ++ key, 1 /* check key */, lock_mode); ++ if (!result) { ++ if (coord->between == AFTER_UNIT && ++ equal_to_rdk(coord->node, key)) { ++ result = goto_right_neighbor(coord, lh); ++ if (result == -E_NO_NEIGHBOR) ++ return RETERR(-EIO); ++ if (result) ++ return result; ++ assert("vs-1152", equal_to_ldk(coord->node, key)); ++ /* ++ * we moved to different node. Invalidate coord ++ * extension, zload is necessary to init it again ++ */ ++ hint->ext_coord.valid = 0; ++ } ++ ++ set_file_state(unix_file_inode_data(inode), CBK_COORD_FOUND, ++ znode_get_level(coord->node)); ++ ++ return CBK_COORD_FOUND; ++ } ++ coord_init_zero(coord); ++ result = find_file_item_nohint(coord, lh, key, lock_mode, inode); ++ set_file_state(unix_file_inode_data(inode), result, ++ znode_get_level(coord->node)); ++ ++ /* FIXME: we might already have coord extension initialized */ ++ hint->ext_coord.valid = 0; ++ return result; ++} ++ ++void hint_init_zero(hint_t * hint) ++{ ++ memset(hint, 0, sizeof(*hint)); ++ init_lh(&hint->lh); ++ hint->ext_coord.lh = &hint->lh; ++} ++ ++static int find_file_state(struct inode *inode, struct unix_file_info *uf_info) ++{ ++ int result; ++ reiser4_key key; ++ coord_t coord; ++ lock_handle lh; ++ ++ assert("edward-2086", ++ inode_file_plugin(inode) == ++ file_plugin_by_id(UNIX_FILE_PLUGIN_ID)); ++ assert("vs-1628", ea_obtained(uf_info)); ++ ++ if (uf_info->container == UF_CONTAINER_UNKNOWN) { ++ build_body_key_unix_file(inode, 0, &key); ++ init_lh(&lh); ++ result = find_file_item_nohint(&coord, &lh, &key, ++ ZNODE_READ_LOCK, inode); ++ set_file_state(uf_info, result, znode_get_level(coord.node)); ++ done_lh(&lh); ++ if (!cbk_errored(result)) ++ result = 0; ++ } else ++ result = 0; ++ assert("vs-1074", ++ ergo(result == 0, uf_info->container != UF_CONTAINER_UNKNOWN)); ++ reiser4_txn_restart_current(); ++ return result; ++} ++ ++/** ++ * Estimate and reserve space needed to truncate page ++ * which gets partially truncated: ++ * 1) one block for page itself; ++ * 2) stat-data update (estimate_one_insert_into_item); ++ * 3) one item insertion (estimate_one_insert_into_item) ++ * which may happen if page corresponds to hole extent ++ * and unallocated one will have to be created. ++ * ++ * @inode: object that the partial page belongs to; ++ * @index: index of the partial page. ++ */ ++static int reserve_partial_page(struct inode *inode, pgoff_t index) ++{ ++ grab_space_enable(); ++ return reiser4_grab_reserved(reiser4_get_current_sb(), ++ 1 + ++ 2 * estimate_one_insert_into_item(meta_subvol_tree()), ++ BA_CAN_COMMIT, get_meta_subvol()); ++} ++ ++/** ++ * estimate and reserve space needed to cut one item and update one stat data ++ * @inode: object to cut; ++ */ ++int reserve_cut_iteration(struct inode *inode) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ assert("nikita-3172", lock_stack_isclean(get_current_lock_stack())); ++ /* ++ * We need to double our estimation now ++ * that we can delete more than one node ++ * FIXME-EDWARD: Not clear why to double. ++ */ ++ grab_space_enable(); ++ return reiser4_grab_reserved(reiser4_get_current_sb(), ++ 2 *(estimate_one_item_removal(&subv->tree) + ++ estimate_one_insert_into_item(&subv->tree)), ++ BA_CAN_COMMIT, subv); ++} ++ ++int reiser4_update_file_size(struct inode *inode, loff_t new_size, ++ int update_sd) ++{ ++ int result = 0; ++ ++ INODE_SET_SIZE(inode, new_size); ++ if (update_sd) { ++ inode->i_ctime = inode->i_mtime = current_time(inode); ++ result = reiser4_update_sd(inode); ++ } ++ return result; ++} ++ ++/** ++ * Cut file body starting from the last item until @new_size of ++ * the file is reached. Reserve space and update file stat data ++ * on every single cut from the tree. ++ */ ++int cut_file_items(struct inode *inode, loff_t new_size, ++ int update_sd, loff_t cur_size, ++ int (*update_actor) (struct inode *, loff_t, int)) ++{ ++ reiser4_tree *tree; ++ reiser4_key from_key, to_key; ++ reiser4_key smallest_removed; ++ file_plugin *fplug = inode_file_plugin(inode); ++ int result; ++ int progress = 0; ++ ++ assert("vs-1248", ++ fplug == file_plugin_by_id(UNIX_FILE_PLUGIN_ID) || ++ fplug == file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); ++ ++ tree = meta_subvol_tree(); ++ fplug->build_body_key(inode, new_size, &from_key); ++ to_key = from_key; ++ set_key_offset(&to_key, cur_size - 1 /*get_key_offset(reiser4_max_key()) */ ); ++ /* ++ * this loop normally runs just once ++ */ ++ while (1) { ++ result = reserve_cut_iteration(inode); ++ if (result) ++ break; ++ ++ result = reiser4_cut_tree_object(tree, ++ &from_key, &to_key, ++ &smallest_removed, inode, 1, ++ &progress); ++ if (result == -E_NO_NEIGHBOR) ++ result = 0; ++ else if (result == -E_REPEAT) { ++ /** ++ * -E_REPEAT is a signal to interrupt a long ++ * file truncation process ++ */ ++ if (progress) { ++ result = update_actor(inode, ++ get_key_offset(&smallest_removed), ++ update_sd); ++ if (result) ++ break; ++ } ++ /* the below does up(sbinfo->delete_mutex). ++ * Do not get confused */ ++ reiser4_release_reserved(inode->i_sb); ++ /** ++ * reiser4_cut_tree_object() was interrupted probably ++ * because current atom requires commit, we have to ++ * release transaction handle to allow atom commit. ++ */ ++ reiser4_txn_restart_current(); ++ continue; ++ } else if (result && ++ !(result == CBK_COORD_NOTFOUND && new_size == 0 ++ && inode->i_size == 0)) ++ break; ++ ++ set_key_offset(&smallest_removed, new_size); ++ /* ++ * Final sd update after the file gets its correct size ++ */ ++ result = update_actor(inode, get_key_offset(&smallest_removed), ++ update_sd); ++ break; ++ } ++ /* ++ * the below does up(sbinfo->delete_mutex). Do not get confused ++ */ ++ reiser4_release_reserved(inode->i_sb); ++ ++ return result; ++} ++ ++/** ++ * make file shorter ++ */ ++static int shorten_file(struct inode *inode, loff_t new_size) ++{ ++ int result; ++ struct page *page; ++ int padd_from; ++ unsigned long index; ++ struct unix_file_info *uf_info; ++ ++ /* ++ * cut file body using volume-specific method ++ */ ++ result = cut_file_items(inode, new_size, ++ 1, /* update_sd */ ++ get_key_offset(reiser4_max_key()), ++ reiser4_update_file_size); ++ if (result) ++ return result; ++ ++ uf_info = unix_file_inode_data(inode); ++ assert("vs-1105", new_size == inode->i_size); ++ if (new_size == 0) { ++ uf_info->container = UF_CONTAINER_EMPTY; ++ return 0; ++ } ++ ++ result = find_file_state(inode, uf_info); ++ if (result) ++ return result; ++ if (uf_info->container == UF_CONTAINER_TAILS) ++ /* ++ * No need to worry about zeroing last page after new file ++ * end ++ */ ++ return 0; ++ ++ padd_from = inode->i_size & (PAGE_SIZE - 1); ++ if (!padd_from) ++ /* file is truncated to page boundary */ ++ return 0; ++ /* ++ * last page is partially truncated - zero its content ++ */ ++ index = (inode->i_size >> PAGE_SHIFT); ++ result = reserve_partial_page(inode, index); ++ if (result) { ++ assert("edward-2294", ++ get_current_super_private()->delete_mutex_owner == NULL); ++ return result; ++ } ++ page = read_mapping_page(inode->i_mapping, index, NULL); ++ if (IS_ERR(page)) { ++ /* ++ * the below does up(sbinfo->delete_mutex). Do not get ++ * confused ++ */ ++ reiser4_release_reserved(inode->i_sb); ++ if (likely(PTR_ERR(page) == -EINVAL)) { ++ /* looks like file is built of tail items */ ++ return 0; ++ } ++ return PTR_ERR(page); ++ } ++ wait_on_page_locked(page); ++ if (!PageUptodate(page)) { ++ put_page(page); ++ /* ++ * the below does up(sbinfo->delete_mutex). Do not get ++ * confused ++ */ ++ reiser4_release_reserved(inode->i_sb); ++ return RETERR(-EIO); ++ } ++ ++ /* ++ * if page correspons to hole extent unit - unallocated one will be ++ * created here. This is not necessary ++ */ ++ result = find_or_create_extent_unix_file(page); ++ ++ /* ++ * FIXME: cut_file_items has already updated inode. Probably it would ++ * be better to update it here when file is really truncated ++ */ ++ if (result) { ++ put_page(page); ++ /* ++ * the below does up(sbinfo->delete_mutex). Do not get ++ * confused ++ */ ++ reiser4_release_reserved(inode->i_sb); ++ return result; ++ } ++ ++ lock_page(page); ++ assert("vs-1066", PageLocked(page)); ++ zero_user_segment(page, padd_from, PAGE_SIZE); ++ unlock_page(page); ++ put_page(page); ++ /* the below does up(sbinfo->delete_mutex). Do not get confused */ ++ reiser4_release_reserved(inode->i_sb); ++ return 0; ++} ++ ++/** ++ * should_have_notail ++ * @uf_info: ++ * @new_size: ++ * ++ * Calls formatting plugin to see whether file of size @new_size has to be ++ * stored in unformatted nodes or in tail items. 0 is returned for later case. ++ */ ++static int should_have_notail(const struct unix_file_info *uf_info, loff_t new_size) ++{ ++ if (!uf_info->tplug) ++ return 1; ++ return !uf_info->tplug->have_tail(unix_file_info_to_inode(uf_info), ++ new_size); ++ ++} ++ ++/** ++ * change length of file ++ * @inode: inode of file ++ * @new_size: new file length ++ * ++ * Adjusts items file @inode is built of to match @new_size. It may either cut ++ * items or add them to represent a hole at the end of file. The caller has to ++ * obtain exclusive access to the file. ++ */ ++static int truncate_body_unix_file(struct inode *inode, struct iattr *attr) ++{ ++ int result; ++ loff_t new_size = attr->ia_size; ++ ++ if (inode->i_size < new_size) { ++ /* expanding truncate */ ++ struct unix_file_info *uf_info = unix_file_inode_data(inode); ++ ++ result = find_file_state(inode, uf_info); ++ if (result) ++ return result; ++ ++ if (should_have_notail(uf_info, new_size)) { ++ /* ++ * file of size @new_size has to be built of ++ * extents. If it is built of tails - convert to ++ * extents ++ */ ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ /* ++ * if file is being convered by another process ++ * - wait until it completes ++ */ ++ while (1) { ++ if (reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)) { ++ drop_exclusive_access(uf_info); ++ schedule(); ++ get_exclusive_access(uf_info); ++ continue; ++ } ++ break; ++ } ++ ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ result = tail2extent(uf_info); ++ if (result) ++ return result; ++ } ++ } ++ result = write_extent_unix_file(NULL, inode, NULL, ++ 0, &new_size); ++ if (result) ++ return result; ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ } else { ++ if (uf_info->container == UF_CONTAINER_EXTENTS) { ++ result = write_extent_unix_file(NULL, inode, ++ NULL, 0, ++ &new_size); ++ if (result) ++ return result; ++ } else { ++ result = write_tail_unix_file(NULL, inode, NULL, ++ 0, &new_size); ++ if (result) ++ return result; ++ uf_info->container = UF_CONTAINER_TAILS; ++ } ++ } ++ BUG_ON(result > 0); ++ result = reiser4_update_file_size(inode, new_size, 1); ++ BUG_ON(result != 0); ++ } else ++ result = shorten_file(inode, new_size); ++ return result; ++} ++ ++/** ++ * load_file_hint - copy hint from struct file to local variable ++ * @file: file to get hint from ++ * @hint: structure to fill ++ * ++ * Reiser4 specific portion of struct file may contain information (hint) ++ * stored on exiting from previous read or write. That information includes ++ * seal of znode and coord within that znode where previous read or write ++ * stopped. This function copies that information to @hint if it was stored or ++ * initializes @hint by 0s otherwise. ++ */ ++int load_file_hint(struct file *file, hint_t *hint) ++{ ++ reiser4_file_fsdata *fsdata; ++ ++ if (file) { ++ fsdata = reiser4_get_file_fsdata(file); ++ if (IS_ERR(fsdata)) ++ return PTR_ERR(fsdata); ++ ++ spin_lock_inode(file_inode(file)); ++ if (reiser4_seal_is_set(&fsdata->reg.hint.seal)) { ++ memcpy(hint, &fsdata->reg.hint, sizeof(*hint)); ++ init_lh(&hint->lh); ++ hint->ext_coord.lh = &hint->lh; ++ spin_unlock_inode(file_inode(file)); ++ /* ++ * force re-validation of the coord on the first ++ * iteration of the read/write loop. ++ */ ++ hint->ext_coord.valid = 0; ++ assert("nikita-19892", ++ coords_equal(&hint->seal.coord1, ++ &hint->ext_coord.coord)); ++ return 0; ++ } ++ memset(&fsdata->reg.hint, 0, sizeof(hint_t)); ++ spin_unlock_inode(file_inode(file)); ++ } ++ hint_init_zero(hint); ++ return 0; ++} ++ ++/** ++ * Copy hint to reiser4 private struct file's part ++ * @file: file to save hint in ++ * @hint: hint to save ++ * ++ * This copies @hint to reiser4 private part of struct file. It can help ++ * speedup future accesses to the file. ++ */ ++void save_file_hint(struct file *file, const hint_t *hint) ++{ ++ reiser4_file_fsdata *fsdata; ++ ++ assert("edward-1337", hint != NULL); ++ ++ if (!file || !reiser4_seal_is_set(&hint->seal)) ++ return; ++ fsdata = reiser4_get_file_fsdata(file); ++ assert("vs-965", !IS_ERR(fsdata)); ++ assert("nikita-19891", ++ coords_equal(&hint->seal.coord1, &hint->ext_coord.coord)); ++ assert("vs-30", hint->lh.owner == NULL); ++ spin_lock_inode(file_inode(file)); ++ fsdata->reg.hint = *hint; ++ spin_unlock_inode(file_inode(file)); ++ return; ++} ++ ++void reiser4_unset_hint(hint_t * hint) ++{ ++ assert("vs-1315", hint); ++ hint->ext_coord.valid = 0; ++ reiser4_seal_done(&hint->seal); ++ done_lh(&hint->lh); ++} ++ ++/* coord must be set properly. So, that reiser4_set_hint ++ has nothing to do */ ++void reiser4_set_hint(hint_t * hint, const reiser4_key * key, ++ znode_lock_mode mode) ++{ ++ ON_DEBUG(coord_t * coord = &hint->ext_coord.coord); ++ assert("vs-1207", WITH_DATA(coord->node, check_coord(coord, key))); ++ ++ reiser4_seal_init(&hint->seal, &hint->ext_coord.coord, key); ++ hint->offset = get_key_offset(key); ++ hint->mode = mode; ++ done_lh(&hint->lh); ++} ++ ++int hint_is_set(const hint_t * hint) ++{ ++ return reiser4_seal_is_set(&hint->seal); ++} ++ ++#if REISER4_DEBUG ++static int all_but_offset_key_eq(const reiser4_key * k1, ++ const reiser4_key * k2) ++{ ++ return (get_key_locality(k1) == get_key_locality(k2) && ++ get_key_type(k1) == get_key_type(k2) && ++ get_key_band(k1) == get_key_band(k2) && ++ get_key_ordering(k1) == get_key_ordering(k2) && ++ get_key_objectid(k1) == get_key_objectid(k2)); ++} ++#endif ++ ++static int hint_validate(hint_t *hint, reiser4_tree *tree, ++ const reiser4_key *key, int check_key, ++ znode_lock_mode lock_mode) ++{ ++ if (!hint || !hint_is_set(hint) || hint->mode != lock_mode) ++ /* hint either not set or set by different operation */ ++ return RETERR(-E_REPEAT); ++ ++ assert("vs-1277", all_but_offset_key_eq(key, &hint->seal.key)); ++ ++ if (check_key && get_key_offset(key) != hint->offset) ++ /* hint is set for different key */ ++ return RETERR(-E_REPEAT); ++ ++ assert("vs-31", hint->ext_coord.lh == &hint->lh); ++ return reiser4_seal_validate(&hint->seal, tree, ++ &hint->ext_coord.coord, key, ++ hint->ext_coord.lh, lock_mode, ++ ZNODE_LOCK_LOPRI); ++} ++ ++/** ++ * Look for place at twig level for extent corresponding to page, ++ * call extent's writepage method to create unallocated extent if ++ * it does not exist yet, initialize jnode, capture page ++ */ ++int find_or_create_extent_unix_file(struct page *page) ++{ ++ int result; ++ struct inode *inode; ++ int plugged_hole; ++ ++ jnode *node; ++ ++ assert("vs-1065", page->mapping && page->mapping->host); ++ ++ inode = page->mapping->host; ++ ++ lock_page(page); ++ node = jnode_of_page(page); ++ if (IS_ERR(node)) { ++ unlock_page(page); ++ return PTR_ERR(node); ++ } ++ JF_SET(node, JNODE_WRITE_PREPARED); ++ unlock_page(page); ++ if (node->blocknr == 0) { ++ plugged_hole = 0; ++ result = update_extent_unix_file(inode, node, ++ page_offset(page), ++ &plugged_hole); ++ if (result) { ++ JF_CLR(node, JNODE_WRITE_PREPARED); ++ jput(node); ++ warning("edward-1549", ++ "failed to update extent (%d)", result); ++ return result; ++ } ++ if (plugged_hole) ++ reiser4_update_sd(inode); ++ } else { ++ struct atom_brick_info *abi; ++ ++ assert("edward-1982", node->subvol != NULL); ++ spin_lock_jnode(node); ++ result = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ spin_unlock_jnode(node); ++ BUG_ON(result != 0); ++ ++ result = check_insert_atom_brick_info(node->subvol->id, ++ &abi); ++ if (result) { ++ jput(node); ++ return result; ++ } ++ spin_lock_jnode(node); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ } ++ BUG_ON(node->atom == NULL); ++ JF_CLR(node, JNODE_WRITE_PREPARED); ++ ++ if (get_current_context()->entd) { ++ entd_context *ent = get_entd_context(inode->i_sb); ++ ++ if (ent->cur_request->page == page) ++ /* the following reference will be ++ dropped in reiser4_writeout */ ++ ent->cur_request->node = jref(node); ++ } ++ jput(node); ++ return 0; ++} ++ ++/** ++ * has_anonymous_pages - check whether inode has pages dirtied via mmap ++ * @inode: inode to check ++ * ++ * Returns true if inode's mapping has dirty pages which do not belong to any ++ * atom. Those are either tagged PAGECACHE_TAG_REISER4_MOVED in mapping's page ++ * tree or were eflushed and can be found via jnodes tagged ++ * EFLUSH_TAG_ANONYMOUS in radix tree of jnodes. ++ */ ++static int has_anonymous_pages(struct inode *inode) ++{ ++ int result; ++ ++ xa_lock_irq(&inode->i_mapping->i_pages); ++ result = radix_tree_tagged(&inode->i_mapping->i_pages, ++ PAGECACHE_TAG_REISER4_MOVED); ++ xa_unlock_irq(&inode->i_mapping->i_pages); ++ return result; ++} ++ ++/** ++ * @page: page to be captured ++ */ ++static int reserve_capture_anon_page(void) ++{ ++ /* ++ * page capture may require extent creation (if it does not exist yet) ++ * and stat data's update (number of blocks changes on extent creation) ++ */ ++ grab_space_enable(); ++ return reiser4_grab_space(1 + ++ 2 * estimate_one_insert_into_item(meta_subvol_tree()), ++ BA_CAN_COMMIT, get_meta_subvol()); ++} ++ ++/* ++ * Support for "anonymous" pages and jnodes. ++ * ++ * When file is write-accessed through mmap pages can be dirtied from the user ++ * level. In this case kernel is not notified until one of following happens: ++ * ++ * (1) msync() ++ * ++ * (2) truncate() (either explicit or through unlink) ++ * ++ * (3) VM scanner starts reclaiming mapped pages, dirtying them before ++ * starting write-back. ++ * ++ * As a result of (3) ->writepage may be called on a dirty page without ++ * jnode. Such page is called "anonymous" in reiser4. Certain work-loads ++ * (iozone) generate huge number of anonymous pages. ++ * ++ * reiser4_sync_sb() method tries to insert anonymous pages into ++ * tree. This is done by capture_anonymous_*() functions below. ++ */ ++ ++/** ++ * involve page into transaction ++ * @pg: page to deal with ++ * ++ * Takes care that @page has corresponding metadata in the tree; ++ * creates jnode for @page and captures it. On success 1 is returned. ++ * Exclusive, or non-exclusive lock must be held. ++ */ ++static int capture_anon_page(struct page *page) ++{ ++ int ret; ++ struct inode *inode; ++ ++ if (PageWriteback(page)) ++ /* ++ * FIXME: do nothing? ++ */ ++ return 0; ++ assert("vs-1084", page->mapping && page->mapping->host); ++ ++ inode = page->mapping->host; ++ ++ assert("vs-1139", ++ unix_file_inode_data(inode)->container == UF_CONTAINER_EXTENTS); ++ assert("vs-1393", inode->i_size > page_offset(page)); ++ ++ ret = reserve_capture_anon_page(); ++ if (ret) ++ return ret; ++ ret = find_or_create_extent_unix_file(page); ++ if (ret) { ++ SetPageError(page); ++ warning("nikita-3329", ++ "Cannot capture anon page: %i", ret); ++ } else ++ ret = 1; ++ return ret; ++} ++ ++/** ++ * capture_anonymous_pages - find and capture pages dirtied via mmap ++ * @mapping: address space where to look for pages ++ * @index: start index ++ * @to_capture: maximum number of pages to capture ++ * @capture_anon_page_fn: method to capture one anonymous page ++ * ++ * Looks for pages tagged REISER4_MOVED starting from the *@index-th page, ++ * captures (involves into atom) them, returns number of captured pages, ++ * updates @index to next page after the last captured one. ++ */ ++static int capture_anon_pages(struct address_space *mapping, ++ pgoff_t *index, unsigned int to_capture, ++ int(*capture_anon_page_fn)(struct page *)) ++{ ++ int result; ++ struct pagevec pvec; ++ unsigned int i, count; ++ int nr; ++ ++ pagevec_init(&pvec); ++ count = min(pagevec_space(&pvec), to_capture); ++ nr = 0; ++ ++ /* find pages tagged MOVED */ ++ xa_lock_irq(&mapping->i_pages); ++ pvec.nr = radix_tree_gang_lookup_tag(&mapping->i_pages, ++ (void **)pvec.pages, *index, count, ++ PAGECACHE_TAG_REISER4_MOVED); ++ if (pagevec_count(&pvec) == 0) { ++ /* ++ * there are no pages tagged MOVED in mapping->page_tree ++ * starting from *index ++ */ ++ xa_unlock_irq(&mapping->i_pages); ++ *index = (pgoff_t)-1; ++ return 0; ++ } ++ ++ /* clear MOVED tag for all found pages */ ++ for (i = 0; i < pagevec_count(&pvec); i++) { ++ get_page(pvec.pages[i]); ++ radix_tree_tag_clear(&mapping->i_pages, pvec.pages[i]->index, ++ PAGECACHE_TAG_REISER4_MOVED); ++ } ++ xa_unlock_irq(&mapping->i_pages); ++ ++ ++ *index = pvec.pages[i - 1]->index + 1; ++ ++ for (i = 0; i < pagevec_count(&pvec); i++) { ++ result = capture_anon_page_fn(pvec.pages[i]); ++ if (result == 1) ++ nr++; ++ else { ++ if (result < 0) { ++ warning("vs-1454", ++ "failed to capture page: " ++ "result=%d, captured=%d)\n", ++ result, i); ++ ++ /* ++ * set MOVED tag to all pages which left not ++ * captured ++ */ ++ xa_lock_irq(&mapping->i_pages); ++ for (; i < pagevec_count(&pvec); i ++) { ++ radix_tree_tag_set(&mapping->i_pages, ++ pvec.pages[i]->index, ++ PAGECACHE_TAG_REISER4_MOVED); ++ } ++ xa_unlock_irq(&mapping->i_pages); ++ ++ pagevec_release(&pvec); ++ return result; ++ } else { ++ /* ++ * result == 0. capture_anonymous_page returns ++ * 0 for Writeback-ed page. Set MOVED tag on ++ * that page ++ */ ++ xa_lock_irq(&mapping->i_pages); ++ radix_tree_tag_set(&mapping->i_pages, ++ pvec.pages[i]->index, ++ PAGECACHE_TAG_REISER4_MOVED); ++ xa_unlock_irq(&mapping->i_pages); ++ if (i == 0) ++ *index = pvec.pages[0]->index; ++ else ++ *index = pvec.pages[i - 1]->index + 1; ++ } ++ } ++ } ++ pagevec_release(&pvec); ++ return nr; ++} ++ ++/** ++ * capture_anonymous_jnodes - find and capture anonymous jnodes ++ * @mapping: address space where to look for jnodes ++ * @from: start index ++ * @to: end index ++ * @to_capture: maximum number of jnodes to capture ++ * ++ * Looks for jnodes tagged EFLUSH_TAG_ANONYMOUS in inode's tree of jnodes in ++ * the range of indexes @from-@to and captures them, returns number of captured ++ * jnodes, updates @from to next jnode after the last captured one. ++ */ ++static int capture_anon_jnodes(struct address_space *mapping, ++ pgoff_t *from, pgoff_t to, int to_capture) ++{ ++ *from = to; ++ return 0; ++} ++ ++/* ++ * Commit atom of the jnode of a page. ++ */ ++int reiser4_sync_page(struct page *page) ++{ ++ int result; ++ do { ++ jnode *node; ++ txn_atom *atom; ++ ++ lock_page(page); ++ node = jprivate(page); ++ if (node != NULL) { ++ spin_lock_jnode(node); ++ atom = jnode_get_atom(node); ++ spin_unlock_jnode(node); ++ } else ++ atom = NULL; ++ unlock_page(page); ++ result = reiser4_sync_atom(atom); ++ } while (result == -E_REPEAT); ++ /* ++ * ZAM-FIXME-HANS: document the logic of this loop, is it just to ++ * handle the case where more pages get added to the atom while we are ++ * syncing it? ++ */ ++ assert("nikita-3485", ergo(result == 0, ++ get_current_context()->trans->atom == NULL)); ++ return result; ++} ++ ++/* ++ * Commit atoms of pages on @pages list. ++ * call sync_page for each page from mapping's page tree ++ */ ++int reiser4_sync_page_list(struct inode *inode) ++{ ++ int result; ++ struct address_space *mapping; ++ unsigned long from; /* start index for radix_tree_gang_lookup */ ++ unsigned int found; /* return value for radix_tree_gang_lookup */ ++ ++ mapping = inode->i_mapping; ++ from = 0; ++ result = 0; ++ ++ xa_lock_irq(&mapping->i_pages); ++ while (result == 0) { ++ struct page *page; ++ ++ found = radix_tree_gang_lookup(&mapping->i_pages, ++ (void **)&page, from, 1); ++ assert("edward-1550", found < 2); ++ if (found == 0) ++ break; ++ /** ++ * page may not leave radix tree because it is protected from ++ * truncating by inode->i_mutex locked by sys_fsync ++ */ ++ get_page(page); ++ xa_unlock_irq(&mapping->i_pages); ++ ++ from = page->index + 1; ++ ++ result = reiser4_sync_page(page); ++ ++ put_page(page); ++ xa_lock_irq(&mapping->i_pages); ++ } ++ xa_unlock_irq(&mapping->i_pages); ++ return result; ++} ++ ++static int commit_file_atoms(struct inode *inode) ++{ ++ int result; ++ struct unix_file_info *uf_info; ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ get_exclusive_access(uf_info); ++ /* ++ * find what items file is made from ++ */ ++ result = find_file_state(inode, uf_info); ++ drop_exclusive_access(uf_info); ++ if (result != 0) ++ return result; ++ ++ /* ++ * file state cannot change because we are under ->i_mutex ++ */ ++ switch (uf_info->container) { ++ case UF_CONTAINER_EXTENTS: ++ /* find_file_state might open join an atom */ ++ reiser4_txn_restart_current(); ++ result = ++ /* ++ * when we are called by ++ * filemap_fdatawrite-> ++ * do_writepages()-> ++ * reiser4_writepages_dispatch() ++ * ++ * inode->i_mapping->dirty_pages are spices into ++ * ->io_pages, leaving ->dirty_pages dirty. ++ * ++ * When we are called from ++ * reiser4_fsync()->sync_unix_file(), we have to ++ * commit atoms of all pages on the ->dirty_list. ++ * ++ * So for simplicity we just commit ->io_pages and ++ * ->dirty_pages. ++ */ ++ reiser4_sync_page_list(inode); ++ break; ++ case UF_CONTAINER_TAILS: ++ /* ++ * NOTE-NIKITA probably we can be smarter for tails. For now ++ * just commit all existing atoms. ++ */ ++ result = txnmgr_force_commit_all(inode->i_sb, 0); ++ break; ++ case UF_CONTAINER_EMPTY: ++ result = 0; ++ break; ++ case UF_CONTAINER_UNKNOWN: ++ default: ++ result = -EIO; ++ break; ++ } ++ ++ /* ++ * commit current transaction: there can be captured nodes from ++ * find_file_state() and finish_conversion(). ++ */ ++ reiser4_txn_restart_current(); ++ return result; ++} ++ ++/** ++ * This captures anonymous pages and anonymous jnodes. Anonymous pages are ++ * pages which are dirtied via mmapping. Anonymous jnodes are ones which were ++ * created by reiser4_writepage. ++ */ ++int reiser4_writepages_generic(struct address_space *mapping, ++ struct writeback_control *wbc, ++ int(*capture_anon_page_fn)(struct page *), ++ int(*commit_file_atoms_fn)(struct inode *)) ++{ ++ int result; ++ struct unix_file_info *uf_info; ++ pgoff_t pindex, jindex, nr_pages; ++ long to_capture; ++ struct inode *inode; ++ ++ inode = mapping->host; ++ if (!has_anonymous_pages(inode)) { ++ result = 0; ++ goto end; ++ } ++ jindex = pindex = wbc->range_start >> PAGE_SHIFT; ++ result = 0; ++ nr_pages = size_in_pages(i_size_read(inode)); ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ do { ++ reiser4_context *ctx; ++ ++ if (wbc->sync_mode != WB_SYNC_ALL) ++ to_capture = min(wbc->nr_to_write, CAPTURE_APAGE_BURST); ++ else ++ to_capture = CAPTURE_APAGE_BURST; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ result = PTR_ERR(ctx); ++ break; ++ } ++ /* avoid recursive calls to ->sync_inodes */ ++ ctx->nobalance = 1; ++ assert("zam-760", lock_stack_isclean(get_current_lock_stack())); ++ assert("edward-1551", LOCK_CNT_NIL(inode_sem_w)); ++ assert("edward-1552", LOCK_CNT_NIL(inode_sem_r)); ++ ++ reiser4_txn_restart_current(); ++ ++ /* we have to get nonexclusive access to the file */ ++ if (get_current_context()->entd) { ++ /* ++ * use nonblocking version of nonexclusive_access to ++ * avoid deadlock which might look like the following: ++ * process P1 holds NEA on file F1 and called entd to ++ * reclaim some memory. Entd works for P1 and is going ++ * to capture pages of file F2. To do that entd has to ++ * get NEA to F2. F2 is held by process P2 which also ++ * called entd. But entd is serving P1 at the moment ++ * and P2 has to wait. Process P3 trying to get EA to ++ * file F2. Existence of pending EA request to file F2 ++ * makes impossible for entd to get NEA to file ++ * F2. Neither of these process can continue. Using ++ * nonblocking version of gettign NEA is supposed to ++ * avoid this deadlock. ++ */ ++ if (try_to_get_nonexclusive_access(uf_info) == 0) { ++ result = RETERR(-EBUSY); ++ reiser4_exit_context(ctx); ++ break; ++ } ++ } else ++ get_nonexclusive_access(uf_info); ++ ++ while (to_capture > 0) { ++ pgoff_t start; ++ ++ assert("vs-1727", jindex <= pindex); ++ if (pindex == jindex) { ++ start = pindex; ++ result = capture_anon_pages(inode->i_mapping, ++ &pindex, ++ to_capture, ++ capture_anon_page_fn); ++ if (result <= 0) ++ break; ++ to_capture -= result; ++ wbc->nr_to_write -= result; ++ if (start + result == pindex) { ++ jindex = pindex; ++ continue; ++ } ++ if (to_capture <= 0) ++ break; ++ } ++ /* ++ * deal with anonymous jnodes between jindex and pindex ++ */ ++ result = capture_anon_jnodes(inode->i_mapping, ++ &jindex, ++ pindex, to_capture); ++ if (result < 0) ++ break; ++ to_capture -= result; ++ get_current_context()->nr_captured += result; ++ ++ if (jindex == (pgoff_t) - 1) { ++ assert("vs-1728", pindex == (pgoff_t) - 1); ++ break; ++ } ++ } ++ if (to_capture <= 0) ++ /* there may be left more pages */ ++ __mark_inode_dirty(inode, I_DIRTY_PAGES); ++ ++ drop_nonexclusive_access(uf_info); ++ if (result < 0) { ++ /* error happened */ ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ if (wbc->sync_mode != WB_SYNC_ALL) { ++ reiser4_exit_context(ctx); ++ return 0; ++ } ++ result = commit_file_atoms_fn(inode); ++ reiser4_exit_context(ctx); ++ if (pindex >= nr_pages && jindex == pindex) ++ break; ++ } while (1); ++ ++ end: ++ if (is_in_reiser4_context()) { ++ if (get_current_context()->nr_captured >= CAPTURE_APAGE_BURST) { ++ /* ++ * there are already pages to flush, flush them out, do ++ * not delay until end of reiser4_sync_inodes ++ */ ++ reiser4_writeout(inode->i_sb, wbc); ++ get_current_context()->nr_captured = 0; ++ } ++ } ++ return result; ++} ++ ++int writepages_unix_file(struct address_space *mapping, ++ struct writeback_control *wbc) ++{ ++ return reiser4_writepages_generic(mapping, wbc, ++ capture_anon_page, ++ commit_file_atoms); ++} ++ ++/** ++ * ->readpage() method of address space operations for unix-file plugin ++ */ ++int readpage_unix_file(struct file *file, struct page *page) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *inode; ++ reiser4_key key; ++ hint_t *hint; ++ lock_handle *lh; ++ coord_t *coord; ++ ++ assert("vs-1062", PageLocked(page)); ++ assert("vs-976", !PageUptodate(page)); ++ assert("vs-1061", page->mapping && page->mapping->host); ++ ++ inode = page->mapping->host; ++ ++ assert("edward-2087", inode_file_plugin(inode) == ++ file_plugin_by_id(UNIX_FILE_PLUGIN_ID)); ++ ++ if (inode->i_size <= page_offset(page)) { ++ /* page is out of file */ ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ unlock_page(page); ++ return 0; ++ } ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ unlock_page(page); ++ return PTR_ERR(ctx); ++ } ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) { ++ unlock_page(page); ++ reiser4_exit_context(ctx); ++ return RETERR(-ENOMEM); ++ } ++ ++ result = load_file_hint(file, hint); ++ if (result) { ++ kfree(hint); ++ unlock_page(page); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ lh = &hint->lh; ++ /* ++ * construct key of the page's first byte ++ */ ++ build_body_key_unix_file(inode, page_offset(page), &key); ++ /* ++ * look for file metadata corresponding to the page's first byte ++ */ ++ get_page(page); ++ unlock_page(page); ++ result = find_file_item(hint, &key, ZNODE_READ_LOCK, inode); ++ lock_page(page); ++ put_page(page); ++ ++ if (page->mapping == NULL) { ++ /* ++ * readpage allows truncate to run concurrently. ++ * Page was truncated while it was not locked ++ */ ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return -EINVAL; ++ } ++ if (result != CBK_COORD_FOUND || ++ hint->ext_coord.coord.between != AT_UNIT) { ++ ++ if (result == CBK_COORD_FOUND && ++ hint->ext_coord.coord.between != AT_UNIT) ++ /* file is truncated */ ++ result = -EINVAL; ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ /* ++ * item corresponding to page is found. ++ * It can not be removed because znode lock is held ++ */ ++ if (PageUptodate(page)) { ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return 0; ++ } ++ coord = &hint->ext_coord.coord; ++ result = zload(coord->node); ++ if (result) { ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ validate_extended_coord(&hint->ext_coord, page_offset(page)); ++ ++ if (!coord_is_existing_unit(coord)) { ++ /* this indicates corruption */ ++ warning("vs-280", ++ "Looking for page %lu of file %llu (size %lli). " ++ "No file items found (%d). File is corrupted?\n", ++ page->index, (unsigned long long)get_inode_oid(inode), ++ inode->i_size, result); ++ zrelse(coord->node); ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return RETERR(-EIO); ++ } ++ switch(item_plugin_by_coord(coord)->h.id) { ++ case EXTENT40_POINTER_ID: ++ result = reiser4_readpage_extent(coord, page); ++ break; ++ case FORMATTING_ID: ++ result = readpage_tail_unix_file(coord, page); ++ break; ++ default: ++ result = RETERR(-EINVAL); ++ } ++ if (!result) { ++ set_key_offset(&key, ++ (loff_t) (page->index + 1) << PAGE_SHIFT); ++ /* FIXME should call reiser4_set_hint() */ ++ reiser4_unset_hint(hint); ++ } else { ++ unlock_page(page); ++ reiser4_unset_hint(hint); ++ } ++ assert("vs-979", ++ ergo(result == 0, (PageLocked(page) || PageUptodate(page)))); ++ assert("vs-9791", ergo(result != 0, !PageLocked(page))); ++ ++ zrelse(coord->node); ++ done_lh(lh); ++ ++ save_file_hint(file, hint); ++ kfree(hint); ++ ++ /* ++ * FIXME: explain why it is needed. HINT: page allocation in write can ++ * not be done when atom is not NULL because reiser4_writepage can not ++ * kick entd and have to eflush ++ */ ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++struct uf_readpages_context { ++ lock_handle lh; ++ coord_t coord; ++}; ++ ++/** ++ * A callback function for readpages_unix_file/read_cache_pages. ++ * We don't take non-exclusive access. If an item different from ++ * extent pointer is found in some iteration, then return error ++ * (-EINVAL). ++ * ++ * FIXME-EDWARD: This function is suboptimal. We can collect information ++ * about the next unit/item in the node to save twig lock and hence to ++ * reduce a number of tree searches ++ * ++ * @data -- a pointer to reiser4_readpages_context object, to save the ++ * twig lock and the coord between read_cache_page iterations. ++ * @page -- page to start read against; ++ * @striped -- if true, then filler is called by striped file plugin. ++ */ ++int reiser4_readpages_filler_generic(void *data, ++ struct page *page, int striped) ++{ ++ int ret = 0; ++ reiser4_extent *ext; ++ __u64 ext_index; ++ int cbk_done = 0; ++ struct uf_readpages_context *rc = data; ++ struct address_space *mapping = page->mapping; ++ file_plugin *fplug = inode_file_plugin(mapping->host); ++ ++ if (PageUptodate(page)) { ++ unlock_page(page); ++ return 0; ++ } ++ get_page(page); ++ ++ if (rc->lh.node == 0) { ++ /* no twig lock - have to do tree search. */ ++ reiser4_key key; ++ repeat: ++ unlock_page(page); ++ ++ fplug->build_body_key(mapping->host, ++ page_offset(page), &key); ++ ++ ret = coord_by_key(meta_subvol_tree(), ++ &key, &rc->coord, &rc->lh, ++ ZNODE_READ_LOCK, FIND_EXACT, ++ TWIG_LEVEL, TWIG_LEVEL, CBK_UNIQUE, NULL); ++ if (unlikely(ret)) ++ goto exit; ++ lock_page(page); ++ if (PageUptodate(page)) ++ goto unlock; ++ cbk_done = 1; ++ } ++ ret = zload(rc->coord.node); ++ if (unlikely(ret)) ++ goto unlock; ++ if (!coord_is_existing_unit(&rc->coord)) { ++ /* ++ * extent pointer representing that block ++ * of data not found ++ */ ++ if (striped) { ++ /* hole in a file */ ++ ret = __reiser4_readpage_extent(NULL, NULL, 0, page); ++ zrelse(rc->coord.node); ++ done_lh(&rc->lh); ++ goto exit; ++ } else { ++ zrelse(rc->coord.node); ++ ret = RETERR(-ENOENT); ++ goto unlock; ++ } ++ } else if (!item_is_extent(&rc->coord)) { ++ /* ++ * ->readpages() is not defined for tail items ++ */ ++ zrelse(rc->coord.node); ++ ret = RETERR(-EINVAL); ++ goto unlock; ++ } ++ ext = extent_by_coord(&rc->coord); ++ ext_index = extent_unit_index(&rc->coord); ++ ++ if (page->index < ext_index || ++ page->index >= ext_index + extent_get_width(ext)) { ++ /* ++ * the page index doesn't belong to the extent unit ++ * which the coord points to - release the lock and ++ * repeat with tree search ++ */ ++ zrelse(rc->coord.node); ++ done_lh(&rc->lh); ++ /* ++ * we can be here after a CBK call only in case of ++ * corruption of the tree or the tree lookup ++ * algorithm bug ++ */ ++ if (unlikely(cbk_done)) { ++ ret = RETERR(-EIO); ++ goto unlock; ++ } ++ goto repeat; ++ } ++ ret = __reiser4_readpage_extent(&rc->coord, ++ ext, page->index - ext_index, ++ page); ++ zrelse(rc->coord.node); ++ if (likely(!ret)) ++ goto exit; ++ unlock: ++ unlock_page(page); ++ exit: ++ put_page(page); ++ return ret; ++} ++ ++static inline int readpages_filler_uf(void *data, struct page *page) ++{ ++ return reiser4_readpages_filler_generic(data, page, 0); ++} ++ ++/** ++ * readpages_unix_file - called by the readahead code, starts reading for each ++ * page of given list of pages ++ */ ++int reiser4_readpages_generic(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages, ++ int (*filler)(void *data, struct page *page)) ++{ ++ reiser4_context *ctx; ++ struct uf_readpages_context rc; ++ int ret; ++ ++ ctx = reiser4_init_context(mapping->host->i_sb); ++ if (IS_ERR(ctx)) { ++ put_pages_list(pages); ++ return PTR_ERR(ctx); ++ } ++ init_lh(&rc.lh); ++ ret = read_cache_pages(mapping, pages, filler, &rc); ++ done_lh(&rc.lh); ++ ++ context_set_commit_async(ctx); ++ /* close the transaction to protect further page allocation from deadlocks */ ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return ret; ++} ++ ++int readpages_unix_file(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages) ++{ ++ return reiser4_readpages_generic(file, mapping, pages, nr_pages, ++ readpages_filler_uf); ++} ++ ++/* this is called with nonexclusive access obtained, ++ file's container can not change */ ++static ssize_t do_read_compound_file(hint_t *hint, struct file *file, ++ char __user *buf, size_t count, ++ loff_t *off) ++{ ++ int result; ++ struct inode *inode; ++ flow_t flow; ++ coord_t *coord; ++ znode *loaded; ++ ++ inode = file_inode(file); ++ ++ /* build flow */ ++ result = flow_by_inode_unix_file(inode, buf, 1 /* user space */, ++ count, *off, READ_OP, &flow); ++ if (unlikely(result)) ++ return result; ++ ++ /* get seal and coord sealed with it from reiser4 private data ++ of struct file. The coord will tell us where our last read ++ of this file finished, and the seal will help to determine ++ if that location is still valid. ++ */ ++ coord = &hint->ext_coord.coord; ++ while (flow.length && result == 0) { ++ result = find_file_item(hint, &flow.key, ++ ZNODE_READ_LOCK, inode); ++ if (cbk_errored(result)) ++ /* error happened */ ++ break; ++ ++ if (coord->between != AT_UNIT) { ++ /* there were no items corresponding to given offset */ ++ done_lh(hint->ext_coord.lh); ++ break; ++ } ++ ++ loaded = coord->node; ++ result = zload(loaded); ++ if (unlikely(result)) { ++ done_lh(hint->ext_coord.lh); ++ break; ++ } ++ ++ if (hint->ext_coord.valid == 0) ++ validate_extended_coord(&hint->ext_coord, ++ get_key_offset(&flow.key)); ++ ++ assert("vs-4", hint->ext_coord.valid == 1); ++ assert("vs-33", hint->ext_coord.lh == &hint->lh); ++ ++ switch(item_plugin_by_coord(coord)->h.id) { ++ case EXTENT40_POINTER_ID: ++ result = read_extent_unix_file(file, &flow, hint); ++ break; ++ case FORMATTING_ID: ++ result = read_tail_unix_file(file, &flow, hint); ++ break; ++ default: ++ result = RETERR(-EINVAL); ++ } ++ zrelse(loaded); ++ done_lh(hint->ext_coord.lh); ++ } ++ return (count - flow.length) ? (count - flow.length) : result; ++} ++ ++static ssize_t read_compound_file(struct file*, char __user*, size_t, loff_t*); ++ ++/** ++ * unix-file specific ->read() method ++ * of struct file_operations. ++ */ ++ssize_t read_unix_file(struct file *file, char __user *buf, ++ size_t read_amount, loff_t *off) ++{ ++ reiser4_context *ctx; ++ ssize_t result; ++ struct inode *inode; ++ struct unix_file_info *uf_info; ++ ++ if (unlikely(read_amount == 0)) ++ return 0; ++ ++ inode = file_inode(file); ++ assert("vs-972", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ result = reserve_update_sd_common(inode); ++ if (unlikely(result != 0)) ++ goto out2; ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ if (uf_info->container == UF_CONTAINER_UNKNOWN) { ++ get_exclusive_access(uf_info); ++ result = find_file_state(inode, uf_info); ++ if (unlikely(result != 0)) ++ goto out; ++ } ++ else ++ get_nonexclusive_access(uf_info); ++ ++ switch (uf_info->container) { ++ case UF_CONTAINER_EXTENTS: ++ if (!reiser4_inode_get_flag(inode, REISER4_PART_MIXED)) { ++ result = new_sync_read(file, buf, read_amount, off); ++ break; ++ } ++ /* fall through */ ++ case UF_CONTAINER_TAILS: ++ case UF_CONTAINER_UNKNOWN: ++ result = read_compound_file(file, buf, read_amount, off); ++ break; ++ case UF_CONTAINER_EMPTY: ++ result = 0; ++ } ++ out: ++ drop_access(uf_info); ++ out2: ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* ++ * Read a file, which contains tails and, maybe, ++ * extents. ++ * ++ * Sometimes file can consist of items of both types ++ * (extents and tails). It can happen, e.g. because ++ * of failed tail conversion. Also the conversion code ++ * may release exclusive lock before calling ++ * balance_dirty_pages(). ++ * ++ * In this case applying a generic VFS library function ++ * would be suboptimal. We use our own "light-weigth" ++ * version below. ++ */ ++static ssize_t read_compound_file(struct file *file, char __user *buf, ++ size_t count, loff_t *off) ++{ ++ ssize_t result = 0; ++ struct inode *inode; ++ hint_t *hint; ++ struct unix_file_info *uf_info; ++ size_t to_read; ++ size_t was_read = 0; ++ loff_t i_size; ++ ++ inode = file_inode(file); ++ assert("vs-972", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ i_size = i_size_read(inode); ++ if (*off >= i_size) ++ /* position to read from is past the end of file */ ++ goto exit; ++ if (*off + count > i_size) ++ count = i_size - *off; ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) ++ return RETERR(-ENOMEM); ++ ++ result = load_file_hint(file, hint); ++ if (result) { ++ kfree(hint); ++ return result; ++ } ++ uf_info = unix_file_inode_data(inode); ++ ++ /* read by page-aligned chunks */ ++ to_read = PAGE_SIZE - (*off & (loff_t)(PAGE_SIZE - 1)); ++ if (to_read > count) ++ to_read = count; ++ while (count > 0) { ++ reiser4_txn_restart_current(); ++ /* ++ * faultin user page ++ */ ++ result = fault_in_pages_writeable(buf, to_read); ++ if (result) ++ return RETERR(-EFAULT); ++ ++ result = do_read_compound_file(hint, file, buf, to_read, off); ++ if (result < 0) ++ break; ++ count -= result; ++ buf += result; ++ ++ /* update position in a file */ ++ *off += result; ++ /* total number of read bytes */ ++ was_read += result; ++ to_read = count; ++ if (to_read > PAGE_SIZE) ++ to_read = PAGE_SIZE; ++ } ++ done_lh(&hint->lh); ++ save_file_hint(file, hint); ++ kfree(hint); ++ if (was_read) ++ file_accessed(file); ++ exit: ++ return was_read ? was_read : result; ++} ++ ++/* This function takes care about @file's pages. First of all it checks if ++ filesystems readonly and if so gets out. Otherwise, it throws out all ++ pages of file if it was mapped for read and going to be mapped for write ++ and consists of tails. This is done in order to not manage few copies ++ of the data (first in page cache and second one in tails them selves) ++ for the case of mapping files consisting tails. ++ ++ Here also tail2extent conversion is performed if it is allowed and file ++ is going to be written or mapped for write. This functions may be called ++ from write_unix_file() or mmap_unix_file(). */ ++static int check_pages_unix_file(struct file *file, struct inode *inode) ++{ ++ reiser4_invalidate_pages(inode->i_mapping, 0, ++ (inode->i_size + PAGE_SIZE - ++ 1) >> PAGE_SHIFT, 0); ++ return unpack(file, inode, 0 /* not forever */ ); ++} ++ ++/** ++ * mmap_unix_file - mmap of struct file_operations ++ * @file: file to mmap ++ * @vma: ++ * ++ * This is implementation of vfs's mmap method of struct file_operations for ++ * unix file plugin. It converts file to extent if necessary. Sets ++ * reiser4_inode's flag - REISER4_HAS_MMAP. ++ */ ++int mmap_unix_file(struct file *file, struct vm_area_struct *vma) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *inode; ++ struct unix_file_info *uf_info; ++ ++ inode = file_inode(file); ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ get_exclusive_access_careful(uf_info, inode); ++ ++ if (!IS_RDONLY(inode) && (vma->vm_flags & (VM_MAYWRITE | VM_SHARED))) { ++ /* ++ * we need file built of extent items. If it is still built of ++ * tail items we have to convert it. Find what items the file ++ * is built of ++ */ ++ result = find_file_state(inode, uf_info); ++ if (result != 0) { ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ assert("vs-1648", (uf_info->container == UF_CONTAINER_TAILS || ++ uf_info->container == UF_CONTAINER_EXTENTS || ++ uf_info->container == UF_CONTAINER_EMPTY)); ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ /* ++ * invalidate all pages and convert file from tails to ++ * extents ++ */ ++ result = check_pages_unix_file(file, inode); ++ if (result) { ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ } ++ } ++ /* ++ * generic_file_mmap will do update_atime. ++ * Grab space for stat data update. ++ */ ++ result = reserve_update_sd_common(inode); ++ if (result) { ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ result = generic_file_mmap(file, vma); ++ if (result == 0) { ++ /* mark file as having mapping. */ ++ reiser4_inode_set_flag(inode, REISER4_HAS_MMAP); ++ } ++ ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/** ++ * find_first_item ++ * @inode: ++ * ++ * Finds file item which is responsible for first byte in the file. ++ */ ++static int find_first_item(struct inode *inode) ++{ ++ coord_t coord; ++ lock_handle lh; ++ reiser4_key key; ++ int result; ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ inode_file_plugin(inode)->build_body_key(inode, 0, &key); ++ result = find_file_item_nohint(&coord, &lh, &key, ZNODE_READ_LOCK, ++ inode); ++ if (result == CBK_COORD_FOUND) { ++ if (coord.between == AT_UNIT) { ++ result = zload(coord.node); ++ if (result == 0) { ++ result = item_id_by_coord(&coord); ++ zrelse(coord.node); ++ if (result != EXTENT40_POINTER_ID && ++ result != FORMATTING_ID) ++ result = RETERR(-EIO); ++ } ++ } else ++ result = RETERR(-EIO); ++ } ++ done_lh(&lh); ++ return result; ++} ++ ++/** ++ * open_unix_file ++ * @inode: ++ * @file: ++ * ++ * If filesystem is not readonly - complete uncompleted tail conversion if ++ * there was one ++ */ ++int open_unix_file(struct inode *inode, struct file *file) ++{ ++ int result; ++ reiser4_context *ctx; ++ struct unix_file_info *uf_info; ++ ++ if (IS_RDONLY(inode)) ++ return 0; ++ ++ if (!reiser4_inode_get_flag(inode, REISER4_PART_MIXED)) ++ return 0; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ get_exclusive_access_careful(uf_info, inode); ++ ++ if (!reiser4_inode_get_flag(inode, REISER4_PART_MIXED)) { ++ /* ++ * other process completed the conversion ++ */ ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return 0; ++ } ++ ++ /* ++ * file left in semi converted state after unclean shutdown or another ++ * thread is doing conversion and dropped exclusive access which doing ++ * balance dirty pages. Complete the conversion ++ */ ++ result = find_first_item(inode); ++ if (result == EXTENT40_POINTER_ID) ++ /* ++ * first item is extent, therefore there was incomplete ++ * tail2extent conversion. Complete it ++ */ ++ result = tail2extent(unix_file_inode_data(inode)); ++ else if (result == FORMATTING_ID) ++ /* ++ * first item is formatting item, therefore there was ++ * incomplete extent2tail conversion. Complete it ++ */ ++ result = extent2tail(file, unix_file_inode_data(inode)); ++ else ++ result = -EIO; ++ ++ assert("vs-1712", ++ ergo(result == 0, ++ (!reiser4_inode_get_flag(inode, REISER4_PART_MIXED) && ++ !reiser4_inode_get_flag(inode, REISER4_PART_IN_CONV)))); ++ drop_exclusive_access(uf_info); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++#define NEITHER_OBTAINED 0 ++#define EA_OBTAINED 1 ++#define NEA_OBTAINED 2 ++ ++static void drop_access(struct unix_file_info *uf_info) ++{ ++ if (uf_info->exclusive_use) ++ drop_exclusive_access(uf_info); ++ else ++ drop_nonexclusive_access(uf_info); ++} ++ ++#define debug_wuf(format, ...) printk("%s: %d: %s: " format "\n", \ ++ __FILE__, __LINE__, __FUNCTION__, ## __VA_ARGS__) ++ ++/** ++ * write_unix_file - private ->write() method of unix_file plugin. ++ * ++ * @file: file to write to ++ * @buf: address of user-space buffer ++ * @count: number of bytes to write ++ * @pos: position in file to write to ++ * @cont: unused argument, as we don't perform plugin conversion when being ++ * managed by unix_file plugin. ++ */ ++ssize_t write_unix_file(struct file *file, ++ const char __user *buf, ++ size_t count, loff_t *pos, ++ struct dispatch_context *cont) ++{ ++ int result; ++ reiser4_context *ctx; ++ struct inode *inode; ++ struct unix_file_info *uf_info; ++ ssize_t written; ++ int to_write = PAGE_SIZE * DEFAULT_WRITE_GRANULARITY; ++ size_t left; ++ ssize_t (*write_op)(struct file *, struct inode *, ++ const char __user *, size_t, ++ loff_t *pos); ++ int ea; ++ int enospc = 0; /* item plugin ->write() returned ENOSPC */ ++ loff_t new_size; ++ ++ ctx = get_current_context(); ++ inode = file_inode(file); ++ ++ assert("vs-947", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ assert("vs-9471", (!reiser4_inode_get_flag(inode, REISER4_PART_MIXED))); ++ ++ result = file_remove_privs(file); ++ if (result) { ++ context_set_commit_async(ctx); ++ return result; ++ } ++ /* remove_suid might create a transaction */ ++ reiser4_txn_restart(ctx); ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ written = 0; ++ left = count; ++ ea = NEITHER_OBTAINED; ++ enospc = 0; ++ ++ new_size = i_size_read(inode); ++ if (*pos + count > new_size) ++ new_size = *pos + count; ++ ++ while (left) { ++ int update_sd = 0; ++ if (left < to_write) ++ to_write = left; ++ ++ if (uf_info->container == UF_CONTAINER_EMPTY) { ++ get_exclusive_access(uf_info); ++ ea = EA_OBTAINED; ++ if (uf_info->container != UF_CONTAINER_EMPTY) { ++ /* file is made not empty by another process */ ++ drop_exclusive_access(uf_info); ++ ea = NEITHER_OBTAINED; ++ continue; ++ } ++ } else if (uf_info->container == UF_CONTAINER_UNKNOWN) { ++ /* ++ * get exclusive access directly just to not have to ++ * re-obtain it if file will appear empty ++ */ ++ get_exclusive_access(uf_info); ++ ea = EA_OBTAINED; ++ result = find_file_state(inode, uf_info); ++ if (result) { ++ drop_exclusive_access(uf_info); ++ ea = NEITHER_OBTAINED; ++ break; ++ } ++ } else { ++ get_nonexclusive_access(uf_info); ++ ea = NEA_OBTAINED; ++ } ++ ++ /* either EA or NEA is obtained. Choose item write method */ ++ if (uf_info->container == UF_CONTAINER_EXTENTS) { ++ /* file is built of extent items */ ++ write_op = write_extent_unix_file; ++ } else if (uf_info->container == UF_CONTAINER_EMPTY) { ++ /* file is empty */ ++ if (should_have_notail(uf_info, new_size)) ++ write_op = write_extent_unix_file; ++ else ++ write_op = write_tail_unix_file; ++ } else { ++ /* file is built of tail items */ ++ if (should_have_notail(uf_info, new_size)) { ++ if (ea == NEA_OBTAINED) { ++ drop_nonexclusive_access(uf_info); ++ get_exclusive_access(uf_info); ++ ea = EA_OBTAINED; ++ } ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ /* ++ * if file is being convered by another ++ * process - wait until it completes ++ */ ++ while (1) { ++ if (reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)) { ++ drop_exclusive_access(uf_info); ++ schedule(); ++ get_exclusive_access(uf_info); ++ continue; ++ } ++ break; ++ } ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ result = tail2extent(uf_info); ++ if (result) { ++ drop_exclusive_access(uf_info); ++ context_set_commit_async(ctx); ++ break; ++ } ++ } ++ } ++ drop_exclusive_access(uf_info); ++ ea = NEITHER_OBTAINED; ++ continue; ++ } ++ write_op = write_tail_unix_file; ++ } ++ ++ written = write_op(file, inode, buf, to_write, pos); ++ if (written == -ENOSPC && !enospc) { ++ drop_access(uf_info); ++ txnmgr_force_commit_all(inode->i_sb, 0); ++ enospc = 1; ++ continue; ++ } ++ if (written < 0) { ++ /* ++ * If this is -ENOSPC, then it happened ++ * second time, so don't try to free space ++ * once again. ++ */ ++ drop_access(uf_info); ++ result = written; ++ break; ++ } ++ /* something is written. */ ++ if (enospc) ++ enospc = 0; ++ if (uf_info->container == UF_CONTAINER_EMPTY) { ++ assert("edward-1553", ea == EA_OBTAINED); ++ uf_info->container = ++ (write_op == write_extent_unix_file) ? ++ UF_CONTAINER_EXTENTS : UF_CONTAINER_TAILS; ++ } ++ assert("edward-1554", ++ ergo(uf_info->container == UF_CONTAINER_EXTENTS, ++ write_op == write_extent_unix_file)); ++ assert("edward-1555", ++ ergo(uf_info->container == UF_CONTAINER_TAILS, ++ write_op == write_tail_unix_file)); ++ if (*pos + written > inode->i_size) { ++ INODE_SET_FIELD(inode, i_size, *pos + written); ++ update_sd = 1; ++ } ++ if (!IS_NOCMTIME(inode)) { ++ inode->i_ctime = inode->i_mtime = current_time(inode); ++ update_sd = 1; ++ } ++ if (update_sd) { ++ /* ++ * space for update_sd was reserved in write_op ++ */ ++ result = reiser4_update_sd(inode); ++ if (result) { ++ warning("edward-1574", ++ "Can not update stat-data: %i. FSCK?", ++ result); ++ drop_access(uf_info); ++ context_set_commit_async(ctx); ++ break; ++ } ++ } ++ drop_access(uf_info); ++ ea = NEITHER_OBTAINED; ++ ++ /* ++ * tell VM how many pages were dirtied. Maybe number of pages ++ * which were dirty already should not be counted ++ */ ++ reiser4_throttle_write(inode); ++ left -= written; ++ buf += written; ++ *pos += written; ++ } ++ if (result == 0 && ((file->f_flags & O_SYNC) || IS_SYNC(inode))) { ++ reiser4_txn_restart_current(); ++ grab_space_enable(); ++ result = reiser4_sync_file_common(file, 0, LONG_MAX, ++ 0 /* data and stat data */); ++ if (result) ++ warning("reiser4-7", "failed to sync file %llu", ++ (unsigned long long)get_inode_oid(inode)); ++ } ++ /* ++ * return number of written bytes or error code if nothing is ++ * written. Note, that it does not work correctly in case when ++ * sync_unix_file returns error ++ */ ++ return (count - left) ? (count - left) : result; ++} ++ ++/** ++ * release_unix_file - release of struct file_operations ++ * @inode: inode of released file ++ * @file: file to release ++ * ++ * Implementation of release method of struct file_operations for unix file ++ * plugin. If last reference to indode is released - convert all extent items ++ * into tail items if necessary. Frees reiser4 specific file data. ++ */ ++int release_unix_file(struct inode *inode, struct file *file) ++{ ++ reiser4_context *ctx; ++ struct unix_file_info *uf_info; ++ int result; ++ int in_reiser4; ++ ++ in_reiser4 = is_in_reiser4_context(); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ result = 0; ++ if (in_reiser4 == 0) { ++ uf_info = unix_file_inode_data(inode); ++ ++ get_exclusive_access_careful(uf_info, inode); ++ if (file->f_path.dentry->d_lockref.count == 1 && ++ uf_info->container == UF_CONTAINER_EXTENTS && ++ !should_have_notail(uf_info, inode->i_size) && ++ !IS_RDONLY(inode)) { ++ result = extent2tail(file, uf_info); ++ if (result != 0) { ++ context_set_commit_async(ctx); ++ warning("nikita-3233", ++ "Failed (%d) to convert in %s (%llu)", ++ result, __FUNCTION__, ++ (unsigned long long) ++ get_inode_oid(inode)); ++ } ++ } ++ drop_exclusive_access(uf_info); ++ } else { ++ /* ++ we are within reiser4 context already. How latter is ++ possible? Simple: ++ ++ (gdb) bt ++ #0 get_exclusive_access () ++ #2 0xc01e56d3 in release_unix_file () ++ #3 0xc01c3643 in reiser4_release () ++ #4 0xc014cae0 in __fput () ++ #5 0xc013ffc3 in remove_vm_struct () ++ #6 0xc0141786 in exit_mmap () ++ #7 0xc0118480 in mmput () ++ #8 0xc0133205 in oom_kill () ++ #9 0xc01332d1 in out_of_memory () ++ #10 0xc013bc1d in try_to_free_pages () ++ #11 0xc013427b in __alloc_pages () ++ #12 0xc013f058 in do_anonymous_page () ++ #13 0xc013f19d in do_no_page () ++ #14 0xc013f60e in handle_mm_fault () ++ #15 0xc01131e5 in do_page_fault () ++ #16 0xc0104935 in error_code () ++ #17 0xc025c0c6 in __copy_to_user_ll () ++ #18 0xc01d496f in reiser4_read_tail () ++ #19 0xc01e4def in read_unix_file () ++ #20 0xc01c3504 in reiser4_read () ++ #21 0xc014bd4f in vfs_read () ++ #22 0xc014bf66 in sys_read () ++ */ ++ warning("vs-44", "out of memory?"); ++ } ++ ++ reiser4_free_file_fsdata(file); ++ ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++static void set_file_notail(struct inode *inode) ++{ ++ reiser4_inode *state; ++ formatting_plugin *tplug; ++ ++ state = reiser4_inode_data(inode); ++ tplug = formatting_plugin_by_id(NEVER_TAILS_FORMATTING_ID); ++ force_plugin_pset(inode, PSET_FORMATTING, (reiser4_plugin *)tplug); ++} ++ ++/* if file is built of tails - convert it to extents */ ++static int unpack(struct file *filp, struct inode *inode, int forever) ++{ ++ int result = 0; ++ struct unix_file_info *uf_info; ++ ++ uf_info = unix_file_inode_data(inode); ++ assert("vs-1628", ea_obtained(uf_info)); ++ ++ result = find_file_state(inode, uf_info); ++ if (result) ++ return result; ++ assert("vs-1074", uf_info->container != UF_CONTAINER_UNKNOWN); ++ ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ /* ++ * if file is being convered by another process - wait until it ++ * completes ++ */ ++ while (1) { ++ if (reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)) { ++ drop_exclusive_access(uf_info); ++ schedule(); ++ get_exclusive_access(uf_info); ++ continue; ++ } ++ break; ++ } ++ if (uf_info->container == UF_CONTAINER_TAILS) { ++ result = tail2extent(uf_info); ++ if (result) ++ return result; ++ } ++ } ++ if (forever) { ++ /* safe new formatting plugin in stat data */ ++ __u64 tograb; ++ ++ set_file_notail(inode); ++ ++ grab_space_enable(); ++ tograb = inode_file_plugin(inode)->estimate.update(inode); ++ result = reiser4_grab_space(tograb, ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (result) { ++ warning("edward-1781", ++ "Can not update sd (%d)", result); ++ return result; ++ } ++ result = reiser4_update_sd(inode); ++ } ++ ++ return result; ++} ++ ++/* implentation of vfs' ioctl method of struct file_operations for unix file ++ plugin ++*/ ++int ioctl_unix_file(struct file *filp, unsigned int cmd, ++ unsigned long arg UNUSED_ARG) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *inode = filp->f_path.dentry->d_inode; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ switch (cmd) { ++ case REISER4_IOC_UNPACK: ++ get_exclusive_access(unix_file_inode_data(inode)); ++ result = unpack(filp, inode, 1 /* forever */ ); ++ drop_exclusive_access(unix_file_inode_data(inode)); ++ break; ++ ++ default: ++ result = RETERR(-ENOTTY); ++ break; ++ } ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* implentation of vfs' bmap method of struct address_space_operations for unix ++ file plugin ++*/ ++sector_t bmap_unix_file(struct address_space * mapping, sector_t lblock) ++{ ++ reiser4_context *ctx; ++ sector_t result; ++ reiser4_key key; ++ coord_t coord; ++ lock_handle lh; ++ struct inode *inode; ++ item_plugin *iplug; ++ sector_t block; ++ ++ inode = mapping->host; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ build_body_key_unix_file(inode, ++ (loff_t) lblock * current_blocksize, ++ &key); ++ init_lh(&lh); ++ result = ++ find_file_item_nohint(&coord, &lh, &key, ZNODE_READ_LOCK, inode); ++ if (cbk_errored(result)) { ++ done_lh(&lh); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ result = zload(coord.node); ++ if (result) { ++ done_lh(&lh); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ iplug = item_plugin_by_coord(&coord); ++ if (iplug->s.file.get_block) { ++ result = iplug->s.file.get_block(&coord, lblock, &block); ++ if (result == 0) ++ result = block; ++ } else ++ result = RETERR(-EINVAL); ++ ++ zrelse(coord.node); ++ done_lh(&lh); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++int build_body_key_unix_file(struct inode *inode, loff_t off, reiser4_key *key) ++{ ++ build_body_key_common(inode, key); ++ set_key_ordering(key, get_inode_ordering(inode)); ++ set_key_offset(key, (__u64) off); ++ return 0; ++} ++ ++/** ++ * Construct flow into @flow according to user-supplied data. ++ * This is used by read/write methods to construct a flow to read/write. ++ * ++ * NIKITA-FIXME-HANS: please create statistics on what functions are ++ * dereferenced how often for the mongo benchmark. You can supervise ++ * Elena doing this for you if that helps. Email me the list of the ++ * top 10, with their counts, and an estimate of the total number of ++ * CPU cycles spent dereferencing as a percentage of CPU cycles spent ++ * processing (non-idle processing). If the total percent is, say, ++ * less than 1%, it will make our coding discussions much easier, and ++ * keep me from questioning whether functions like the below are too ++ * frequently called to be dereferenced. If the total percent is more ++ * than 1%, perhaps private methods should be listed in a "required" ++ * comment at the top of each plugin (with stern language about how if ++ * the comment is missing it will not be accepted by the maintainer), ++ * and implemented using macros not dereferenced functions. How about ++ * replacing this whole private methods part of the struct with a ++ * thorough documentation of what the standard helper functions are for ++ * use in constructing plugins? I think users have been asking for ++ * that, though not in so many words. ++ * ++ * flow_by_inode_unix_file - initizlize structure flow ++ * @inode: inode of file for which read or write is abou ++ * @buf: buffer to perform read to or write from ++ * @user: flag showing whether @buf is user space or kernel space ++ * @size: size of buffer @buf ++ * @off: start offset fro read or write ++ * @op: READ or WRITE ++ * @flow: ++ * ++ * Initializes fields of @flow: key, size of data, i/o mode (read or write). ++ */ ++int flow_by_inode_unix_file(struct inode *inode, ++ const char __user *buf, int user, ++ loff_t size, loff_t off, ++ rw_op op, flow_t *flow) ++{ ++ assert("nikita-1100", inode != NULL); ++ ++ flow->length = size; ++ memcpy(&flow->data, &buf, sizeof(buf)); ++ flow->user = user; ++ flow->op = op; ++ assert("nikita-1931", inode_file_plugin(inode) != NULL); ++ /* ++ * calculate key of write position and insert it into flow->key ++ */ ++ return build_body_key_unix_file(inode, off, &flow->key); ++} ++ ++/* plugin->u.file.set_plug_in_sd = NULL ++ plugin->u.file.set_plug_in_inode = NULL ++ plugin->u.file.create_blank_sd = NULL */ ++/* plugin->u.file.delete */ ++/* ++ plugin->u.file.add_link = reiser4_add_link_common ++ plugin->u.file.rem_link = NULL */ ++ ++/* plugin->u.file.owns_item ++ this is common_file_owns_item with assertion */ ++/* Audited by: green(2002.06.15) */ ++int ++owns_item_unix_file(const struct inode *inode /* object to check against */ , ++ const coord_t * coord /* coord to check */ ) ++{ ++ int result; ++ ++ result = owns_item_common(inode, coord); ++ if (!result) ++ return 0; ++ if (!plugin_of_group(item_plugin_by_coord(coord), ++ FILE_BODY_ITEM_TYPE)) ++ return 0; ++ assert("vs-547", ++ item_is_extent(coord) || ++ item_id_by_coord(coord) == FORMATTING_ID); ++ return 1; ++} ++ ++static int setattr_truncate(struct inode *inode, struct iattr *attr, ++ int (*truncate_file_body_fn)(struct inode *, ++ struct iattr *)) ++{ ++ int result; ++ int s_result; ++ loff_t old_size; ++ struct super_block *super = reiser4_get_current_sb(); ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ inode_check_scale(inode, inode->i_size, attr->ia_size); ++ ++ old_size = inode->i_size; ++ ++ result = safe_link_grab(super, BA_CAN_COMMIT, subv); ++ if (result == 0) ++ result = safe_link_add(inode, SAFE_TRUNCATE); ++ if (result == 0) ++ result = truncate_file_body_fn(inode, attr); ++ if (result) ++ warning("vs-1588", "truncate_file failed: oid %lli, " ++ "old size %lld, new size %lld, retval %d", ++ (unsigned long long)get_inode_oid(inode), ++ old_size, attr->ia_size, result); ++ ++ s_result = safe_link_grab(super, BA_CAN_COMMIT, subv); ++ if (s_result == 0) ++ s_result = safe_link_del(subv, ++ get_inode_oid(inode), ++ SAFE_TRUNCATE); ++ if (s_result != 0) { ++ warning("nikita-3417", "Cannot kill safelink %lli: %i", ++ (unsigned long long)get_inode_oid(inode), s_result); ++ } ++ safe_link_release(super); ++ return result; ++} ++ ++/** ++ * @dentry: object to change attributes; ++ * @attr: change description; ++ * @truncate_body_fn: method of truncating file body ++ */ ++int reiser4_setattr_generic(struct dentry *dentry, struct iattr *attr, ++ int (*truncate_file_body_fn)(struct inode *, ++ struct iattr *)) ++{ ++ int result; ++ ++ if (attr->ia_valid & ATTR_SIZE) { ++ reiser4_context *ctx; ++ struct unix_file_info *uf_info; ++ /* ++ * truncate does reservation itself and ++ * requires exclusive access obtained ++ */ ++ ctx = reiser4_init_context(dentry->d_inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ uf_info = unix_file_inode_data(dentry->d_inode); ++ get_exclusive_access_careful(uf_info, dentry->d_inode); ++ result = setattr_truncate(dentry->d_inode, ++ attr, truncate_file_body_fn); ++ drop_exclusive_access(uf_info); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ } else ++ result = reiser4_setattr_common(dentry, attr); ++ ++ return result; ++} ++ ++int setattr_unix_file(struct dentry *dentry, struct iattr *attr) ++{ ++ return reiser4_setattr_generic(dentry, attr, truncate_body_unix_file); ++} ++ ++void init_inode_data_unix_file(struct inode *inode, ++ reiser4_object_create_data *crd, ++ const reiser4_key *sd_key, int create) ++{ ++ struct unix_file_info *data; ++ ++ data = unix_file_inode_data(inode); ++ data->container = create ? UF_CONTAINER_EMPTY : UF_CONTAINER_UNKNOWN; ++ init_rwsem(&data->latch); ++ data->tplug = inode_formatting_plugin(inode); ++ data->exclusive_use = 0; ++#if REISER4_DEBUG ++ data->ea_owner = NULL; ++ atomic_set(&data->nr_neas, 0); ++#endif ++ init_inode_ordering(inode, crd, sd_key, create); ++} ++ ++/** ++ * delete_unix_file - delete_object of file_plugin ++ * @inode: inode to be deleted ++ * ++ * Truncates file to length 0, removes stat data and safe link. ++ */ ++int delete_object_unix_file(struct inode *inode) ++{ ++ struct unix_file_info *uf_info; ++ int result; ++ ++ if (reiser4_inode_get_flag(inode, REISER4_NO_SD)) ++ return 0; ++ ++ /* truncate file body first */ ++ uf_info = unix_file_inode_data(inode); ++ get_exclusive_access(uf_info); ++ result = shorten_file(inode, 0 /* size */ ); ++ drop_exclusive_access(uf_info); ++ ++ if (result) ++ warning("edward-1556", ++ "failed to truncate file (%llu) on removal: %d", ++ get_inode_oid(inode), result); ++ ++ /* remove stat data and safe link */ ++ return reiser4_delete_object_common(inode); ++} ++ ++int reiser4_write_begin_common(struct file *file, struct page *page, ++ loff_t pos, unsigned len, ++ int(*readpage_fn)(struct file *, struct page *)) ++{ ++ int ret; ++ if (len == PAGE_SIZE || PageUptodate(page)) ++ return 0; ++ ++ ret = readpage_fn(file, page); ++ if (ret) { ++ SetPageError(page); ++ ClearPageUptodate(page); ++ /* All reiser4 readpage() implementations should return the ++ * page locked in case of error. */ ++ assert("nikita-3472", PageLocked(page)); ++ return ret; ++ } ++ /* ++ * ->readpage() either: ++ * ++ * 1. starts IO against @page. @page is locked for IO in ++ * this case. ++ * ++ * 2. doesn't start IO. @page is unlocked. ++ * ++ * In either case, page should be locked. ++ */ ++ lock_page(page); ++ /* ++ * IO (if any) is completed at this point. Check for IO ++ * errors. ++ */ ++ if (!PageUptodate(page)) ++ return RETERR(-EIO); ++ return ret; ++} ++ ++/** ++ * Estimate and reserve space needed for write_end_unix_file(): ++ * one block for page itself, and one item insertion which may ++ * happen if page corresponds to hole extent and unallocated one ++ * will have to be created. ++ * @inode: object that the page belongs to; ++ * @index: index of the page. ++ */ ++static int reserve_write_begin(void) ++{ ++ grab_space_enable(); ++ return reiser4_grab_space(1 + ++ estimate_one_insert_into_item(meta_subvol_tree()), ++ BA_CAN_COMMIT, get_meta_subvol()); ++} ++ ++/** ++ * implementation of ->write_begin() address space operation ++ * for unix-file plugin ++ */ ++int write_begin_unix_file(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata) ++{ ++ int ret; ++ struct inode * inode; ++ struct unix_file_info *info; ++ ++ inode = file_inode(file); ++ info = unix_file_inode_data(inode); ++ ++ ret = reserve_write_begin(); ++ if (ret) ++ return ret; ++ get_exclusive_access(info); ++ ret = find_file_state(file_inode(file), info); ++ if (unlikely(ret != 0)) { ++ drop_exclusive_access(info); ++ return ret; ++ } ++ if (info->container == UF_CONTAINER_TAILS) { ++ ret = tail2extent(info); ++ if (ret) { ++ warning("edward-1575", ++ "tail conversion failed: %d", ret); ++ drop_exclusive_access(info); ++ return ret; ++ } ++ } ++ ret = reiser4_write_begin_common(file, page, pos, len, ++ readpage_unix_file); ++ if (unlikely(ret != 0)) ++ drop_exclusive_access(info); ++ /* else exclusive access will be dropped in ->write_end() */ ++ return ret; ++} ++ ++/** ++ * ->write_end() address space operation for unix-files ++ */ ++int write_end_unix_file(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata) ++{ ++ int ret; ++ struct inode *inode; ++ struct unix_file_info *info; ++ ++ inode = file_inode(file); ++ info = unix_file_inode_data(inode); ++ ++ unlock_page(page); ++ ret = find_or_create_extent_unix_file(page); ++ if (ret) { ++ SetPageError(page); ++ goto exit; ++ } ++ if (pos + copied > inode->i_size) { ++ INODE_SET_FIELD(inode, i_size, pos + copied); ++ ret = reiser4_update_sd(inode); ++ if (unlikely(ret != 0)) ++ warning("edward-1604", ++ "Can not update stat-data: %i. FSCK?", ++ ret); ++ } ++ exit: ++ drop_exclusive_access(unix_file_inode_data(file_inode(file))); ++ return ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/file_conversion.c linux-5.10.2/fs/reiser4/plugin/file/file_conversion.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/file_conversion.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/file_conversion.c 2020-12-23 16:07:46.124813217 +0100 +@@ -0,0 +1,762 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, ++ licensing governed by reiser4/README */ ++ ++/** ++ * This file contains dispatching hooks, and conversion methods, which ++ * implement transitions in the FILE interface. ++ * ++ * Dispatching hook makes a decision (at dispatching point) about the ++ * most reasonable plugin. Such decision is made in accordance with some ++ * O(1)-heuristic. ++ * ++ * We implement a transition CRYPTCOMPRESS -> UNIX_FILE for files with ++ * incompressible data. Current heuristic to estimate compressibility is ++ * very simple: if first complete logical cluster (64K by default) of a ++ * file is incompressible, then we make a decision, that the whole file ++ * is incompressible. ++ * ++ * To enable dispatching we install a special "magic" compression mode ++ * plugin CONVX_COMPRESSION_MODE_ID at file creation time. ++ * ++ * Note, that we don't perform back conversion (UNIX_FILE->CRYPTCOMPRESS) ++ * because of compatibility reasons). ++ * ++ * In conversion time we protect CS, the conversion set (file's (meta)data ++ * and plugin table (pset)) via special per-inode rw-semaphore (conv_sem). ++ * The methods which implement conversion are CS writers. The methods of FS ++ * interface (file_operations, inode_operations, address_space_operations) ++ * are CS readers. ++ */ ++ ++#include ++#include "../../inode.h" ++#include "../cluster.h" ++#include "file.h" ++ ++#define conversion_enabled(inode) \ ++ (inode_compression_mode_plugin(inode) == \ ++ compression_mode_plugin_by_id(CONVX_COMPRESSION_MODE_ID)) ++ ++/** ++ * Located sections (readers and writers of @pset) are not permanently ++ * critical: cryptcompress file can be converted only if the conversion ++ * is enabled (see the macrio above). Also we don't perform back ++ * conversion. The following helper macro is a sanity check to decide ++ * if we need the protection (locks are always additional overheads). ++ */ ++#define should_protect(inode) \ ++ (inode_file_plugin(inode) == \ ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID) && \ ++ conversion_enabled(inode)) ++/** ++ * To avoid confusion with read/write file operations, we'll speak about ++ * "passive" protection for FCS readers and "active" protection for FCS ++ * writers. All methods with active or passive protection have suffix ++ * "careful". ++ */ ++/** ++ * Macros for passive protection. ++ * ++ * Construct invariant operation to be supplied to VFS. ++ * The macro accepts the following lexemes: ++ * @type - type of the value represented by the compound statement; ++ * @method - name of an operation to be supplied to VFS (reiser4 file ++ * plugin also should contain a method with such name). ++ */ ++#define PROT_PASSIVE(type, method, args) \ ++({ \ ++ type _result; \ ++ struct rw_semaphore * guard = \ ++ &reiser4_inode_data(inode)->conv_sem; \ ++ \ ++ if (should_protect(inode)) { \ ++ down_read(guard); \ ++ if (!should_protect(inode)) \ ++ up_read(guard); \ ++ } \ ++ _result = inode_file_plugin(inode)->method args; \ ++ if (should_protect(inode)) \ ++ up_read(guard); \ ++ _result; \ ++}) ++ ++#define PROT_PASSIVE_VOID(method, args) \ ++({ \ ++ struct rw_semaphore * guard = \ ++ &reiser4_inode_data(inode)->conv_sem; \ ++ \ ++ if (should_protect(inode)) { \ ++ down_read(guard); \ ++ if (!should_protect(inode)) \ ++ up_read(guard); \ ++ } \ ++ inode_file_plugin(inode)->method args; \ ++ \ ++ if (should_protect(inode)) \ ++ up_read(guard); \ ++}) ++ ++/* Pass management to the unix-file plugin with "notail" policy */ ++static int __cryptcompress2unixfile(struct file *file, struct inode * inode) ++{ ++ int result; ++ reiser4_inode *info; ++ struct unix_file_info * uf; ++ info = reiser4_inode_data(inode); ++ ++ result = aset_set_unsafe(&info->pset, ++ PSET_FILE, ++ (reiser4_plugin *) ++ file_plugin_by_id(UNIX_FILE_PLUGIN_ID)); ++ if (result) ++ return result; ++ result = aset_set_unsafe(&info->pset, ++ PSET_FORMATTING, ++ (reiser4_plugin *) ++ formatting_plugin_by_id(NEVER_TAILS_FORMATTING_ID)); ++ if (result) ++ return result; ++ /* get rid of non-standard plugins */ ++ info->plugin_mask &= ~cryptcompress_mask; ++ /* get rid of plugin stat-data extension */ ++ info->extmask &= ~(1 << PLUGIN_STAT); ++ ++ reiser4_inode_clr_flag(inode, REISER4_SDLEN_KNOWN); ++ ++ /* Init unix-file specific part of inode */ ++ uf = unix_file_inode_data(inode); ++ uf->container = UF_CONTAINER_UNKNOWN; ++ init_rwsem(&uf->latch); ++ uf->tplug = inode_formatting_plugin(inode); ++ uf->exclusive_use = 0; ++#if REISER4_DEBUG ++ uf->ea_owner = NULL; ++ atomic_set(&uf->nr_neas, 0); ++#endif ++ /** ++ * we was carefull for file_ops, inode_ops and as_ops ++ * to be invariant for plugin conversion, so there is ++ * no need to update ones already installed in the ++ * vfs's residence. ++ */ ++ return 0; ++} ++ ++#if REISER4_DEBUG ++static int disabled_conversion_inode_ok(struct inode * inode) ++{ ++ __u64 extmask = reiser4_inode_data(inode)->extmask; ++ __u16 plugin_mask = reiser4_inode_data(inode)->plugin_mask; ++ ++ return ((extmask & (1 << LIGHT_WEIGHT_STAT)) && ++ (extmask & (1 << UNIX_STAT)) && ++ (extmask & (1 << LARGE_TIMES_STAT)) && ++ (extmask & (1 << PLUGIN_STAT)) && ++ (plugin_mask & (1 << PSET_COMPRESSION_MODE))); ++} ++#endif ++ ++/** ++ * Disable future attempts to schedule/convert file plugin. ++ * This function is called by plugin schedule hooks. ++ * ++ * To disable conversion we assign any compression mode plugin id ++ * different from CONVX_COMPRESSION_MODE_ID. ++ */ ++static int disable_conversion(struct inode * inode) ++{ ++ int result; ++ result = ++ force_plugin_pset(inode, ++ PSET_COMPRESSION_MODE, ++ (reiser4_plugin *)compression_mode_plugin_by_id ++ (LATTD_COMPRESSION_MODE_ID)); ++ assert("edward-1500", ++ ergo(!result, disabled_conversion_inode_ok(inode))); ++ return result; ++} ++ ++/** ++ * Check if we really have achieved plugin scheduling point ++ */ ++static int check_dispatch_point(struct inode * inode, ++ loff_t pos /* position in the ++ file to write from */, ++ struct cluster_handle * clust, ++ struct dispatch_context * cont) ++{ ++ assert("edward-1505", conversion_enabled(inode)); ++ /* ++ * if file size is more then cluster size, then compressible ++ * status must be figured out (i.e. compression was disabled, ++ * or file plugin was converted to unix_file) ++ */ ++ assert("edward-1506", inode->i_size <= inode_cluster_size(inode)); ++ ++ if (pos > inode->i_size) ++ /* first logical cluster will contain a (partial) hole */ ++ return disable_conversion(inode); ++ if (pos < inode_cluster_size(inode)) ++ /* writing to the first logical cluster */ ++ return 0; ++ /* ++ * here we have: ++ * cluster_size <= pos <= i_size <= cluster_size, ++ * and, hence, pos == i_size == cluster_size ++ */ ++ assert("edward-1498", ++ pos == inode->i_size && ++ pos == inode_cluster_size(inode)); ++ assert("edward-1539", cont != NULL); ++ assert("edward-1540", cont->state == DISPATCH_INVAL_STATE); ++ ++ cont->state = DISPATCH_POINT; ++ return 0; ++} ++ ++static void start_check_compressibility(struct inode * inode, ++ struct cluster_handle * clust, ++ hint_t * hint) ++{ ++ assert("edward-1507", clust->index == 1); ++ assert("edward-1508", !tfm_cluster_is_uptodate(&clust->tc)); ++ assert("edward-1509", cluster_get_tfm_act(&clust->tc) == TFMA_READ); ++ ++ hint_init_zero(hint); ++ clust->hint = hint; ++ clust->index --; ++ clust->nr_pages = size_in_pages(lbytes(clust->index, inode)); ++ ++ /* first logical cluster (of index #0) must be complete */ ++ assert("edward-1510", lbytes(clust->index, inode) == ++ inode_cluster_size(inode)); ++} ++ ++static void finish_check_compressibility(struct inode * inode, ++ struct cluster_handle * clust, ++ hint_t * hint) ++{ ++ reiser4_unset_hint(clust->hint); ++ clust->hint = hint; ++ clust->index ++; ++} ++ ++#if REISER4_DEBUG ++static int prepped_dclust_ok(hint_t * hint) ++{ ++ reiser4_key key; ++ coord_t * coord = &hint->ext_coord.coord; ++ ++ item_key_by_coord(coord, &key); ++ return (item_id_by_coord(coord) == CTAIL_ID && ++ !coord_is_unprepped_ctail(coord) && ++ (get_key_offset(&key) + nr_units_ctail(coord) == ++ dclust_get_extension_dsize(hint))); ++} ++#endif ++ ++#define fifty_persent(size) (size >> 1) ++/* evaluation of data compressibility */ ++#define data_is_compressible(osize, isize) \ ++ (osize < fifty_persent(isize)) ++ ++/** ++ * A simple O(1)-heuristic for compressibility. ++ * This is called not more then one time per file's life. ++ * Read first logical cluster (of index #0) and estimate its compressibility. ++ * Save estimation result in @cont. ++ */ ++static int read_check_compressibility(struct inode * inode, ++ struct cluster_handle * clust, ++ struct dispatch_context * cont) ++{ ++ int i; ++ int result; ++ size_t dst_len; ++ hint_t tmp_hint; ++ hint_t * cur_hint = clust->hint; ++ assert("edward-1541", cont->state == DISPATCH_POINT); ++ ++ start_check_compressibility(inode, clust, &tmp_hint); ++ ++ reset_cluster_pgset(clust, cluster_nrpages(inode)); ++ result = grab_page_cluster(inode, clust, READ_OP); ++ if (result) ++ return result; ++ /* Read page cluster here */ ++ for (i = 0; i < clust->nr_pages; i++) { ++ struct page *page = clust->pages[i]; ++ lock_page(page); ++ result = do_readpage_ctail(inode, clust, page, ++ ZNODE_READ_LOCK); ++ unlock_page(page); ++ if (result) ++ goto error; ++ } ++ tfm_cluster_clr_uptodate(&clust->tc); ++ ++ cluster_set_tfm_act(&clust->tc, TFMA_WRITE); ++ ++ if (hint_is_valid(&tmp_hint) && !hint_is_unprepped_dclust(&tmp_hint)) { ++ /* lenght of compressed data is known, no need to compress */ ++ assert("edward-1511", ++ znode_is_any_locked(tmp_hint.lh.node)); ++ assert("edward-1512", ++ WITH_DATA(tmp_hint.ext_coord.coord.node, ++ prepped_dclust_ok(&tmp_hint))); ++ dst_len = dclust_get_extension_dsize(&tmp_hint); ++ } ++ else { ++ struct tfm_cluster * tc = &clust->tc; ++ compression_plugin * cplug = inode_compression_plugin(inode); ++ result = grab_tfm_stream(inode, tc, INPUT_STREAM); ++ if (result) ++ goto error; ++ for (i = 0; i < clust->nr_pages; i++) { ++ char *data; ++ lock_page(clust->pages[i]); ++ BUG_ON(!PageUptodate(clust->pages[i])); ++ data = kmap(clust->pages[i]); ++ memcpy(tfm_stream_data(tc, INPUT_STREAM) + pg_to_off(i), ++ data, PAGE_SIZE); ++ kunmap(clust->pages[i]); ++ unlock_page(clust->pages[i]); ++ } ++ result = grab_tfm_stream(inode, tc, OUTPUT_STREAM); ++ if (result) ++ goto error; ++ result = grab_coa(tc, cplug); ++ if (result) ++ goto error; ++ tc->len = tc->lsize = lbytes(clust->index, inode); ++ assert("edward-1513", tc->len == inode_cluster_size(inode)); ++ dst_len = tfm_stream_size(tc, OUTPUT_STREAM); ++ cplug->compress(get_coa(tc, cplug->h.id, tc->act), ++ tfm_input_data(clust), tc->len, ++ tfm_output_data(clust), &dst_len); ++ assert("edward-1514", ++ dst_len <= tfm_stream_size(tc, OUTPUT_STREAM)); ++ } ++ finish_check_compressibility(inode, clust, cur_hint); ++ cont->state = ++ (data_is_compressible(dst_len, inode_cluster_size(inode)) ? ++ DISPATCH_REMAINS_OLD : ++ DISPATCH_ASSIGNED_NEW); ++ return 0; ++ error: ++ put_page_cluster(clust, inode, READ_OP); ++ return result; ++} ++ ++/* Cut disk cluster of index @idx */ ++static int cut_disk_cluster(struct inode * inode, cloff_t idx) ++{ ++ reiser4_key from, to; ++ assert("edward-1515", inode_file_plugin(inode) == ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); ++ build_body_key_cryptcompress(inode, clust_to_off(idx, inode), &from); ++ to = from; ++ set_key_offset(&to, ++ get_key_offset(&from) + inode_cluster_size(inode) - 1); ++ return reiser4_cut_tree(meta_subvol_tree(), &from, &to, inode, 0); ++} ++ ++static int reserve_cryptcompress2unixfile(struct inode *inode) ++{ ++ int ret; ++ reiser4_block_nr num_unformatted = cluster_nrpages(inode); ++ reiser4_subvol *subv = get_meta_subvol(); ++ /* ++ * space required for one iteration of extent->tail conversion: ++ * ++ * 1. kill ctail items ++ * ++ * 2. insert N unformatted nodes ++ * ++ * 3. insert N (worst-case single-block ++ * extents) extent units. ++ * ++ * 4. drilling to the leaf level by coord_by_key() ++ * ++ * 5. possible update of stat-data ++ * ++ * reserve for 2 ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(num_unformatted, BA_CAN_COMMIT, subv); ++ if (ret) ++ return ret; ++ /* ++ * reserve for 1,3,4,5 ++ */ ++ grab_space_enable(); ++ return reiser4_grab_space(2 * subv->tree.height + ++ num_unformatted * ++ estimate_one_insert_into_item(&subv->tree) + ++ 1 + estimate_one_insert_item(&subv->tree) + ++ inode_file_plugin(inode)->estimate.update(inode), ++ BA_CAN_COMMIT, subv); ++} ++ ++/** ++ * Convert cryptcompress file plugin to unix_file plugin. ++ */ ++static int cryptcompress2unixfile(struct file *file, struct inode *inode, ++ struct dispatch_context *cont) ++{ ++ int i; ++ int result = 0; ++ struct cryptcompress_info *cr_info; ++ struct unix_file_info *uf_info; ++ assert("edward-1516", cont->pages[0]->index == 0); ++ ++ /* release all cryptcompress-specific resources */ ++ cr_info = cryptcompress_inode_data(inode); ++ result = reserve_cryptcompress2unixfile(inode); ++ if (result) ++ goto out; ++ /* tell kill_hook to not truncate pages */ ++ reiser4_inode_set_flag(inode, REISER4_FILE_IN_CONVERSION); ++ result = cut_disk_cluster(inode, 0); ++ if (result) ++ goto out; ++ /* captured jnode of cluster and assotiated resources (pages, ++ reserved disk space) were released by ->kill_hook() method ++ of the item plugin */ ++ ++ result = __cryptcompress2unixfile(file, inode); ++ if (result) ++ goto out; ++ /* At this point file is managed by unix file plugin */ ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ assert("edward-1518", ++ ergo(jprivate(cont->pages[0]), ++ !jnode_is_cluster_page(jprivate(cont->pages[0])))); ++ for(i = 0; i < cont->nr_pages; i++) { ++ assert("edward-1519", cont->pages[i]); ++ assert("edward-1520", PageUptodate(cont->pages[i])); ++ ++ result = find_or_create_extent_unix_file(cont->pages[i]); ++ if (result) ++ break; ++ } ++ if (unlikely(result)) ++ goto out; ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ result = reiser4_update_sd(inode); ++ out: ++ all_grabbed2free(); ++ return result; ++} ++ ++#define convert_file_plugin cryptcompress2unixfile ++ ++/** ++ * This is called by ->write() method of a cryptcompress file plugin. ++ * Make a decision about the most reasonable file plugin id to manage ++ * the file. ++ */ ++int write_dispatch_hook(struct file *file, struct inode *inode, ++ loff_t pos, struct cluster_handle *clust, ++ struct dispatch_context *cont) ++{ ++ int result; ++ if (!conversion_enabled(inode)) ++ return 0; ++ result = check_dispatch_point(inode, pos, clust, cont); ++ if (result || cont->state != DISPATCH_POINT) ++ return result; ++ result = read_check_compressibility(inode, clust, cont); ++ if (result) ++ return result; ++ if (cont->state == DISPATCH_REMAINS_OLD) { ++ put_page_cluster(clust, inode, READ_OP); ++ return disable_conversion(inode); ++ } ++ assert("edward-1543", cont->state == DISPATCH_ASSIGNED_NEW); ++ /* ++ * page cluster is grabbed and uptodate. It will be ++ * released with a pgset after plugin conversion is ++ * finished, see put_dispatch_context(). ++ */ ++ reiser4_unset_hint(clust->hint); ++ move_cluster_pgset(clust, &cont->pages, &cont->nr_pages); ++ return 0; ++} ++ ++/** ++ * This is called by ->setattr() method of cryptcompress file plugin. ++ */ ++int setattr_dispatch_hook(struct inode * inode) ++{ ++ if (conversion_enabled(inode)) ++ return disable_conversion(inode); ++ return 0; ++} ++ ++static inline void init_dispatch_context(struct dispatch_context * cont) ++{ ++ memset(cont, 0, sizeof(*cont)); ++} ++ ++static inline void done_dispatch_context(struct dispatch_context * cont, ++ struct inode * inode) ++{ ++ if (cont->pages) { ++ __put_page_cluster(0, cont->nr_pages, cont->pages, inode); ++ kfree(cont->pages); ++ } ++} ++ ++static inline ssize_t reiser4_write_checks(struct file *file, ++ const char __user *buf, ++ size_t count, loff_t *off) ++{ ++ ssize_t result; ++ struct iovec iov = { .iov_base = (void __user *)buf, .iov_len = count }; ++ struct kiocb iocb; ++ struct iov_iter iter; ++ ++ init_sync_kiocb(&iocb, file); ++ iocb.ki_pos = *off; ++ iov_iter_init(&iter, WRITE, &iov, 1, count); ++ ++ result = generic_write_checks(&iocb, &iter); ++ *off = iocb.ki_pos; ++ return result; ++} ++ ++/* ++ * ->write() VFS file operation ++ * ++ * performs "intelligent" conversion in the FILE interface. ++ * Write a file in 3 steps (2d and 3d steps are optional). ++ */ ++ssize_t reiser4_write_dispatch(struct file *file, const char __user *buf, ++ size_t count, loff_t *off) ++{ ++ ssize_t result; ++ reiser4_context *ctx; ++ ssize_t written_old = 0; /* bytes written with initial plugin */ ++ ssize_t written_new = 0; /* bytes written with new plugin */ ++ struct dispatch_context cont; ++ struct inode * inode = file_inode(file); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ current->backing_dev_info = inode_to_bdi(inode); ++ init_dispatch_context(&cont); ++ inode_lock(inode); ++ ++ result = reiser4_write_checks(file, buf, count, off); ++ if (unlikely(result <= 0)) ++ goto exit; ++ /** ++ * First step. ++ * Start write with initial file plugin. ++ * Keep a plugin schedule status at @cont (if any). ++ */ ++ written_old = inode_file_plugin(inode)->write(file, ++ buf, ++ count, ++ off, ++ &cont); ++ if (cont.state != DISPATCH_ASSIGNED_NEW || written_old < 0) ++ goto exit; ++ /** ++ * Second step. ++ * New file plugin has been scheduled. ++ * Commit respective atom and pass management to the new plugin. ++ */ ++ assert("edward-181", cont.pages[0] != NULL); ++ /* ++ * this will commit the whole logical cluster ++ * the file consists of ++ */ ++ reiser4_sync_page(cont.pages[0]); ++ ++ down_read(&reiser4_inode_data(inode)->conv_sem); ++ result = convert_file_plugin(file, inode, &cont); ++ up_read(&reiser4_inode_data(inode)->conv_sem); ++ if (result) { ++ warning("edward-1544", ++ "Inode %llu: file plugin conversion failed (%d)", ++ (unsigned long long)get_inode_oid(inode), ++ (int)result); ++ goto exit; ++ } ++ reiser4_txn_restart(ctx); ++ /** ++ * Third step: ++ * Finish write with the new file plugin. ++ */ ++ assert("edward-1536", ++ inode_file_plugin(inode) == ++ file_plugin_by_id(UNIX_FILE_PLUGIN_ID)); ++ ++ written_new = inode_file_plugin(inode)->write(file, ++ buf + written_old, ++ count - written_old, ++ off, ++ NULL); ++ exit: ++ inode_unlock(inode); ++ done_dispatch_context(&cont, inode); ++ current->backing_dev_info = NULL; ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ ++ return written_old + (written_new < 0 ? 0 : written_new); ++} ++ ++/* ++ * Dispatchers with "passive" protection for: ++ * ++ * ->open(); ++ * ->read(); ++ * ->ioctl(); ++ * ->mmap(); ++ * ->release(); ++ * ->bmap(). ++ */ ++ ++int reiser4_open_dispatch(struct inode *inode, struct file *file) ++{ ++ return PROT_PASSIVE(int, open, (inode, file)); ++} ++ ++ssize_t reiser4_read_dispatch(struct file * file, char __user * buf, ++ size_t size, loff_t * off) ++{ ++ struct inode * inode = file_inode(file); ++ return PROT_PASSIVE(ssize_t, read, (file, buf, size, off)); ++} ++ ++long reiser4_ioctl_dispatch(struct file *filp, unsigned int cmd, ++ unsigned long arg) ++{ ++ struct inode * inode = file_inode(filp); ++ return PROT_PASSIVE(int, ioctl, (filp, cmd, arg)); ++} ++ ++int reiser4_mmap_dispatch(struct file *file, struct vm_area_struct *vma) ++{ ++ struct inode *inode = file_inode(file); ++ return PROT_PASSIVE(int, mmap, (file, vma)); ++} ++ ++int reiser4_release_dispatch(struct inode *inode, struct file *file) ++{ ++ return PROT_PASSIVE(int, release, (inode, file)); ++} ++ ++sector_t reiser4_bmap_dispatch(struct address_space * mapping, sector_t lblock) ++{ ++ struct inode *inode = mapping->host; ++ return PROT_PASSIVE(sector_t, bmap, (mapping, lblock)); ++} ++ ++/** ++ * NOTE: The following two methods are ++ * used only for loopback functionality. ++ * reiser4_write_end() can not cope with ++ * short writes for now. ++ */ ++int reiser4_write_begin_dispatch(struct file *file, ++ struct address_space *mapping, ++ loff_t pos, ++ unsigned len, ++ unsigned flags, ++ struct page **pagep, ++ void **fsdata) ++{ ++ int ret = 0; ++ struct page *page; ++ pgoff_t index; ++ reiser4_context *ctx; ++ struct inode * inode = file_inode(file); ++ ++ index = pos >> PAGE_SHIFT; ++ page = grab_cache_page_write_begin(mapping, index, ++ flags & AOP_FLAG_NOFS); ++ *pagep = page; ++ if (!page) ++ return -ENOMEM; ++ ++ ctx = reiser4_init_context(file_inode(file)->i_sb); ++ if (IS_ERR(ctx)) { ++ ret = PTR_ERR(ctx); ++ goto err2; ++ } ++ /* ++ * reserve space to update stat-data: ++ * one when updating file size and one when updating mtime/ctime ++ */ ++ ret = reiser4_grab_space_force(2 * estimate_update_common(inode), ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (ret) ++ goto err1; ++ ret = PROT_PASSIVE(int, write_begin, (file, page, pos, len, fsdata)); ++ if (unlikely(ret)) ++ goto err1; ++ /* Success. Resorces will be released in write_end_dispatch */ ++ return 0; ++ err1: ++ reiser4_exit_context(ctx); ++ err2: ++ unlock_page(page); ++ put_page(page); ++ return ret; ++} ++ ++int reiser4_write_end_dispatch(struct file *file, ++ struct address_space *mapping, ++ loff_t pos, ++ unsigned len, ++ unsigned copied, ++ struct page *page, ++ void *fsdata) ++{ ++ int ret; ++ reiser4_context *ctx; ++ struct inode *inode = page->mapping->host; ++ ++ assert("umka-3101", file != NULL); ++ assert("umka-3102", page != NULL); ++ assert("umka-3093", PageLocked(page)); ++ ++ ctx = get_current_context(); ++ ++ SetPageUptodate(page); ++ set_page_dirty_notag(page); ++ ++ ret = PROT_PASSIVE(int, write_end, (file, page, pos, copied, fsdata)); ++ put_page(page); ++ ++ /* don't commit transaction under inode semaphore */ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return ret == 0 ? copied : ret; ++} ++ ++/* ++ * Dispatchers without protection ++ */ ++int reiser4_setattr_dispatch(struct dentry *dentry, struct iattr *attr) ++{ ++ return inode_file_plugin(dentry->d_inode)->setattr(dentry, attr); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/file.h linux-5.10.2/fs/reiser4/plugin/file/file.h +--- linux-5.10.2.orig/fs/reiser4/plugin/file/file.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/file.h 2020-12-23 16:07:46.124813217 +0100 +@@ -0,0 +1,382 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* this file contains declarations of methods implementing ++ file plugins (UNIX_FILE_PLUGIN_ID, CRYPTCOMPRESS_FILE_PLUGIN_ID, ++ STRIPED_FILE_PLUGIN_ID and SYMLINK_FILE_PLUGIN_ID) */ ++ ++#if !defined( __REISER4_FILE_H__ ) ++#define __REISER4_FILE_H__ ++ ++/* possible states in dispatching process */ ++typedef enum { ++ DISPATCH_INVAL_STATE, /* invalid state */ ++ DISPATCH_POINT, /* dispatching point has been achieved */ ++ DISPATCH_REMAINS_OLD, /* made a decision to manage by old plugin */ ++ DISPATCH_ASSIGNED_NEW /* a new plugin has been assigned */ ++} dispatch_state; ++ ++/* UPdate eXtent flags */ ++#define UPX_TRUNCATE (1 << 0) ++#define UPX_PROXY_FULL (1 << 1) ++ ++struct dispatch_context { ++ int nr_pages; ++ struct page **pages; ++ dispatch_state state; ++}; ++ ++/* ++ * Declarations of methods provided for VFS. ++ */ ++ ++/* inode operations */ ++int reiser4_setattr_dispatch(struct dentry *, struct iattr *); ++ ++/* file operations */ ++ssize_t reiser4_read_dispatch(struct file *, char __user *buf, ++ size_t count, loff_t *off); ++ssize_t reiser4_write_dispatch(struct file *, const char __user *buf, ++ size_t count, loff_t * off); ++long reiser4_ioctl_dispatch(struct file *filp, unsigned int cmd, ++ unsigned long arg); ++int reiser4_mmap_dispatch(struct file *, struct vm_area_struct *); ++int reiser4_open_dispatch(struct inode *inode, struct file *file); ++int reiser4_release_dispatch(struct inode *, struct file *); ++int reiser4_sync_file_common(struct file *, loff_t, loff_t, int datasync); ++int reiser4_sync_page(struct page *page); ++ ++/* address space operations */ ++int reiser4_readpage_dispatch(struct file *, struct page *); ++int reiser4_readpages_dispatch(struct file *, struct address_space *, ++ struct list_head *, unsigned); ++int reiser4_writepages_dispatch(struct address_space *, ++ struct writeback_control *); ++int reiser4_write_begin_dispatch(struct file *file, ++ struct address_space *mapping, ++ loff_t pos, unsigned len, unsigned flags, ++ struct page **pagep, void **fsdata); ++int reiser4_write_end_dispatch(struct file *file, ++ struct address_space *mapping, ++ loff_t pos, unsigned len, unsigned copied, ++ struct page *page, void *fsdata); ++sector_t reiser4_bmap_dispatch(struct address_space *, sector_t lblock); ++ ++/* ++ * Private methods of unix-file plugin ++ * (UNIX_FILE_PLUGIN_ID) ++ */ ++ ++int build_body_key_unix_file(struct inode *inode, loff_t off, ++ reiser4_key *key); ++/* private inode operations */ ++int setattr_unix_file(struct dentry *, struct iattr *); ++ ++/* private file operations */ ++ ++ssize_t read_unix_file(struct file *, char __user *buf, size_t read_amount, ++ loff_t *off); ++ssize_t write_unix_file(struct file *, const char __user *buf, size_t write_amount, ++ loff_t * off, struct dispatch_context * cont); ++int ioctl_unix_file(struct file *, unsigned int cmd, unsigned long arg); ++int mmap_unix_file(struct file *, struct vm_area_struct *); ++int open_unix_file(struct inode *, struct file *); ++int release_unix_file(struct inode *, struct file *); ++ ++/* private address space operations */ ++int readpage_unix_file(struct file *, struct page *); ++int readpages_unix_file(struct file*, struct address_space*, struct list_head*, ++ unsigned); ++int reiser4_writepages_generic(struct address_space *mapping, ++ struct writeback_control *wbc, ++ int(*capture_anon_page_fn)(struct page *), ++ int(*commit_file_atoms_fn)(struct inode *)); ++int writepages_unix_file(struct address_space *, struct writeback_control *); ++int write_begin_unix_file(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata); ++int write_end_unix_file(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata); ++sector_t bmap_unix_file(struct address_space *, sector_t lblock); ++ ++/* other private methods */ ++int delete_object_unix_file(struct inode *); ++int flow_by_inode_unix_file(struct inode *, const char __user *buf, ++ int user, loff_t, loff_t, rw_op, flow_t *); ++int owns_item_unix_file(const struct inode *, const coord_t *); ++void init_inode_data_unix_file(struct inode *, reiser4_object_create_data *, ++ const reiser4_key *sd_key, int create); ++ ++/* ++ * Private methods of cryptcompress file plugin ++ * (CRYPTCOMPRESS_FILE_PLUGIN_ID) ++ */ ++ ++/* private inode operations */ ++int setattr_cryptcompress(struct dentry *, struct iattr *); ++ ++/* private file operations */ ++ssize_t read_cryptcompress(struct file *, char __user *buf, ++ size_t count, loff_t *off); ++ssize_t write_cryptcompress(struct file *, const char __user *buf, ++ size_t count, loff_t * off, ++ struct dispatch_context *cont); ++int ioctl_cryptcompress(struct file *, unsigned int cmd, unsigned long arg); ++int mmap_cryptcompress(struct file *, struct vm_area_struct *); ++int open_cryptcompress(struct inode *, struct file *); ++int release_cryptcompress(struct inode *, struct file *); ++ ++/* private address space operations */ ++int readpage_cryptcompress(struct file *, struct page *); ++int readpages_cryptcompress(struct file*, struct address_space*, ++ struct list_head*, unsigned); ++int writepages_cryptcompress(struct address_space *, ++ struct writeback_control *); ++int write_begin_cryptcompress(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata); ++int write_end_cryptcompress(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata); ++sector_t bmap_cryptcompress(struct address_space *, sector_t lblock); ++ ++/* other private methods */ ++ ++int flow_by_inode_cryptcompress(struct inode *, const char __user *buf, ++ int user, loff_t, loff_t, rw_op, flow_t *); ++int build_body_key_cryptcompress(struct inode *, loff_t off, reiser4_key *); ++int create_object_cryptcompress(struct inode *, struct inode *, ++ reiser4_object_create_data *, oid_t *); ++int delete_object_cryptcompress(struct inode *); ++void init_inode_data_cryptcompress(struct inode *, reiser4_object_create_data *, ++ const reiser4_key *sd_key, int create); ++int cut_tree_worker_cryptcompress(tap_t *, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed, ++ struct inode *object, int truncate, ++ int *progress); ++void destroy_inode_cryptcompress(struct inode *); ++ ++/* ++ * Private methods of striped-file plugin ++ * (STRIPED_FILE_PLUGIN_ID) ++ */ ++int build_body_key_stripe(struct inode *inode, loff_t off, ++ reiser4_key *key); ++int flow_by_inode_stripe(struct inode *inode, const char __user *buf, int user, ++ loff_t size, loff_t off, rw_op op, flow_t *flow); ++int create_object_stripe(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *data, oid_t *oid); ++void init_inode_data_stripe(struct inode *, reiser4_object_create_data *, ++ const reiser4_key *sd_key, int create); ++int open_stripe(struct inode *, struct file *); ++int release_stripe(struct inode *inode, struct file *file); ++ssize_t read_stripe(struct file *file, char __user *buf, ++ size_t read_amount, loff_t *off); ++ssize_t write_stripe(struct file *file, const char __user *buf, size_t count, ++ loff_t *pos, struct dispatch_context *cont); ++int readpages_stripe(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages); ++int readpage_stripe(struct file *file, struct page *page); ++int writepages_stripe(struct address_space *, struct writeback_control *); ++int setattr_stripe(struct dentry *, struct iattr *); ++int delete_object_stripe(struct inode *); ++int cut_tree_worker_stripe(tap_t *, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed, ++ struct inode *object, int truncate, ++ int *progress); ++int write_begin_stripe(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata); ++int write_end_stripe(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata); ++int ioctl_stripe(struct file *filp, unsigned int cmd, unsigned long arg); ++int migrate_stripe(struct inode *object, u64 *dst_id); ++ ++/* ++ * Private methods of symlink file plugin ++ * (SYMLINK_FILE_PLUGIN_ID) ++ */ ++int reiser4_create_symlink(struct inode *symlink, struct inode *dir, ++ reiser4_object_create_data *, oid_t *); ++void destroy_inode_symlink(struct inode *); ++ ++/* ++ * all the write into unix file is performed by item write method. Write method ++ * of unix file plugin only decides which item plugin (extent or tail) and in ++ * which mode (one from the enum below) to call ++ */ ++typedef enum { ++ FIRST_ITEM = 1, ++ APPEND_ITEM = 2, ++ OVERWRITE_ITEM = 3 ++} write_mode_t; ++ ++/* unix file may be in one the following states */ ++typedef enum { ++ UF_CONTAINER_UNKNOWN = 0, ++ UF_CONTAINER_TAILS = 1, ++ UF_CONTAINER_EXTENTS = 2, ++ UF_CONTAINER_EMPTY = 3 ++} file_container_t; ++ ++struct formatting_plugin; ++struct inode; ++ ++/* unix file plugin specific part of reiser4 inode */ ++struct unix_file_info { ++ /* ++ * this read-write lock protects file containerization change. Accesses ++ * which do not change file containerization (see file_container_t) ++ * (read, readpage, writepage, write (until tail conversion is ++ * involved)) take read-lock. Accesses which modify file ++ * containerization (truncate, conversion from tail to extent and back) ++ * take write-lock. ++ */ ++ struct rw_semaphore latch; ++ /* this enum specifies which items are used to build the file */ ++ file_container_t container; ++ /* ++ * plugin which controls when file is to be converted to extents and ++ * back to tail ++ */ ++ struct formatting_plugin *tplug; ++ /* if this is set, file is in exclusive use */ ++ int exclusive_use; ++#if REISER4_DEBUG ++ /* pointer to task struct of thread owning exclusive access to file */ ++ void *ea_owner; ++ atomic_t nr_neas; ++ void *last_reader; ++#endif ++}; ++ ++struct unix_file_info *unix_file_inode_data(const struct inode *inode); ++void get_exclusive_access(struct unix_file_info *); ++void drop_exclusive_access(struct unix_file_info *); ++void get_nonexclusive_access(struct unix_file_info *); ++void drop_nonexclusive_access(struct unix_file_info *); ++int try_to_get_nonexclusive_access(struct unix_file_info *); ++int find_file_item(hint_t *, const reiser4_key *, znode_lock_mode, ++ struct inode *); ++int find_file_item_nohint(coord_t *, lock_handle *, ++ const reiser4_key *, znode_lock_mode, ++ struct inode *); ++ ++int load_file_hint(struct file *, hint_t *); ++void save_file_hint(struct file *, const hint_t *); ++ ++#include "../item/extent.h" ++#include "../item/tail.h" ++#include "../item/ctail.h" ++ ++struct uf_coord { ++ coord_t coord; ++ lock_handle *lh; ++ int valid; ++ union { ++ struct extent_coord_extension extent; ++ struct tail_coord_extension tail; ++ struct ctail_coord_extension ctail; ++ } extension; ++}; ++ ++#include "../../forward.h" ++#include "../../seal.h" ++#include "../../lock.h" ++ ++/* ++ * This structure is used to speed up file operations (reads and writes). A ++ * hint is a suggestion about where a key resolved to last time. A seal ++ * indicates whether a node has been modified since a hint was last recorded. ++ * You check the seal, and if the seal is still valid, you can use the hint ++ * without traversing the tree again. ++ */ ++struct hint { ++ seal_t seal; /* a seal over last file item accessed */ ++ uf_coord_t ext_coord; ++ loff_t offset; ++ znode_lock_mode mode; ++ lock_handle lh; ++}; ++ ++static inline int hint_is_valid(hint_t * hint) ++{ ++ return hint->ext_coord.valid; ++} ++ ++static inline void hint_set_valid(hint_t * hint) ++{ ++ hint->ext_coord.valid = 1; ++} ++ ++static inline void hint_clr_valid(hint_t * hint) ++{ ++ hint->ext_coord.valid = 0; ++} ++ ++int load_file_hint(struct file *, hint_t *); ++void save_file_hint(struct file *, const hint_t *); ++void hint_init_zero(hint_t *); ++void reiser4_set_hint(hint_t *, const reiser4_key *, znode_lock_mode); ++int hint_is_set(const hint_t *); ++void reiser4_unset_hint(hint_t *); ++ ++int reiser4_sync_page_list(struct inode *inode); ++int reiser4_update_file_size(struct inode *, loff_t, int update_sd); ++int reserve_cut_iteration(struct inode *inode); ++int cut_file_items(struct inode *, loff_t new_size, ++ int update_sd, loff_t cur_size, ++ int (*update_actor) (struct inode *, loff_t, int)); ++#if REISER4_DEBUG ++ ++/* return 1 is exclusive access is obtained, 0 - otherwise */ ++static inline int ea_obtained(struct unix_file_info * uf_info) ++{ ++ int ret; ++ ++ ret = down_read_trylock(&uf_info->latch); ++ if (ret) ++ up_read(&uf_info->latch); ++ return !ret; ++} ++ ++#endif ++ ++int tail2extent(struct unix_file_info *); ++int extent2tail(struct file *, struct unix_file_info *); ++ ++int goto_right_neighbor(coord_t *, lock_handle *); ++int find_or_create_extent_stripe(struct page *page, unsigned flags); ++int find_or_create_extent_unix_file(struct page *); ++int reiser4_setattr_generic(struct dentry *dentry, struct iattr *attr, ++ int (*truncate_file_body_fn)(struct inode *, ++ struct iattr *)); ++int reiser4_readpages_filler_generic(void *data, ++ struct page *page, int striped); ++int reiser4_readpages_generic(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages, ++ int (*filler)(void *data, struct page *page)); ++int reiser4_write_begin_common(struct file *file, struct page *page, ++ loff_t pos, unsigned len, ++ int(*readpage_fn)(struct file *, struct page *)); ++int equal_to_ldk(znode *, const reiser4_key *); ++ ++void init_uf_coord(uf_coord_t *uf_coord, lock_handle *lh); ++ ++static inline int cbk_errored(int cbk_result) ++{ ++ return (cbk_result != CBK_COORD_NOTFOUND ++ && cbk_result != CBK_COORD_FOUND); ++} ++ ++/* __REISER4_FILE_H__ */ ++#endif ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/invert.c linux-5.10.2/fs/reiser4/plugin/file/invert.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/invert.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/invert.c 2020-12-23 16:07:46.124813217 +0100 +@@ -0,0 +1,493 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Suppose you want to conveniently read and write a large variety of small files conveniently within a single emacs ++ buffer, without having a separate buffer for each 8 byte or so file. Inverts are the way to do that. An invert ++ provides you with the contents of a set of subfiles plus its own contents. It is a file which inherits other files ++ when you read it, and allows you to write to it and through it to the files that it inherits from. In order for it ++ to know which subfiles each part of your write should go into, there must be delimiters indicating that. It tries to ++ make that easy for you by providing those delimiters in what you read from it. ++ ++ When you read it, an invert performs an inverted assignment. Instead of taking an assignment command and writing a ++ bunch of files, it takes a bunch of files and composes an assignment command for you to read from it that if executed ++ would create those files. But which files? Well, that must be specified in the body of the invert using a special ++ syntax, and that specification is called the invert of the assignment. ++ ++ When written to, an invert performs the assignment command that is written ++ to it, and modifies its own body to contain the invert of that ++ assignment. ++ ++ In other words, writing to an invert file what you have read from it ++ is the identity operation. ++ ++ Malformed assignments cause write errors. Partial writes are not ++ supported in v4.0, but will be. ++ ++ Example: ++ ++ If an invert contains: ++ ++ /filenameA/<>+"(some text stored in the invert)+/filenameB/<> ++ ++====================== ++Each element in this definition should be an invert, and all files ++should be called recursively - too. This is bad. If one of the ++included files in not a regular or invert file, then we can't read ++main file. ++ ++I think to make it is possible easier: ++ ++internal structure of invert file should be like symlink file. But ++read and write method should be explitely indicated in i/o operation.. ++ ++By default we read and write (if probably) as symlink and if we ++specify ..invert at reading time that too we can specify it at write time. ++ ++example: ++/my_invert_file/..invert<- ( (/filenameA<-"(The contents of filenameA))+"(some text stored in the invert)+(/filenameB<-"(The contents of filenameB) ) ) ++will create /my_invert_file as invert, and will creat /filenameA and /filenameB with specified body. ++ ++read of /my_invert_file/..invert will be ++/filenameA<-"(The contents of filenameA)+"(some text stored in the invert)+/filenameB<-"(The contents of filenameB) ++ ++but read of /my_invert_file/ will be ++The contents of filenameAsome text stored in the invertThe contents of filenameB ++ ++we also can creat this file as ++/my_invert_file/<-/filenameA+"(some text stored in the invert)+/filenameB ++will create /my_invert_file , and use existing files /filenameA and /filenameB. ++ ++and when we will read it will be as previously invert file. ++ ++This is correct? ++ ++ vv ++DEMIDOV-FIXME-HANS: ++ ++Maybe you are right, but then you must disable writes to /my_invert_file/ and only allow writes to /my_invert_file/..invert ++ ++Do you agree? Discuss it on reiserfs-list.... ++ ++-Hans ++======================= ++ ++ Then a read will return: ++ ++ /filenameA<-"(The contents of filenameA)+"(some text stored in the invert)+/filenameB<-"(The contents of filenameB) ++ ++ and a write of the line above to the invert will set the contents of ++ the invert and filenameA and filenameB to their original values. ++ ++ Note that the contents of an invert have no influence on the effect ++ of a write unless the write is a partial write (and a write of a ++ shorter file without using truncate first is a partial write). ++ ++ truncate() has no effect on filenameA and filenameB, it merely ++ resets the value of the invert. ++ ++ Writes to subfiles via the invert are implemented by preceding them ++ with truncates. ++ ++ Parse failures cause write failures. ++ ++ Questions to ponder: should the invert be acted on prior to file ++ close when writing to an open filedescriptor? ++ ++ Example: ++ ++ If an invert contains: ++ ++ "(This text and a pair of quotes are all that is here.) ++ ++Then a read will return: ++ ++ "(This text and a pair of quotes are all that is here.) ++ ++*/ ++ ++/* OPEN method places a struct file in memory associated with invert body ++ and returns something like file descriptor to the user for the future access ++ to the invert file. ++ During opening we parse the body of invert and get a list of the 'entryes' ++ (that describes all its subfiles) and place pointer on the first struct in ++ reiserfs-specific part of invert inode (arbitrary decision). ++ ++ Each subfile is described by the struct inv_entry that has a pointer @sd on ++ in-core based stat-data and a pointer on struct file @f (if we find that the ++ subfile uses more then one unformated node (arbitrary decision), we load ++ struct file in memory, otherwise we load base stat-data (and maybe 1-2 bytes ++ of some other information we need) ++ ++ Since READ and WRITE methods for inverts were formulated in assignment ++ language, they don't contain arguments 'size' and 'offset' that make sense ++ only in ordinary read/write methods. ++ ++ READ method is a combination of two methods: ++ 1) ordinary read method (with offset=0, lenght = @f->...->i_size) for entries ++ with @f != 0, this method uses pointer on struct file as an argument ++ 2) read method for inode-less files with @sd != 0, this method uses ++ in-core based stat-data instead struct file as an argument. ++ in the first case we don't use pagecache, just copy data that we got after ++ cbk() into userspace. ++ ++ WRITE method for invert files is more complex. ++ Besides declared WRITE-interface in assignment languageb above we need ++ to have an opportunity to edit unwrapped body of invert file with some ++ text editor, it means we need GENERIC WRITE METHOD for invert file: ++ ++ my_invert_file/..invert <- "string" ++ ++ this method parses "string" and looks for correct subfile signatures, also ++ the parsing process splits this "string" on the set of flows in accordance ++ with the set of subfiles specified by this signarure. ++ The found list of signatures #S is compared with the opened one #I of invert ++ file. If it doesn't have this one (#I==0, it will be so for instance if we ++ have just create this invert file) the write method assignes found signature ++ (#I=#S;) to the invert file. Then if #I==#S, generic write method splits ++ itself to the some write methods for ordinary or light-weight, or call itself ++ recursively for invert files with corresponding flows. ++ I am not sure, but the list of signatures looks like what mr.Demidov means ++ by 'delimiters'. ++ ++ The cases when #S<#I (#I<#S) (in the sense of set-theory) are also available ++ and cause delete (create new) subfiles (arbitrary decision - it may looks ++ too complex, but this interface will be the completest). The order of entries ++ of list #S (#I) and inherited order on #I (#S) must coincide. ++ The other parsing results give malformed signature that aborts READ method ++ and releases all resources. ++ ++ Format of subfile (entry) signature: ++ ++ "START_MAGIC"<>(TYPE="...",LOOKUP_ARG="...")SUBFILE_BODY"END_MAGIC" ++ ++ Legend: ++ ++ START_MAGIC - keyword indicates the start of subfile signature; ++ ++ <> indicates the start of 'subfile metadata', that is the pair ++ (TYPE="...",LOOKUP_ARG="...") in parenthesis separated by comma. ++ ++ TYPE - the string "type" indicates the start of one of the three words: ++ - ORDINARY_FILE, ++ - LIGHT_WEIGHT_FILE, ++ - INVERT_FILE; ++ ++ LOOKUP_ARG - lookup argument depends on previous type: ++ */ ++ ++ /************************************************************/ ++ /* TYPE * LOOKUP ARGUMENT */ ++ /************************************************************/ ++ /* LIGH_WEIGHT_FILE * stat-data key */ ++ /************************************************************/ ++ /* ORDINARY_FILE * filename */ ++ /************************************************************/ ++ /* INVERT_FILE * filename */ ++ /************************************************************/ ++ ++ /* where: ++ *stat-data key - the string contains stat data key of this subfile, it will be ++ passed to fast-access lookup method for light-weight files; ++ *filename - pathname of this subfile, iyt well be passed to VFS lookup methods ++ for ordinary and invert files; ++ ++ SUBFILE_BODY - data of this subfile (it will go to the flow) ++ END_MAGIC - the keyword indicates the end of subfile signature. ++ ++ The other simbols inside the signature interpreted as 'unformatted content', ++ which is available with VFS's read_link() (arbitraruy decision). ++ ++ NOTE: Parse method for a body of invert file uses mentioned signatures _without_ ++ subfile bodies. ++ ++ Now the only unclear thing is WRITE in regular light-weight subfile A that we ++ can describe only in assignment language: ++ ++ A <- "some_string" ++ ++ I guess we don't want to change stat-data and body items of file A ++ if this file exist, and size(A) != size("some_string") because this operation is ++ expencive, so we only do the partial write if size(A) > size("some_string") ++ and do truncate of the "some_string", and then do A <- "truncated string", if ++ size(A) < size("some_string"). This decision is also arbitrary.. ++ */ ++ ++/* here is infrastructure for formated flows */ ++ ++#define SUBFILE_HEADER_MAGIC 0x19196605 ++#define FLOW_HEADER_MAGIC 0x01194304 ++ ++#include "../plugin.h" ++#include "../../debug.h" ++#include "../../forward.h" ++#include "../object.h" ++#include "../item/item.h" ++#include "../item/static_stat.h" ++#include "../../dformat.h" ++#include "../znode.h" ++#include "../inode.h" ++ ++#include ++#include /* for struct file */ ++#include /* for struct list_head */ ++ ++typedef enum { ++ LIGHT_WEIGHT_FILE, ++ ORDINARY_FILE, ++ INVERT_FILE ++} inv_entry_type; ++ ++typedef struct flow_header { ++ d32 fl_magic; ++ d16 fl_nr; /* number of subfiles in the flow */ ++}; ++ ++typedef struct subfile_header { ++ d32 sh_magic; /* subfile magic */ ++ d16 sh_type; /* type of subfile: light-weight, ordinary, invert */ ++ d16 sh_arg_len; /* lenght of lookup argument (filename, key) */ ++ d32 sh_body_len; /* lenght of subfile body */ ++}; ++ ++/* functions to get/set fields of flow header */ ++ ++static void fl_set_magic(flow_header * fh, __u32 value) ++{ ++ cputod32(value, &fh->fh_magic); ++} ++ ++static __u32 fl_get_magic(flow_header * fh) ++{ ++ return d32tocpu(&fh->fh_magic); ++} ++static void fl_set_number(flow_header * fh, __u16 value) ++{ ++ cputod16(value, &fh->fh_nr); ++} ++static unsigned fl_get_number(flow_header * fh) ++{ ++ return d16tocpu(&fh->fh_nr); ++} ++ ++/* functions to get/set fields of subfile header */ ++ ++static void sh_set_magic(subfile_header * sh, __u32 value) ++{ ++ cputod32(value, &sh->sh_magic); ++} ++ ++static __u32 sh_get_magic(subfile_header * sh) ++{ ++ return d32tocpu(&sh->sh_magic); ++} ++static void sh_set_type(subfile_header * sh, __u16 value) ++{ ++ cputod16(value, &sh->sh_magic); ++} ++static unsigned sh_get_type(subfile_header * sh) ++{ ++ return d16tocpu(&sh->sh_magic); ++} ++static void sh_set_arg_len(subfile_header * sh, __u16 value) ++{ ++ cputod16(value, &sh->sh_arg_len); ++} ++static unsigned sh_get_arg_len(subfile_header * sh) ++{ ++ return d16tocpu(&sh->sh_arg_len); ++} ++static void sh_set_body_len(subfile_header * sh, __u32 value) ++{ ++ cputod32(value, &sh->sh_body_len); ++} ++ ++static __u32 sh_get_body_len(subfile_header * sh) ++{ ++ return d32tocpu(&sh->sh_body_len); ++} ++ ++/* in-core minimal stat-data, light-weight analog of inode */ ++ ++struct incore_sd_base { ++ umode_t isd_mode; ++ nlink_t isd_nlink; ++ loff_t isd_size; ++ char *isd_data; /* 'subflow' to write */ ++}; ++ ++/* open invert create a list of invert entries, ++ every entry is represented by structure inv_entry */ ++ ++struct inv_entry { ++ struct list_head *ie_list; ++ struct file *ie_file; /* this is NULL if the file doesn't ++ have unformated nodes */ ++ struct incore_sd_base *ie_sd; /* inode-less analog of struct file */ ++}; ++ ++/* allocate and init invert entry */ ++ ++static struct inv_entry *allocate_inv_entry(void) ++{ ++ struct inv_entry *inv_entry; ++ ++ inv_entry = reiser4_kmalloc(sizeof(struct inv_entry), GFP_KERNEL); ++ if (!inv_entry) ++ return ERR_PTR(RETERR(-ENOMEM)); ++ inv_entry->ie_file = NULL; ++ inv_entry->ie_sd = NULL; ++ INIT_LIST_HEAD(&inv_entry->ie_list); ++ return inv_entry; ++} ++ ++static int put_inv_entry(struct inv_entry *ientry) ++{ ++ int result = 0; ++ ++ assert("edward-96", ientry != NULL); ++ assert("edward-97", ientry->ie_list != NULL); ++ ++ list_del(ientry->ie_list); ++ if (ientry->ie_sd != NULL) { ++ kfree(ientry->ie_sd); ++ kfree(ientry); ++ } ++ if (ientry->ie_file != NULL) ++ result = filp_close(ientry->file, NULL); ++ return result; ++} ++ ++static int allocate_incore_sd_base(struct inv_entry *inv_entry) ++{ ++ struct incore_sd_base *isd_base assert("edward-98", inv_entry != NULL); ++ assert("edward-99", inv_entry->ie_inode = NULL); ++ assert("edward-100", inv_entry->ie_sd = NULL); ++ ++ isd_base = reiser4_kmalloc(sizeof(struct incore_sd_base), GFP_KERNEL); ++ if (!isd_base) ++ return RETERR(-ENOMEM); ++ inv_entry->ie_sd = isd_base; ++ return 0; ++} ++ ++/* this can be installed as ->init_inv_entry () method of ++ item_plugins[ STATIC_STAT_DATA_IT ] (fs/reiser4/plugin/item/item.c). ++ Copies data from on-disk stat-data format into light-weight analog of inode . ++ Doesn't hanlde stat-data extensions. */ ++ ++static void sd_base_load(struct inv_entry *inv_entry, char *sd) ++{ ++ reiser4_stat_data_base *sd_base; ++ ++ assert("edward-101", inv_entry != NULL); ++ assert("edward-101", inv_entry->ie_sd != NULL); ++ assert("edward-102", sd != NULL); ++ ++ sd_base = (reiser4_stat_data_base *) sd; ++ inv_entry->incore_sd_base->isd_mode = d16tocpu(&sd_base->mode); ++ inv_entry->incore_sd_base->isd_nlink = d32tocpu(&sd_base->nlink); ++ inv_entry->incore_sd_base->isd_size = d64tocpu(&sd_base->size); ++ inv_entry->incore_sd_base->isd_data = NULL; ++} ++ ++/* initialise incore stat-data */ ++ ++static void init_incore_sd_base(struct inv_entry *inv_entry, coord_t * coord) ++{ ++ reiser4_plugin *plugin = item_plugin_by_coord(coord); ++ void *body = item_body_by_coord(coord); ++ ++ assert("edward-103", inv_entry != NULL); ++ assert("edward-104", plugin != NULL); ++ assert("edward-105", body != NULL); ++ ++ sd_base_load(inv_entry, body); ++} ++ ++/* takes a key or filename and allocates new invert_entry, ++ init and adds it into the list, ++ we use lookup_sd_by_key() for light-weight files and VFS lookup by filename */ ++ ++int get_inv_entry(struct inode *invert_inode, /* inode of invert's body */ ++ inv_entry_type type, /* LIGHT-WEIGHT or ORDINARY */ ++ const reiser4_key * key, /* key of invert entry stat-data */ ++ char *filename, /* filename of the file to be opened */ ++ int flags, int mode) ++{ ++ int result; ++ struct inv_entry *ientry; ++ ++ assert("edward-107", invert_inode != NULL); ++ ++ ientry = allocate_inv_entry(); ++ if (IS_ERR(ientry)) ++ return (PTR_ERR(ientry)); ++ ++ if (type == LIGHT_WEIGHT_FILE) { ++ coord_t coord; ++ lock_handle lh; ++ ++ assert("edward-108", key != NULL); ++ ++ init_coord(&coord); ++ init_lh(&lh); ++ result = ++ lookup_sd_by_key(meta_subvol_tree(), ++ ZNODE_READ_LOCK, &coord, &lh, key); ++ if (result == 0) ++ init_incore_sd_base(ientry, coord); ++ ++ done_lh(&lh); ++ done_coord(&coord); ++ return (result); ++ } else { ++ struct file *file = filp_open(filename, flags, mode); ++ /* FIXME_EDWARD here we need to check if we ++ did't follow to any mount point */ ++ ++ assert("edward-108", filename != NULL); ++ ++ if (IS_ERR(file)) ++ return (PTR_ERR(file)); ++ ientry->ie_file = file; ++ return 0; ++ } ++} ++ ++/* takes inode of invert, reads the body of this invert, parses it, ++ opens all invert entries and return pointer on the first inv_entry */ ++ ++struct inv_entry *open_invert(struct file *invert_file) ++{ ++ ++} ++ ++ssize_t subfile_read(struct *invert_entry, flow * f) ++{ ++ ++} ++ ++ssize_t subfile_write(struct *invert_entry, flow * f) ++{ ++ ++} ++ ++ssize_t invert_read(struct *file, flow * f) ++{ ++ ++} ++ ++ssize_t invert_write(struct *file, flow * f) ++{ ++ ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/Makefile linux-5.10.2/fs/reiser4/plugin/file/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/file/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/Makefile 2020-12-23 16:07:46.124813217 +0100 +@@ -0,0 +1,8 @@ ++obj-$(CONFIG_REISER4_FS) += file_plugins.o ++ ++file_plugins-objs := \ ++ file.o \ ++ tail_conversion.o \ ++ symlink.o \ ++ cryptcompress.o \ ++ stripe.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/stripe.c linux-5.10.2/fs/reiser4/plugin/file/stripe.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/stripe.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/stripe.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,1313 @@ ++/* ++ Copyright (c) 2018-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++/* ++ * Implementation of regular files with distributed bodies. ++ * ++ * Logical unit of distribution in such file is called "stripe". ++ * Every stripe, which got physical addresses, is composed of extents ++ * (IO units), and every extent is a set of filesystem blocks (allocation ++ * units) with contiguous disk addresses. ++ * Neighboring extents of any two adjacent (in the logical order) stripes, ++ * which got to the same device, get merged at the stripe boundary if ++ * their physical addresses are adjusent. ++ * In the storage tree extents are represented by extent pointers (items) ++ * of EXTENT41_POINTER_ID. Extent pointer's key is calculated like for ++ * classic unix files (UNIX_FILE_PLUGIN_ID) except the ordering component, ++ * which in our case contains ID of a brick (subvolume), where that extent ++ * should be stored in. ++ * Holes in a striped file are not represented by any items. ++ */ ++ ++#include "../../inode.h" ++#include "../../super.h" ++#include "../../tree_walk.h" ++#include "../../carry.h" ++#include "../../page_cache.h" ++#include "../object.h" ++#include "../cluster.h" ++#include "../../safe_link.h" ++#include "../volume/volume.h" ++ ++#include ++#include ++#include ++ ++reiser4_block_nr estimate_migration_iter(void); ++reiser4_block_nr estimate_write_stripe_meta(int count); ++int readpages_filler_generic(void *data, struct page *page, int striped); ++ ++static inline reiser4_extent *ext_by_offset(const znode *node, int offset) ++{ ++ reiser4_extent *ext; ++ ++ ext = (reiser4_extent *) (zdata(node) + offset); ++ return ext; ++} ++ ++int build_body_key_stripe(struct inode *inode, loff_t off, reiser4_key *key) ++{ ++ build_body_key_common(inode, key); ++ set_key_ordering(key, KEY_ORDERING_MASK /* max value */); ++ set_key_offset(key, (__u64) off); ++ return 0; ++} ++ ++int flow_by_inode_stripe(struct inode *inode, ++ const char __user *buf, int user, ++ loff_t size, loff_t off, ++ rw_op op, flow_t *flow) ++{ ++ flow->length = size; ++ memcpy(&flow->data, &buf, sizeof(buf)); ++ flow->user = user; ++ flow->op = op; ++ /* ++ * calculate key of write position and insert it into flow->key ++ */ ++ return build_body_key_stripe(inode, off, &flow->key); ++} ++ ++/* ++ * Tree search with a sealing technique for striped files ++ * ++ * To save CPU resources, every time before releasing a longterm lock ++ * we "seal" a position in the tree, which represents an existing object. ++ * Next time when we want to lock a positon in the tree, we check the seal. ++ * If it is unbroken, and it was created for a suitable object, we don't ++ * perform an expensive tree traversal. Instead, we lock the "sealed" node ++ * and perform fast lookup from the "sealed" position. ++ */ ++ ++#if REISER4_DEBUG ++ ++static inline int equal_to_ldk_nonprec(znode *node, const reiser4_key *key) ++{ ++ int ret; ++ ++ read_lock_dk(znode_get_tree(node)); ++ ret = all_but_ordering_keyeq(key, znode_get_ld_key(node)); ++ read_unlock_dk(znode_get_tree(node)); ++ return ret; ++} ++#endif ++ ++static inline int equal_to_rdk_nonprec(znode *node, const reiser4_key *key) ++{ ++ int ret; ++ ++ read_lock_dk(znode_get_tree(node)); ++ ret = all_but_ordering_keyeq(key, znode_get_rd_key(node)); ++ read_unlock_dk(znode_get_tree(node)); ++ return ret; ++} ++ ++/** ++ * Check if the seal was created against the previous block pointer. ++ * And if so, then validate it. ++ */ ++static int hint_validate(hint_t *hint, reiser4_tree *tree, ++ const reiser4_key *key, znode_lock_mode lock_mode) ++{ ++ reiser4_key vkey; ++ ++ if (!hint || !hint_is_set(hint) || hint->mode != lock_mode || ++ get_key_offset(key) != hint->offset + PAGE_SIZE) ++ return RETERR(-E_REPEAT); ++ ++ assert("edward-2377", hint->ext_coord.lh == &hint->lh); ++ ++ memcpy(&vkey, key, sizeof(vkey)); ++ set_key_offset(&vkey, hint->offset); ++ ++ return reiser4_seal_validate(&hint->seal, tree, ++ &hint->ext_coord.coord, &vkey, ++ hint->ext_coord.lh, lock_mode, ++ ZNODE_LOCK_LOPRI); ++} ++ ++/** ++ * Search-by-key procedure optimized for sequential operations ++ * by using "sealing" technique. ++ * ++ * @key: key of a block pointer we are looking for. That key is ++ * not precise, that is we don't know its "ordering" component. ++ */ ++int find_stripe_item(hint_t *hint, const reiser4_key *key, ++ znode_lock_mode lock_mode, struct inode *inode) ++{ ++ int ret; ++ coord_t *coord; ++ coord_t rcoord; ++ lock_handle *lh; ++ struct extent_coord_extension *ext_coord; ++ ++ assert("edward-2378", hint != NULL); ++ assert("edward-2379", inode != NULL); ++ assert("edward-2380", reiser4_schedulable()); ++ assert("edward-2381", (get_key_offset(key) & (PAGE_SIZE - 1)) == 0); ++ assert("edward-2382", inode_file_plugin(inode) == ++ file_plugin_by_id(STRIPED_FILE_PLUGIN_ID)); ++ ++ coord = &hint->ext_coord.coord; ++ lh = hint->ext_coord.lh; ++ init_lh(lh); ++ ++ ret = hint_validate(hint, meta_subvol_tree(), key, lock_mode); ++ if (ret) ++ goto nohint; ++ /* ++ * we always seal only valid coord of existing block pointer ++ */ ++ assert("edward-2385", ++ WITH_DATA(coord->node, coord_is_existing_unit(coord))); ++ hint->ext_coord.valid = 1; ++ ext_coord = &hint->ext_coord.extension.extent; ++ ++ /* fast lookup in the sealed coord locality */ ++ ++ ext_coord->pos_in_unit ++; ++ if (ext_coord->pos_in_unit < ext_coord->width) ++ /* ++ * found within the unit specified by @coord ++ */ ++ return CBK_COORD_FOUND; ++ /* ++ * end of unit is reached. Try to move to next unit ++ */ ++ ext_coord->pos_in_unit = 0; ++ coord->unit_pos ++; ++ if (coord->unit_pos < ext_coord->nr_units) { ++ /* ++ * found within next unit. Update coord extension ++ */ ++ ext_coord->ext_offset += sizeof(reiser4_extent); ++ ext_coord->width = ++ extent_get_width(ext_by_offset(coord->node, ++ ext_coord->ext_offset)); ++ ON_DEBUG(ext_coord->extent = ++ *ext_by_offset(coord->node, ext_coord->ext_offset)); ++ return CBK_COORD_FOUND; ++ } ++ /* ++ * end of item reached. Try to find in the next item at the right ++ */ ++ coord->unit_pos --; ++ coord->between = AFTER_UNIT; ++ hint->ext_coord.valid = 0; /* moving to the next item invalidates ++ the coord extension */ ++ ret = zload(lh->node); ++ if (ret) { ++ done_lh(lh); ++ return ret; ++ } ++ coord_dup(&rcoord, coord); ++ if (!coord_next_item(&rcoord)) { ++ /* ++ * rcoord is set to next item ++ */ ++ reiser4_key rkey; ++ if (!item_is_extent(&rcoord) || ++ !all_but_ordering_keyeq(key, ++ item_key_by_coord(&rcoord, &rkey))) { ++ zrelse(lh->node); ++ assert("edward-2386", coord->between == AFTER_UNIT); ++ return CBK_COORD_NOTFOUND; ++ } ++ coord_dup(coord, &rcoord); ++ zrelse(lh->node); ++ coord->between = AT_UNIT; ++ return CBK_COORD_FOUND; ++ } ++ zrelse(lh->node); ++ /* ++ * end of node reached. Try to find in the next node at the right ++ */ ++ if (equal_to_rdk_nonprec(coord->node, key)) { ++ ret = goto_right_neighbor(coord, lh); ++ if (unlikely(ret)) { ++ done_lh(lh); ++ assert("edward-2387", ret != CBK_COORD_NOTFOUND); ++ return ret == -E_NO_NEIGHBOR ? RETERR(-EIO) : ret; ++ } ++ ret = zload(lh->node); ++ if (unlikely(ret)) { ++ done_lh(lh); ++ return ret; ++ } ++ if (unlikely(node_is_empty(coord->node))) { ++ /* ++ * for simplicity we don't go further to ++ * the right. Instead we call slow lookup. ++ */ ++ zrelse(lh->node); ++ done_lh(lh); ++ goto nohint; ++ } ++ /* ++ * it is guaranteed that the first item at the ++ * right neighbor has @key, because exclusive, or ++ * non-exclusive lock of the file is held by us. ++ */ ++ assert("edward-2384", equal_to_ldk_nonprec(coord->node, key)); ++ zrelse(lh->node); ++ assert("edward-2388", coord->between == AT_UNIT); ++ return CBK_COORD_FOUND; ++ } ++ assert("edward-2389", coord->between == AFTER_UNIT); ++ return CBK_COORD_NOTFOUND; ++ nohint: ++ /* full-fledged lookup */ ++ coord_init_zero(coord); ++ hint->ext_coord.valid = 0; ++ return find_file_item_nohint(coord, lh, key, lock_mode, inode); ++} ++ ++ssize_t read_stripe(struct file *file, char __user *buf, ++ size_t read_amount, loff_t *off) ++{ ++ ssize_t result; ++ struct inode *inode; ++ reiser4_context *ctx; ++ struct unix_file_info *uf_info; ++ ++ if (unlikely(read_amount == 0)) ++ return 0; ++ ++ inode = file_inode(file); ++ assert("edward-2029", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ result = reserve_update_sd_common(inode); ++ if (unlikely(result != 0)) ++ goto out; ++ uf_info = unix_file_inode_data(inode); ++ ++ get_nonexclusive_access(uf_info); ++ result = new_sync_read(file, buf, read_amount, off); ++ drop_nonexclusive_access(uf_info); ++ out: ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++static inline size_t write_granularity(void) ++{ ++ if (current_stripe_bits) { ++ int ret = 1 << (current_stripe_bits - current_blocksize_bits); ++ if (ret > DEFAULT_WRITE_GRANULARITY) ++ ret = DEFAULT_WRITE_GRANULARITY; ++ return ret; ++ } else ++ return DEFAULT_WRITE_GRANULARITY; ++} ++ ++static inline ssize_t write_extent_stripe_handle_enospc(struct file *file, ++ struct inode *inode, ++ const char __user *buf, ++ size_t count, ++ loff_t *pos) ++{ ++ int ret; ++ struct unix_file_info *uf_info = unix_file_inode_data(inode); ++ ++ get_nonexclusive_access(uf_info); ++ ret = write_extent_stripe(file, inode, buf, count, pos, 0); ++ if (ret == -ENOSPC) { ++ drop_nonexclusive_access(uf_info); ++ txnmgr_force_commit_all(inode->i_sb, 0); ++ get_nonexclusive_access(uf_info); ++ ret = write_extent_stripe(file, inode, buf, count, pos, 0); ++ if (ret == -ENOSPC && ++ reiser4_is_set(reiser4_get_current_sb(), ++ REISER4_PROXY_IO)) { ++ drop_nonexclusive_access(uf_info); ++ reiser4_txn_restart_current(); ++ get_nonexclusive_access(uf_info); ++ ret = write_extent_stripe(file, inode, buf, count, pos, ++ UPX_PROXY_FULL); ++ if (0 && ret == -ENOSPC) { ++ drop_nonexclusive_access(uf_info); ++ txnmgr_force_commit_all(inode->i_sb, 0); ++ get_nonexclusive_access(uf_info); ++ ret = write_extent_stripe(file, inode, buf, ++ count, pos, ++ UPX_PROXY_FULL); ++ } ++ } ++ } ++ drop_nonexclusive_access(uf_info); ++ return ret; ++} ++ ++ssize_t write_stripe(struct file *file, ++ const char __user *buf, ++ size_t count, loff_t *pos, ++ struct dispatch_context *cont) ++{ ++ int ret; ++ reiser4_context *ctx = get_current_context(); ++ struct inode *inode = file_inode(file); ++ ssize_t written = 0; ++ int to_write; ++ int chunk_size = PAGE_SIZE * write_granularity(); ++ size_t left = count; ++ ++ assert("edward-2030", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ ret = file_remove_privs(file); ++ if (ret) { ++ context_set_commit_async(ctx); ++ return ret; ++ } ++ /* remove_suid might create a transaction */ ++ reiser4_txn_restart(ctx); ++ ++ while (left) { ++ int update_sd = 0; ++ /* ++ * write not more then one logical chunk per iteration ++ */ ++ to_write = chunk_size - (*pos & (chunk_size - 1)); ++ if (left < to_write) ++ to_write = left; ++ ++ written = write_extent_stripe_handle_enospc(file, inode, buf, ++ to_write, pos); ++ if (written < 0) ++ break; ++ /* ++ * something is written ++ */ ++ if (*pos + written > inode->i_size) { ++ INODE_SET_FIELD(inode, i_size, *pos + written); ++ update_sd = 1; ++ } ++ if (!IS_NOCMTIME(inode)) { ++ inode->i_ctime = inode->i_mtime = current_time(inode); ++ update_sd = 1; ++ } ++ if (update_sd) { ++ /* ++ * space for update_sd was reserved ++ * in write_extent() ++ */ ++ ret = reiser4_update_sd(inode); ++ if (ret) { ++ warning("edward-1574", ++ "Can not update stat-data: %i. FSCK?", ++ ret); ++ context_set_commit_async(ctx); ++ break; ++ } ++ } ++ /* ++ * tell VM how many pages were dirtied. Maybe number of pages ++ * which were dirty already should not be counted ++ */ ++ reiser4_throttle_write(inode); ++ left -= written; ++ buf += written; ++ *pos += written; ++ } ++ if (ret == 0 && ((file->f_flags & O_SYNC) || IS_SYNC(inode))) { ++ reiser4_txn_restart_current(); ++ grab_space_enable(); ++ ret = reiser4_sync_file_common(file, 0, LONG_MAX, ++ 0 /* data and stat data */); ++ if (ret) ++ warning("edward-2367", "failed to sync file %llu", ++ (unsigned long long)get_inode_oid(inode)); ++ } ++ /* ++ * return number of written bytes or error code if nothing is ++ * written. Note, that it does not work correctly in case when ++ * sync_unix_file returns error ++ */ ++ return (count - left) ? (count - left) : ret; ++} ++ ++static inline int readpages_filler_stripe(void *data, struct page *page) ++{ ++ return reiser4_readpages_filler_generic(data, page, 1); ++} ++ ++int readpages_stripe(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages) ++{ ++ return reiser4_readpages_generic(file, mapping, pages, nr_pages, ++ readpages_filler_stripe); ++} ++ ++void validate_extended_coord(uf_coord_t *uf_coord, loff_t offset); ++/** ++ * ->readpage() method of address space operations for striped-file plugin ++ */ ++int readpage_stripe(struct file *file, struct page *page) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *inode; ++ reiser4_key key; ++ hint_t *hint; ++ lock_handle *lh; ++ coord_t *coord; ++ ++ assert("vs-1062", PageLocked(page)); ++ assert("vs-976", !PageUptodate(page)); ++ assert("vs-1061", page->mapping && page->mapping->host); ++ ++ inode = page->mapping->host; ++ ++ if (inode->i_size <= page_offset(page)) { ++ /* page is out of file */ ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ unlock_page(page); ++ return 0; ++ } ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ unlock_page(page); ++ return PTR_ERR(ctx); ++ } ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) { ++ unlock_page(page); ++ reiser4_exit_context(ctx); ++ return RETERR(-ENOMEM); ++ } ++ ++ result = load_file_hint(file, hint); ++ if (result) { ++ kfree(hint); ++ unlock_page(page); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ lh = &hint->lh; ++ /* ++ * construct key of the page's first byte ++ */ ++ build_body_key_stripe(inode, page_offset(page), &key); ++ /* ++ * look for file metadata corresponding to the page's first byte ++ */ ++ get_page(page); ++ unlock_page(page); ++ result = find_file_item_nohint(&hint->ext_coord.coord, ++ hint->ext_coord.lh, &key, ++ ZNODE_READ_LOCK, inode); ++ lock_page(page); ++ put_page(page); ++ ++ if (page->mapping == NULL) { ++ /* ++ * readpage allows truncate to run concurrently. ++ * Page was truncated while it was not locked ++ */ ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return -EINVAL; ++ } ++ if (IS_CBKERR(result)) { ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ if (PageUptodate(page)) { ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return 0; ++ } ++ coord = &hint->ext_coord.coord; ++ result = zload(coord->node); ++ if (result) { ++ done_lh(lh); ++ kfree(hint); ++ unlock_page(page); ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ validate_extended_coord(&hint->ext_coord, page_offset(page)); ++ ++ if (coord_is_existing_unit(coord)) { ++ result = reiser4_readpage_extent(coord, page); ++ assert("edward-2032", result == 0); ++ } else { ++ /* hole in the file */ ++ result = __reiser4_readpage_extent(NULL, NULL, 0, page); ++ assert("edward-2033", result == 0); ++ } ++ if (result) { ++ unlock_page(page); ++ reiser4_unset_hint(hint); ++ } else { ++ build_body_key_stripe(inode, ++ (loff_t)(page->index + 1) << PAGE_SHIFT, ++ &key); ++ /* FIXME should call reiser4_set_hint() */ ++ reiser4_unset_hint(hint); ++ } ++ assert("edward-2034", ++ ergo(result == 0, (PageLocked(page) || PageUptodate(page)))); ++ assert("edward-2035", ++ ergo(result != 0, !PageLocked(page))); ++ zrelse(coord->node); ++ done_lh(lh); ++ ++ kfree(hint); ++ /* ++ * FIXME: explain why it is needed. HINT: page allocation in write can ++ * not be done when atom is not NULL because reiser4_writepage can not ++ * kick entd and have to eflush ++ */ ++ reiser4_txn_restart(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++#define CUT_TREE_MIN_ITERATIONS 64 ++ ++int cut_tree_worker_stripe(tap_t *tap, const reiser4_key *from_key, ++ const reiser4_key *to_key, ++ reiser4_key *smallest_removed, struct inode *object, ++ int truncate, int *progress) ++{ ++ int ret; ++ coord_t left_coord; ++ reiser4_key left_key; ++ reiser4_key right_key; ++ lock_handle next_node_lock; ++ ++ assert("edward-2287", tap->coord->node != NULL); ++ assert("edward-2288", znode_is_write_locked(tap->coord->node)); ++ ++ *progress = 0; ++ init_lh(&next_node_lock); ++ ++ while (1) { ++ znode *node = tap->coord->node; ++ ++ ret = reiser4_get_left_neighbor(&next_node_lock, node, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (ret != 0 && ret != -E_NO_NEIGHBOR) ++ break; ++ ret = reiser4_tap_load(tap); ++ if (ret) ++ break; ++ if (*progress) ++ /* prepare right point */ ++ coord_init_last_unit(tap->coord, node); ++ /* prepare left point */ ++ ret = node_plugin_by_node(node)->lookup(node, from_key, ++ FIND_MAX_NOT_MORE_THAN, ++ &left_coord); ++ if (IS_CBKERR(ret)) ++ break; ++ /* ++ * adjust coordinates so that they are set to existing units ++ */ ++ if (coord_set_to_right(&left_coord) || ++ coord_set_to_left(tap->coord)) { ++ ret = CBK_COORD_NOTFOUND; ++ break; ++ } ++ if (coord_compare(&left_coord, tap->coord) == ++ COORD_CMP_ON_RIGHT) { ++ /* no keys of [from_key, @to_key] in the tree */ ++ ret = CBK_COORD_NOTFOUND; ++ break; ++ } ++ /* ++ * Make keys precise. ++ * Set right_key to last byte of the item at tap->coord ++ */ ++ item_key_by_coord(tap->coord, &right_key); ++ set_key_offset(&right_key, ++ get_key_offset(&right_key) + ++ reiser4_extent_size(tap->coord) - 1); ++ assert("edward-2289", ++ get_key_offset(&right_key) <= get_key_offset(to_key)); ++ assert("edward-2290", ++ get_key_offset(from_key) <= get_key_offset(&right_key)); ++ /* ++ * @from_key may not exist in the tree ++ */ ++ unit_key_by_coord(&left_coord, &left_key); ++ ++ if (get_key_offset(&left_key) < get_key_offset(from_key)) ++ set_key_offset(&left_key, get_key_offset(from_key)); ++ ++ /* cut data from one node */ ++ ret = kill_node_content(&left_coord, tap->coord, ++ &left_key, &right_key, ++ smallest_removed, ++ next_node_lock.node /* left neighbor */, ++ object, truncate); ++ reiser4_tap_relse(tap); ++ if (ret) ++ break; ++ (*progress)++; ++ if (keyle(smallest_removed, from_key)) ++ break; ++ if (next_node_lock.node == NULL) ++ break; ++ ret = reiser4_tap_move(tap, &next_node_lock); ++ done_lh(&next_node_lock); ++ if (ret) ++ break; ++ /* break long truncate if atom requires commit */ ++ ++ if (*progress > CUT_TREE_MIN_ITERATIONS && ++ current_atom_should_commit()) { ++ ret = -E_REPEAT; ++ break; ++ } ++ } ++ done_lh(&next_node_lock); ++ return ret; ++} ++ ++/** ++ * Cut body of a striped file ++ */ ++static int cut_file_items_stripe(struct inode *inode, loff_t new_size, ++ int update_sd, loff_t cur_size, ++ reiser4_key *smallest_removed, ++ int (*update_size_fn) (struct inode *, ++ loff_t, int)) ++{ ++ int ret = 0; ++ reiser4_key from_key, to_key; ++ reiser4_tree *tree = meta_subvol_tree(); ++ ++ assert("edward-2021", inode_file_plugin(inode) == ++ file_plugin_by_id(STRIPED_FILE_PLUGIN_ID)); ++ ++ build_body_key_stripe(inode, cur_size - 1, &to_key); ++ from_key = to_key; ++ set_key_offset(&from_key, new_size); ++ ++ while (1) { ++ int progress = 0; ++ /* ++ * this takes sbinfo->delete_mutex ++ */ ++ ret = reserve_cut_iteration(inode); ++ if (ret) ++ return ret; ++ ++ ret = reiser4_cut_tree_object(tree, ++ &from_key, &to_key, ++ smallest_removed, inode, ++ 1 /* truncate */, &progress); ++ assert("edward-2291", ret != -E_NO_NEIGHBOR); ++ ++ if (ret == -E_REPEAT) { ++ if (progress) { ++ ret = update_size_fn(inode, ++ get_key_offset(smallest_removed), ++ update_sd); ++ if (ret) ++ break; ++ } ++ /* this releases sbinfo->delete_mutex */ ++ ++ reiser4_release_reserved(inode->i_sb); ++ reiser4_txn_restart_current(); ++ continue; ++ } else if (ret == 0 || ret == CBK_COORD_NOTFOUND) ++ ret = update_size_fn(inode, new_size, update_sd); ++ break; ++ } ++ /* this releases sbinfo->delete_mutex */ ++ ++ reiser4_release_reserved(inode->i_sb); ++ return ret; ++} ++ ++#if 0 ++static void check_partial_page_truncate(struct inode *inode, ++ reiser4_key *smallest_removed) ++{ ++ int ret; ++ reiser4_key key; ++ lock_handle lh; ++ coord_t coord; ++ ++ init_lh(&lh); ++ memcpy(&key, smallest_removed, sizeof(key)); ++ set_key_offset(&key, round_down(inode->i_size, PAGE_SIZE)); ++ ++ ret = find_file_item_nohint(&coord, &lh, &key, ++ ZNODE_READ_LOCK, inode); ++ done_lh(&lh); ++ assert("edward-2369", ret == 0); ++ assert("edward-2370", coord.between == AT_UNIT); ++} ++#endif ++ ++#if REISER4_DEBUG ++static void check_truncate_jnodes(struct inode *inode, pgoff_t start) ++{ ++ int ret; ++ jnode *node = NULL; ++ ++ read_lock_tree(); ++ ret = radix_tree_gang_lookup(jnode_tree_by_reiser4_inode(reiser4_inode_data(inode)), ++ (void **)node, start, 1); ++ read_unlock_tree(); ++ if (ret) ++ warning("edward-2467", "found jnode index=%lu, file_size=%llu", ++ index_jnode(node), inode->i_size); ++} ++#endif ++ ++/** ++ * Exclusive access to the file must be acquired ++ */ ++static int shorten_stripe(struct inode *inode, loff_t new_size) ++{ ++ int result; ++ struct page *page; ++ int padd_from; ++ unsigned long index; ++ reiser4_key smallest_removed; ++ ++ memcpy(&smallest_removed, ++ reiser4_max_key(), sizeof(smallest_removed)); ++ /* ++ * cut file body ++ */ ++ result = cut_file_items_stripe(inode, new_size, ++ 1, /* update_sd */ ++ get_key_offset(reiser4_max_key()), ++ &smallest_removed, ++ reiser4_update_file_size); ++ if (result) ++ return result; ++ assert("vs-1105", new_size == inode->i_size); ++ /* ++ * drop all the pages that don't have jnodes (i.e. pages ++ * which can not be truncated by cut_file_items() because ++ * of holes, which are not represented by any items, so ++ * that we can't call kill hooks to truncate them like in ++ * the case of calassic unix-files ++ */ ++ truncate_inode_pages(inode->i_mapping, round_up(new_size, PAGE_SIZE)); ++ ON_DEBUG(check_truncate_jnodes(inode, ++ round_up(new_size, PAGE_SIZE) >> PAGE_SHIFT)); ++ ++ padd_from = inode->i_size & (PAGE_SIZE - 1); ++ if (!padd_from) ++ /* file is truncated to page boundary */ ++ return 0; ++ if (get_key_offset(&smallest_removed) != new_size) ++ /* ++ * the cut offset is in the logical block, which is ++ * not represented by a block pointer in the tree - ++ * there is no need to handle partial page truncate ++ */ ++ return 0; ++ /* ++ * Handle partial page truncate. ++ * Reserve space on meta-data brick ++ */ ++ grab_space_enable(); ++ result = reiser4_grab_reserved(reiser4_get_current_sb(), ++ estimate_write_stripe_meta(1), ++ BA_CAN_COMMIT, ++ get_meta_subvol()); ++ if (result) { ++ assert("edward-2295", ++ get_current_super_private()->delete_mutex_owner == NULL); ++ return result; ++ } ++ /* ++ * reserve space on data brick, where the partially ++ * trunated page should be stored ++ */ ++ grab_space_enable(); ++ result = reiser4_grab_reserved(reiser4_get_current_sb(), ++ 1, /* count */ ++ BA_CAN_COMMIT, ++ subvol_by_key(&smallest_removed)); ++ if (result) ++ return result; ++ /* ++ * zero content of partially truncated page ++ */ ++ index = (inode->i_size >> PAGE_SHIFT); ++ ++ page = read_mapping_page(inode->i_mapping, index, NULL); ++ if (IS_ERR(page)) { ++ reiser4_release_reserved(inode->i_sb); ++ return PTR_ERR(page); ++ } ++ wait_on_page_locked(page); ++ if (!PageUptodate(page)) { ++ put_page(page); ++ reiser4_release_reserved(inode->i_sb); ++ return RETERR(-EIO); ++ } ++ lock_page(page); ++ assert("edward-2036", PageLocked(page)); ++ zero_user_segment(page, padd_from, PAGE_SIZE); ++ unlock_page(page); ++ ++ result = find_or_create_extent_stripe(page, UPX_TRUNCATE); ++ ++ reiser4_release_reserved(inode->i_sb); ++ put_page(page); ++ return result; ++} ++ ++static int truncate_body_stripe(struct inode *inode, struct iattr *attr) ++{ ++ loff_t new_size = attr->ia_size; ++ ++ if (inode->i_size < new_size) { ++ /* expand */ ++ return reiser4_update_file_size(inode, new_size, 1); ++ } else if (inode->i_size > new_size) ++ /* shrink */ ++ return shorten_stripe(inode, new_size); ++ return 0; ++} ++ ++int setattr_stripe(struct dentry *dentry, struct iattr *attr) ++{ ++ return reiser4_setattr_generic(dentry, attr, truncate_body_stripe); ++} ++ ++int delete_object_stripe(struct inode *inode) ++{ ++ struct unix_file_info *uf_info; ++ int result; ++ ++ if (reiser4_inode_get_flag(inode, REISER4_NO_SD)) ++ return 0; ++ ++ /* truncate file body first */ ++ uf_info = unix_file_inode_data(inode); ++ ++ get_exclusive_access(uf_info); ++ result = shorten_stripe(inode, 0 /* new size */); ++ drop_exclusive_access(uf_info); ++ ++ if (unlikely(result != 0)) ++ warning("edward-2037", ++ "failed to truncate striped file (%llu) on removal: %d", ++ get_inode_oid(inode), result); ++ ++ /* remove stat data and safe link */ ++ return reiser4_delete_object_common(inode); ++} ++ ++int create_object_stripe(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *data, oid_t *oid) ++{ ++ reiser4_inode *info; ++ ++ assert("edward-2038", object != NULL); ++ assert("edward-2039", parent != NULL); ++ assert("edward-2040", data != NULL); ++ assert("edward-2041", reiser4_inode_get_flag(object, REISER4_NO_SD)); ++ assert("edward-2042", data->id == STRIPED_FILE_PLUGIN_ID); ++ ++ info = reiser4_inode_data(object); ++ ++ assert("edward-2043", info != NULL); ++ /* ++ * Since striped file plugin is not default, we ++ * need to store its id in stat-data extention ++ */ ++ info->plugin_mask |= (1 << PSET_FILE); ++ ++ return write_sd_by_inode_common(object, oid); ++} ++ ++int open_stripe(struct inode *inode, struct file *file) ++{ ++ /* ++ * nothing to do at open time ++ */ ++ return 0; ++} ++ ++int release_stripe(struct inode *inode, struct file *file) ++{ ++ reiser4_free_file_fsdata(file); ++ return 0; ++} ++ ++/** ++ * Capture one anonymous page. ++ * Exclusive, or non-exclusive access to the file must be acquired. ++ */ ++static int capture_anon_page(struct page *page) ++{ ++ int ret; ++ struct inode *inode; ++ ++ if (PageWriteback(page)) ++ /* ++ * FIXME: do nothing? ++ */ ++ return 0; ++ assert("edward-2044", page->mapping && page->mapping->host); ++ ++ inode = page->mapping->host; ++ ++ assert("edward-2045", inode->i_size > page_offset(page)); ++ /* ++ * reserve space on meta-data brick ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(estimate_write_stripe_meta(1), ++ 0, /* flags */ ++ get_meta_subvol() /* where */); ++ if (ret) ++ return ret; ++ ret = find_or_create_extent_stripe(page, 0); ++ if (ret == -ENOSPC && ++ reiser4_is_set(reiser4_get_current_sb(), REISER4_PROXY_IO)) ++ ret = find_or_create_extent_stripe(page, UPX_PROXY_FULL); ++ if (ret) { ++ SetPageError(page); ++ warning("edward-2046", ++ "Failed to capture anon page of striped file: %i", ret); ++ } else ++ ret = 1; ++ return ret; ++} ++ ++int sync_jnode(jnode *node) ++{ ++ int result; ++ ++ assert("edward-2452", node != NULL); ++ assert("edward-2453", get_current_context() != NULL); ++ assert("edward-2454", get_current_context()->trans != NULL); ++ ++ do { ++ txn_atom *atom; ++ ++ spin_lock_jnode(node); ++ atom = jnode_get_atom(node); ++ spin_unlock_jnode(node); ++ result = reiser4_sync_atom(atom); ++ ++ } while (result == -E_REPEAT); ++ ++ assert("edward-2455", ++ ergo(result == 0, ++ get_current_context()->trans->atom == NULL)); ++ return result; ++} ++ ++int sync_jnode_list(struct inode *inode) ++{ ++ int result = 0; ++ unsigned long from; /* start index for radix_tree_gang_lookup */ ++ unsigned int found; /* return value for radix_tree_gang_lookup */ ++ ++ from = 0; ++ read_lock_tree(); ++ while (result == 0) { ++ jnode *node = NULL; ++ ++ found = radix_tree_gang_lookup(jnode_tree_by_inode(inode), ++ (void **)&node, from, 1); ++ if (found == 0) ++ break; ++ assert("edward-2456", node != NULL); ++ /** ++ * node may not leave radix tree because it is ++ * protected from truncating by exclusive lock ++ */ ++ jref(node); ++ read_unlock_tree(); ++ ++ from = node->key.j.index + 1; ++ ++ result = sync_jnode(node); ++ ++ jput(node); ++ read_lock_tree(); ++ } ++ read_unlock_tree(); ++ return result; ++} ++ ++static int commit_stripe_atoms(struct inode *inode) ++{ ++ int ret; ++ ++ reiser4_txn_restart_current(); ++ ret = ++ /* ++ * when we are called by ++ * filemap_fdatawrite-> ++ * do_writepages()-> ++ * reiser4_writepages_dispatch() ++ * ++ * inode->i_mapping->dirty_pages are spices into ++ * ->io_pages, leaving ->dirty_pages dirty. ++ * ++ * When we are called from ++ * reiser4_fsync()->sync_unix_file(), we have to ++ * commit atoms of all pages on the ->dirty_list. ++ * ++ * So for simplicity we just commit ->io_pages and ++ * ->dirty_pages. ++ */ ++ reiser4_sync_page_list(inode); ++ /* ++ * commit current transaction: there can be captured nodes from ++ * find_file_state() and finish_conversion(). ++ */ ++ reiser4_txn_restart_current(); ++ return ret; ++} ++ ++int writepages_stripe(struct address_space *mapping, ++ struct writeback_control *wbc) ++{ ++ return reiser4_writepages_generic(mapping, wbc, ++ capture_anon_page, ++ commit_stripe_atoms); ++} ++ ++int ioctl_stripe(struct file *filp, unsigned int cmd, unsigned long arg) ++{ ++ return reiser4_ioctl_volume(filp, cmd, arg, reiser4_volume_op_file); ++} ++ ++/** ++ * implementation of ->write_begin() address space operation ++ * for striped-file plugin ++ */ ++int write_begin_stripe(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata) ++{ ++ int ret; ++ /* ++ * Reserve space on meta-data brick. ++ * In particular, it is needed to "drill" the leaf level ++ * by search procedure. ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(estimate_write_stripe_meta(1), ++ 0, /* flags */ ++ get_meta_subvol() /* where */); ++ if (ret) ++ return ret; ++ ++ get_nonexclusive_access(unix_file_inode_data(file_inode(file))); ++ ret = reiser4_write_begin_common(file, page, pos, len, ++ readpage_stripe); ++ if (unlikely(ret != 0)) ++ drop_nonexclusive_access(unix_file_inode_data(file_inode(file))); ++ return ret; ++} ++ ++/** ++ * Implementation of ->write_end() address space operation ++ * for striped-file plugin ++ */ ++int write_end_stripe(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata) ++{ ++ int ret; ++ struct inode *inode; ++ struct unix_file_info *info; ++ ++ inode = file_inode(file); ++ info = unix_file_inode_data(inode); ++ ++ unlock_page(page); ++ ret = find_or_create_extent_stripe(page, 0); ++ if (ret == -ENOSPC && reiser4_is_set(reiser4_get_current_sb(), ++ REISER4_PROXY_IO)) ++ ret = find_or_create_extent_stripe(page, UPX_PROXY_FULL); ++ if (ret) { ++ SetPageError(page); ++ goto exit; ++ } ++ if (pos + copied > inode->i_size) { ++ INODE_SET_FIELD(inode, i_size, pos + copied); ++ ret = reiser4_update_sd(inode); ++ if (unlikely(ret != 0)) ++ warning("edward-2431", ++ "Can not update stat-data: %i. FSCK?", ++ ret); ++ } ++ exit: ++ drop_nonexclusive_access(unix_file_inode_data(file_inode(file))); ++ return ret; ++} ++ ++/** ++ * Migrate data blocks of a regular file specified by @inode ++ * Exclusive access to the file should be acquired by caller. ++ * ++ * Implementation details: ++ * Scan file body from right to left, read all pages which should ++ * get location on other bricks, and make them dirty. In flush time ++ * those pages will get disk addresses on the new bricks. ++ * ++ * IMPORTANT: This implementation assumes that logical order on ++ * the file coincides with the physical order. ++ */ ++static int __migrate_stripe(struct inode *inode, u64 *dst_id) ++{ ++ int ret; ++ reiser4_key key; /* search key */ ++ reiser4_key ikey; /* item key */ ++ struct unix_file_info *uf; ++ coord_t coord; ++ lock_handle lh; ++ item_plugin *iplug; ++ ++ /* ++ * commit all file atoms before migration! ++ */ ++ reiser4_txn_restart_current(); ++ ret = sync_jnode_list(inode); ++ reiser4_txn_restart_current(); ++ if (ret) ++ return ret; ++ all_grabbed2free(); ++ /* ++ * Reserve space for the first iteration of the migration ++ * procedure. We grab from reserved area, as rebalancing can ++ * be launched on a volume with no free space. ++ */ ++ ret = reserve_migration_iter(); ++ if (ret) ++ return ret; ++ uf = unix_file_inode_data(inode); ++ ++ reiser4_inode_set_flag(inode, REISER4_FILE_IN_MIGRATION); ++ ++ build_body_key_stripe(inode, get_key_offset(reiser4_max_key()), ++ &key); ++ while (1) { ++ znode *loaded; ++ loff_t done_off; ++ ++ init_lh(&lh); ++ ret = coord_by_key(meta_subvol_tree(), &key, ++ &coord, &lh, ZNODE_WRITE_LOCK, ++ FIND_MAX_NOT_MORE_THAN, ++ TWIG_LEVEL, TWIG_LEVEL, ++ CBK_UNIQUE, NULL); ++ if (IS_CBKERR(ret)) { ++ done_lh(&lh); ++ reiser4_release_reserved(inode->i_sb); ++ return ret; ++ } ++ ret = zload(coord.node); ++ if (ret) { ++ done_lh(&lh); ++ reiser4_release_reserved(inode->i_sb); ++ return ret; ++ } ++ loaded = coord.node; ++ ++ coord_set_to_left(&coord); ++ if (!coord_is_existing_item(&coord)) { ++ /* ++ * nothing to migrate ++ */ ++ zrelse(loaded); ++ goto done; ++ } ++ /* ++ * check that found item belongs to the file ++ */ ++ if (!inode_file_plugin(inode)->owns_item(inode, &coord)) { ++ zrelse(loaded); ++ goto done; ++ } ++ item_key_by_coord(&coord, &ikey); ++ iplug = item_plugin_by_coord(&coord); ++ assert("edward-2349", iplug->v.migrate != NULL); ++ zrelse(loaded); ++ /* ++ * Migrate data blocks (from right to left) pointed ++ * out by the found extent item at @coord. ++ * On success (ret == 0 || ret == -E_REPEAT) at least ++ * one of the mentioned blocks has to be migrated. In ++ * this case @done_off contains offset of the leftmost ++ * migrated byte ++ */ ++ ret = iplug->v.migrate(&coord, &ikey, &lh, inode, &done_off, ++ dst_id); ++ done_lh(&lh); ++ reiser4_release_reserved(inode->i_sb); ++ if (ret && ret != -E_REPEAT) ++ return ret; ++ if (done_off == 0) ++ /* nothing to migrate any more */ ++ break; ++ /* ++ * look for the item, which points out to the ++ * rightmost not processed block ++ */ ++ set_key_offset(&key, done_off - 1); ++ } ++ done: ++ /* ++ * The whole file has been successfully migrated. ++ * Clean up unbalanced status ++ */ ++ assert("edward-2104", reiser4_lock_counters()->d_refs == 0); ++ done_lh(&lh); ++ reiser4_inode_clr_flag(inode, REISER4_FILE_IN_MIGRATION); ++ return 0; ++} ++ ++int migrate_stripe(struct inode *inode, u64 *dst_id) ++{ ++ int ret; ++ ++ get_exclusive_access(unix_file_inode_data(inode)); ++ ret = __migrate_stripe(inode, dst_id); ++ drop_exclusive_access(unix_file_inode_data(inode)); ++ return ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 80 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/symfile.c linux-5.10.2/fs/reiser4/plugin/file/symfile.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/symfile.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/symfile.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,87 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Symfiles are a generalization of Unix symlinks. ++ ++ A symfile when read behaves as though you took its contents and ++ substituted them into the reiser4 naming system as the right hand side ++ of an assignment, and then read that which you had assigned to it. ++ ++ A key issue for symfiles is how to implement writes through to ++ subfiles. In general, one must have some method of determining what ++ of that which is written to the symfile is written to what subfile. ++ This can be done by use of custom plugin methods written by users, or ++ by using a few general methods we provide for those willing to endure ++ the insertion of delimiters into what is read. ++ ++ Writing to symfiles without delimiters to denote what is written to ++ what subfile is not supported by any plugins we provide in this ++ release. Our most sophisticated support for writes is that embodied ++ by the invert plugin (see invert.c). ++ ++ A read only version of the /etc/passwd file might be ++ constructed as a symfile whose contents are as follows: ++ ++ /etc/passwd/userlines/* ++ ++ or ++ ++ /etc/passwd/userlines/demidov+/etc/passwd/userlines/edward+/etc/passwd/userlines/reiser+/etc/passwd/userlines/root ++ ++ or ++ ++ /etc/passwd/userlines/(demidov+edward+reiser+root) ++ ++ A symfile with contents ++ ++ /filenameA+"(some text stored in the uninvertable symfile)+/filenameB ++ ++ will return when read ++ ++ The contents of filenameAsome text stored in the uninvertable symfileThe contents of filenameB ++ ++ and write of what has been read will not be possible to implement as ++ an identity operation because there are no delimiters denoting the ++ boundaries of what is to be written to what subfile. ++ ++ Note that one could make this a read/write symfile if one specified ++ delimiters, and the write method understood those delimiters delimited ++ what was written to subfiles. ++ ++ So, specifying the symfile in a manner that allows writes: ++ ++ /etc/passwd/userlines/demidov+"( ++ )+/etc/passwd/userlines/edward+"( ++ )+/etc/passwd/userlines/reiser+"( ++ )+/etc/passwd/userlines/root+"( ++ ) ++ ++ or ++ ++ /etc/passwd/userlines/(demidov+"( ++ )+edward+"( ++ )+reiser+"( ++ )+root+"( ++ )) ++ ++ and the file demidov might be specified as: ++ ++ /etc/passwd/userlines/demidov/username+"(:)+/etc/passwd/userlines/demidov/password+"(:)+/etc/passwd/userlines/demidov/userid+"(:)+/etc/passwd/userlines/demidov/groupid+"(:)+/etc/passwd/userlines/demidov/gecos+"(:)+/etc/passwd/userlines/demidov/home+"(:)+/etc/passwd/userlines/demidov/shell ++ ++ or ++ ++ /etc/passwd/userlines/demidov/(username+"(:)+password+"(:)+userid+"(:)+groupid+"(:)+gecos+"(:)+home+"(:)+shell) ++ ++ Notice that if the file demidov has a carriage return in it, the ++ parsing fails, but then if you put carriage returns in the wrong place ++ in a normal /etc/passwd file it breaks things also. ++ ++ Note that it is forbidden to have no text between two interpolations ++ if one wants to be able to define what parts of a write go to what ++ subfiles referenced in an interpolation. ++ ++ If one wants to be able to add new lines by writing to the file, one ++ must either write a custom plugin for /etc/passwd that knows how to ++ name an added line, or one must use an invert, or one must use a more ++ sophisticated symfile syntax that we are not planning to write for ++ version 4.0. ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/symlink.c linux-5.10.2/fs/reiser4/plugin/file/symlink.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/symlink.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/symlink.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,92 @@ ++/* Copyright 2002, 2003, 2005 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../inode.h" ++ ++#include ++#include ++ ++/* file plugin methods specific for symlink files ++ (SYMLINK_FILE_PLUGIN_ID) */ ++ ++/* this is implementation of create_object method of file plugin for ++ SYMLINK_FILE_PLUGIN_ID ++ */ ++ ++/** ++ * reiser4_create_symlink - create a synlink (object managed by ++ * file plugin with SYMLINK_FILE_PLUGIN_ID. ++ * Inserts stat data with symlink extension where into the tree. ++ * ++ * @symlink: inode of symlink object ++ * @dir: inode of parent directory ++ * @data: parameters of new object (in particular, filled by reiser4() syscall) ++ */ ++int reiser4_create_symlink(struct inode *symlink, ++ struct inode *dir UNUSED_ARG, ++ reiser4_object_create_data *data, oid_t *oid) ++{ ++ int result; ++ ++ assert("nikita-680", symlink != NULL); ++ assert("nikita-681", S_ISLNK(symlink->i_mode)); ++ assert("nikita-685", reiser4_inode_get_flag(symlink, REISER4_NO_SD)); ++ assert("nikita-682", dir != NULL); ++ assert("nikita-684", data != NULL); ++ assert("nikita-686", data->id == SYMLINK_FILE_PLUGIN_ID); ++ /* ++ * stat data of symlink has symlink extension in which we store ++ * symlink content, that is, path symlink is pointing to. ++ */ ++ reiser4_inode_data(symlink)->extmask |= (1 << SYMLINK_STAT); ++ ++ assert("vs-838", symlink->i_private == NULL); ++ symlink->i_private = (void *)data->name; ++ ++ assert("vs-843", symlink->i_size == 0); ++ INODE_SET_FIELD(symlink, i_size, strlen(data->name)); ++ ++ /* insert stat data appended with data->name */ ++ result = inode_file_plugin(symlink)->write_sd_by_inode(symlink, oid); ++ if (result) { ++ /* FIXME-VS: Make sure that symlink->i_private is not attached ++ to kmalloced data */ ++ INODE_SET_FIELD(symlink, i_size, 0); ++ } else { ++ assert("vs-849", symlink->i_private ++ && reiser4_inode_get_flag(symlink, ++ REISER4_GENERIC_PTR_USED)); ++ assert("vs-850", ++ !memcmp((char *)symlink->i_private, data->name, ++ (size_t) symlink->i_size + 1)); ++ } ++ return result; ++} ++ ++/* this is implementation of destroy_inode method of file plugin for ++ SYMLINK_FILE_PLUGIN_ID ++ */ ++void destroy_inode_symlink(struct inode *inode) ++{ ++ assert("edward-799", ++ inode_file_plugin(inode) == ++ file_plugin_by_id(SYMLINK_FILE_PLUGIN_ID)); ++ assert("edward-800", !is_bad_inode(inode) && is_inode_loaded(inode)); ++ assert("edward-801", reiser4_inode_get_flag(inode, ++ REISER4_GENERIC_PTR_USED)); ++ assert("vs-839", S_ISLNK(inode->i_mode)); ++ ++ kfree(inode->i_private); ++ inode->i_private = NULL; ++ reiser4_inode_clr_flag(inode, REISER4_GENERIC_PTR_USED); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file/tail_conversion.c linux-5.10.2/fs/reiser4/plugin/file/tail_conversion.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file/tail_conversion.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file/tail_conversion.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,810 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../inode.h" ++#include "../../super.h" ++#include "../../page_cache.h" ++#include "../../carry.h" ++#include "../../safe_link.h" ++#include "../../vfs_ops.h" ++ ++#include ++ ++/* this file contains: ++ tail2extent and extent2tail */ ++ ++/** ++ * exclusive access to a file is acquired when file state changes: ++ * tail2extent, empty2tail, extent2tail, etc ++ */ ++void get_exclusive_access(struct unix_file_info * uf_info) ++{ ++ assert("nikita-3028", reiser4_schedulable()); ++ assert("nikita-3047", LOCK_CNT_NIL(inode_sem_w)); ++ assert("nikita-3048", LOCK_CNT_NIL(inode_sem_r)); ++ /* ++ * "deadlock avoidance": sometimes we commit a transaction under ++ * rw-semaphore on a file. Such commit can deadlock with another ++ * thread that captured some block (hence preventing atom from being ++ * committed) and waits on rw-semaphore. ++ */ ++ reiser4_txn_restart_current(); ++ LOCK_CNT_INC(inode_sem_w); ++ down_write(&uf_info->latch); ++ uf_info->exclusive_use = 1; ++ assert("vs-1713", uf_info->ea_owner == NULL); ++ assert("vs-1713", atomic_read(&uf_info->nr_neas) == 0); ++ ON_DEBUG(uf_info->ea_owner = current); ++} ++ ++void drop_exclusive_access(struct unix_file_info * uf_info) ++{ ++ assert("vs-1714", uf_info->ea_owner == current); ++ assert("vs-1715", atomic_read(&uf_info->nr_neas) == 0); ++ ON_DEBUG(uf_info->ea_owner = NULL); ++ uf_info->exclusive_use = 0; ++ up_write(&uf_info->latch); ++ assert("nikita-3049", LOCK_CNT_NIL(inode_sem_r)); ++ assert("nikita-3049", LOCK_CNT_GTZ(inode_sem_w)); ++ LOCK_CNT_DEC(inode_sem_w); ++ reiser4_txn_restart_current(); ++} ++ ++/** ++ * nea_grabbed - do something when file semaphore is down_read-ed ++ * @uf_info: ++ * ++ * This is called when nonexclisive access is obtained on file. All it does is ++ * for debugging purposes. ++ */ ++static void nea_grabbed(struct unix_file_info *uf_info) ++{ ++#if REISER4_DEBUG ++ LOCK_CNT_INC(inode_sem_r); ++ assert("vs-1716", uf_info->ea_owner == NULL); ++ atomic_inc(&uf_info->nr_neas); ++ uf_info->last_reader = current; ++#endif ++} ++ ++/** ++ * get_nonexclusive_access - get nonexclusive access to a file ++ * @uf_info: unix file specific part of inode to obtain access to ++ * ++ * Nonexclusive access is obtained on a file before read, write, readpage. ++ */ ++void get_nonexclusive_access(struct unix_file_info *uf_info) ++{ ++ assert("nikita-3029", reiser4_schedulable()); ++ assert("nikita-3361", get_current_context()->trans->atom == NULL); ++ ++ down_read(&uf_info->latch); ++ nea_grabbed(uf_info); ++} ++ ++/** ++ * try_to_get_nonexclusive_access - try to get nonexclusive access to a file ++ * @uf_info: unix file specific part of inode to obtain access to ++ * ++ * Non-blocking version of nonexclusive access obtaining. ++ */ ++int try_to_get_nonexclusive_access(struct unix_file_info *uf_info) ++{ ++ int result; ++ ++ result = down_read_trylock(&uf_info->latch); ++ if (result) ++ nea_grabbed(uf_info); ++ return result; ++} ++ ++void drop_nonexclusive_access(struct unix_file_info * uf_info) ++{ ++ assert("vs-1718", uf_info->ea_owner == NULL); ++ assert("vs-1719", atomic_read(&uf_info->nr_neas) > 0); ++ ON_DEBUG(atomic_dec(&uf_info->nr_neas)); ++ ++ up_read(&uf_info->latch); ++ ++ LOCK_CNT_DEC(inode_sem_r); ++ reiser4_txn_restart_current(); ++} ++ ++/** ++ * part of tail2extent. ++ * Cut all items covering @count bytes starting from @offset ++ */ ++static int cut_formatting_items(struct inode *inode, loff_t offset, int count) ++{ ++ reiser4_key from, to; ++ /* ++ * AUDIT: How about putting an assertion here, what would check ++ * all provided range is covered by tail items only? ++ */ ++ /* ++ * key of first byte in the range to be cut ++ */ ++ build_body_key_unix_file(inode, offset, &from); ++ /* ++ * key of last byte in that range ++ */ ++ to = from; ++ set_key_offset(&to, (__u64) (offset + count - 1)); ++ /* ++ * cut everything between those keys ++ */ ++ return reiser4_cut_tree(meta_subvol_tree(), &from, &to, ++ inode, 0); ++} ++ ++static void release_all_pages(struct page **pages, unsigned nr_pages) ++{ ++ unsigned i; ++ ++ for (i = 0; i < nr_pages; i++) { ++ if (pages[i] == NULL) { ++#if REISER4_DEBUG ++ unsigned j; ++ for (j = i + 1; j < nr_pages; j++) ++ assert("vs-1620", pages[j] == NULL); ++#endif ++ break; ++ } ++ put_page(pages[i]); ++ pages[i] = NULL; ++ } ++} ++ ++/** ++ * Part of tail2extent. replace tail items with extent one. ++ * Content of tail items (@count bytes) being cut are copied already into ++ * pages. extent_writepage method is called to create extents corresponding ++ * to those pages ++ */ ++static int replace(struct inode *inode, struct page **pages, unsigned nr_pages, int count) ++{ ++ int result; ++ unsigned i; ++ STORE_COUNTERS; ++ ++ if (nr_pages == 0) ++ return 0; ++ ++ assert("vs-596", pages[0]); ++ /* ++ * cut copied items ++ */ ++ result = cut_formatting_items(inode, page_offset(pages[0]), count); ++ if (result) ++ return result; ++ ++ CHECK_COUNTERS; ++ /* ++ * put into tree replacement for just removed items: extent item, namely ++ */ ++ for (i = 0; i < nr_pages; i++) { ++ result = add_to_page_cache_lru(pages[i], inode->i_mapping, ++ pages[i]->index, ++ mapping_gfp_mask(inode-> ++ i_mapping)); ++ if (result) ++ break; ++ SetPageUptodate(pages[i]); ++ set_page_dirty_notag(pages[i]); ++ unlock_page(pages[i]); ++ result = find_or_create_extent_unix_file(pages[i]); ++ if (result) { ++ /* ++ * Unsuccess in critical place: ++ * tail has been removed, ++ * but extent hasn't been created ++ */ ++ warning("edward-1572", ++ "Report the error code %i to developers. Run FSCK", ++ result); ++ break; ++ } ++ } ++ return result; ++} ++ ++#define TAIL2EXTENT_PAGE_NUM 3 /* number of pages to fill before cutting tail ++ * items */ ++ ++/** ++ * @offset - offset of portion of data to be converted to extent ++ */ ++static int reserve_tail2extent_iteration(struct inode *inode, loff_t offset) ++{ ++ int ret; ++ reiser4_subvol *subv = get_meta_subvol(); ++ /* ++ * space required for one iteration of extent->tail conversion: ++ * ++ * 1. kill N tail items ++ * ++ * 2. insert TAIL2EXTENT_PAGE_NUM unformatted nodes ++ * ++ * 3. insert TAIL2EXTENT_PAGE_NUM (worst-case single-block ++ * extents) extent units. ++ * ++ * 4. drilling to the leaf level by coord_by_key() - see ++ * comment in the carry_extent() ++ * ++ * 5. possible update of stat-data ++ * ++ * reserve for 2 on data subvolume ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(TAIL2EXTENT_PAGE_NUM, BA_CAN_COMMIT, subv); ++ if (ret) ++ return ret; ++ /* ++ * reserve for 1,3,4,5 on meta-data subvolume ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(2 * subv->tree.height + ++ TAIL2EXTENT_PAGE_NUM * ++ estimate_one_insert_into_item(&subv->tree) + ++ 1 + estimate_one_insert_item(&subv->tree) + ++ inode_file_plugin(inode)->estimate.update(inode), ++ BA_CAN_COMMIT, ++ subv); ++ return ret; ++} ++ ++/** ++ * Clear stat data's flag indicating that conversion is not completed ++ * and update stat-data ++ */ ++static int complete_conversion(struct inode *inode) ++{ ++ int result; ++ ++ grab_space_enable(); ++ result = ++ reiser4_grab_space(inode_file_plugin(inode)->estimate.update(inode), ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (result) { ++ warning("vs-1696", "Failed to clear converting bit of %llu: %i", ++ (unsigned long long)get_inode_oid(inode), result); ++ return result; ++ } ++ reiser4_inode_clr_flag(inode, REISER4_PART_MIXED); ++ return reiser4_update_sd(inode); ++} ++ ++/** ++ * find_start ++ * @inode: ++ * @id: ++ * @offset: ++ * ++ * this is used by tail2extent and extent2tail to detect where previous ++ * uncompleted conversion stopped ++ */ ++static int find_start(struct inode *inode, reiser4_plugin_id id, __u64 *offset) ++{ ++ int result; ++ lock_handle lh; ++ coord_t coord; ++ struct unix_file_info *ufo; ++ int found; ++ reiser4_key key; ++ ++ ufo = unix_file_inode_data(inode); ++ init_lh(&lh); ++ result = 0; ++ found = 0; ++ build_body_key_unix_file(inode, *offset, &key); ++ do { ++ init_lh(&lh); ++ result = find_file_item_nohint(&coord, &lh, &key, ++ ZNODE_READ_LOCK, inode); ++ ++ if (result == CBK_COORD_FOUND) { ++ if (coord.between == AT_UNIT) { ++ /*coord_clear_iplug(&coord); */ ++ result = zload(coord.node); ++ if (result == 0) { ++ if (item_id_by_coord(&coord) == id) ++ found = 1; ++ else ++ item_plugin_by_coord(&coord)->s. ++ file.append_key(&coord, ++ &key); ++ zrelse(coord.node); ++ } ++ } else ++ result = RETERR(-ENOENT); ++ } ++ done_lh(&lh); ++ } while (result == 0 && !found); ++ *offset = get_key_offset(&key); ++ return result; ++} ++ ++int tail2extent(struct unix_file_info *uf_info) ++{ ++ int result; ++ reiser4_key key; /* key of next byte to be moved to page */ ++ char *p_data; /* data of page */ ++ unsigned page_off = 0, /* offset within the page where to copy data */ ++ count; /* number of bytes of item which can be ++ * copied to page */ ++ struct page *pages[TAIL2EXTENT_PAGE_NUM]; ++ struct page *page; ++ int done; /* set to 1 when all file is read */ ++ char *item; ++ int i; ++ struct inode *inode; ++ int first_iteration; ++ int bytes; ++ __u64 offset; ++ ++ assert("nikita-3362", ea_obtained(uf_info)); ++ inode = unix_file_info_to_inode(uf_info); ++ assert("nikita-3412", !IS_RDONLY(inode)); ++ assert("vs-1649", uf_info->container != UF_CONTAINER_EXTENTS); ++ assert("", !reiser4_inode_get_flag(inode, REISER4_PART_IN_CONV)); ++ ++ offset = 0; ++ first_iteration = 1; ++ result = 0; ++ get_current_super_private()->ctx = get_current_context(); ++ ++ if (reiser4_inode_get_flag(inode, REISER4_PART_MIXED)) { ++ /* ++ * file is marked on disk as there was a conversion which did ++ * not complete due to either crash or some error. Find which ++ * offset tail conversion stopped at ++ */ ++ result = find_start(inode, FORMATTING_ID, &offset); ++ if (result == -ENOENT) { ++ /* ++ * no tail items found, everything is converted ++ */ ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ complete_conversion(inode); ++ return 0; ++ } else if (result != 0) ++ /* ++ * some other error ++ */ ++ return result; ++ first_iteration = 0; ++ } ++ reiser4_inode_set_flag(inode, REISER4_PART_IN_CONV); ++ /* ++ * get key of first byte of a file ++ */ ++ build_body_key_unix_file(inode, offset, &key); ++ ++ done = 0; ++ while (done == 0) { ++ memset(pages, 0, sizeof(pages)); ++ result = reserve_tail2extent_iteration(inode, ++ get_key_offset(&key)); ++ if (result != 0) { ++ reiser4_inode_clr_flag(inode, REISER4_PART_IN_CONV); ++ goto out; ++ } ++ if (first_iteration) { ++ reiser4_inode_set_flag(inode, REISER4_PART_MIXED); ++ reiser4_update_sd(inode); ++ first_iteration = 0; ++ } ++ bytes = 0; ++ for (i = 0; i < sizeof_array(pages) && done == 0; i++) { ++ assert("vs-598", ++ (get_key_offset(&key) & ~PAGE_MASK) == 0); ++ page = alloc_page(reiser4_ctx_gfp_mask_get()); ++ if (!page) { ++ result = RETERR(-ENOMEM); ++ goto error; ++ } ++ page->index = ++ (unsigned long)(get_key_offset(&key) >> ++ PAGE_SHIFT); ++ /* ++ * usually when one is going to longterm lock znode (as ++ * find_file_item does, for instance) he must not hold ++ * locked pages. However, there is an exception for ++ * case tail2extent. Pages appearing here are not ++ * reachable to everyone else, they are clean, they do ++ * not have jnodes attached so keeping them locked do ++ * not risk deadlock appearance ++ */ ++ assert("vs-983", !PagePrivate(page)); ++ reiser4_invalidate_pages(inode->i_mapping, page->index, ++ 1, 0); ++ for (page_off = 0; page_off < PAGE_SIZE;) { ++ coord_t coord; ++ lock_handle lh; ++ /* ++ * get next item ++ * FIXME: we might want to readahead here ++ */ ++ init_lh(&lh); ++ result = find_file_item_nohint(&coord, ++ &lh, &key, ++ ZNODE_READ_LOCK, ++ inode); ++ if (result != CBK_COORD_FOUND) { ++ /* ++ * error happened of not items of file ++ * were found ++ */ ++ done_lh(&lh); ++ put_page(page); ++ goto error; ++ } ++ if (coord.between == AFTER_UNIT) { ++ /* ++ * end of file is reached. Padd page ++ * with zeros ++ */ ++ done_lh(&lh); ++ done = 1; ++ p_data = kmap_atomic(page); ++ memset(p_data + page_off, 0, ++ PAGE_SIZE - page_off); ++ kunmap_atomic(p_data); ++ break; ++ } ++ result = zload(coord.node); ++ if (result) { ++ put_page(page); ++ done_lh(&lh); ++ goto error; ++ } ++ assert("vs-856", coord.between == AT_UNIT); ++ item = ((char *)item_body_by_coord(&coord)) + ++ coord.unit_pos; ++ /* ++ * how many bytes to copy ++ */ ++ count = item_length_by_coord(&coord) - ++ coord.unit_pos; ++ /* ++ * limit length of copy to end of page ++ */ ++ if (count > PAGE_SIZE - page_off) ++ count = PAGE_SIZE - page_off; ++ /* ++ * copy item (as much as will fit starting from ++ * the beginning of the item) into the page ++ */ ++ p_data = kmap_atomic(page); ++ memcpy(p_data + page_off, item, count); ++ kunmap_atomic(p_data); ++ ++ page_off += count; ++ bytes += count; ++ set_key_offset(&key, ++ get_key_offset(&key) + count); ++ ++ zrelse(coord.node); ++ done_lh(&lh); ++ /* ++ * end of loop which fills one page by ++ * content of formatting items ++ */ ++ } ++ if (page_off) { ++ /* ++ * something was copied into page ++ */ ++ pages[i] = page; ++ } else { ++ put_page(page); ++ assert("vs-1648", done == 1); ++ break; ++ } ++ /* end of loop through pages of one conversion iteration */ ++ } ++ if (i > 0) { ++ result = replace(inode, pages, i, bytes); ++ release_all_pages(pages, sizeof_array(pages)); ++ if (result) ++ goto error; ++ /* ++ * We have to drop exclusive access to avoid deadlock ++ * which may happen because called by reiser4_writepages ++ * capture_unix_file requires to get non-exclusive ++ * access to a file. It is safe to drop EA in the middle ++ * of tail2extent conversion because write_unix_file, ++ * setattr_unix_file(truncate), mmap_unix_file, ++ * release_unix_file(extent2tail) checks if conversion ++ * is not in progress (see comments before ++ * get_exclusive_access_careful(). ++ * Other processes that acquire non-exclusive access ++ * (read_unix_file, reiser4_writepages, etc) should work ++ * on partially converted files. ++ */ ++ drop_exclusive_access(uf_info); ++ /* ++ * throttle the conversion ++ */ ++ reiser4_throttle_write(inode); ++ get_exclusive_access(uf_info); ++ /* ++ * nobody is allowed to complete conversion but a ++ * process which started it ++ */ ++ assert("", reiser4_inode_get_flag(inode, ++ REISER4_PART_MIXED)); ++ } ++ } ++ if (result == 0) { ++ /* ++ * file is converted to extent items ++ */ ++ reiser4_inode_clr_flag(inode, REISER4_PART_IN_CONV); ++ assert("vs-1697", reiser4_inode_get_flag(inode, ++ REISER4_PART_MIXED)); ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ complete_conversion(inode); ++ } else { ++ /* ++ * conversion is not complete. Inode was already marked as ++ * REISER4_PART_MIXED and stat-data were updated at the first ++ * iteration of the loop above. ++ */ ++ error: ++ release_all_pages(pages, sizeof_array(pages)); ++ reiser4_inode_clr_flag(inode, REISER4_PART_IN_CONV); ++ warning("edward-1548", "Partial conversion of %llu: %i", ++ (unsigned long long)get_inode_oid(inode), result); ++ } ++ out: ++ /* ++ * this flag should be cleared, otherwise get_exclusive_access_careful() ++ * will fall into infinite loop ++ */ ++ assert("edward-1549", !reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)); ++ return result; ++} ++ ++static int reserve_extent2tail_iteration(struct inode *inode) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ reiser4_tree *tree = &subv->tree; ++ /* ++ * reserve blocks for (in this order): ++ * ++ * 1. removal of extent item ++ * ++ * 2. insertion of tail by insert_flow() ++ * ++ * 3. drilling to the leaf level by coord_by_key() ++ * ++ * 4. possible update of stat-data ++ */ ++ grab_space_enable(); ++ return reiser4_grab_space(estimate_one_item_removal(tree) + ++ estimate_insert_flow(tree->height) + ++ 1 + estimate_one_insert_item(tree) + ++ inode_file_plugin(inode)->estimate.update(inode), ++ BA_CAN_COMMIT, subv); ++} ++ ++/** ++ * for every page of file: read page, cut part of extent pointing to this page, ++ * put data of page tree by tail item ++ */ ++int extent2tail(struct file * file, struct unix_file_info *uf_info) ++{ ++ int result; ++ struct inode *inode; ++ struct page *page; ++ unsigned long num_pages, i; ++ unsigned long start_page; ++ reiser4_key from; ++ reiser4_key to; ++ unsigned count; ++ __u64 offset; ++ ++ assert("nikita-3362", ea_obtained(uf_info)); ++ inode = unix_file_info_to_inode(uf_info); ++ assert("nikita-3412", !IS_RDONLY(inode)); ++ assert("vs-1649", uf_info->container != UF_CONTAINER_TAILS); ++ assert("", !reiser4_inode_get_flag(inode, REISER4_PART_IN_CONV)); ++ ++ offset = 0; ++ if (reiser4_inode_get_flag(inode, REISER4_PART_MIXED)) { ++ /* ++ * file is marked on disk as there was a conversion which did ++ * not complete due to either crash or some error. Find which ++ * offset tail conversion stopped at ++ */ ++ result = find_start(inode, EXTENT40_POINTER_ID, &offset); ++ if (result == -ENOENT) { ++ /* ++ * no extent found, everything is converted ++ */ ++ uf_info->container = UF_CONTAINER_TAILS; ++ complete_conversion(inode); ++ return 0; ++ } else if (result != 0) ++ /* ++ * some other error ++ */ ++ return result; ++ } ++ reiser4_inode_set_flag(inode, REISER4_PART_IN_CONV); ++ /* ++ * number of pages in the file ++ */ ++ num_pages = ++ (inode->i_size + - offset + PAGE_SIZE - 1) >> PAGE_SHIFT; ++ start_page = offset >> PAGE_SHIFT; ++ ++ build_body_key_unix_file(inode, offset, &from); ++ to = from; ++ ++ result = 0; ++ for (i = 0; i < num_pages; i++) { ++ __u64 start_byte; ++ ++ result = reserve_extent2tail_iteration(inode); ++ if (result != 0) ++ break; ++ if (i == 0 && offset == 0) { ++ reiser4_inode_set_flag(inode, REISER4_PART_MIXED); ++ reiser4_update_sd(inode); ++ } ++ page = read_mapping_page(inode->i_mapping, ++ (unsigned)(i + start_page), NULL); ++ if (IS_ERR(page)) { ++ result = PTR_ERR(page); ++ warning("edward-1569", ++ "Can not read page %lu of %lu: %i", ++ i, num_pages, result); ++ break; ++ } ++ wait_on_page_locked(page); ++ ++ if (!PageUptodate(page)) { ++ put_page(page); ++ result = RETERR(-EIO); ++ break; ++ } ++ /* ++ * cut part of file we have read ++ */ ++ start_byte = (__u64) ((i + start_page) << PAGE_SHIFT); ++ set_key_offset(&from, start_byte); ++ set_key_offset(&to, start_byte + PAGE_SIZE - 1); ++ /* ++ * reiser4_cut_tree_object() returns -E_REPEAT to allow atom ++ * commits during over-long truncates. But ++ * extent->tail conversion should be performed in one ++ * transaction. ++ */ ++ result = reiser4_cut_tree(meta_subvol_tree(), ++ &from, &to, inode, 0); ++ if (result) { ++ put_page(page); ++ warning("edward-1570", ++ "Can not delete converted chunk: %i", ++ result); ++ break; ++ } ++ /* ++ * put page data into tree via tail_write ++ */ ++ count = PAGE_SIZE; ++ if ((i == (num_pages - 1)) && ++ (inode->i_size & ~PAGE_MASK)) ++ /* ++ * last page can be incompleted ++ */ ++ count = (inode->i_size & ~PAGE_MASK); ++ while (count) { ++ loff_t pos = start_byte; ++ ++ assert("edward-1537", ++ file != NULL && file->f_path.dentry != NULL); ++ assert("edward-1538", ++ file_inode(file) == inode); ++ ++ result = write_tail_noreserve(file, inode, ++ (char __user *)kmap(page), ++ count, &pos); ++ kunmap(page); ++ /* ++ * FIXME: may be put_file_hint() instead ? ++ */ ++ reiser4_free_file_fsdata(file); ++ if (result <= 0) { ++ /* ++ * Unsuccess in critical place: ++ * extent has been removed, ++ * but tail hasn't been created ++ */ ++ warning("edward-1571", ++ "Report the error code %i to developers. Run FSCK", ++ result); ++ put_page(page); ++ reiser4_inode_clr_flag(inode, ++ REISER4_PART_IN_CONV); ++ return result; ++ } ++ count -= result; ++ } ++ /* ++ * release page ++ */ ++ lock_page(page); ++ /* ++ * page is already detached from jnode and mapping ++ */ ++ assert("vs-1086", page->mapping == NULL); ++ assert("nikita-2690", ++ (!PagePrivate(page) && jprivate(page) == 0)); ++ /* ++ * waiting for writeback completion with page lock held is ++ * perfectly valid ++ */ ++ wait_on_page_writeback(page); ++ reiser4_drop_page(page); ++ /* ++ * release reference taken by read_cache_page() above ++ */ ++ put_page(page); ++ ++ drop_exclusive_access(uf_info); ++ /* ++ * throttle the conversion ++ */ ++ reiser4_throttle_write(inode); ++ get_exclusive_access(uf_info); ++ /* ++ * nobody is allowed to complete conversion but a process which ++ * started it ++ */ ++ assert("", reiser4_inode_get_flag(inode, REISER4_PART_MIXED)); ++ } ++ reiser4_inode_clr_flag(inode, REISER4_PART_IN_CONV); ++ ++ if (i == num_pages) { ++ /* ++ * file is converted to formatting items ++ */ ++ assert("vs-1698", reiser4_inode_get_flag(inode, ++ REISER4_PART_MIXED)); ++ assert("vs-1260", ++ inode_has_no_jnodes(reiser4_inode_data(inode))); ++ uf_info->container = UF_CONTAINER_TAILS; ++ complete_conversion(inode); ++ return 0; ++ } ++ /* ++ * conversion is not complete. Inode was already marked as ++ * REISER4_PART_MIXED and stat-data were updated at the first ++ * iteration of the loop above. ++ */ ++ warning("nikita-2282", ++ "Partial conversion of %llu: %lu of %lu: %i", ++ (unsigned long long)get_inode_oid(inode), i, ++ num_pages, result); ++ /* ++ * this flag should be cleared, otherwise get_exclusive_access_careful() ++ * will fall into infinite loop ++ */ ++ assert("edward-1550", !reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)); ++ return result; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file_ops.c linux-5.10.2/fs/reiser4/plugin/file_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file_ops.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,120 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* this file contains typical implementations for some of methods of ++ struct file_operations and of struct address_space_operations ++*/ ++ ++#include "../inode.h" ++#include "object.h" ++ ++/* file operations */ ++ ++/* implementation of vfs's llseek method of struct file_operations for ++ typical directory can be found in file_ops_readdir.c ++*/ ++loff_t reiser4_llseek_dir_common(struct file *, loff_t, int origin); ++ ++/* implementation of vfs's iterate method of struct file_operations for ++ typical directory can be found in file_ops_readdir.c ++*/ ++int reiser4_iterate_common(struct file *, struct dir_context *); ++ ++/** ++ * reiser4_release_dir_common - release of struct file_operations ++ * @inode: inode of released file ++ * @file: file to release ++ * ++ * Implementation of release method of struct file_operations for typical ++ * directory. All it does is freeing of reiser4 specific file data. ++*/ ++int reiser4_release_dir_common(struct inode *inode, struct file *file) ++{ ++ reiser4_context *ctx; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ reiser4_free_file_fsdata(file); ++ reiser4_exit_context(ctx); ++ return 0; ++} ++ ++/* this is common implementation of vfs's fsync method of struct ++ file_operations ++*/ ++int reiser4_sync_common(struct file *file, loff_t start, ++ loff_t end, int datasync) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct dentry *dentry = file->f_path.dentry; ++ ++ ctx = reiser4_init_context(dentry->d_inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ result = txnmgr_force_commit_all(dentry->d_inode->i_sb, 0); ++ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* ++ * common sync method for regular files. ++ * ++ * We are trying to be smart here. Instead of committing all atoms (original ++ * solution), we scan dirty pages of this file and commit all atoms they are ++ * part of. ++ * ++ * Situation is complicated by anonymous pages: i.e., extent-less pages ++ * dirtied through mmap. Fortunately sys_fsync() first calls ++ * filemap_fdatawrite() that will ultimately call reiser4_writepages_dispatch, ++ * insert all missing extents and capture anonymous pages. ++ */ ++int reiser4_sync_file_common(struct file *file, loff_t start, loff_t end, int datasync) ++{ ++ int ret; ++ reiser4_context *ctx; ++ struct dentry *dentry = file->f_path.dentry; ++ struct inode *inode = file->f_mapping->host; ++ ++ int err = filemap_write_and_wait_range(inode->i_mapping, start, end); ++ if (err) ++ return err; ++ ++ ctx = reiser4_init_context(dentry->d_inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ inode_lock(inode); ++ ret = reserve_update_sd_common(inode); ++ if (ret) { ++ reiser4_exit_context(ctx); ++ inode_unlock(inode); ++ return RETERR(-ENOSPC); ++ } ++ write_sd_by_inode_common(dentry->d_inode, NULL); ++ ret = force_commit_current_atom(); ++ if (ret) ++ warning("", "Failed to sync file %s", dentry->d_name.name); ++ reiser4_exit_context(ctx); ++ inode_unlock(inode); ++ return ret; ++} ++ ++long reiser4_ioctl_dir_common(struct file *file, unsigned int cmd, unsigned long arg) ++{ ++ return reiser4_ioctl_volume(file, cmd, arg, reiser4_volume_op_dir); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file_ops_readdir.c linux-5.10.2/fs/reiser4/plugin/file_ops_readdir.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file_ops_readdir.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file_ops_readdir.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,660 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include ++#include "../inode.h" ++ ++/* return true, iff @coord points to the valid directory item that is part of ++ * @inode directory. */ ++static int is_valid_dir_coord(struct inode *inode, coord_t *coord) ++{ ++ return plugin_of_group(item_plugin_by_coord(coord), ++ DIR_ENTRY_ITEM_TYPE) && ++ inode_file_plugin(inode)->owns_item(inode, coord); ++} ++ ++/* compare two logical positions within the same directory */ ++static cmp_t dir_pos_cmp(const struct dir_pos *p1, const struct dir_pos *p2) ++{ ++ cmp_t result; ++ ++ assert("nikita-2534", p1 != NULL); ++ assert("nikita-2535", p2 != NULL); ++ ++ result = de_id_cmp(&p1->dir_entry_key, &p2->dir_entry_key); ++ if (result == EQUAL_TO) { ++ int diff; ++ ++ diff = p1->pos - p2->pos; ++ result = ++ (diff < 0) ? LESS_THAN : (diff ? GREATER_THAN : EQUAL_TO); ++ } ++ return result; ++} ++ ++/* see comment before reiser4_readdir_common() for overview of why "adjustment" ++ * is necessary. */ ++static void ++adjust_dir_pos(struct file *dir, struct readdir_pos *readdir_spot, ++ const struct dir_pos *mod_point, int adj) ++{ ++ struct dir_pos *pos; ++ ++ /* ++ * new directory entry was added (adj == +1) or removed (adj == -1) at ++ * the @mod_point. Directory file descriptor @dir is doing readdir and ++ * is currently positioned at @readdir_spot. Latter has to be updated ++ * to maintain stable readdir. ++ */ ++ /* directory is positioned to the beginning. */ ++ if (readdir_spot->entry_no == 0) ++ return; ++ ++ pos = &readdir_spot->position; ++ switch (dir_pos_cmp(mod_point, pos)) { ++ case LESS_THAN: ++ /* @mod_pos is _before_ @readdir_spot, that is, entry was ++ * added/removed on the left (in key order) of current ++ * position. */ ++ /* logical number of directory entry readdir is "looking" at ++ * changes */ ++ readdir_spot->entry_no += adj; ++ assert("nikita-2577", ++ ergo(dir != NULL, ++ reiser4_get_dir_fpos(dir, dir->f_pos) + adj >= 0)); ++ if (de_id_cmp(&pos->dir_entry_key, ++ &mod_point->dir_entry_key) == EQUAL_TO) { ++ assert("nikita-2575", mod_point->pos < pos->pos); ++ /* ++ * if entry added/removed has the same key as current ++ * for readdir, update counter of duplicate keys in ++ * @readdir_spot. ++ */ ++ pos->pos += adj; ++ } ++ break; ++ case GREATER_THAN: ++ /* directory is modified after @pos: nothing to do. */ ++ break; ++ case EQUAL_TO: ++ /* cannot insert an entry readdir is looking at, because it ++ already exists. */ ++ assert("nikita-2576", adj < 0); ++ /* directory entry to which @pos points to is being ++ removed. ++ ++ NOTE-NIKITA: Right thing to do is to update @pos to point ++ to the next entry. This is complex (we are under spin-lock ++ for one thing). Just rewind it to the beginning. Next ++ readdir will have to scan the beginning of ++ directory. Proper solution is to use semaphore in ++ spin lock's stead and use rewind_right() here. ++ ++ NOTE-NIKITA: now, semaphore is used, so... ++ */ ++ memset(readdir_spot, 0, sizeof *readdir_spot); ++ } ++} ++ ++/* scan all file-descriptors for this directory and adjust their ++ positions respectively. Should be used by implementations of ++ add_entry and rem_entry of dir plugin */ ++void reiser4_adjust_dir_file(struct inode *dir, const struct dentry *de, ++ int offset, int adj) ++{ ++ reiser4_file_fsdata *scan; ++ struct dir_pos mod_point; ++ ++ assert("nikita-2536", dir != NULL); ++ assert("nikita-2538", de != NULL); ++ assert("nikita-2539", adj != 0); ++ ++ build_de_id(dir, &de->d_name, &mod_point.dir_entry_key); ++ mod_point.pos = offset; ++ ++ spin_lock_inode(dir); ++ ++ /* ++ * new entry was added/removed in directory @dir. Scan all file ++ * descriptors for @dir that are currently involved into @readdir and ++ * update them. ++ */ ++ ++ list_for_each_entry(scan, get_readdir_list(dir), dir.linkage) ++ adjust_dir_pos(scan->back, &scan->dir.readdir, &mod_point, adj); ++ ++ spin_unlock_inode(dir); ++} ++ ++/* ++ * traverse tree to start/continue readdir from the readdir position @pos. ++ */ ++static int dir_go_to(struct file *dir, struct readdir_pos *pos, tap_t *tap) ++{ ++ reiser4_key key; ++ int result; ++ struct inode *inode; ++ ++ assert("nikita-2554", pos != NULL); ++ ++ inode = file_inode(dir); ++ result = inode_dir_plugin(inode)->build_readdir_key(dir, &key); ++ if (result != 0) ++ return result; ++ result = reiser4_object_lookup(meta_subvol_tree(), ++ inode, ++ &key, ++ tap->coord, ++ tap->lh, ++ tap->mode, ++ FIND_EXACT, ++ LEAF_LEVEL, LEAF_LEVEL, ++ 0, &tap->ra_info); ++ if (result == CBK_COORD_FOUND) ++ result = rewind_right(tap, (int)pos->position.pos); ++ else { ++ tap->coord->node = NULL; ++ done_lh(tap->lh); ++ result = RETERR(-EIO); ++ } ++ return result; ++} ++ ++/* ++ * handling of non-unique keys: calculate at what ordinal position within ++ * sequence of directory items with identical keys @pos is. ++ */ ++static int set_pos(struct inode *inode, struct readdir_pos *pos, tap_t *tap) ++{ ++ int result; ++ coord_t coord; ++ lock_handle lh; ++ tap_t scan; ++ de_id *did; ++ reiser4_key de_key; ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ reiser4_tap_init(&scan, &coord, &lh, ZNODE_READ_LOCK); ++ reiser4_tap_copy(&scan, tap); ++ reiser4_tap_load(&scan); ++ pos->position.pos = 0; ++ ++ did = &pos->position.dir_entry_key; ++ ++ if (is_valid_dir_coord(inode, scan.coord)) { ++ ++ build_de_id_by_key(unit_key_by_coord(scan.coord, &de_key), did); ++ ++ while (1) { ++ ++ result = go_prev_unit(&scan); ++ if (result != 0) ++ break; ++ ++ if (!is_valid_dir_coord(inode, scan.coord)) { ++ result = -EINVAL; ++ break; ++ } ++ ++ /* get key of directory entry */ ++ unit_key_by_coord(scan.coord, &de_key); ++ if (de_id_key_cmp(did, &de_key) != EQUAL_TO) { ++ /* duplicate-sequence is over */ ++ break; ++ } ++ pos->position.pos++; ++ } ++ } else ++ result = RETERR(-ENOENT); ++ reiser4_tap_relse(&scan); ++ reiser4_tap_done(&scan); ++ return result; ++} ++ ++/* ++ * "rewind" directory to @offset, i.e., set @pos and @tap correspondingly. ++ */ ++static int dir_rewind(struct file *dir, loff_t *fpos, struct readdir_pos *pos, tap_t *tap) ++{ ++ __u64 destination; ++ __s64 shift; ++ int result; ++ struct inode *inode; ++ loff_t dirpos; ++ ++ assert("nikita-2553", dir != NULL); ++ assert("nikita-2548", pos != NULL); ++ assert("nikita-2551", tap->coord != NULL); ++ assert("nikita-2552", tap->lh != NULL); ++ ++ dirpos = reiser4_get_dir_fpos(dir, *fpos); ++ shift = dirpos - pos->fpos; ++ /* this is logical directory entry within @dir which we are rewinding ++ * to */ ++ destination = pos->entry_no + shift; ++ ++ inode = file_inode(dir); ++ if (dirpos < 0) ++ return RETERR(-EINVAL); ++ else if (destination == 0ll || dirpos == 0) { ++ /* rewind to the beginning of directory */ ++ memset(pos, 0, sizeof *pos); ++ return dir_go_to(dir, pos, tap); ++ } else if (destination >= inode->i_size) ++ return RETERR(-ENOENT); ++ ++ if (shift < 0) { ++ /* I am afraid of negative numbers */ ++ shift = -shift; ++ /* rewinding to the left */ ++ if (shift <= (int)pos->position.pos) { ++ /* destination is within sequence of entries with ++ duplicate keys. */ ++ result = dir_go_to(dir, pos, tap); ++ } else { ++ shift -= pos->position.pos; ++ while (1) { ++ /* repetitions: deadlock is possible when ++ going to the left. */ ++ result = dir_go_to(dir, pos, tap); ++ if (result == 0) { ++ result = rewind_left(tap, shift); ++ if (result == -E_DEADLOCK) { ++ reiser4_tap_done(tap); ++ continue; ++ } ++ } ++ break; ++ } ++ } ++ } else { ++ /* rewinding to the right */ ++ result = dir_go_to(dir, pos, tap); ++ if (result == 0) ++ result = rewind_right(tap, shift); ++ } ++ if (result == 0) { ++ result = set_pos(inode, pos, tap); ++ if (result == 0) { ++ /* update pos->position.pos */ ++ pos->entry_no = destination; ++ pos->fpos = dirpos; ++ } ++ } ++ return result; ++} ++ ++/* ++ * Function that is called by common_readdir() on each directory entry while ++ * doing readdir. ->filldir callback may block, so we had to release long term ++ * lock while calling it. To avoid repeating tree traversal, seal is used. If ++ * seal is broken, we return -E_REPEAT. Node is unlocked in this case. ++ * ++ * Whether node is unlocked in case of any other error is undefined. It is ++ * guaranteed to be still locked if success (0) is returned. ++ * ++ * When ->filldir() wants no more, feed_entry() returns 1, and node is ++ * unlocked. ++ */ ++static int feed_entry(tap_t *tap, reiser4_tree *tree, ++ struct dir_context *context) ++{ ++ item_plugin *iplug; ++ char *name; ++ reiser4_key sd_key; ++ int result; ++ char buf[DE_NAME_BUF_LEN]; ++ char name_buf[32]; ++ char *local_name; ++ unsigned file_type; ++ seal_t seal; ++ coord_t *coord; ++ reiser4_key entry_key; ++ ++ coord = tap->coord; ++ iplug = item_plugin_by_coord(coord); ++ ++ /* pointer to name within the node */ ++ name = iplug->s.dir.extract_name(coord, buf); ++ assert("nikita-1371", name != NULL); ++ ++ /* key of object the entry points to */ ++ if (iplug->s.dir.extract_key(coord, &sd_key) != 0) ++ return RETERR(-EIO); ++ ++ /* we must release longterm znode lock before calling filldir to avoid ++ deadlock which may happen if filldir causes page fault. So, copy ++ name to intermediate buffer */ ++ if (strlen(name) + 1 > sizeof(name_buf)) { ++ local_name = kmalloc(strlen(name) + 1, ++ reiser4_ctx_gfp_mask_get()); ++ if (local_name == NULL) ++ return RETERR(-ENOMEM); ++ } else ++ local_name = name_buf; ++ ++ strcpy(local_name, name); ++ file_type = iplug->s.dir.extract_file_type(coord); ++ ++ unit_key_by_coord(coord, &entry_key); ++ reiser4_seal_init(&seal, coord, &entry_key); ++ ++ longterm_unlock_znode(tap->lh); ++ ++ /* ++ * send information about directory entry to the ->filldir() filler ++ * supplied to us by caller (VFS). ++ * ++ * ->filldir is entitled to do weird things. For example, ->filldir ++ * supplied by knfsd re-enters file system. Make sure no locks are ++ * held. ++ */ ++ assert("nikita-3436", lock_stack_isclean(get_current_lock_stack())); ++ ++ reiser4_txn_restart_current(); ++ if (!dir_emit(context, name, (int)strlen(name), ++ /* inode number of object bounden by this entry */ ++ oid_to_uino(get_key_objectid(&sd_key)), file_type)) ++ /* ->filldir() is satisfied. (no space in buffer, IOW) */ ++ result = 1; ++ else ++ result = reiser4_seal_validate(&seal, tree, coord, &entry_key, ++ tap->lh, tap->mode, ++ ZNODE_LOCK_HIPRI); ++ ++ if (local_name != name_buf) ++ kfree(local_name); ++ ++ return result; ++} ++ ++static void move_entry(struct readdir_pos *pos, coord_t *coord) ++{ ++ reiser4_key de_key; ++ de_id *did; ++ ++ /* update @pos */ ++ ++pos->entry_no; ++ did = &pos->position.dir_entry_key; ++ ++ /* get key of directory entry */ ++ unit_key_by_coord(coord, &de_key); ++ ++ if (de_id_key_cmp(did, &de_key) == EQUAL_TO) ++ /* we are within sequence of directory entries ++ with duplicate keys. */ ++ ++pos->position.pos; ++ else { ++ pos->position.pos = 0; ++ build_de_id_by_key(&de_key, did); ++ } ++ ++pos->fpos; ++} ++ ++/* ++ * STATELESS READDIR ++ * ++ * readdir support in reiser4 relies on ability to update readdir_pos embedded ++ * into reiser4_file_fsdata on each directory modification (name insertion and ++ * removal), see reiser4_readdir_common() function below. This obviously doesn't ++ * work when reiser4 is accessed over NFS, because NFS doesn't keep any state ++ * across client READDIR requests for the same directory. ++ * ++ * To address this we maintain a "pool" of detached reiser4_file_fsdata ++ * (d_cursor). Whenever NFS readdir request comes, we detect this, and try to ++ * find detached reiser4_file_fsdata corresponding to previous readdir ++ * request. In other words, additional state is maintained on the ++ * server. (This is somewhat contrary to the design goals of NFS protocol.) ++ * ++ * To efficiently detect when our ->readdir() method is called by NFS server, ++ * dentry is marked as "stateless" in reiser4_decode_fh() (this is checked by ++ * file_is_stateless() function). ++ * ++ * To find out d_cursor in the pool, we encode client id (cid) in the highest ++ * bits of NFS readdir cookie: when first readdir request comes to the given ++ * directory from the given client, cookie is set to 0. This situation is ++ * detected, global cid_counter is incremented, and stored in highest bits of ++ * all direntry offsets returned to the client, including last one. As the ++ * only valid readdir cookie is one obtained as direntry->offset, we are ++ * guaranteed that next readdir request (continuing current one) will have ++ * current cid in the highest bits of starting readdir cookie. All d_cursors ++ * are hashed into per-super-block hash table by (oid, cid) key. ++ * ++ * In addition d_cursors are placed into per-super-block radix tree where they ++ * are keyed by oid alone. This is necessary to efficiently remove them during ++ * rmdir. ++ * ++ * At last, currently unused d_cursors are linked into special list. This list ++ * is used d_cursor_shrink to reclaim d_cursors on memory pressure. ++ * ++ */ ++ ++/* ++ * prepare for readdir. ++ * ++ * NOTE: @f->f_pos may be out-of-date (iterate() vs readdir()). ++ * @fpos is effective position. ++ */ ++static int dir_readdir_init(struct file *f, loff_t* fpos, tap_t *tap, ++ struct readdir_pos **pos) ++{ ++ struct inode *inode; ++ reiser4_file_fsdata *fsdata; ++ int result; ++ ++ assert("nikita-1359", f != NULL); ++ inode = file_inode(f); ++ assert("nikita-1360", inode != NULL); ++ ++ if (!S_ISDIR(inode->i_mode)) ++ return RETERR(-ENOTDIR); ++ ++ /* try to find detached readdir state */ ++ result = reiser4_attach_fsdata(f, fpos, inode); ++ if (result != 0) ++ return result; ++ ++ fsdata = reiser4_get_file_fsdata(f); ++ assert("nikita-2571", fsdata != NULL); ++ if (IS_ERR(fsdata)) ++ return PTR_ERR(fsdata); ++ ++ /* add file descriptor to the readdir list hanging of directory ++ * inode. This list is used to scan "readdirs-in-progress" while ++ * inserting or removing names in the directory. */ ++ spin_lock_inode(inode); ++ if (list_empty_careful(&fsdata->dir.linkage)) ++ list_add(&fsdata->dir.linkage, get_readdir_list(inode)); ++ *pos = &fsdata->dir.readdir; ++ spin_unlock_inode(inode); ++ ++ /* move @tap to the current position */ ++ return dir_rewind(f, fpos, *pos, tap); ++} ++ ++/* this is implementation of vfs's llseek method of struct file_operations for ++ typical directory ++ See comment before reiser4_iterate_common() for explanation. ++*/ ++loff_t reiser4_llseek_dir_common(struct file *file, loff_t off, int origin) ++{ ++ reiser4_context *ctx; ++ loff_t result; ++ struct inode *inode; ++ ++ inode = file_inode(file); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ inode_lock(inode); ++ ++ /* update ->f_pos */ ++ result = default_llseek_unlocked(file, off, origin); ++ if (result >= 0) { ++ int ff; ++ coord_t coord; ++ lock_handle lh; ++ tap_t tap; ++ struct readdir_pos *pos; ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ reiser4_tap_init(&tap, &coord, &lh, ZNODE_READ_LOCK); ++ ++ ff = dir_readdir_init(file, &file->f_pos, &tap, &pos); ++ reiser4_detach_fsdata(file); ++ if (ff != 0) ++ result = (loff_t) ff; ++ reiser4_tap_done(&tap); ++ } ++ reiser4_detach_fsdata(file); ++ inode_unlock(inode); ++ ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* this is common implementation of vfs's readdir method of struct ++ file_operations ++ ++ readdir problems: ++ ++ readdir(2)/getdents(2) interface is based on implicit assumption that ++ readdir can be restarted from any particular point by supplying file system ++ with off_t-full of data. That is, file system fills ->d_off field in struct ++ dirent and later user passes ->d_off to the seekdir(3), which is, actually, ++ implemented by glibc as lseek(2) on directory. ++ ++ Reiser4 cannot restart readdir from 64 bits of data, because two last ++ components of the key of directory entry are unknown, which given 128 bits: ++ locality and type fields in the key of directory entry are always known, to ++ start readdir() from given point objectid and offset fields have to be ++ filled. ++ ++ Traditional UNIX API for scanning through directory ++ (readdir/seekdir/telldir/opendir/closedir/rewindir/getdents) is based on the ++ assumption that directory is structured very much like regular file, in ++ particular, it is implied that each name within given directory (directory ++ entry) can be uniquely identified by scalar offset and that such offset is ++ stable across the life-time of the name is identifies. ++ ++ This is manifestly not so for reiser4. In reiser4 the only stable unique ++ identifies for the directory entry is its key that doesn't fit into ++ seekdir/telldir API. ++ ++ solution: ++ ++ Within each file descriptor participating in readdir-ing of directory ++ plugin/dir/dir.h:readdir_pos is maintained. This structure keeps track of ++ the "current" directory entry that file descriptor looks at. It contains a ++ key of directory entry (plus some additional info to deal with non-unique ++ keys that we wouldn't dwell onto here) and a logical position of this ++ directory entry starting from the beginning of the directory, that is ++ ordinal number of this entry in the readdir order. ++ ++ Obviously this logical position is not stable in the face of directory ++ modifications. To work around this, on each addition or removal of directory ++ entry all file descriptors for directory inode are scanned and their ++ readdir_pos are updated accordingly (adjust_dir_pos()). ++*/ ++int reiser4_iterate_common(struct file *f /* directory file being read */, ++ struct dir_context *context /* callback data passed to us by VFS */) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *inode; ++ coord_t coord; ++ lock_handle lh; ++ tap_t tap; ++ struct readdir_pos *pos; ++ ++ assert("nikita-1359", f != NULL); ++ inode = file_inode(f); ++ assert("nikita-1360", inode != NULL); ++ ++ if (!S_ISDIR(inode->i_mode)) ++ return RETERR(-ENOTDIR); ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ reiser4_tap_init(&tap, &coord, &lh, ZNODE_READ_LOCK); ++ ++ reiser4_readdir_readahead_init(inode, &tap); ++ ++repeat: ++ result = dir_readdir_init(f, &context->pos, &tap, &pos); ++ if (result == 0) { ++ result = reiser4_tap_load(&tap); ++ /* scan entries one by one feeding them to @filld */ ++ while (result == 0) { ++ coord_t *coord; ++ ++ coord = tap.coord; ++ assert("nikita-2572", coord_is_existing_unit(coord)); ++ assert("nikita-3227", is_valid_dir_coord(inode, coord)); ++ ++ result = feed_entry(&tap, meta_subvol_tree(), context); ++ if (result > 0) { ++ break; ++ } else if (result == 0) { ++ ++context->pos; ++ result = go_next_unit(&tap); ++ if (result == -E_NO_NEIGHBOR || ++ result == -ENOENT) { ++ result = 0; ++ break; ++ } else if (result == 0) { ++ if (is_valid_dir_coord(inode, coord)) ++ move_entry(pos, coord); ++ else ++ break; ++ } ++ } else if (result == -E_REPEAT) { ++ /* feed_entry() had to restart. */ ++ ++context->pos; ++ reiser4_tap_relse(&tap); ++ goto repeat; ++ } else ++ warning("vs-1617", ++ "reiser4_readdir_common: unexpected error %d", ++ result); ++ } ++ reiser4_tap_relse(&tap); ++ ++ if (result >= 0) ++ f->f_version = inode_query_iversion(inode); ++ } else if (result == -E_NO_NEIGHBOR || result == -ENOENT) ++ result = 0; ++ reiser4_tap_done(&tap); ++ reiser4_detach_fsdata(f); ++ /* ++ * try to update directory's atime ++ */ ++ if (reserve_update_sd_common(inode) != 0) ++ warning("", "failed to update atime on readdir: %llu", ++ get_inode_oid(inode)); ++ else ++ file_accessed(f); ++ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ ++ return (result <= 0) ? result : 0; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/file_plugin_common.c linux-5.10.2/fs/reiser4/plugin/file_plugin_common.c +--- linux-5.10.2.orig/fs/reiser4/plugin/file_plugin_common.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/file_plugin_common.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,1076 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ reiser4/README */ ++ ++/* this file contains typical implementations for most of methods of ++ file plugin ++*/ ++ ++#include "../inode.h" ++#include "object.h" ++#include "../safe_link.h" ++ ++static int insert_new_sd(struct inode *inode, oid_t oid); ++static int update_sd(struct inode *inode); ++ ++void build_body_key_common(struct inode *inode, reiser4_key *key) ++{ ++ reiser4_key_init(key); ++ set_key_locality(key, reiser4_inode_data(inode)->locality_id); ++ set_key_objectid(key, get_inode_oid(inode)); ++ set_key_type(key, KEY_BODY_MINOR); ++} ++ ++/** ++ * Common implementation of ->write_sd_by_inode() of file plugins. ++ * Either insert stat-data or update it. ++ * @inode: object to write stat-data of ++ */ ++int write_sd_by_inode_common(struct inode *inode, oid_t *oid) ++{ ++ int result; ++ ++ assert("nikita-730", inode != NULL); ++ ++ if (reiser4_inode_get_flag(inode, REISER4_NO_SD)) { ++ /* ++ * object doesn't have stat-data yet ++ */ ++ assert("edward-1785", oid != NULL); ++ result = insert_new_sd(inode, *oid); ++ } ++ else ++ assert("edward-1786", oid == NULL); ++ result = update_sd(inode); ++ ++ if (result != 0 && ++ result != -ENAMETOOLONG && ++ result != -ENOMEM) ++ /* ++ * Don't issue warnings about "name is too long" ++ */ ++ warning("nikita-2221", ++ "Failed to save sd for %llu: %i", ++ (unsigned long long)get_inode_oid(inode), ++ result); ++ return result; ++} ++ ++/* this is common implementation of set_plug_in_inode method of file plugin ++ */ ++int set_plug_in_inode_common(struct inode *object /* inode to set plugin on */ , ++ struct inode *parent /* parent object */ , ++ reiser4_object_create_data * data /* creational ++ * data */ ) ++{ ++ __u64 mask; ++ ++ object->i_mode = data->mode; ++ /* this should be plugin decision */ ++ object->i_uid = current_fsuid(); ++ object->i_mtime = object->i_atime = object->i_ctime = current_time(object); ++ ++ /* support for BSD style group-id assignment. See mount's manual page ++ description of bsdgroups ext2 mount options for more details */ ++ if (reiser4_is_set(object->i_sb, REISER4_BSD_GID)) ++ object->i_gid = parent->i_gid; ++ else if (parent->i_mode & S_ISGID) { ++ /* parent directory has sguid bit */ ++ object->i_gid = parent->i_gid; ++ if (S_ISDIR(object->i_mode)) ++ /* sguid is inherited by sub-directories */ ++ object->i_mode |= S_ISGID; ++ } else ++ object->i_gid = current_fsgid(); ++ ++ /* this object doesn't have stat-data yet */ ++ reiser4_inode_set_flag(object, REISER4_NO_SD); ++#if 0 ++ /* this is now called after all inode plugins are initialized: ++ do_create_vfs_child after adjust_to_parent */ ++ /* setup inode and file-operations for this inode */ ++ setup_inode_ops(object, data); ++#endif ++ reiser4_seal_init(&reiser4_inode_data(object)->sd_seal, NULL, NULL); ++ mask = (1 << UNIX_STAT) | (1 << LIGHT_WEIGHT_STAT); ++ if (!reiser4_is_set(object->i_sb, REISER4_32_BIT_TIMES)) ++ mask |= (1 << LARGE_TIMES_STAT); ++ ++ reiser4_inode_data(object)->extmask = mask; ++ return 0; ++} ++ ++/* this is common implementation of adjust_to_parent method of file plugin for ++ regular files ++ */ ++int adjust_to_parent_common(struct inode *object /* new object */ , ++ struct inode *parent /* parent directory */ , ++ struct inode *root/* root directory */) ++{ ++ assert("nikita-2165", object != NULL); ++ if (parent == NULL) ++ parent = root; ++ assert("nikita-2069", parent != NULL); ++ ++ /* ++ * inherit missing plugins from parent ++ */ ++ ++ grab_plugin_pset(object, parent, PSET_FILE); ++ grab_plugin_pset(object, parent, PSET_SD); ++ grab_plugin_pset(object, parent, PSET_FORMATTING); ++ grab_plugin_pset(object, parent, PSET_PERM); ++ return 0; ++} ++ ++/* this is common implementation of adjust_to_parent method of file plugin for ++ typical directories ++ */ ++int adjust_to_parent_common_dir(struct inode *object /* new object */ , ++ struct inode *parent /* parent directory */ , ++ struct inode *root/* root directory */) ++{ ++ int result = 0; ++ pset_member memb; ++ ++ assert("nikita-2166", object != NULL); ++ if (parent == NULL) ++ parent = root; ++ assert("nikita-2167", parent != NULL); ++ ++ /* ++ * inherit missing plugins from parent ++ */ ++ for (memb = 0; memb < PSET_LAST; ++memb) { ++ result = grab_plugin_pset(object, parent, memb); ++ if (result != 0) ++ break; ++ } ++ return result; ++} ++ ++int adjust_to_parent_cryptcompress(struct inode *object /* new object */ , ++ struct inode *parent /* parent directory */, ++ struct inode *root/* root directory */) ++{ ++ int result; ++ result = adjust_to_parent_common(object, parent, root); ++ if (result) ++ return result; ++ assert("edward-1416", parent != NULL); ++ ++ grab_plugin_pset(object, parent, PSET_CLUSTER); ++ grab_plugin_pset(object, parent, PSET_CIPHER); ++ grab_plugin_pset(object, parent, PSET_DIGEST); ++ grab_plugin_pset(object, parent, PSET_COMPRESSION); ++ grab_plugin_pset(object, parent, PSET_COMPRESSION_MODE); ++ ++ return 0; ++} ++ ++/* ++ * this is common implementation of ->create_object() of file plugins ++ */ ++int reiser4_create_object_common(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *data, oid_t *oid) ++{ ++ assert("nikita-744", object != NULL); ++ assert("nikita-745", parent != NULL); ++ assert("nikita-747", data != NULL); ++ assert("nikita-748", reiser4_inode_get_flag(object, REISER4_NO_SD)); ++ ++ return write_sd_by_inode_common(object, oid); ++} ++ ++/** ++ * Reserve disk space to update stat-data item ++ */ ++int reserve_update_sd_common(struct inode *inode) ++{ ++ reiser4_block_nr amount; ++ ++ assert("vs-1249", ++ inode_file_plugin(inode)->estimate.update == ++ estimate_update_common); ++ ++ amount = inode_file_plugin(inode)->estimate.update(inode); ++ ++ return reiser4_grab_space_force(amount, BA_CAN_COMMIT, ++ get_meta_subvol()); ++} ++ ++/** ++ * grab space which is needed to remove 2 items from the tree: ++ * stat data and safe-link ++ * @inode: object to be deleted ++ */ ++static int reserve_delete_object(struct inode *inode) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ return reiser4_grab_space_force(2 * ++ estimate_one_item_removal(&subv->tree), ++ BA_RESERVED | BA_CAN_COMMIT, subv); ++} ++ ++static int common_object_delete_no_reserve(struct inode *inode); ++ ++/** ++ * reiser4_delete_object_common - delete_object of file_plugin ++ * @inode: inode to be deleted ++ * ++ * Common implementation of ->delete_object() of file_plugin. ++ * It applies to object its deletion consists of removing two items - stat data ++ * and safe-link. ++ */ ++int reiser4_delete_object_common(struct inode *inode) ++{ ++ int ret; ++ ++ assert("nikita-1477", inode != NULL); ++ /* ++ * FIXME: if file body deletion failed (i/o error, for instance), ++ * inode->i_size can be != 0 here ++ */ ++ assert("nikita-3420", inode->i_size == 0 || S_ISLNK(inode->i_mode)); ++ assert("nikita-3421", inode->i_nlink == 0); ++ ++ if (reiser4_inode_get_flag(inode, REISER4_NO_SD)) ++ return 0; ++ ret = reserve_delete_object(inode); ++ if (ret) ++ return ret; ++ return common_object_delete_no_reserve(inode); ++} ++ ++/** ++ * reiser4_delete_dir_common - delete_object of file_plugin ++ * @inode: inode to be deleted ++ * ++ * This is common implementation of delete_object method of file_plugin for ++ * typical directory. It calls done method of dir_plugin to remove "." and ++ * removes stat data and safe-link. ++ */ ++int reiser4_delete_dir_common(struct inode *inode) ++{ ++ int result; ++ dir_plugin *dplug; ++ ++ assert("", (get_current_context() && ++ get_current_context()->trans->atom == NULL)); ++ ++ dplug = inode_dir_plugin(inode); ++ assert("vs-1101", dplug && dplug->done); ++ /* ++ * kill cursors which might be attached to inode ++ */ ++ reiser4_kill_cursors(inode); ++ result = reserve_delete_object(inode); ++ if (result) ++ return result; ++ result = dplug->done(inode); ++ if (result) ++ return result; ++ return common_object_delete_no_reserve(inode); ++} ++ ++/* this is common implementation of add_link method of file plugin ++ */ ++int reiser4_add_link_common(struct inode *object, struct inode *parent) ++{ ++ /* ++ * increment ->i_nlink and update ->i_ctime ++ */ ++ ++ INODE_INC_NLINK(object); ++ object->i_ctime = current_time(object); ++ return 0; ++} ++ ++/* this is common implementation of rem_link method of file plugin ++ */ ++int reiser4_rem_link_common(struct inode *object, struct inode *parent) ++{ ++ assert("nikita-2021", object != NULL); ++ assert("nikita-2163", object->i_nlink > 0); ++ ++ /* ++ * decrement ->i_nlink and update ->i_ctime ++ */ ++ ++ INODE_DROP_NLINK(object); ++ object->i_ctime = current_time(object); ++ return 0; ++} ++ ++/* this is common implementation of rem_link method of file plugin for typical ++ directory ++*/ ++int rem_link_common_dir(struct inode *object, struct inode *parent UNUSED_ARG) ++{ ++ assert("nikita-20211", object != NULL); ++ assert("nikita-21631", object->i_nlink > 0); ++ ++ /* ++ * decrement ->i_nlink and update ->i_ctime ++ */ ++ if(object->i_nlink == 2) ++ INODE_SET_NLINK(object, 0); ++ ++ else ++ INODE_DROP_NLINK(object); ++ object->i_ctime = current_time(object); ++ return 0; ++} ++ ++/* this is common implementation of owns_item method of file plugin ++ compare objectids of keys in inode and coord */ ++int owns_item_common(const struct inode *inode, /* object to check ++ * against */ ++ const coord_t *coord/* coord to check */) ++{ ++ reiser4_key item_key; ++ reiser4_key file_key; ++ ++ assert("nikita-760", inode != NULL); ++ assert("nikita-761", coord != NULL); ++ ++ return coord_is_existing_item(coord) && ++ (get_key_objectid(build_sd_key(inode, &file_key)) == ++ get_key_objectid(item_key_by_coord(coord, &item_key))); ++} ++ ++/* this is common implementation of owns_item method of file plugin ++ for typical directory ++*/ ++int owns_item_common_dir(const struct inode *inode,/* object to check against */ ++ const coord_t *coord/* coord of item to check */) ++{ ++ reiser4_key item_key; ++ ++ assert("nikita-1335", inode != NULL); ++ assert("nikita-1334", coord != NULL); ++ ++ if (plugin_of_group(item_plugin_by_coord(coord), DIR_ENTRY_ITEM_TYPE)) ++ return get_key_locality(item_key_by_coord(coord, &item_key)) == ++ get_inode_oid(inode); ++ else ++ return owns_item_common(inode, coord); ++} ++ ++/* this is common implementation of can_add_link method of file plugin ++ checks whether yet another hard links to this object can be added ++*/ ++int can_add_link_common(const struct inode *object/* object to check */) ++{ ++ assert("nikita-732", object != NULL); ++ ++ /* inode->i_nlink is unsigned int, so just check for integer ++ overflow */ ++ return object->i_nlink + 1 != 0; ++} ++ ++/* this is common implementation of can_rem_link method of file plugin for ++ typical directory ++*/ ++int can_rem_link_common_dir(const struct inode *inode) ++{ ++ /* is_dir_empty() returns 0 is dir is empty */ ++ return !is_dir_empty(inode); ++} ++ ++/* this is common implementation of detach method of file plugin for typical ++ directory ++*/ ++int reiser4_detach_common_dir(struct inode *child, struct inode *parent) ++{ ++ dir_plugin *dplug; ++ ++ dplug = inode_dir_plugin(child); ++ assert("nikita-2883", dplug != NULL); ++ assert("nikita-2884", dplug->detach != NULL); ++ return dplug->detach(child, parent); ++} ++ ++/* this is common implementation of bind method of file plugin for typical ++ directory ++*/ ++int reiser4_bind_common_dir(struct inode *child, struct inode *parent) ++{ ++ dir_plugin *dplug; ++ ++ dplug = inode_dir_plugin(child); ++ assert("nikita-2646", dplug != NULL); ++ return dplug->attach(child, parent); ++} ++ ++static int process_truncate(struct inode *, __u64 size); ++ ++/* this is common implementation of safelink method of file plugin ++ */ ++int safelink_common(struct inode *object, reiser4_safe_link_t link, __u64 value) ++{ ++ int result; ++ ++ assert("vs-1705", get_current_context()->trans->atom == NULL); ++ if (link == SAFE_UNLINK) ++ /* nothing to do. iput() in the caller (process_safelink) will ++ * finish with file */ ++ result = 0; ++ else if (link == SAFE_TRUNCATE) ++ result = process_truncate(object, value); ++ else { ++ warning("nikita-3438", "Unrecognized safe-link type: %i", link); ++ result = RETERR(-EIO); ++ } ++ return result; ++} ++ ++/* this is common implementation of estimate.create method of file plugin ++ can be used when object creation involves insertion of one item (usually stat ++ data) into tree ++*/ ++reiser4_block_nr estimate_create_common(const struct inode *object) ++{ ++ return estimate_one_insert_item(meta_subvol_tree()); ++} ++ ++/* this is common implementation of estimate.create method of file plugin for ++ typical directory ++ can be used when directory creation involves insertion of two items (usually ++ stat data and item containing "." and "..") into tree ++*/ ++reiser4_block_nr estimate_create_common_dir(const struct inode *object) ++{ ++ return 2 * estimate_one_insert_item(meta_subvol_tree()); ++} ++ ++/* this is common implementation of estimate.update method of file plugin ++ can be used when stat data update does not do more than inserting a unit ++ into a stat data item which is probably true for most cases ++*/ ++reiser4_block_nr estimate_update_common(const struct inode *inode) ++{ ++ return estimate_one_insert_into_item(meta_subvol_tree()); ++} ++ ++/* this is common implementation of estimate.unlink method of file plugin ++ */ ++reiser4_block_nr ++estimate_unlink_common(const struct inode *object UNUSED_ARG, ++ const struct inode *parent UNUSED_ARG) ++{ ++ return 0; ++} ++ ++/* this is common implementation of estimate.unlink method of file plugin for ++ typical directory ++*/ ++reiser4_block_nr ++estimate_unlink_common_dir(const struct inode *object, ++ const struct inode *parent) ++{ ++ dir_plugin *dplug; ++ ++ dplug = inode_dir_plugin(object); ++ assert("nikita-2888", dplug != NULL); ++ assert("nikita-2887", dplug->estimate.unlink != NULL); ++ return dplug->estimate.unlink(object, parent); ++} ++ ++char *wire_write_common(struct inode *inode, char *start) ++{ ++ return build_inode_onwire(inode, start); ++} ++ ++char *wire_read_common(char *addr, reiser4_object_on_wire * obj) ++{ ++ if (!obj) ++ return locate_obj_key_id_onwire(addr); ++ return extract_obj_key_id_from_onwire(addr, &obj->u.std.key_id); ++} ++ ++struct dentry *wire_get_common(struct super_block *sb, ++ reiser4_object_on_wire * obj) ++{ ++ struct inode *inode; ++ struct dentry *dentry; ++ reiser4_key key; ++ ++ extract_key_from_id(&obj->u.std.key_id, &key); ++ inode = reiser4_iget(sb, &key, FIND_EXACT, 1); ++ if (!IS_ERR(inode)) { ++ reiser4_iget_complete(inode); ++ dentry = d_obtain_alias(inode); ++ if (!IS_ERR(dentry)) ++ dentry->d_op = &get_super_private(sb)->ops.dentry; ++ } else if (PTR_ERR(inode) == -ENOENT) ++ /* ++ * inode wasn't found at the key encoded in the file ++ * handle. Hence, file handle is stale. ++ */ ++ dentry = ERR_PTR(RETERR(-ESTALE)); ++ else ++ dentry = (void *)inode; ++ return dentry; ++} ++ ++int wire_size_common(struct inode *inode) ++{ ++ return inode_onwire_size(inode); ++} ++ ++void wire_done_common(reiser4_object_on_wire * obj) ++{ ++ /* nothing to do */ ++} ++ ++/* helper function to print errors */ ++static void key_warning(const reiser4_key * key /* key to print */ , ++ const struct inode *inode, ++ int code/* error code to print */) ++{ ++ assert("nikita-716", key != NULL); ++ ++ if (code != -ENOMEM) { ++ warning("nikita-717", "Error for inode %llu (%i)", ++ (unsigned long long)get_key_objectid(key), code); ++ reiser4_print_key("for key", key); ++ } ++} ++ ++/* NIKITA-FIXME-HANS: perhaps this function belongs in another file? */ ++#if REISER4_DEBUG ++static void ++check_inode_seal(const struct inode *inode, ++ const coord_t *coord, const reiser4_key * key) ++{ ++ reiser4_key unit_key; ++ ++ unit_key_by_coord(coord, &unit_key); ++ assert("nikita-2752", ++ WITH_DATA_RET(coord->node, 1, keyeq(key, &unit_key))); ++ assert("nikita-2753", get_inode_oid(inode) == get_key_objectid(key)); ++} ++ ++static void check_sd_coord(coord_t *coord, const reiser4_key *key) ++{ ++ coord_clear_iplug(coord); ++ if (zload(coord->node)) ++ return; ++ if (!coord_is_existing_unit(coord) || ++ !item_plugin_by_coord(coord) || ++ (znode_get_level(coord->node) != LEAF_LEVEL) || ++ !item_is_statdata(coord)) { ++ warning("nikita-1901", "Conspicuous seal"); ++ reiser4_print_key("key", key); ++ print_coord("coord", coord, 1); ++ impossible("nikita-2877", "no way"); ++ } ++ zrelse(coord->node); ++} ++#else ++#define check_inode_seal(inode, coord, key) noop ++#define check_sd_coord(coord, key) noop ++#endif ++ ++/** ++ * insert new stat-data into tree. Called with inode state ++ * locked. Return inode state locked. ++ * @inode - inode to create stat-data for; ++ * @oid - pre-allocated object id. ++ */ ++static int insert_new_sd(struct inode *inode, oid_t oid) ++{ ++ int result; ++ reiser4_key key; ++ coord_t coord; ++ reiser4_item_data data; ++ char *area; ++ reiser4_inode *ref; ++ lock_handle lh; ++ ++ assert("nikita-723", inode != NULL); ++ assert("nikita-3406", reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ ref = reiser4_inode_data(inode); ++ spin_lock_inode(inode); ++ ++ if (ref->plugin_mask != 0) ++ /* inode has non-standard plugins */ ++ inode_set_extension(inode, PLUGIN_STAT); ++ /* ++ * prepare specification of new item to be inserted ++ */ ++ ++ data.iplug = inode_sd_plugin(inode); ++ data.length = data.iplug->s.sd.save_len(inode); ++ spin_unlock_inode(inode); ++ ++ data.data = NULL; ++ data.user = 0; ++ /* ++ * could be optimized for case where there is only one node ++ * format in use in the filesystem, probably there are lots ++ * of such places we could optimize for only one node layout. ++ * -Hans ++ */ ++ if (data.length > meta_subvol_tree()->nplug->max_item_size()) { ++ /* ++ * This is silly check, but we don't know actual node ++ * where insertion will go into ++ */ ++ return RETERR(-ENAMETOOLONG); ++ } ++ /* ++ * oid = oid_allocate(inode->i_sb); ++ * NIKITA-FIXME-HANS: what is your opinion on whether this error ++ * check should be encapsulated into oid_allocate? ++ * if (oid == ABSOLUTE_MAX_OID) ++ * return RETERR(-EOVERFLOW); ++ * ++ * oid had been allocated before grabbing space for the ++ * new stat-data as we need to know id of the subvolume ++ * where this stat-data will be written to. - Edward. ++ */ ++ set_inode_oid(inode, oid); ++ ++ coord_init_zero(&coord); ++ init_lh(&lh); ++ ++ result = insert_by_key(meta_subvol_tree(), ++ build_sd_key(inode, &key), &data, &coord, &lh, ++ /* stat data lives on a leaf level */ ++ LEAF_LEVEL, CBK_UNIQUE); ++ ++ /* we don't want to re-check that somebody didn't insert ++ stat-data while we were doing io, because if it did, ++ insert_by_key() returned error. */ ++ /* but what _is_ possible is that plugin for inode's stat-data, ++ list of non-standard plugins or their state would change ++ during io, so that stat-data wouldn't fit into sd. To avoid ++ this race we keep inode_state lock. This lock has to be ++ taken each time you access inode in a way that would cause ++ changes in sd size: changing plugins etc. ++ */ ++ ++ if (result == IBK_INSERT_OK) { ++ coord_clear_iplug(&coord); ++ result = zload(coord.node); ++ if (result == 0) { ++ /* have we really inserted stat data? */ ++ assert("nikita-725", item_is_statdata(&coord)); ++ ++ /* inode was just created. It is inserted into hash ++ table, but no directory entry was yet inserted into ++ parent. So, inode is inaccessible through ++ ->lookup(). All places that directly grab inode ++ from hash-table (like old knfsd), should check ++ IMMUTABLE flag that is set by common_create_child. ++ */ ++ assert("nikita-3240", data.iplug != NULL); ++ assert("nikita-3241", data.iplug->s.sd.save != NULL); ++ area = item_body_by_coord(&coord); ++ result = data.iplug->s.sd.save(inode, &area); ++ znode_make_dirty(coord.node); ++ if (result == 0) { ++ /* object has stat-data now */ ++ reiser4_inode_clr_flag(inode, REISER4_NO_SD); ++ reiser4_inode_set_flag(inode, ++ REISER4_SDLEN_KNOWN); ++ /* initialise stat-data seal */ ++ reiser4_seal_init(&ref->sd_seal, &coord, &key); ++ ref->sd_coord = coord; ++ check_inode_seal(inode, &coord, &key); ++ } else if (result != -ENOMEM) ++ /* ++ * convert any other error code to -EIO to ++ * avoid confusing user level with unexpected ++ * errors. ++ */ ++ result = RETERR(-EIO); ++ zrelse(coord.node); ++ } ++ } ++ done_lh(&lh); ++ ++ if (result != 0) ++ key_warning(&key, inode, result); ++ else ++ oid_count_allocated(); ++ ++ return result; ++} ++ ++/** ++ * Find stat-data in a tree by key. ++ * ++ * Sometimes we are not able to construct precise key to look for ++ * stat-data (specifically, its ordering component is unknown). ++ * In this case we set maximal possible ordering value and perform ++ * lookup with FIND_MAX_NOT_MORE_THAN lookup bias. ++ * ++ *@inode: inode to look stat-data for ++ *@key: key of stat-data ++ *@bias: lookup bias - ++ * FIND_EXACT, if the key is precise, ++ * FIND_MAX_NOT_MORE_THAN, if we don't know ordering component ++ * of the key ++ *@coord: resulting coord ++ *@lh: resulting lock handle ++ */ ++int lookup_sd(struct inode *inode, znode_lock_mode lock_mode, ++ coord_t *coord, lock_handle *lh, const reiser4_key *key, ++ lookup_bias bias, int silent) ++{ ++ int result; ++ __u32 flags; ++ ++ assert("nikita-1692", inode != NULL); ++ assert("nikita-1693", coord != NULL); ++ assert("nikita-1694", key != NULL); ++ ++ /* look for the object's stat data in a tree. ++ This returns in "node" pointer to a locked znode and in "pos" ++ position of an item found in node. Both are only valid if ++ coord_found is returned. */ ++ flags = (lock_mode == ZNODE_WRITE_LOCK) ? CBK_FOR_INSERT : 0; ++ flags |= CBK_UNIQUE; ++ /* ++ * traverse tree to find stat data. We cannot use vroot here, because ++ * it only covers _body_ of the file, and stat data don't belong ++ * there. ++ */ ++ result = coord_by_key(meta_subvol_tree(), ++ key, ++ coord, ++ lh, ++ lock_mode, ++ bias, LEAF_LEVEL, LEAF_LEVEL, flags, NULL); ++ if (unlikely(IS_CBKERR(result))) { ++ key_warning(key, inode, result); ++ return result; ++ } ++ if (result == CBK_COORD_FOUND) { ++ check_sd_coord(coord, key); ++ return 0; ++ } ++ /* not found */ ++ if (bias == FIND_MAX_NOT_MORE_THAN) { ++ /* ++ * In this mode we don't expect that stat-data, ++ * we are looking for, necessarily exists. ++ */ ++ if (coord->between != AFTER_ITEM) { ++ warning("edward-2320", ++ "Unexpected between state (%d)", ++ coord->between); ++ key_warning(key, inode, result); ++ return -EIO; ++ } ++ coord->between = AT_UNIT; ++ coord->unit_pos = 0; ++ return 0; ++ } ++ /* not found by exact key */ ++ if (!silent) ++ key_warning(key, inode, result); ++ return result; ++} ++ ++static int locate_inode_sd(struct inode *inode, ++ reiser4_key *key, coord_t *coord, lock_handle *lh) ++{ ++ reiser4_inode *state; ++ seal_t seal; ++ int result; ++ ++ assert("nikita-3483", inode != NULL); ++ ++ state = reiser4_inode_data(inode); ++ spin_lock_inode(inode); ++ *coord = state->sd_coord; ++ coord_clear_iplug(coord); ++ seal = state->sd_seal; ++ spin_unlock_inode(inode); ++ ++ build_sd_key(inode, key); ++ /* first, try to use seal */ ++ if (reiser4_seal_is_set(&seal)) { ++ result = reiser4_seal_validate(&seal, ++ meta_subvol_tree(), ++ coord, ++ key, ++ lh, ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_LOPRI); ++ if (result == 0) { ++ check_sd_coord(coord, key); ++ return 0; ++ } ++ } ++ /* hint is invalid, ++ * so traverse tree ++ */ ++ coord_init_zero(coord); ++ return lookup_sd(inode, ZNODE_WRITE_LOCK, coord, lh, key, ++ FIND_EXACT, 0); ++} ++ ++#if REISER4_DEBUG ++static int all_but_offset_key_eq(const reiser4_key * k1, const reiser4_key * k2) ++{ ++ return (get_key_locality(k1) == get_key_locality(k2) && ++ get_key_type(k1) == get_key_type(k2) && ++ get_key_band(k1) == get_key_band(k2) && ++ get_key_ordering(k1) == get_key_ordering(k2) && ++ get_key_objectid(k1) == get_key_objectid(k2)); ++} ++ ++#include "../tree_walk.h" ++ ++/* make some checks before and after stat-data resize operation */ ++static int check_sd_resize(struct inode *inode, coord_t *coord, ++ int length, int progress/* 1 means after resize */) ++{ ++ int ret = 0; ++ lock_handle left_lock; ++ coord_t left_coord; ++ reiser4_key left_key; ++ reiser4_key key; ++ ++ if (inode_file_plugin(inode) != ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)) ++ return 0; ++ if (!length) ++ return 0; ++ if (coord->item_pos != 0) ++ return 0; ++ ++ init_lh(&left_lock); ++ ret = reiser4_get_left_neighbor(&left_lock, ++ coord->node, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (ret == -E_REPEAT || ret == -E_NO_NEIGHBOR || ++ ret == -ENOENT || ret == -EINVAL ++ || ret == -E_DEADLOCK) { ++ ret = 0; ++ goto exit; ++ } ++ ret = zload(left_lock.node); ++ if (ret) ++ goto exit; ++ coord_init_last_unit(&left_coord, left_lock.node); ++ item_key_by_coord(&left_coord, &left_key); ++ item_key_by_coord(coord, &key); ++ ++ if (all_but_offset_key_eq(&key, &left_key)) ++ /* corruption occured */ ++ ret = 1; ++ zrelse(left_lock.node); ++ exit: ++ done_lh(&left_lock); ++ return ret; ++} ++#endif ++ ++/* update stat-data at @coord */ ++static int ++update_sd_at(struct inode *inode, coord_t *coord, reiser4_key * key, ++ lock_handle * lh) ++{ ++ int result; ++ reiser4_item_data data; ++ char *area; ++ reiser4_inode *state; ++ znode *loaded; ++ ++ state = reiser4_inode_data(inode); ++ ++ coord_clear_iplug(coord); ++ result = zload(coord->node); ++ if (result != 0) ++ return result; ++ loaded = coord->node; ++ ++ spin_lock_inode(inode); ++ assert("nikita-728", inode_sd_plugin(inode) != NULL); ++ data.iplug = inode_sd_plugin(inode); ++ ++ /* if inode has non-standard plugins, add appropriate stat data ++ * extension */ ++ if (state->extmask & (1 << PLUGIN_STAT)) { ++ if (state->plugin_mask == 0) ++ inode_clr_extension(inode, PLUGIN_STAT); ++ } else if (state->plugin_mask != 0) ++ inode_set_extension(inode, PLUGIN_STAT); ++ ++ if (state->extmask & (1 << HEIR_STAT)) { ++ if (state->heir_mask == 0) ++ inode_clr_extension(inode, HEIR_STAT); ++ } else if (state->heir_mask != 0) ++ inode_set_extension(inode, HEIR_STAT); ++ ++ /* data.length is how much space to add to (or remove ++ from if negative) sd */ ++ if (!reiser4_inode_get_flag(inode, REISER4_SDLEN_KNOWN)) { ++ /* recalculate stat-data length */ ++ data.length = ++ data.iplug->s.sd.save_len(inode) - ++ item_length_by_coord(coord); ++ reiser4_inode_set_flag(inode, REISER4_SDLEN_KNOWN); ++ } else ++ data.length = 0; ++ spin_unlock_inode(inode); ++ ++ /* if on-disk stat data is of different length than required ++ for this inode, resize it */ ++ ++ if (data.length != 0) { ++ data.data = NULL; ++ data.user = 0; ++ ++ assert("edward-1441", ++ !check_sd_resize(inode, coord, ++ data.length, 0/* before resize */)); ++ ++ /* insertion code requires that insertion point (coord) was ++ * between units. */ ++ coord->between = AFTER_UNIT; ++ result = reiser4_resize_item(coord, &data, key, lh, ++ COPI_DONT_SHIFT_LEFT); ++ if (result != 0) { ++ key_warning(key, inode, result); ++ zrelse(loaded); ++ return result; ++ } ++ if (loaded != coord->node) { ++ /* reiser4_resize_item moved coord to another node. ++ Zload it */ ++ zrelse(loaded); ++ coord_clear_iplug(coord); ++ result = zload(coord->node); ++ if (result != 0) ++ return result; ++ loaded = coord->node; ++ } ++ assert("edward-1442", ++ !check_sd_resize(inode, coord, ++ data.length, 1/* after resize */)); ++ } ++ area = item_body_by_coord(coord); ++ spin_lock_inode(inode); ++ result = data.iplug->s.sd.save(inode, &area); ++ znode_make_dirty(coord->node); ++ ++ /* re-initialise stat-data seal */ ++ ++ /* ++ * coord.between was possibly skewed from AT_UNIT when stat-data size ++ * was changed and new extensions were pasted into item. ++ */ ++ coord->between = AT_UNIT; ++ reiser4_seal_init(&state->sd_seal, coord, key); ++ state->sd_coord = *coord; ++ spin_unlock_inode(inode); ++ check_inode_seal(inode, coord, key); ++ zrelse(loaded); ++ return result; ++} ++ ++/* Update existing stat-data in a tree. Called with inode state locked. Return ++ inode state locked. */ ++static int update_sd(struct inode *inode/* inode to update sd for */) ++{ ++ int result; ++ reiser4_key key; ++ coord_t coord; ++ lock_handle lh; ++ ++ assert("nikita-726", inode != NULL); ++ ++ /* no stat-data, nothing to update?! */ ++ assert("nikita-3482", !reiser4_inode_get_flag(inode, REISER4_NO_SD)); ++ ++ init_lh(&lh); ++ ++ result = locate_inode_sd(inode, &key, &coord, &lh); ++ if (result == 0) ++ result = update_sd_at(inode, &coord, &key, &lh); ++ done_lh(&lh); ++ ++ return result; ++} ++ ++/** ++ * Helper for reiser4_delete_object_common and reiser4_delete_dir_common. ++ * Remove object's body, stat data and safe link from the tree. ++ * Space for that must be reserved by caller before ++ * @inode: object to be deleted ++ */ ++static int common_object_delete_no_reserve(struct inode *inode) ++{ ++ int result; ++ ++ assert("nikita-1477", inode != NULL); ++ ++ if (!reiser4_inode_get_flag(inode, REISER4_NO_SD)) { ++ reiser4_key sd_key; ++ ++ build_sd_key(inode, &sd_key); ++ result = reiser4_cut_tree(meta_subvol_tree(), ++ &sd_key, &sd_key, NULL, 0); ++ if (result == 0) { ++ reiser4_inode_set_flag(inode, REISER4_NO_SD); ++ result = oid_release(inode->i_sb, get_inode_oid(inode)); ++ if (result == 0) { ++ oid_count_released(); ++ ++ result = safe_link_del(get_meta_subvol(), ++ get_inode_oid(inode), ++ SAFE_UNLINK); ++ } ++ } ++ } else ++ result = 0; ++ return result; ++} ++ ++/* helper for safelink_common */ ++static int process_truncate(struct inode *inode, __u64 size) ++{ ++ int result; ++ struct iattr attr; ++ file_plugin *fplug; ++ reiser4_context *ctx; ++ struct dentry dentry; ++ ++ assert("vs-21", is_in_reiser4_context()); ++ ctx = reiser4_init_context(inode->i_sb); ++ assert("vs-22", !IS_ERR(ctx)); ++ ++ attr.ia_size = size; ++ attr.ia_valid = ATTR_SIZE | ATTR_CTIME; ++ fplug = inode_file_plugin(inode); ++ ++ inode_lock(inode); ++ assert("vs-1704", get_current_context()->trans->atom == NULL); ++ dentry.d_inode = inode; ++ result = inode->i_op->setattr(&dentry, &attr); ++ inode_unlock(inode); ++ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ ++ return result; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/hash.c linux-5.10.2/fs/reiser4/plugin/hash.c +--- linux-5.10.2.orig/fs/reiser4/plugin/hash.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/hash.c 2020-12-23 16:07:46.125813231 +0100 +@@ -0,0 +1,347 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Hash functions */ ++ ++#include "../debug.h" ++#include "plugin_header.h" ++#include "plugin.h" ++#include "../super.h" ++#include "../inode.h" ++ ++#include ++ ++/* old rupasov (yura) hash */ ++static __u64 hash_rupasov(const unsigned char *name /* name to hash */ , ++ int len/* @name's length */) ++{ ++ int i; ++ int j; ++ int pow; ++ __u64 a; ++ __u64 c; ++ ++ assert("nikita-672", name != NULL); ++ assert("nikita-673", len >= 0); ++ ++ for (pow = 1, i = 1; i < len; ++i) ++ pow = pow * 10; ++ ++ if (len == 1) ++ a = name[0] - 48; ++ else ++ a = (name[0] - 48) * pow; ++ ++ for (i = 1; i < len; ++i) { ++ c = name[i] - 48; ++ for (pow = 1, j = i; j < len - 1; ++j) ++ pow = pow * 10; ++ a = a + c * pow; ++ } ++ for (; i < 40; ++i) { ++ c = '0' - 48; ++ for (pow = 1, j = i; j < len - 1; ++j) ++ pow = pow * 10; ++ a = a + c * pow; ++ } ++ ++ for (; i < 256; ++i) { ++ c = i; ++ for (pow = 1, j = i; j < len - 1; ++j) ++ pow = pow * 10; ++ a = a + c * pow; ++ } ++ ++ a = a << 7; ++ return a; ++} ++ ++/* r5 hash */ ++static __u64 hash_r5(const unsigned char *name /* name to hash */ , ++ int len UNUSED_ARG/* @name's length */) ++{ ++ __u64 a = 0; ++ ++ assert("nikita-674", name != NULL); ++ assert("nikita-675", len >= 0); ++ ++ while (*name) { ++ a += *name << 4; ++ a += *name >> 4; ++ a *= 11; ++ name++; ++ } ++ return a; ++} ++ ++/* Keyed 32-bit hash function using TEA in a Davis-Meyer function ++ H0 = Key ++ Hi = E Mi(Hi-1) + Hi-1 ++ ++ (see Applied Cryptography, 2nd edition, p448). ++ ++ Jeremy Fitzhardinge 1998 ++ ++ Jeremy has agreed to the contents of reiserfs/README. -Hans ++ ++ This code was blindly upgraded to __u64 by s/__u32/__u64/g. ++*/ ++static __u64 hash_tea(const unsigned char *name /* name to hash */ , ++ int len/* @name's length */) ++{ ++ __u64 k[] = { 0x9464a485u, 0x542e1a94u, 0x3e846bffu, 0xb75bcfc3u }; ++ ++ __u64 h0 = k[0], h1 = k[1]; ++ __u64 a, b, c, d; ++ __u64 pad; ++ int i; ++ ++ assert("nikita-676", name != NULL); ++ assert("nikita-677", len >= 0); ++ ++#define DELTA 0x9E3779B9u ++#define FULLROUNDS 10 /* 32 is overkill, 16 is strong crypto */ ++#define PARTROUNDS 6 /* 6 gets complete mixing */ ++ ++/* a, b, c, d - data; h0, h1 - accumulated hash */ ++#define TEACORE(rounds) \ ++ do { \ ++ __u64 sum = 0; \ ++ int n = rounds; \ ++ __u64 b0, b1; \ ++ \ ++ b0 = h0; \ ++ b1 = h1; \ ++ \ ++ do { \ ++ sum += DELTA; \ ++ b0 += ((b1 << 4)+a) ^ (b1+sum) ^ ((b1 >> 5)+b); \ ++ b1 += ((b0 << 4)+c) ^ (b0+sum) ^ ((b0 >> 5)+d); \ ++ } while (--n); \ ++ \ ++ h0 += b0; \ ++ h1 += b1; \ ++ } while (0) ++ ++ pad = (__u64) len | ((__u64) len << 8); ++ pad |= pad << 16; ++ ++ while (len >= 16) { ++ a = (__u64) name[0] | (__u64) name[1] << 8 | (__u64) name[2] << ++ 16 | (__u64) name[3] << 24; ++ b = (__u64) name[4] | (__u64) name[5] << 8 | (__u64) name[6] << ++ 16 | (__u64) name[7] << 24; ++ c = (__u64) name[8] | (__u64) name[9] << 8 | (__u64) name[10] << ++ 16 | (__u64) name[11] << 24; ++ d = (__u64) name[12] | (__u64) name[13] << 8 | (__u64) name[14] ++ << 16 | (__u64) name[15] << 24; ++ ++ TEACORE(PARTROUNDS); ++ ++ len -= 16; ++ name += 16; ++ } ++ ++ if (len >= 12) { ++ assert("", len < 16); ++ ++ a = (__u64) name[0] | (__u64) name[1] << 8 | (__u64) name[2] << ++ 16 | (__u64) name[3] << 24; ++ b = (__u64) name[4] | (__u64) name[5] << 8 | (__u64) name[6] << ++ 16 | (__u64) name[7] << 24; ++ c = (__u64) name[8] | (__u64) name[9] << 8 | (__u64) name[10] << ++ 16 | (__u64) name[11] << 24; ++ ++ d = pad; ++ for (i = 12; i < len; i++) { ++ d <<= 8; ++ d |= name[i]; ++ } ++ } else if (len >= 8) { ++ assert("", len < 12); ++ ++ a = (__u64) name[0] | (__u64) name[1] << 8 | (__u64) name[2] << ++ 16 | (__u64) name[3] << 24; ++ b = (__u64) name[4] | (__u64) name[5] << 8 | (__u64) name[6] << ++ 16 | (__u64) name[7] << 24; ++ ++ c = d = pad; ++ for (i = 8; i < len; i++) { ++ c <<= 8; ++ c |= name[i]; ++ } ++ } else if (len >= 4) { ++ assert("", len < 8); ++ ++ a = (__u64) name[0] | (__u64) name[1] << 8 | (__u64) name[2] << ++ 16 | (__u64) name[3] << 24; ++ ++ b = c = d = pad; ++ for (i = 4; i < len; i++) { ++ b <<= 8; ++ b |= name[i]; ++ } ++ } else { ++ assert("", len < 4); ++ ++ a = b = c = d = pad; ++ for (i = 0; i < len; i++) { ++ a <<= 8; ++ a |= name[i]; ++ } ++ } ++ ++ TEACORE(FULLROUNDS); ++ ++/* return 0;*/ ++ return h0 ^ h1; ++ ++} ++ ++/* classical 64 bit Fowler/Noll/Vo-1 (FNV-1) hash. ++ ++ See http://www.isthe.com/chongo/tech/comp/fnv/ for details. ++ ++ Excerpts: ++ ++ FNV hashes are designed to be fast while maintaining a low collision ++ rate. ++ ++ [This version also seems to preserve lexicographical order locally.] ++ ++ FNV hash algorithms and source code have been released into the public ++ domain. ++ ++*/ ++static __u64 hash_fnv1(const unsigned char *name /* name to hash */ , ++ int len UNUSED_ARG/* @name's length */) ++{ ++ unsigned long long a = 0xcbf29ce484222325ull; ++ const unsigned long long fnv_64_prime = 0x100000001b3ull; ++ ++ assert("nikita-678", name != NULL); ++ assert("nikita-679", len >= 0); ++ ++ /* FNV-1 hash each octet in the buffer */ ++ for (; *name; ++name) { ++ /* multiply by the 32 bit FNV magic prime mod 2^64 */ ++ a *= fnv_64_prime; ++ /* xor the bottom with the current octet */ ++ a ^= (unsigned long long)(*name); ++ } ++ /* return our new hash value */ ++ return a; ++} ++ ++/* degenerate hash function used to simplify testing of non-unique key ++ handling */ ++static __u64 hash_deg(const unsigned char *name UNUSED_ARG /* name to hash */ , ++ int len UNUSED_ARG/* @name's length */) ++{ ++ return 0xc0c0c0c010101010ull; ++} ++ ++static int change_hash(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ int result; ++ ++ assert("nikita-3503", inode != NULL); ++ assert("nikita-3504", plugin != NULL); ++ ++ assert("nikita-3505", is_reiser4_inode(inode)); ++ assert("nikita-3507", plugin->h.type_id == REISER4_HASH_PLUGIN_TYPE); ++ ++ if (!plugin_of_group(inode_file_plugin(inode), REISER4_DIRECTORY_FILE)) ++ return RETERR(-EINVAL); ++ ++ result = 0; ++ if (inode_hash_plugin(inode) == NULL || ++ inode_hash_plugin(inode)->h.id != plugin->h.id) { ++ if (is_dir_empty(inode) == 0) ++ result = aset_set_unsafe(&reiser4_inode_data(inode)->pset, ++ PSET_HASH, plugin); ++ else ++ result = RETERR(-ENOTEMPTY); ++ ++ } ++ return result; ++} ++ ++static reiser4_plugin_ops hash_plugin_ops = { ++ .init = NULL, ++ .load = NULL, ++ .save_len = NULL, ++ .save = NULL, ++ .change = change_hash ++}; ++ ++/* hash plugins */ ++hash_plugin hash_plugins[LAST_HASH_ID] = { ++ [RUPASOV_HASH_ID] = { ++ .h = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .id = RUPASOV_HASH_ID, ++ .pops = &hash_plugin_ops, ++ .label = "rupasov", ++ .desc = "Original Yura's hash", ++ .linkage = {NULL, NULL} ++ }, ++ .hash = hash_rupasov ++ }, ++ [R5_HASH_ID] = { ++ .h = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .id = R5_HASH_ID, ++ .pops = &hash_plugin_ops, ++ .label = "r5", ++ .desc = "r5 hash", ++ .linkage = {NULL, NULL} ++ }, ++ .hash = hash_r5 ++ }, ++ [TEA_HASH_ID] = { ++ .h = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .id = TEA_HASH_ID, ++ .pops = &hash_plugin_ops, ++ .label = "tea", ++ .desc = "tea hash", ++ .linkage = {NULL, NULL} ++ }, ++ .hash = hash_tea ++ }, ++ [FNV1_HASH_ID] = { ++ .h = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .id = FNV1_HASH_ID, ++ .pops = &hash_plugin_ops, ++ .label = "fnv1", ++ .desc = "fnv1 hash", ++ .linkage = {NULL, NULL} ++ }, ++ .hash = hash_fnv1 ++ }, ++ [DEGENERATE_HASH_ID] = { ++ .h = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .id = DEGENERATE_HASH_ID, ++ .pops = &hash_plugin_ops, ++ .label = "degenerate hash", ++ .desc = "Degenerate hash: only for testing", ++ .linkage = {NULL, NULL} ++ }, ++ .hash = hash_deg ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/inode_ops.c linux-5.10.2/fs/reiser4/plugin/inode_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/inode_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/inode_ops.c 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,909 @@ ++/* ++ * Copyright 2005 by Hans Reiser, licensing governed by reiser4/README ++ */ ++ ++/* ++ * this file contains typical implementations for most of methods of struct ++ * inode_operations ++ */ ++ ++#include "../inode.h" ++#include "../safe_link.h" ++ ++#include ++ ++static int create_vfs_object(struct inode *parent, struct dentry *dentry, ++ reiser4_object_create_data *data); ++ ++/** ++ * reiser4_create_common - create of inode operations ++ * @parent: inode of parent directory ++ * @dentry: dentry of new object to create ++ * @mode: the permissions to use ++ * @exclusive: ++ * ++ * This is common implementation of vfs's create method of struct ++ * inode_operations. ++ * Creates regular file using file plugin from parent directory plugin set. ++ */ ++int reiser4_create_common(struct inode *parent, struct dentry *dentry, ++ umode_t mode, bool exclusive) ++{ ++ reiser4_object_create_data data; ++ file_plugin *fplug; ++ ++ memset(&data, 0, sizeof data); ++ data.mode = S_IFREG | mode; ++ fplug = child_create_plugin(parent) ? : inode_create_plugin(parent); ++ if (!plugin_of_group(fplug, REISER4_REGULAR_FILE)) { ++ warning("vpf-1900", "'%s' is not a regular file plugin.", ++ fplug->h.label); ++ return RETERR(-EIO); ++ } ++ data.id = fplug->h.id; ++ return create_vfs_object(parent, dentry, &data); ++} ++ ++int reiser4_lookup_name(struct inode *dir, struct dentry *, reiser4_key *); ++void check_light_weight(struct inode *inode, struct inode *parent); ++ ++/** ++ * reiser4_lookup_common - lookup of inode operations ++ * @parent: inode of directory to lookup into ++ * @dentry: name to look for ++ * @flags: ++ * ++ * This is common implementation of vfs's lookup method of struct ++ * inode_operations. ++ */ ++struct dentry *reiser4_lookup_common(struct inode *parent, ++ struct dentry *dentry, ++ unsigned int flags) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct dentry *new; ++ struct inode *inode; ++ reiser4_dir_entry_desc entry; ++ ++ ctx = reiser4_init_context(parent->i_sb); ++ if (IS_ERR(ctx)) ++ return (struct dentry *)ctx; ++ ++ /* set up operations on dentry. */ ++ dentry->d_op = &get_super_private(parent->i_sb)->ops.dentry; ++ ++ result = reiser4_lookup_name(parent, dentry, &entry.key); ++ if (result) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ if (result == -ENOENT) { ++ /* object not found */ ++ if (!IS_DEADDIR(parent)) ++ d_add(dentry, NULL); ++ return NULL; ++ } ++ return ERR_PTR(result); ++ } ++ ++ inode = reiser4_iget(parent->i_sb, &entry.key, FIND_EXACT, 0); ++ if (IS_ERR(inode)) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return ERR_PTR(PTR_ERR(inode)); ++ } ++ ++ /* success */ ++ check_light_weight(inode, parent); ++ new = d_splice_alias(inode, dentry); ++ reiser4_iget_complete(inode); ++ ++ /* prevent balance_dirty_pages() from being called: we don't want to ++ * do this under directory i_mutex. */ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return new; ++} ++ ++static reiser4_block_nr common_estimate_link(struct inode *parent, ++ struct inode *object); ++int reiser4_update_dir(struct inode *); ++ ++static inline void reiser4_check_immutable(struct inode *inode) ++{ ++ do { ++ if (!reiser4_inode_get_flag(inode, REISER4_IMMUTABLE)) ++ break; ++ yield(); ++ } while (1); ++} ++ ++/** ++ * reiser4_link_common - link of inode operations ++ * @existing: dentry of object which is to get new name ++ * @parent: directory where new name is to be created ++ * @newname: new name ++ * ++ * This is common implementation of vfs's link method of struct ++ * inode_operations. ++ */ ++int reiser4_link_common(struct dentry *existing, struct inode *parent, ++ struct dentry *newname) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *object; ++ dir_plugin *parent_dplug; ++ reiser4_dir_entry_desc entry; ++ reiser4_object_create_data data; ++ reiser4_block_nr reserve; ++ ++ ctx = reiser4_init_context(parent->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ assert("nikita-1431", existing != NULL); ++ assert("nikita-1432", parent != NULL); ++ assert("nikita-1433", newname != NULL); ++ ++ object = existing->d_inode; ++ assert("nikita-1434", object != NULL); ++ ++ /* check for race with create_object() */ ++ reiser4_check_immutable(object); ++ ++ parent_dplug = inode_dir_plugin(parent); ++ ++ memset(&entry, 0, sizeof entry); ++ entry.obj = object; ++ ++ data.mode = object->i_mode; ++ data.id = inode_file_plugin(object)->h.id; ++ ++ reserve = common_estimate_link(parent, existing->d_inode); ++ if ((__s64) reserve < 0) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return reserve; ++ } ++ if (reiser4_grab_space(reserve, BA_CAN_COMMIT, get_meta_subvol())) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return RETERR(-ENOSPC); ++ } ++ /* ++ * Subtle race handling: sys_link() doesn't take i_mutex on @parent. It ++ * means that link(2) can race against unlink(2) or rename(2), and ++ * inode is dead (->i_nlink == 0) when reiser4_link() is entered. ++ * ++ * For such inode we have to undo special processing done in ++ * reiser4_unlink() viz. creation of safe-link. ++ */ ++ if (unlikely(object->i_nlink == 0)) { ++ result = safe_link_del(get_meta_subvol(), ++ get_inode_oid(object), SAFE_UNLINK); ++ if (result != 0) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ } ++ ++ /* increment nlink of @existing and update its stat data */ ++ result = reiser4_add_nlink(object, parent, 1); ++ if (result == 0) { ++ /* add entry to the parent */ ++ result = ++ parent_dplug->add_entry(parent, newname, &data, &entry); ++ if (result != 0) { ++ /* failed to add entry to the parent, decrement nlink ++ of @existing */ ++ reiser4_del_nlink(object, parent, 1); ++ /* ++ * now, if that failed, we have a file with too big ++ * nlink---space leak, much better than directory ++ * entry pointing to nowhere ++ */ ++ } ++ } ++ if (result == 0) { ++ atomic_inc(&object->i_count); ++ /* ++ * Upon successful completion, link() shall mark for update ++ * the st_ctime field of the file. Also, the st_ctime and ++ * st_mtime fields of the directory that contains the new ++ * entry shall be marked for update. --SUS ++ */ ++ result = reiser4_update_dir(parent); ++ } ++ if (result == 0) ++ d_instantiate(newname, existing->d_inode); ++ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++static int unlink_check_and_grab(struct inode *parent, struct dentry *victim); ++ ++/** ++ * reiser4_unlink_common - unlink of inode operations ++ * @parent: inode of directory to remove name from ++ * @victim: name to be removed ++ * ++ * This is common implementation of vfs's unlink method of struct ++ * inode_operations. ++ */ ++int reiser4_unlink_common(struct inode *parent, struct dentry *victim) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *object; ++ file_plugin *fplug; ++ ++ ctx = reiser4_init_context(parent->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ object = victim->d_inode; ++ fplug = inode_file_plugin(object); ++ assert("nikita-2882", fplug->detach != NULL); ++ ++ result = unlink_check_and_grab(parent, victim); ++ if (result != 0) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ result = fplug->detach(object, parent); ++ if (result == 0) { ++ dir_plugin *parent_dplug; ++ reiser4_dir_entry_desc entry; ++ ++ parent_dplug = inode_dir_plugin(parent); ++ memset(&entry, 0, sizeof entry); ++ ++ /* first, delete directory entry */ ++ result = parent_dplug->rem_entry(parent, victim, &entry); ++ if (result == 0) { ++ /* ++ * if name was removed successfully, we _have_ to ++ * return 0 from this function, because upper level ++ * caller (vfs_{rmdir,unlink}) expect this. ++ * ++ * now that directory entry is removed, update ++ * stat-data ++ */ ++ reiser4_del_nlink(object, parent, 1); ++ /* ++ * Upon successful completion, unlink() shall mark for ++ * update the st_ctime and st_mtime fields of the ++ * parent directory. Also, if the file's link count is ++ * not 0, the st_ctime field of the file shall be ++ * marked for update. --SUS ++ */ ++ reiser4_update_dir(parent); ++ /* add safe-link for this file */ ++ if (object->i_nlink == 0) ++ safe_link_add(object, SAFE_UNLINK); ++ } ++ } ++ ++ if (unlikely(result != 0)) { ++ if (result != -ENOMEM) ++ warning("nikita-3398", "Cannot unlink %llu (%i)", ++ (unsigned long long)get_inode_oid(object), ++ result); ++ /* if operation failed commit pending inode modifications to ++ * the stat-data */ ++ reiser4_update_sd(object); ++ reiser4_update_sd(parent); ++ } ++ ++ reiser4_release_reserved(object->i_sb); ++ ++ /* @object's i_ctime was updated by ->rem_link() method(). */ ++ ++ /* @victim can be already removed from the disk by this time. Inode is ++ then marked so that iput() wouldn't try to remove stat data. But ++ inode itself is still there. ++ */ ++ ++ /* ++ * we cannot release directory semaphore here, because name has ++ * already been deleted, but dentry (@victim) still exists. Prevent ++ * balance_dirty_pages() from being called on exiting this context: we ++ * don't want to do this under directory i_mutex. ++ */ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/** ++ * reiser4_symlink_common - symlink of inode operations ++ * @parent: inode of parent directory ++ * @dentry: dentry of object to be created ++ * @linkname: string symlink is to contain ++ * ++ * This is common implementation of vfs's symlink method of struct ++ * inode_operations. ++ * Creates object using file plugin SYMLINK_FILE_PLUGIN_ID. ++ */ ++int reiser4_symlink_common(struct inode *parent, struct dentry *dentry, ++ const char *linkname) ++{ ++ reiser4_object_create_data data; ++ ++ memset(&data, 0, sizeof data); ++ data.name = linkname; ++ data.id = SYMLINK_FILE_PLUGIN_ID; ++ data.mode = S_IFLNK | S_IRWXUGO; ++ return create_vfs_object(parent, dentry, &data); ++} ++ ++/** ++ * reiser4_mkdir_common - mkdir of inode operations ++ * @parent: inode of parent directory ++ * @dentry: dentry of object to be created ++ * @mode: the permissions to use ++ * ++ * This is common implementation of vfs's mkdir method of struct ++ * inode_operations. ++ * Creates object using file plugin DIRECTORY_FILE_PLUGIN_ID. ++ */ ++int reiser4_mkdir_common(struct inode *parent, struct dentry *dentry, umode_t mode) ++{ ++ reiser4_object_create_data data; ++ ++ memset(&data, 0, sizeof data); ++ data.mode = S_IFDIR | mode; ++ data.id = DIRECTORY_FILE_PLUGIN_ID; ++ return create_vfs_object(parent, dentry, &data); ++} ++ ++/** ++ * reiser4_mknod_common - mknod of inode operations ++ * @parent: inode of parent directory ++ * @dentry: dentry of object to be created ++ * @mode: the permissions to use and file type ++ * @rdev: minor and major of new device file ++ * ++ * This is common implementation of vfs's mknod method of struct ++ * inode_operations. ++ * Creates object using file plugin SPECIAL_FILE_PLUGIN_ID. ++ */ ++int reiser4_mknod_common(struct inode *parent, struct dentry *dentry, ++ umode_t mode, dev_t rdev) ++{ ++ reiser4_object_create_data data; ++ ++ memset(&data, 0, sizeof data); ++ data.mode = mode; ++ data.rdev = rdev; ++ data.id = SPECIAL_FILE_PLUGIN_ID; ++ return create_vfs_object(parent, dentry, &data); ++} ++ ++/* ++ * implementation of vfs's rename method of struct inode_operations for typical ++ * directory is in inode_ops_rename.c ++ */ ++ ++/** ++ * reiser4_get_link_common: ->get_link() of inode_operations ++ * @dentry: dentry of symlink ++ * ++ * Assumes that inode's i_private points to the content of symbolic link. ++ */ ++const char *reiser4_get_link_common(struct dentry *dentry, ++ struct inode *inode, ++ struct delayed_call *done) ++{ ++ if (!dentry) ++ return ERR_PTR(-ECHILD); ++ ++ assert("vs-851", S_ISLNK(dentry->d_inode->i_mode)); ++ ++ if (!dentry->d_inode->i_private || ++ !reiser4_inode_get_flag(dentry->d_inode, REISER4_GENERIC_PTR_USED)) ++ return ERR_PTR(RETERR(-EINVAL)); ++ ++ return dentry->d_inode->i_private; ++} ++ ++/** ++ * reiser4_permission_common - permission of inode operations ++ * @inode: inode to check permissions for ++ * @mask: mode bits to check permissions for ++ * @flags: ++ * ++ * Uses generic function to check for rwx permissions. ++ */ ++int reiser4_permission_common(struct inode *inode, int mask) ++{ ++ // generic_permission() says that it's rcu-aware... ++#if 0 ++ if (mask & MAY_NOT_BLOCK) ++ return -ECHILD; ++#endif ++ return generic_permission(inode, mask); ++} ++ ++static int setattr_reserve(struct inode *); ++ ++/* this is common implementation of vfs's setattr method of struct ++ inode_operations ++*/ ++int reiser4_setattr_common(struct dentry *dentry, struct iattr *attr) ++{ ++ reiser4_context *ctx; ++ struct inode *inode; ++ int result; ++ ++ inode = dentry->d_inode; ++ result = setattr_prepare(dentry, attr); ++ if (result) ++ return result; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ assert("nikita-3119", !(attr->ia_valid & ATTR_SIZE)); ++ ++ /* ++ * grab disk space and call standard ++ * setattr_copy(); ++ * mark_inode_dirty(). ++ */ ++ result = setattr_reserve(inode); ++ if (!result) { ++ setattr_copy(inode, attr); ++ mark_inode_dirty(inode); ++ result = reiser4_update_sd(inode); ++ } ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/* this is common implementation of vfs's getattr method of struct ++ inode_operations ++*/ ++int reiser4_getattr_common(const struct path *path, struct kstat *stat, ++ u32 request_mask, unsigned int flags) ++{ ++ struct inode *obj; ++ ++ assert("nikita-2298", path != NULL); ++ assert("nikita-2299", stat != NULL); ++ ++ obj = d_inode(path->dentry); ++ ++ stat->dev = obj->i_sb->s_dev; ++ stat->ino = oid_to_uino(get_inode_oid(obj)); ++ stat->mode = obj->i_mode; ++ /* don't confuse userland with huge nlink. This is not entirely ++ * correct, because nlink_t is not necessary 16 bit signed. */ ++ stat->nlink = min(obj->i_nlink, (typeof(obj->i_nlink)) 0x7fff); ++ stat->uid = obj->i_uid; ++ stat->gid = obj->i_gid; ++ stat->rdev = obj->i_rdev; ++ stat->atime = obj->i_atime; ++ stat->mtime = obj->i_mtime; ++ stat->ctime = obj->i_ctime; ++ stat->size = obj->i_size; ++ stat->blocks = ++ (inode_get_bytes(obj) + VFS_BLKSIZE - 1) >> VFS_BLKSIZE_BITS; ++ /* "preferred" blocksize for efficient file system I/O */ ++ stat->blksize = get_super_private(obj->i_sb)->optimal_io_size; ++ ++ return 0; ++} ++ ++/* Estimate the maximum amount of nodes which might be allocated or changed on ++ typical new object creation. Typical creation consists of calling create ++ method of file plugin, adding directory entry to parent and update parent ++ directory's stat data. ++*/ ++static reiser4_block_nr estimate_create_vfs_object(struct inode *parent, ++ /* parent object */ ++ struct inode *object ++ /* object */) ++{ ++ assert("vpf-309", parent != NULL); ++ assert("vpf-307", object != NULL); ++ ++ return ++ /* object creation estimation */ ++ inode_file_plugin(object)->estimate.create(object) + ++ /* stat data of parent directory estimation */ ++ inode_file_plugin(parent)->estimate.update(parent) + ++ /* adding entry estimation */ ++ inode_dir_plugin(parent)->estimate.add_entry(parent) + ++ /* to undo in the case of failure */ ++ inode_dir_plugin(parent)->estimate.rem_entry(parent); ++} ++ ++/** ++ * Create child in a directory. ++ * ++ * . get object's plugin ++ * . get fresh inode ++ * . initialize inode ++ * . add object's stat-data ++ * . initialize object's directory ++ * . add entry to the parent ++ * . instantiate dentry ++ * ++ * @data - parameters of new object ++ */ ++static int do_create_vfs_child(reiser4_object_create_data *data, ++ struct inode **retobj) ++{ ++ int result; ++ ++ struct dentry *dentry; /* parent object */ ++ struct inode *parent; /* new name */ ++ oid_t oid; /* new object id */ ++ ++ dir_plugin *par_dir; /* directory plugin on the parent */ ++ dir_plugin *obj_dir; /* directory plugin on the new object */ ++ file_plugin *obj_plug; /* object plugin on the new object */ ++ struct inode *object; /* new object */ ++ ++ reiser4_dir_entry_desc entry; /* new directory entry */ ++ ++ assert("nikita-1420", data != NULL); ++ parent = data->parent; ++ dentry = data->dentry; ++ ++ assert("nikita-1418", parent != NULL); ++ assert("nikita-1419", dentry != NULL); ++ ++ /* check, that name is acceptable for parent */ ++ par_dir = inode_dir_plugin(parent); ++ if (par_dir->is_name_acceptable && ++ !par_dir->is_name_acceptable(parent, ++ dentry->d_name.name, ++ (int)dentry->d_name.len)) ++ return RETERR(-ENAMETOOLONG); ++ ++ result = 0; ++ obj_plug = file_plugin_by_id((int)data->id); ++ if (obj_plug == NULL) { ++ warning("nikita-430", "Cannot find plugin %i", data->id); ++ return RETERR(-ENOENT); ++ } ++ /* ++ * allocate object id for the new object ++ */ ++ oid = oid_allocate(parent->i_sb); ++ if (oid == ABSOLUTE_MAX_OID) ++ return RETERR(-EOVERFLOW); ++ ++ object = new_inode(parent->i_sb); ++ if (object == NULL) ++ return RETERR(-ENOMEM); ++ /* ++ * new_inode() initializes i_ino to "arbitrary" value. Reset it to 0, ++ * to simplify error handling: if some error occurs before i_ino is ++ * initialized with oid, i_ino should already be set to some ++ * distinguished value ++ */ ++ object->i_ino = 0; ++ ++ /* So that on error iput will be called. */ ++ *retobj = object; ++ ++ memset(&entry, 0, sizeof entry); ++ entry.obj = object; ++ ++ set_plugin(&reiser4_inode_data(object)->pset, PSET_FILE, ++ file_plugin_to_plugin(obj_plug)); ++ ++ result = obj_plug->set_plug_in_inode(object, parent, data); ++ if (result) { ++ warning("nikita-431", "Cannot install plugin %i on %llx", ++ data->id, (unsigned long long)get_inode_oid(object)); ++ return result; ++ } ++ /* ++ * reget plugin after installation ++ */ ++ obj_plug = inode_file_plugin(object); ++ ++ if (obj_plug->create_object == NULL) ++ return RETERR(-EPERM); ++ /* ++ * if any of hash, tail, sd or permission plugins for newly created ++ * object are not set yet set them here inheriting them from parent ++ * directory ++ */ ++ assert("nikita-2070", obj_plug->adjust_to_parent != NULL); ++ result = obj_plug->adjust_to_parent(object, ++ parent, ++ object->i_sb->s_root->d_inode); ++ if (result == 0) ++ result = finish_pset(object); ++ if (result != 0) { ++ warning("nikita-432", "Cannot inherit from %llx to %llx", ++ (unsigned long long)get_inode_oid(parent), ++ (unsigned long long)get_inode_oid(object)); ++ return result; ++ } ++ /* ++ * setup inode and file-operations for this inode ++ */ ++ setup_inode_ops(object, data); ++ /* ++ * call file plugin's method to initialize plugin specific part of ++ * inode ++ */ ++ if (obj_plug->init_inode_data) ++ obj_plug->init_inode_data(object, data, NULL, 1 /*create */); ++ /* ++ * obtain directory plugin (if any) for new object ++ */ ++ obj_dir = inode_dir_plugin(object); ++ if (obj_dir != NULL && obj_dir->init == NULL) ++ return RETERR(-EPERM); ++ reiser4_inode_data(object)->locality_id = get_inode_oid(parent); ++ ++ if (reiser4_grab_space(estimate_create_vfs_object(parent, object), ++ BA_CAN_COMMIT, get_meta_subvol())) ++ return RETERR(-ENOSPC); ++ /* ++ mark inode `immutable'. We disable changes to the file being ++ created until valid directory entry for it is inserted. Otherwise, ++ if file were expanded and insertion of directory entry fails, we ++ have to remove file, but we only alloted enough space in ++ transaction to remove _empty_ file. 3.x code used to remove stat ++ data in different transaction thus possibly leaking disk space on ++ crash. This all only matters if it's possible to access file ++ without name, for example, by inode number ++ */ ++ reiser4_inode_set_flag(object, REISER4_IMMUTABLE); ++ ++ /* create empty object, this includes allocation of new objectid. For ++ directories this implies creation of dot and dotdot */ ++ assert("nikita-2265", reiser4_inode_get_flag(object, REISER4_NO_SD)); ++ ++ /* mark inode as `loaded'. From this point onward ++ reiser4_delete_inode() will try to remove its stat-data. */ ++ reiser4_inode_set_flag(object, REISER4_LOADED); ++ ++ result = obj_plug->create_object(object, parent, data, &oid); ++ if (result != 0) { ++ reiser4_inode_clr_flag(object, REISER4_IMMUTABLE); ++ if (result != -ENAMETOOLONG && result != -ENOMEM) ++ warning("nikita-2219", ++ "Failed to create sd for %llu", ++ (unsigned long long)get_inode_oid(object)); ++ return result; ++ } ++ ++ if (obj_dir != NULL) ++ result = obj_dir->init(object, parent, data); ++ if (result == 0) { ++ assert("nikita-434", !reiser4_inode_get_flag(object, ++ REISER4_NO_SD)); ++ /* insert inode into VFS hash table */ ++ insert_inode_hash(object); ++ /* create entry */ ++ result = par_dir->add_entry(parent, dentry, data, &entry); ++ if (result == 0) { ++ /* If O_CREAT is set and the file did not previously ++ exist, upon successful completion, open() shall ++ mark for update the st_atime, st_ctime, and ++ st_mtime fields of the file and the st_ctime and ++ st_mtime fields of the parent directory. --SUS ++ */ ++ object->i_ctime = current_time(object); ++ reiser4_update_dir(parent); ++ } ++ if (result != 0) ++ /* cleanup failure to add entry */ ++ obj_plug->detach(object, parent); ++ } else if (result != -ENOMEM) ++ warning("nikita-2219", "Failed to initialize dir for %llu: %i", ++ (unsigned long long)get_inode_oid(object), result); ++ ++ /* ++ * update stat-data, committing all pending modifications to the inode ++ * fields. ++ */ ++ reiser4_update_sd(object); ++ if (result != 0) { ++ /* if everything was ok (result == 0), parent stat-data is ++ * already updated above (update_parent_dir()) */ ++ reiser4_update_sd(parent); ++ /* failure to create entry, remove object */ ++ obj_plug->delete_object(object); ++ } ++ ++ /* file has name now, clear immutable flag */ ++ reiser4_inode_clr_flag(object, REISER4_IMMUTABLE); ++ ++ /* on error, iput() will call ->delete_inode(). We should keep track ++ of the existence of stat-data for this inode and avoid attempt to ++ remove it in reiser4_delete_inode(). This is accomplished through ++ REISER4_NO_SD bit in inode.u.reiser4_i.plugin.flags ++ */ ++ return result; ++} ++ ++/* this is helper for common implementations of reiser4_mkdir, reiser4_create, ++ reiser4_mknod and reiser4_symlink ++*/ ++static int ++create_vfs_object(struct inode *parent, ++ struct dentry *dentry, reiser4_object_create_data * data) ++{ ++ reiser4_context *ctx; ++ int result; ++ struct inode *child; ++ ++ ctx = reiser4_init_context(parent->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ context_set_commit_async(ctx); ++ ++ data->parent = parent; ++ data->dentry = dentry; ++ child = NULL; ++ result = do_create_vfs_child(data, &child); ++ if (unlikely(result != 0)) { ++ if (child != NULL) { ++ /* for unlinked inode accounting in iput() */ ++ clear_nlink(child); ++ reiser4_make_bad_inode(child); ++ iput(child); ++ } ++ } else ++ d_instantiate(dentry, child); ++ ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++/** ++ * helper for link_common. Estimate disk space necessary to add a link ++ * from @parent to @object ++ */ ++static reiser4_block_nr common_estimate_link(struct inode *parent /* parent ++ * directory ++ */, ++ struct inode *object /* object to ++ * which new ++ * link is ++ * being ++ * created */) ++{ ++ reiser4_block_nr res = 0; ++ file_plugin *fplug; ++ dir_plugin *dplug; ++ ++ assert("vpf-317", object != NULL); ++ assert("vpf-318", parent != NULL); ++ ++ fplug = inode_file_plugin(object); ++ dplug = inode_dir_plugin(parent); ++ /* VS-FIXME-HANS: why do we do fplug->estimate.update(object) twice ++ * instead of multiplying by 2? */ ++ /* reiser4_add_nlink(object) */ ++ res += fplug->estimate.update(object); ++ /* add_entry(parent) */ ++ res += dplug->estimate.add_entry(parent); ++ /* reiser4_del_nlink(object) */ ++ res += fplug->estimate.update(object); ++ /* update_dir(parent) */ ++ res += inode_file_plugin(parent)->estimate.update(parent); ++ /* safe-link */ ++ res += estimate_one_item_removal(meta_subvol_tree()); ++ ++ return res; ++} ++ ++/* Estimate disk space necessary to remove a link between @parent and ++ @object. ++*/ ++static reiser4_block_nr estimate_unlink(struct inode *parent /* parent ++ * directory */, ++ struct inode *object /* object to which ++ * new link is ++ * being created ++ */) ++{ ++ reiser4_block_nr res = 0; ++ file_plugin *fplug; ++ dir_plugin *dplug; ++ ++ assert("vpf-317", object != NULL); ++ assert("vpf-318", parent != NULL); ++ ++ fplug = inode_file_plugin(object); ++ dplug = inode_dir_plugin(parent); ++ ++ /* rem_entry(parent) */ ++ res += dplug->estimate.rem_entry(parent); ++ /* reiser4_del_nlink(object) */ ++ res += fplug->estimate.update(object); ++ /* update_dir(parent) */ ++ res += inode_file_plugin(parent)->estimate.update(parent); ++ /* fplug->unlink */ ++ res += fplug->estimate.unlink(object, parent); ++ /* safe-link */ ++ res += estimate_one_insert_item(meta_subvol_tree()); ++ ++ return res; ++} ++ ++/** ++ * helper for reiser4_unlink_common. Estimate and grab space for unlink ++ */ ++static int unlink_check_and_grab(struct inode *parent, struct dentry *victim) ++{ ++ file_plugin *fplug; ++ struct inode *child; ++ int result; ++ ++ result = 0; ++ child = victim->d_inode; ++ fplug = inode_file_plugin(child); ++ ++ /* check for race with create_object() */ ++ reiser4_check_immutable(child); ++ ++ /* object being deleted should have stat data */ ++ assert("vs-949", !reiser4_inode_get_flag(child, REISER4_NO_SD)); ++ ++ /* ask object plugin */ ++ if (fplug->can_rem_link != NULL && !fplug->can_rem_link(child)) ++ return RETERR(-ENOTEMPTY); ++ ++ result = (int)estimate_unlink(parent, child); ++ if (result < 0) ++ return result; ++ ++ return reiser4_grab_reserved(child->i_sb, result, ++ BA_CAN_COMMIT, get_meta_subvol()); ++} ++ ++/** ++ * Helper for reiser4_setattr_common; ++ * Reserve space for stat-data update ++ */ ++static int setattr_reserve(struct inode *inode) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ assert("edward-1793", subv != NULL); ++ assert("vs-1096", is_grab_enabled(get_current_context())); ++ ++ return reiser4_grab_space(estimate_one_insert_into_item(&subv->tree), ++ BA_CAN_COMMIT, subv); ++} ++ ++/* helper function. Standards require that for many file-system operations ++ on success ctime and mtime of parent directory is to be updated. */ ++int reiser4_update_dir(struct inode *dir) ++{ ++ assert("nikita-2525", dir != NULL); ++ ++ dir->i_ctime = dir->i_mtime = current_time(dir); ++ return reiser4_update_sd(dir); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/inode_ops_rename.c linux-5.10.2/fs/reiser4/plugin/inode_ops_rename.c +--- linux-5.10.2.orig/fs/reiser4/plugin/inode_ops_rename.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/inode_ops_rename.c 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,957 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "../inode.h" ++#include "../safe_link.h" ++ ++static const char *possible_leak = "Possible disk space leak."; ++ ++/* re-bind existing name at @from_coord in @from_dir to point to @to_inode. ++ ++ Helper function called from hashed_rename() */ ++static int replace_name(struct inode *to_inode, /* inode where @from_coord is ++ * to be re-targeted at */ ++ struct inode *from_dir, /* directory where @from_coord ++ * lives */ ++ struct inode *from_inode, /* inode @from_coord ++ * originally point to */ ++ coord_t *from_coord, /* where directory entry is in ++ * the tree */ ++ lock_handle * from_lh/* lock handle on @from_coord */) ++{ ++ item_plugin *from_item; ++ int result; ++ znode *node; ++ ++ coord_clear_iplug(from_coord); ++ node = from_coord->node; ++ result = zload(node); ++ if (result != 0) ++ return result; ++ from_item = item_plugin_by_coord(from_coord); ++ if (plugin_of_group(item_plugin_by_coord(from_coord), ++ DIR_ENTRY_ITEM_TYPE)) { ++ reiser4_key to_key; ++ ++ build_sd_key(to_inode, &to_key); ++ ++ /* everything is found and prepared to change directory entry ++ at @from_coord to point to @to_inode. ++ ++ @to_inode is just about to get new name, so bump its link ++ counter. ++ ++ */ ++ result = reiser4_add_nlink(to_inode, from_dir, 0); ++ if (result != 0) { ++ /* Don't issue warning: this may be plain -EMLINK */ ++ zrelse(node); ++ return result; ++ } ++ ++ result = ++ from_item->s.dir.update_key(from_coord, &to_key, from_lh); ++ if (result != 0) { ++ reiser4_del_nlink(to_inode, from_dir, 0); ++ zrelse(node); ++ return result; ++ } ++ ++ /* @from_inode just lost its name, he-he. ++ ++ If @from_inode was directory, it contained dotdot pointing ++ to @from_dir. @from_dir i_nlink will be decreased when ++ iput() will be called on @from_inode. ++ ++ If file-system is not ADG (hard-links are ++ supported on directories), iput(from_inode) will not remove ++ @from_inode, and thus above is incorrect, but hard-links on ++ directories are problematic in many other respects. ++ */ ++ result = reiser4_del_nlink(from_inode, from_dir, 0); ++ if (result != 0) { ++ warning("nikita-2330", ++ "Cannot remove link from source: %i. %s", ++ result, possible_leak); ++ } ++ /* Has to return success, because entry is already ++ * modified. */ ++ result = 0; ++ ++ /* NOTE-NIKITA consider calling plugin method in stead of ++ accessing inode fields directly. */ ++ from_dir->i_mtime = current_time(from_dir); ++ } else { ++ warning("nikita-2326", "Unexpected item type"); ++ result = RETERR(-EIO); ++ } ++ zrelse(node); ++ return result; ++} ++ ++/* add new entry pointing to @inode into @dir at @coord, locked by @lh ++ ++ Helper function used by hashed_rename(). */ ++static int add_name(struct inode *inode, /* inode where @coord is to be ++ * re-targeted at */ ++ struct inode *dir, /* directory where @coord lives */ ++ struct dentry *name, /* new name */ ++ coord_t *coord, /* where directory entry is in the tree ++ */ ++ lock_handle * lh, /* lock handle on @coord */ ++ int is_dir/* true, if @inode is directory */) ++{ ++ int result; ++ reiser4_dir_entry_desc entry; ++ ++ assert("nikita-2333", lh->node == coord->node); ++ assert("nikita-2334", is_dir == S_ISDIR(inode->i_mode)); ++ ++ memset(&entry, 0, sizeof entry); ++ entry.obj = inode; ++ /* build key of directory entry description */ ++ inode_dir_plugin(dir)->build_entry_key(dir, &name->d_name, &entry.key); ++ ++ /* ext2 does this in different order: first inserts new entry, ++ then increases directory nlink. We don't want do this, ++ because reiser4_add_nlink() calls ->add_link() plugin ++ method that can fail for whatever reason, leaving as with ++ cleanup problems. ++ */ ++ /* @inode is getting new name */ ++ reiser4_add_nlink(inode, dir, 0); ++ /* create @new_name in @new_dir pointing to ++ @old_inode */ ++ result = WITH_COORD(coord, ++ inode_dir_item_plugin(dir)->s.dir.add_entry(dir, ++ coord, ++ lh, ++ name, ++ &entry)); ++ if (result != 0) { ++ int result2; ++ result2 = reiser4_del_nlink(inode, dir, 0); ++ if (result2 != 0) { ++ warning("nikita-2327", ++ "Cannot drop link on %lli %i. %s", ++ (unsigned long long)get_inode_oid(inode), ++ result2, possible_leak); ++ } ++ } else ++ INODE_INC_FIELD(dir, i_size); ++ return result; ++} ++ ++static reiser4_block_nr estimate_rename(struct inode *old_dir, /* directory ++ * where @old is ++ * located */ ++ struct dentry *old_name,/* old name */ ++ struct inode *new_dir, /* directory ++ * where @new is ++ * located */ ++ struct dentry *new_name /* new name */) ++{ ++ reiser4_block_nr res1, res2; ++ dir_plugin * p_parent_old, *p_parent_new; ++ file_plugin * p_child_old, *p_child_new; ++ ++ assert("vpf-311", old_dir != NULL); ++ assert("vpf-312", new_dir != NULL); ++ assert("vpf-313", old_name != NULL); ++ assert("vpf-314", new_name != NULL); ++ ++ p_parent_old = inode_dir_plugin(old_dir); ++ p_parent_new = inode_dir_plugin(new_dir); ++ p_child_old = inode_file_plugin(old_name->d_inode); ++ if (new_name->d_inode) ++ p_child_new = inode_file_plugin(new_name->d_inode); ++ else ++ p_child_new = NULL; ++ ++ /* find_entry - can insert one leaf. */ ++ res1 = res2 = 1; ++ ++ /* replace_name */ ++ { ++ /* reiser4_add_nlink(p_child_old) and ++ * reiser4_del_nlink(p_child_old) */ ++ res1 += 2 * p_child_old->estimate.update(old_name->d_inode); ++ /* update key */ ++ res1 += 1; ++ /* reiser4_del_nlink(p_child_new) */ ++ if (p_child_new) ++ res1 += p_child_new->estimate.update(new_name->d_inode); ++ } ++ ++ /* else add_name */ ++ { ++ /* reiser4_add_nlink(p_parent_new) and ++ * reiser4_del_nlink(p_parent_new) */ ++ res2 += ++ 2 * inode_file_plugin(new_dir)->estimate.update(new_dir); ++ /* reiser4_add_nlink(p_parent_old) */ ++ res2 += p_child_old->estimate.update(old_name->d_inode); ++ /* add_entry(p_parent_new) */ ++ res2 += p_parent_new->estimate.add_entry(new_dir); ++ /* reiser4_del_nlink(p_parent_old) */ ++ res2 += p_child_old->estimate.update(old_name->d_inode); ++ } ++ ++ res1 = res1 < res2 ? res2 : res1; ++ ++ /* reiser4_write_sd(p_parent_new) */ ++ res1 += inode_file_plugin(new_dir)->estimate.update(new_dir); ++ ++ /* reiser4_write_sd(p_child_new) */ ++ if (p_child_new) ++ res1 += p_child_new->estimate.update(new_name->d_inode); ++ ++ /* hashed_rem_entry(p_parent_old) */ ++ res1 += p_parent_old->estimate.rem_entry(old_dir); ++ ++ /* reiser4_del_nlink(p_child_old) */ ++ res1 += p_child_old->estimate.update(old_name->d_inode); ++ ++ /* replace_name */ ++ { ++ /* reiser4_add_nlink(p_parent_dir_new) */ ++ res1 += inode_file_plugin(new_dir)->estimate.update(new_dir); ++ /* update_key */ ++ res1 += 1; ++ /* reiser4_del_nlink(p_parent_new) */ ++ res1 += inode_file_plugin(new_dir)->estimate.update(new_dir); ++ /* reiser4_del_nlink(p_parent_old) */ ++ res1 += inode_file_plugin(old_dir)->estimate.update(old_dir); ++ } ++ ++ /* reiser4_write_sd(p_parent_old) */ ++ res1 += inode_file_plugin(old_dir)->estimate.update(old_dir); ++ ++ /* reiser4_write_sd(p_child_old) */ ++ res1 += p_child_old->estimate.update(old_name->d_inode); ++ ++ return res1; ++} ++ ++static int hashed_rename_estimate_and_grab(struct inode *old_dir, /* directory ++ * where @old ++ * is located ++ */ ++ struct dentry *old_name,/* old name ++ */ ++ struct inode *new_dir, /* directory ++ * where @new ++ * is located ++ */ ++ struct dentry *new_name /* new name ++ */) ++{ ++ reiser4_block_nr reserve; ++ ++ reserve = estimate_rename(old_dir, old_name, new_dir, new_name); ++ ++ if (reiser4_grab_space(reserve, BA_CAN_COMMIT, get_meta_subvol())) ++ return RETERR(-ENOSPC); ++ return 0; ++} ++ ++/* check whether @old_inode and @new_inode can be moved within file system ++ * tree. This singles out attempts to rename pseudo-files, for example. */ ++static int can_rename(struct inode *old_dir, struct inode *old_inode, ++ struct inode *new_dir, struct inode *new_inode) ++{ ++ file_plugin *fplug; ++ dir_plugin *dplug; ++ ++ assert("nikita-3370", old_inode != NULL); ++ ++ dplug = inode_dir_plugin(new_dir); ++ fplug = inode_file_plugin(old_inode); ++ ++ if (dplug == NULL) ++ return RETERR(-ENOTDIR); ++ else if (new_dir->i_op->create == NULL) ++ return RETERR(-EPERM); ++ else if (!fplug->can_add_link(old_inode)) ++ return RETERR(-EMLINK); ++ else if (new_inode != NULL) { ++ fplug = inode_file_plugin(new_inode); ++ if (fplug->can_rem_link != NULL && ++ !fplug->can_rem_link(new_inode)) ++ return RETERR(-EBUSY); ++ } ++ return 0; ++} ++ ++int reiser4_find_entry(struct inode *, struct dentry *, lock_handle * , ++ znode_lock_mode, reiser4_dir_entry_desc *); ++int reiser4_update_dir(struct inode *); ++ ++/* this is common implementation of vfs's rename2 method of struct ++ inode_operations ++ See comments in the body. ++ ++ It is arguable that this function can be made generic so, that it ++ will be applicable to any kind of directory plugin that deals with ++ directories composed out of directory entries. The only obstacle ++ here is that we don't have any data-type to represent directory ++ entry. This should be re-considered when more than one different ++ directory plugin will be implemented. ++*/ ++int reiser4_rename2_common(struct inode *old_dir /* directory where @old ++ * is located */ , ++ struct dentry *old_name /* old name */ , ++ struct inode *new_dir /* directory where @new ++ * is located */ , ++ struct dentry *new_name /* new name */ , ++ unsigned flags /* specific flags */) ++{ ++ /* From `The Open Group Base Specifications Issue 6' ++ ++ If either the old or new argument names a symbolic link, rename() ++ shall operate on the symbolic link itself, and shall not resolve ++ the last component of the argument. If the old argument and the new ++ argument resolve to the same existing file, rename() shall return ++ successfully and perform no other action. ++ ++ [this is done by VFS: vfs_rename()] ++ ++ If the old argument points to the pathname of a file that is not a ++ directory, the new argument shall not point to the pathname of a ++ directory. ++ ++ [checked by VFS: vfs_rename->may_delete()] ++ ++ If the link named by the new argument exists, it shall ++ be removed and old renamed to new. In this case, a link named new ++ shall remain visible to other processes throughout the renaming ++ operation and refer either to the file referred to by new or old ++ before the operation began. ++ ++ [we should assure this] ++ ++ Write access permission is required for ++ both the directory containing old and the directory containing new. ++ ++ [checked by VFS: vfs_rename->may_delete(), may_create()] ++ ++ If the old argument points to the pathname of a directory, the new ++ argument shall not point to the pathname of a file that is not a ++ directory. ++ ++ [checked by VFS: vfs_rename->may_delete()] ++ ++ If the directory named by the new argument exists, it ++ shall be removed and old renamed to new. In this case, a link named ++ new shall exist throughout the renaming operation and shall refer ++ either to the directory referred to by new or old before the ++ operation began. ++ ++ [we should assure this] ++ ++ If new names an existing directory, it shall be ++ required to be an empty directory. ++ ++ [we should check this] ++ ++ If the old argument points to a pathname of a symbolic link, the ++ symbolic link shall be renamed. If the new argument points to a ++ pathname of a symbolic link, the symbolic link shall be removed. ++ ++ The new pathname shall not contain a path prefix that names ++ old. Write access permission is required for the directory ++ containing old and the directory containing new. If the old ++ argument points to the pathname of a directory, write access ++ permission may be required for the directory named by old, and, if ++ it exists, the directory named by new. ++ ++ [checked by VFS: vfs_rename(), vfs_rename_dir()] ++ ++ If the link named by the new argument exists and the file's link ++ count becomes 0 when it is removed and no process has the file ++ open, the space occupied by the file shall be freed and the file ++ shall no longer be accessible. If one or more processes have the ++ file open when the last link is removed, the link shall be removed ++ before rename() returns, but the removal of the file contents shall ++ be postponed until all references to the file are closed. ++ ++ [iput() handles this, but we can do this manually, a la ++ reiser4_unlink()] ++ ++ Upon successful completion, rename() shall mark for update the ++ st_ctime and st_mtime fields of the parent directory of each file. ++ ++ [N/A] ++ ++ */ ++ ++ /* From Documentation/filesystems/vfs.txt: ++ ++ rename2: this has an additional flags argument compared to rename. ++ f no flags are supported by the filesystem then this method ++ need not be implemented. If some flags are supported then the ++ filesystem must return -EINVAL for any unsupported or unknown ++ flags. Currently the following flags are implemented: ++ (1) RENAME_NOREPLACE: this flag indicates that if the target ++ of the rename exists the rename should fail with -EEXIST ++ instead of replacing the target. The VFS already checks for ++ existence, so for local filesystems the RENAME_NOREPLACE ++ implementation is equivalent to plain rename. ++ (2) RENAME_EXCHANGE: exchange source and target. Both must ++ exist; this is checked by the VFS. Unlike plain rename, ++ source and target may be of different type. ++ */ ++ ++ static const unsigned supported_flags = RENAME_NOREPLACE; ++ ++ reiser4_context *ctx; ++ int result; ++ int is_dir; /* is @old_name directory */ ++ ++ struct inode *old_inode; ++ struct inode *new_inode; ++ coord_t *new_coord; ++ ++ struct reiser4_dentry_fsdata *new_fsdata; ++ dir_plugin *dplug; ++ file_plugin *fplug; ++ ++ reiser4_dir_entry_desc *old_entry, *new_entry, *dotdot_entry; ++ lock_handle * new_lh, *dotdot_lh; ++ struct dentry *dotdot_name; ++ struct reiser4_dentry_fsdata *dataonstack; ++ ++ ctx = reiser4_init_context(old_dir->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ /* ++ * Check rename2() flags. ++ * ++ * "If some flags are supported then the filesystem must return ++ * -EINVAL for any unsupported or unknown flags." ++ * ++ * We support: ++ * - RENAME_NOREPLACE (no-op) ++ */ ++ if ((flags & supported_flags) != flags) ++ return RETERR(-EINVAL); ++ ++ old_entry = kzalloc(3 * sizeof(*old_entry) + 2 * sizeof(*new_lh) + ++ sizeof(*dotdot_name) + sizeof(*dataonstack), ++ reiser4_ctx_gfp_mask_get()); ++ if (!old_entry) { ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return RETERR(-ENOMEM); ++ } ++ ++ new_entry = old_entry + 1; ++ dotdot_entry = old_entry + 2; ++ new_lh = (lock_handle *)(old_entry + 3); ++ dotdot_lh = new_lh + 1; ++ dotdot_name = (struct dentry *)(new_lh + 2); ++ dataonstack = (struct reiser4_dentry_fsdata *)(dotdot_name + 1); ++ ++ assert("nikita-2318", old_dir != NULL); ++ assert("nikita-2319", new_dir != NULL); ++ assert("nikita-2320", old_name != NULL); ++ assert("nikita-2321", new_name != NULL); ++ ++ old_inode = old_name->d_inode; ++ new_inode = new_name->d_inode; ++ ++ dplug = inode_dir_plugin(old_dir); ++ fplug = NULL; ++ ++ new_fsdata = reiser4_get_dentry_fsdata(new_name); ++ if (IS_ERR(new_fsdata)) { ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return PTR_ERR(new_fsdata); ++ } ++ ++ new_coord = &new_fsdata->dec.entry_coord; ++ coord_clear_iplug(new_coord); ++ ++ is_dir = S_ISDIR(old_inode->i_mode); ++ ++ assert("nikita-3461", old_inode->i_nlink >= 1 + !!is_dir); ++ ++ /* if target is existing directory and it's not empty---return error. ++ ++ This check is done specifically, because is_dir_empty() requires ++ tree traversal and have to be done before locks are taken. ++ */ ++ if (is_dir && new_inode != NULL && is_dir_empty(new_inode) != 0) { ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return RETERR(-ENOTEMPTY); ++ } ++ ++ result = can_rename(old_dir, old_inode, new_dir, new_inode); ++ if (result != 0) { ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ result = hashed_rename_estimate_and_grab(old_dir, old_name, ++ new_dir, new_name); ++ if (result != 0) { ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ init_lh(new_lh); ++ ++ /* find entry for @new_name */ ++ result = reiser4_find_entry(new_dir, new_name, new_lh, ZNODE_WRITE_LOCK, ++ new_entry); ++ ++ if (IS_CBKERR(result)) { ++ done_lh(new_lh); ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++ } ++ ++ reiser4_seal_done(&new_fsdata->dec.entry_seal); ++ ++ /* add or replace name for @old_inode as @new_name */ ++ if (new_inode != NULL) { ++ /* target (@new_name) exists. */ ++ /* Not clear what to do with objects that are ++ both directories and files at the same time. */ ++ if (result == CBK_COORD_FOUND) { ++ result = replace_name(old_inode, ++ new_dir, ++ new_inode, new_coord, new_lh); ++ if (result == 0) ++ fplug = inode_file_plugin(new_inode); ++ } else if (result == CBK_COORD_NOTFOUND) { ++ /* VFS told us that @new_name is bound to existing ++ inode, but we failed to find directory entry. */ ++ warning("nikita-2324", "Target not found"); ++ result = RETERR(-ENOENT); ++ } ++ } else { ++ /* target (@new_name) doesn't exists. */ ++ if (result == CBK_COORD_NOTFOUND) ++ result = add_name(old_inode, ++ new_dir, ++ new_name, new_coord, new_lh, is_dir); ++ else if (result == CBK_COORD_FOUND) { ++ /* VFS told us that @new_name is "negative" dentry, ++ but we found directory entry. */ ++ warning("nikita-2331", "Target found unexpectedly"); ++ result = RETERR(-EIO); ++ } ++ } ++ ++ assert("nikita-3462", ergo(result == 0, ++ old_inode->i_nlink >= 2 + !!is_dir)); ++ ++ /* We are done with all modifications to the @new_dir, release lock on ++ node. */ ++ done_lh(new_lh); ++ ++ if (fplug != NULL) { ++ /* detach @new_inode from name-space */ ++ result = fplug->detach(new_inode, new_dir); ++ if (result != 0) ++ warning("nikita-2330", "Cannot detach %lli: %i. %s", ++ (unsigned long long)get_inode_oid(new_inode), ++ result, possible_leak); ++ } ++ ++ if (new_inode != NULL) ++ reiser4_update_sd(new_inode); ++ ++ if (result == 0) { ++ old_entry->obj = old_inode; ++ ++ dplug->build_entry_key(old_dir, ++ &old_name->d_name, &old_entry->key); ++ ++ /* At this stage new name was introduced for ++ @old_inode. @old_inode, @new_dir, and @new_inode i_nlink ++ counters were updated. ++ ++ We want to remove @old_name now. If @old_inode wasn't ++ directory this is simple. ++ */ ++ result = dplug->rem_entry(old_dir, old_name, old_entry); ++ if (result != 0 && result != -ENOMEM) { ++ warning("nikita-2335", ++ "Cannot remove old name: %i", result); ++ } else { ++ result = reiser4_del_nlink(old_inode, old_dir, 0); ++ if (result != 0 && result != -ENOMEM) { ++ warning("nikita-2337", ++ "Cannot drop link on old: %i", result); ++ } ++ } ++ ++ if (result == 0 && is_dir) { ++ /* @old_inode is directory. We also have to update ++ dotdot entry. */ ++ coord_t *dotdot_coord; ++ ++ memset(dataonstack, 0, sizeof(*dataonstack)); ++ memset(dotdot_entry, 0, sizeof(*dotdot_entry)); ++ dotdot_entry->obj = old_dir; ++ memset(dotdot_name, 0, sizeof(*dotdot_name)); ++ dotdot_name->d_name.name = ".."; ++ dotdot_name->d_name.len = 2; ++ /* ++ * allocate ->d_fsdata on the stack to avoid using ++ * reiser4_get_dentry_fsdata(). Locking is not needed, ++ * because dentry is private to the current thread. ++ */ ++ dotdot_name->d_fsdata = dataonstack; ++ init_lh(dotdot_lh); ++ ++ dotdot_coord = &dataonstack->dec.entry_coord; ++ coord_clear_iplug(dotdot_coord); ++ ++ result = reiser4_find_entry(old_inode, dotdot_name, ++ dotdot_lh, ZNODE_WRITE_LOCK, ++ dotdot_entry); ++ if (result == 0) { ++ /* replace_name() decreases i_nlink on ++ * @old_dir */ ++ result = replace_name(new_dir, ++ old_inode, ++ old_dir, ++ dotdot_coord, dotdot_lh); ++ } else ++ result = RETERR(-EIO); ++ done_lh(dotdot_lh); ++ } ++ } ++ reiser4_update_dir(new_dir); ++ reiser4_update_dir(old_dir); ++ reiser4_update_sd(old_inode); ++ if (result == 0) { ++ file_plugin *fplug; ++ ++ if (new_inode != NULL) { ++ /* add safe-link for target file (in case we removed ++ * last reference to the poor fellow */ ++ fplug = inode_file_plugin(new_inode); ++ if (new_inode->i_nlink == 0) ++ result = safe_link_add(new_inode, SAFE_UNLINK); ++ } ++ } ++ kfree(old_entry); ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++ ++#if 0 ++int reiser4_rename_common(struct inode *old_dir /* directory where @old ++ * is located */ , ++ struct dentry *old_name /* old name */ , ++ struct inode *new_dir /* directory where @new ++ * is located */ , ++ struct dentry *new_name/* new name */) ++{ ++ /* From `The Open Group Base Specifications Issue 6' ++ ++ If either the old or new argument names a symbolic link, rename() ++ shall operate on the symbolic link itself, and shall not resolve ++ the last component of the argument. If the old argument and the new ++ argument resolve to the same existing file, rename() shall return ++ successfully and perform no other action. ++ ++ [this is done by VFS: vfs_rename()] ++ ++ If the old argument points to the pathname of a file that is not a ++ directory, the new argument shall not point to the pathname of a ++ directory. ++ ++ [checked by VFS: vfs_rename->may_delete()] ++ ++ If the link named by the new argument exists, it shall ++ be removed and old renamed to new. In this case, a link named new ++ shall remain visible to other processes throughout the renaming ++ operation and refer either to the file referred to by new or old ++ before the operation began. ++ ++ [we should assure this] ++ ++ Write access permission is required for ++ both the directory containing old and the directory containing new. ++ ++ [checked by VFS: vfs_rename->may_delete(), may_create()] ++ ++ If the old argument points to the pathname of a directory, the new ++ argument shall not point to the pathname of a file that is not a ++ directory. ++ ++ [checked by VFS: vfs_rename->may_delete()] ++ ++ If the directory named by the new argument exists, it ++ shall be removed and old renamed to new. In this case, a link named ++ new shall exist throughout the renaming operation and shall refer ++ either to the directory referred to by new or old before the ++ operation began. ++ ++ [we should assure this] ++ ++ If new names an existing directory, it shall be ++ required to be an empty directory. ++ ++ [we should check this] ++ ++ If the old argument points to a pathname of a symbolic link, the ++ symbolic link shall be renamed. If the new argument points to a ++ pathname of a symbolic link, the symbolic link shall be removed. ++ ++ The new pathname shall not contain a path prefix that names ++ old. Write access permission is required for the directory ++ containing old and the directory containing new. If the old ++ argument points to the pathname of a directory, write access ++ permission may be required for the directory named by old, and, if ++ it exists, the directory named by new. ++ ++ [checked by VFS: vfs_rename(), vfs_rename_dir()] ++ ++ If the link named by the new argument exists and the file's link ++ count becomes 0 when it is removed and no process has the file ++ open, the space occupied by the file shall be freed and the file ++ shall no longer be accessible. If one or more processes have the ++ file open when the last link is removed, the link shall be removed ++ before rename() returns, but the removal of the file contents shall ++ be postponed until all references to the file are closed. ++ ++ [iput() handles this, but we can do this manually, a la ++ reiser4_unlink()] ++ ++ Upon successful completion, rename() shall mark for update the ++ st_ctime and st_mtime fields of the parent directory of each file. ++ ++ [N/A] ++ ++ */ ++ reiser4_context *ctx; ++ int result; ++ int is_dir; /* is @old_name directory */ ++ struct inode *old_inode; ++ struct inode *new_inode; ++ reiser4_dir_entry_desc old_entry; ++ reiser4_dir_entry_desc new_entry; ++ coord_t *new_coord; ++ struct reiser4_dentry_fsdata *new_fsdata; ++ lock_handle new_lh; ++ dir_plugin *dplug; ++ file_plugin *fplug; ++ ++ ctx = reiser4_init_context(old_dir->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ assert("nikita-2318", old_dir != NULL); ++ assert("nikita-2319", new_dir != NULL); ++ assert("nikita-2320", old_name != NULL); ++ assert("nikita-2321", new_name != NULL); ++ ++ old_inode = old_name->d_inode; ++ new_inode = new_name->d_inode; ++ ++ dplug = inode_dir_plugin(old_dir); ++ fplug = NULL; ++ ++ new_fsdata = reiser4_get_dentry_fsdata(new_name); ++ if (IS_ERR(new_fsdata)) { ++ result = PTR_ERR(new_fsdata); ++ goto exit; ++ } ++ ++ new_coord = &new_fsdata->dec.entry_coord; ++ coord_clear_iplug(new_coord); ++ ++ is_dir = S_ISDIR(old_inode->i_mode); ++ ++ assert("nikita-3461", old_inode->i_nlink >= 1 + !!is_dir); ++ ++ /* if target is existing directory and it's not empty---return error. ++ ++ This check is done specifically, because is_dir_empty() requires ++ tree traversal and have to be done before locks are taken. ++ */ ++ if (is_dir && new_inode != NULL && is_dir_empty(new_inode) != 0) ++ return RETERR(-ENOTEMPTY); ++ ++ result = can_rename(old_dir, old_inode, new_dir, new_inode); ++ if (result != 0) ++ goto exit; ++ ++ result = hashed_rename_estimate_and_grab(old_dir, old_name, ++ new_dir, new_name); ++ if (result != 0) ++ goto exit; ++ ++ init_lh(&new_lh); ++ ++ /* find entry for @new_name */ ++ result = reiser4_find_entry(new_dir, new_name, &new_lh, ++ ZNODE_WRITE_LOCK, &new_entry); ++ ++ if (IS_CBKERR(result)) { ++ done_lh(&new_lh); ++ goto exit; ++ } ++ ++ reiser4_seal_done(&new_fsdata->dec.entry_seal); ++ ++ /* add or replace name for @old_inode as @new_name */ ++ if (new_inode != NULL) { ++ /* target (@new_name) exists. */ ++ /* Not clear what to do with objects that are ++ both directories and files at the same time. */ ++ if (result == CBK_COORD_FOUND) { ++ result = replace_name(old_inode, ++ new_dir, ++ new_inode, new_coord, &new_lh); ++ if (result == 0) ++ fplug = inode_file_plugin(new_inode); ++ } else if (result == CBK_COORD_NOTFOUND) { ++ /* VFS told us that @new_name is bound to existing ++ inode, but we failed to find directory entry. */ ++ warning("nikita-2324", "Target not found"); ++ result = RETERR(-ENOENT); ++ } ++ } else { ++ /* target (@new_name) doesn't exists. */ ++ if (result == CBK_COORD_NOTFOUND) ++ result = add_name(old_inode, ++ new_dir, ++ new_name, new_coord, &new_lh, is_dir); ++ else if (result == CBK_COORD_FOUND) { ++ /* VFS told us that @new_name is "negative" dentry, ++ but we found directory entry. */ ++ warning("nikita-2331", "Target found unexpectedly"); ++ result = RETERR(-EIO); ++ } ++ } ++ ++ assert("nikita-3462", ergo(result == 0, ++ old_inode->i_nlink >= 2 + !!is_dir)); ++ ++ /* We are done with all modifications to the @new_dir, release lock on ++ node. */ ++ done_lh(&new_lh); ++ ++ if (fplug != NULL) { ++ /* detach @new_inode from name-space */ ++ result = fplug->detach(new_inode, new_dir); ++ if (result != 0) ++ warning("nikita-2330", "Cannot detach %lli: %i. %s", ++ (unsigned long long)get_inode_oid(new_inode), ++ result, possible_leak); ++ } ++ ++ if (new_inode != NULL) ++ reiser4_update_sd(new_inode); ++ ++ if (result == 0) { ++ memset(&old_entry, 0, sizeof old_entry); ++ old_entry.obj = old_inode; ++ ++ dplug->build_entry_key(old_dir, ++ &old_name->d_name, &old_entry.key); ++ ++ /* At this stage new name was introduced for ++ @old_inode. @old_inode, @new_dir, and @new_inode i_nlink ++ counters were updated. ++ ++ We want to remove @old_name now. If @old_inode wasn't ++ directory this is simple. ++ */ ++ result = dplug->rem_entry(old_dir, old_name, &old_entry); ++ /*result = rem_entry_hashed(old_dir, old_name, &old_entry); */ ++ if (result != 0 && result != -ENOMEM) { ++ warning("nikita-2335", ++ "Cannot remove old name: %i", result); ++ } else { ++ result = reiser4_del_nlink(old_inode, old_dir, 0); ++ if (result != 0 && result != -ENOMEM) { ++ warning("nikita-2337", ++ "Cannot drop link on old: %i", result); ++ } ++ } ++ ++ if (result == 0 && is_dir) { ++ /* @old_inode is directory. We also have to update ++ dotdot entry. */ ++ coord_t *dotdot_coord; ++ lock_handle dotdot_lh; ++ struct dentry dotdot_name; ++ reiser4_dir_entry_desc dotdot_entry; ++ struct reiser4_dentry_fsdata dataonstack; ++ struct reiser4_dentry_fsdata *fsdata; ++ ++ memset(&dataonstack, 0, sizeof dataonstack); ++ memset(&dotdot_entry, 0, sizeof dotdot_entry); ++ dotdot_entry.obj = old_dir; ++ memset(&dotdot_name, 0, sizeof dotdot_name); ++ dotdot_name.d_name.name = ".."; ++ dotdot_name.d_name.len = 2; ++ /* ++ * allocate ->d_fsdata on the stack to avoid using ++ * reiser4_get_dentry_fsdata(). Locking is not needed, ++ * because dentry is private to the current thread. ++ */ ++ dotdot_name.d_fsdata = &dataonstack; ++ init_lh(&dotdot_lh); ++ ++ fsdata = &dataonstack; ++ dotdot_coord = &fsdata->dec.entry_coord; ++ coord_clear_iplug(dotdot_coord); ++ ++ result = reiser4_find_entry(old_inode, ++ &dotdot_name, ++ &dotdot_lh, ++ ZNODE_WRITE_LOCK, ++ &dotdot_entry); ++ if (result == 0) { ++ /* replace_name() decreases i_nlink on ++ * @old_dir */ ++ result = replace_name(new_dir, ++ old_inode, ++ old_dir, ++ dotdot_coord, &dotdot_lh); ++ } else ++ result = RETERR(-EIO); ++ done_lh(&dotdot_lh); ++ } ++ } ++ reiser4_update_dir(new_dir); ++ reiser4_update_dir(old_dir); ++ reiser4_update_sd(old_inode); ++ if (result == 0) { ++ file_plugin *fplug; ++ ++ if (new_inode != NULL) { ++ /* add safe-link for target file (in case we removed ++ * last reference to the poor fellow */ ++ fplug = inode_file_plugin(new_inode); ++ if (new_inode->i_nlink == 0) ++ result = safe_link_add(new_inode, SAFE_UNLINK); ++ } ++ } ++exit: ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ return result; ++} ++#endif +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/acl.h linux-5.10.2/fs/reiser4/plugin/item/acl.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/acl.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/acl.h 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,66 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Directory entry. */ ++ ++#if !defined( __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ ) ++#define __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++ ++#include ++#include /* for struct dentry */ ++ ++typedef struct directory_entry_format { ++ /* key of object stat-data. It's not necessary to store whole ++ key here, because it's always key of stat-data, so minor ++ packing locality and offset can be omitted here. But this ++ relies on particular key allocation scheme for stat-data, so, ++ for extensibility sake, whole key can be stored here. ++ ++ We store key as array of bytes, because we don't want 8-byte ++ alignment of dir entries. ++ */ ++ obj_key_id id; ++ /* file name. Null terminated string. */ ++ d8 name[0]; ++} directory_entry_format; ++ ++void print_de(const char *prefix, coord_t * coord); ++int extract_key_de(const coord_t * coord, reiser4_key * key); ++int update_key_de(const coord_t * coord, const reiser4_key * key, ++ lock_handle * lh); ++char *extract_name_de(const coord_t * coord, char *buf); ++unsigned extract_file_type_de(const coord_t * coord); ++int add_entry_de(struct inode *dir, coord_t * coord, ++ lock_handle * lh, const struct dentry *name, ++ reiser4_dir_entry_desc * entry); ++int rem_entry_de(struct inode *dir, const struct qstr *name, coord_t * coord, ++ lock_handle * lh, reiser4_dir_entry_desc * entry); ++int max_name_len_de(const struct inode *dir); ++ ++int de_rem_and_shrink(struct inode *dir, coord_t * coord, int length); ++ ++char *extract_dent_name(const coord_t * coord, ++ directory_entry_format * dent, char *buf); ++ ++#if REISER4_LARGE_KEY ++#define DE_NAME_BUF_LEN (24) ++#else ++#define DE_NAME_BUF_LEN (16) ++#endif ++ ++/* __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/blackbox.c linux-5.10.2/fs/reiser4/plugin/item/blackbox.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/blackbox.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/blackbox.c 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,142 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Black box item implementation */ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../coord.h" ++#include "../../tree.h" ++#include "../../lock.h" ++ ++#include "blackbox.h" ++#include "item.h" ++#include "../plugin.h" ++ ++int ++store_black_box(reiser4_tree * tree, ++ const reiser4_key * key, void *data, int length) ++{ ++ int result; ++ reiser4_item_data idata; ++ coord_t coord; ++ lock_handle lh; ++ ++ memset(&idata, 0, sizeof idata); ++ ++ idata.data = data; ++ idata.user = 0; ++ idata.length = length; ++ idata.iplug = item_plugin_by_id(BLACK_BOX_ID); ++ ++ init_lh(&lh); ++ result = insert_by_key(tree, key, ++ &idata, &coord, &lh, LEAF_LEVEL, CBK_UNIQUE); ++ ++ assert("nikita-3413", ++ ergo(result == 0, ++ WITH_COORD(&coord, ++ item_length_by_coord(&coord) == length))); ++ ++ done_lh(&lh); ++ return result; ++} ++ ++int ++load_black_box(reiser4_tree * tree, ++ reiser4_key * key, void *data, int length, int exact) ++{ ++ int result; ++ coord_t coord; ++ lock_handle lh; ++ ++ init_lh(&lh); ++ result = coord_by_key(tree, key, ++ &coord, &lh, ZNODE_READ_LOCK, ++ exact ? FIND_EXACT : FIND_MAX_NOT_MORE_THAN, ++ LEAF_LEVEL, LEAF_LEVEL, CBK_UNIQUE, NULL); ++ ++ if (result == 0) { ++ int ilen; ++ ++ result = zload(coord.node); ++ if (result == 0) { ++ ilen = item_length_by_coord(&coord); ++ if (ilen <= length) { ++ memcpy(data, item_body_by_coord(&coord), ilen); ++ unit_key_by_coord(&coord, key); ++ } else if (exact) { ++ /* ++ * item is larger than buffer provided by the ++ * user. Only issue a warning if @exact is ++ * set. If @exact is false, we are iterating ++ * over all safe-links and here we are reaching ++ * the end of the iteration. ++ */ ++ warning("nikita-3415", ++ "Wrong black box length: %i > %i", ++ ilen, length); ++ result = RETERR(-EIO); ++ } ++ zrelse(coord.node); ++ } ++ } ++ ++ done_lh(&lh); ++ return result; ++ ++} ++ ++int ++update_black_box(reiser4_tree * tree, ++ const reiser4_key * key, void *data, int length) ++{ ++ int result; ++ coord_t coord; ++ lock_handle lh; ++ ++ init_lh(&lh); ++ result = coord_by_key(tree, key, ++ &coord, &lh, ZNODE_READ_LOCK, ++ FIND_EXACT, ++ LEAF_LEVEL, LEAF_LEVEL, CBK_UNIQUE, NULL); ++ if (result == 0) { ++ int ilen; ++ ++ result = zload(coord.node); ++ if (result == 0) { ++ ilen = item_length_by_coord(&coord); ++ if (length <= ilen) { ++ memcpy(item_body_by_coord(&coord), data, ++ length); ++ } else { ++ warning("nikita-3437", ++ "Wrong black box length: %i < %i", ++ ilen, length); ++ result = RETERR(-EIO); ++ } ++ zrelse(coord.node); ++ } ++ } ++ ++ done_lh(&lh); ++ return result; ++ ++} ++ ++int kill_black_box(reiser4_tree * tree, const reiser4_key * key) ++{ ++ return reiser4_cut_tree(tree, key, key, NULL, 1); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/blackbox.h linux-5.10.2/fs/reiser4/plugin/item/blackbox.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/blackbox.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/blackbox.h 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,33 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* "Black box" entry to fixed-width contain user supplied data */ ++ ++#if !defined( __FS_REISER4_BLACK_BOX_H__ ) ++#define __FS_REISER4_BLACK_BOX_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++ ++extern int store_black_box(reiser4_tree * tree, ++ const reiser4_key * key, void *data, int length); ++extern int load_black_box(reiser4_tree * tree, ++ reiser4_key * key, void *data, int length, int exact); ++extern int kill_black_box(reiser4_tree * tree, const reiser4_key * key); ++extern int update_black_box(reiser4_tree * tree, ++ const reiser4_key * key, void *data, int length); ++ ++/* __FS_REISER4_BLACK_BOX_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/brick_symbol.c linux-5.10.2/fs/reiser4/plugin/item/brick_symbol.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/brick_symbol.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/brick_symbol.c 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,175 @@ ++/* ++ Copyright (c) 2019-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../coord.h" ++#include "../../tree.h" ++#include "../../lock.h" ++#include "../../super.h" ++ ++#include "brick_symbol.h" ++#include "item.h" ++#include "../plugin.h" ++ ++int store_brick_symbol(const reiser4_key *key, void *data, int length) ++{ ++ int ret; ++ reiser4_item_data idata; ++ coord_t coord; ++ lock_handle lh; ++ ++ memset(&idata, 0, sizeof idata); ++ ++ idata.data = data; ++ idata.user = 0; ++ idata.length = length; ++ idata.iplug = item_plugin_by_id(BRICK_SYMBOL_ID); ++ ++ init_lh(&lh); ++ ret = insert_by_key(meta_subvol_tree(), key, ++ &idata, &coord, &lh, LEAF_LEVEL, CBK_UNIQUE); ++ assert("edward-2296", ++ ergo(ret == 0, ++ WITH_COORD(&coord, ++ item_length_by_coord(&coord) == length))); ++ done_lh(&lh); ++ return ret; ++} ++ ++int load_brick_symbol(const reiser4_key *key, void *data, ++ int length, int exact) ++{ ++ int ret; ++ coord_t coord; ++ lock_handle lh; ++ ++ init_lh(&lh); ++ ret = coord_by_key(meta_subvol_tree(), key, ++ &coord, &lh, ZNODE_READ_LOCK, ++ exact ? FIND_EXACT : FIND_MAX_NOT_MORE_THAN, ++ LEAF_LEVEL, LEAF_LEVEL, CBK_UNIQUE, NULL); ++ if (ret == 0) { ++ ret = zload(coord.node); ++ if (ret == 0) { ++ int ilen = item_length_by_coord(&coord); ++ if (ilen == length) ++ memcpy(data, item_body_by_coord(&coord), ilen); ++ else { ++ warning("edward-2297", ++ "Wrong brick symbol length: %i != %i", ++ ilen, length); ++ ret = RETERR(-EIO); ++ } ++ } ++ zrelse(coord.node); ++ } ++ done_lh(&lh); ++ return ret; ++} ++ ++int kill_brick_symbol(const reiser4_key *key) ++{ ++ return reiser4_cut_tree(meta_subvol_tree(), key, key, NULL, 1); ++} ++ ++typedef struct brick_symbol { ++ d64 id; /* internal brick ID, AKA index in the array of slots */ ++} brick_symbol_t; ++ ++ ++static oid_t brick_symbol_locality(void) ++{ ++ return get_key_objectid(get_meta_subvol()->df_plug-> ++ root_dir_key(NULL)) + 2; ++} ++ ++/** ++ * convert 1-st 8 bytes of brick's UUID to a 64-bit number ++ */ ++static u64 brick_symbol_fulloid(reiser4_subvol *subv) ++{ ++ return le64_to_cpu(get_unaligned((u64 *)subv->uuid)); ++} ++ ++/** ++ * convert 2-nd 8 bytes of brick's UUID to a 64-bit number ++ */ ++static u64 brick_symbol_offset(reiser4_subvol *subv) ++{ ++ return le64_to_cpu(get_unaligned((u64 *)&subv->uuid[8])); ++} ++ ++/* ++ Construct a key for brick symbol item. Key has the following format: ++ ++| 60 | 4 | 64 | 64 | 64 | +++---------------+---+------------------+-------------------+-------------------+ ++| locality | 0 | 0 | 1-st part of uuid | 2-nd part of uuid | +++---------------+---+------------------+-------------------+-------------------+ ++| | | | | ++| 8 bytes | 8 bytes | 8 bytes | 8 bytes | ++ ++ This is in large keys format. In small keys format second 8 byte chunk is ++ out. Locality is a constant returned by safe_link_locality(). ++ UUID is external ID of the brick for which we construct the key. ++*/ ++ ++static reiser4_key *build_brick_symbol_key(reiser4_key *key, ++ reiser4_subvol *subv) ++{ ++ reiser4_key_init(key); ++ set_key_locality(key, brick_symbol_locality()); ++ set_key_fulloid(key, brick_symbol_fulloid(subv)); ++ set_key_offset(key, brick_symbol_offset(subv)); ++ return key; ++} ++ ++int brick_symbol_add(reiser4_subvol *subv) ++{ ++ reiser4_key key; ++ brick_symbol_t bs; ++ ++ put_unaligned(cpu_to_le64(subv->id), &bs.id); ++ build_brick_symbol_key(&key, subv); ++ ++ return store_brick_symbol(&key, &bs, sizeof bs); ++} ++ ++int brick_symbol_del(reiser4_subvol *subv) ++{ ++ reiser4_key key; ++ ++ return kill_brick_symbol(build_brick_symbol_key(&key, subv)); ++} ++ ++int brick_identify(reiser4_subvol *subv) ++{ ++ int ret; ++ reiser4_key key; ++ brick_symbol_t bs; ++ ++ ret = load_brick_symbol(build_brick_symbol_key(&key, subv), ++ &bs, sizeof bs, 1 /* exact */); ++ if (ret) ++ return 0; ++ return bs.id == subv->id; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/brick_symbol.h linux-5.10.2/fs/reiser4/plugin/item/brick_symbol.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/brick_symbol.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/brick_symbol.h 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,30 @@ ++/* "Brick symbol" contains internal and extermal brick IDs */ ++ ++#if !defined( __FS_REISER4_BRICK_SYMBOL_H__ ) ++#define __FS_REISER4_BRICK_SYMBOL_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++ ++extern int store_brick_symbol(const reiser4_key *key, void *data, int len); ++extern int load_brick_symbol(const reiser4_key *key, void *data, ++ int len, int exact); ++extern int kill_brick_symbol(const reiser4_key *key); ++extern int brick_symbol_add(reiser4_subvol *subv); ++extern int brick_symbol_del(reiser4_subvol *subv); ++extern int brick_identify(reiser4_subvol *subv); ++ ++/* __FS_REISER4_BRICK_SYMBOL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/cde.c linux-5.10.2/fs/reiser4/plugin/item/cde.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/cde.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/cde.c 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,1005 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Directory entry implementation */ ++ ++/* DESCRIPTION: ++ ++ This is "compound" directory item plugin implementation. This directory ++ item type is compound (as opposed to the "simple directory item" in ++ fs/reiser4/plugin/item/sde.[ch]), because it consists of several directory ++ entries. ++ ++ The reason behind this decision is disk space efficiency: all directory ++ entries inside the same directory have identical fragment in their ++ keys. This, of course, depends on key assignment policy. In our default key ++ assignment policy, all directory entries have the same locality which is ++ equal to the object id of their directory. ++ ++ Composing directory item out of several directory entries for the same ++ directory allows us to store said key fragment only once. That is, this is ++ some ad hoc form of key compression (stem compression) that is implemented ++ here, because general key compression is not supposed to be implemented in ++ v4.0. ++ ++ Another decision that was made regarding all directory item plugins, is ++ that they will store entry keys unaligned. This is for that sake of disk ++ space efficiency again. ++ ++ In should be noted, that storing keys unaligned increases CPU consumption, ++ at least on some architectures. ++ ++ Internal on-disk structure of the compound directory item is the following: ++ ++ HEADER cde_item_format. Here number of entries is stored. ++ ENTRY_HEADER_0 cde_unit_header. Here part of entry key and ++ ENTRY_HEADER_1 offset of entry body are stored. ++ ENTRY_HEADER_2 (basically two last parts of key) ++ ... ++ ENTRY_HEADER_N ++ ENTRY_BODY_0 directory_entry_format. Here part of stat data key and ++ ENTRY_BODY_1 NUL-terminated name are stored. ++ ENTRY_BODY_2 (part of statadta key in the ++ sence that since all SDs have ++ zero offset, this offset is not ++ stored on disk). ++ ... ++ ENTRY_BODY_N ++ ++ When it comes to the balancing, each directory entry in compound directory ++ item is unit, that is, something that can be cut from one item and pasted ++ into another item of the same type. Handling of unit cut and paste is major ++ reason for the complexity of code below. ++ ++*/ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "sde.h" ++#include "cde.h" ++#include "item.h" ++#include "../node/node.h" ++#include "../plugin.h" ++#include "../../znode.h" ++#include "../../carry.h" ++#include "../../tree.h" ++#include "../../inode.h" ++ ++#include /* for struct inode */ ++#include /* for struct dentry */ ++ ++#if 0 ++#define CHECKME(coord) \ ++({ \ ++ const char *message; \ ++ coord_t dup; \ ++ \ ++ coord_dup_nocheck(&dup, (coord)); \ ++ dup.unit_pos = 0; \ ++ assert("nikita-2871", cde_check(&dup, &message) == 0); \ ++}) ++#else ++#define CHECKME(coord) noop ++#endif ++ ++static_assert(REISER4_SEQ_SEARCH_BREAK > 2); ++ ++/* return body of compound directory item at @coord */ ++static inline cde_item_format *formatted_at(const coord_t * coord) ++{ ++ assert("nikita-1282", coord != NULL); ++ return item_body_by_coord(coord); ++} ++ ++/* return entry header at @coord */ ++static inline cde_unit_header *header_at(const coord_t * ++ coord /* coord of item */ , ++ int idx /* index of unit */ ) ++{ ++ assert("nikita-1283", coord != NULL); ++ return &formatted_at(coord)->entry[idx]; ++} ++ ++/* return number of units in compound directory item at @coord */ ++static int units(const coord_t * coord /* coord of item */ ) ++{ ++ return le16_to_cpu(get_unaligned(&formatted_at(coord)->num_of_entries)); ++} ++ ++/* return offset of the body of @idx-th entry in @coord */ ++static unsigned int offset_of(const coord_t * coord /* coord of item */ , ++ int idx /* index of unit */ ) ++{ ++ if (idx < units(coord)) ++ return le16_to_cpu(get_unaligned(&header_at(coord, idx)->offset)); ++ else if (idx == units(coord)) ++ return item_length_by_coord(coord); ++ else ++ impossible("nikita-1308", "Wrong idx"); ++ return 0; ++} ++ ++/* set offset of the body of @idx-th entry in @coord */ ++static void set_offset(const coord_t * coord /* coord of item */ , ++ int idx /* index of unit */ , ++ unsigned int offset /* new offset */ ) ++{ ++ put_unaligned(cpu_to_le16((__u16) offset), &header_at(coord, idx)->offset); ++} ++ ++static void adj_offset(const coord_t * coord /* coord of item */ , ++ int idx /* index of unit */ , ++ int delta /* offset change */ ) ++{ ++ d16 *doffset; ++ __u16 offset; ++ ++ doffset = &header_at(coord, idx)->offset; ++ offset = le16_to_cpu(get_unaligned(doffset)); ++ offset += delta; ++ put_unaligned(cpu_to_le16((__u16) offset), doffset); ++} ++ ++/* return pointer to @offset-th byte from the beginning of @coord */ ++static char *address(const coord_t * coord /* coord of item */ , ++ int offset) ++{ ++ return ((char *)item_body_by_coord(coord)) + offset; ++} ++ ++/* return pointer to the body of @idx-th entry in @coord */ ++static directory_entry_format *entry_at(const coord_t * coord /* coord of ++ * item */ , ++ int idx /* index of unit */ ) ++{ ++ return (directory_entry_format *) address(coord, ++ (int)offset_of(coord, idx)); ++} ++ ++/* return number of unit referenced by @coord */ ++static int idx_of(const coord_t * coord /* coord of item */ ) ++{ ++ assert("nikita-1285", coord != NULL); ++ return coord->unit_pos; ++} ++ ++/* find position where entry with @entry_key would be inserted into @coord */ ++static int find(const coord_t * coord /* coord of item */ , ++ const reiser4_key * entry_key /* key to look for */ , ++ cmp_t * last /* result of last comparison */ ) ++{ ++ int entries; ++ ++ int left; ++ int right; ++ ++ cde_unit_header *header; ++ ++ assert("nikita-1295", coord != NULL); ++ assert("nikita-1296", entry_key != NULL); ++ assert("nikita-1297", last != NULL); ++ ++ entries = units(coord); ++ left = 0; ++ right = entries - 1; ++ while (right - left >= REISER4_SEQ_SEARCH_BREAK) { ++ int median; ++ ++ median = (left + right) >> 1; ++ ++ header = header_at(coord, median); ++ *last = de_id_key_cmp(&header->hash, entry_key); ++ switch (*last) { ++ case LESS_THAN: ++ left = median; ++ break; ++ case GREATER_THAN: ++ right = median; ++ break; ++ case EQUAL_TO:{ ++ do { ++ median--; ++ header--; ++ } while (median >= 0 && ++ de_id_key_cmp(&header->hash, ++ entry_key) == EQUAL_TO); ++ return median + 1; ++ } ++ } ++ } ++ header = header_at(coord, left); ++ for (; left < entries; ++left, ++header) { ++ prefetch(header + 1); ++ *last = de_id_key_cmp(&header->hash, entry_key); ++ if (*last != LESS_THAN) ++ break; ++ } ++ if (left < entries) ++ return left; ++ else ++ return RETERR(-ENOENT); ++ ++} ++ ++/* expand @coord as to accommodate for insertion of @no new entries starting ++ from @pos, with total bodies size @size. */ ++static int expand_item(const coord_t * coord /* coord of item */ , ++ int pos /* unit position */ , int no /* number of new ++ * units*/ , ++ int size /* total size of new units' data */ , ++ unsigned int data_size /* free space already reserved ++ * in the item for insertion */ ) ++{ ++ int entries; ++ cde_unit_header *header; ++ char *dent; ++ int i; ++ ++ assert("nikita-1310", coord != NULL); ++ assert("nikita-1311", pos >= 0); ++ assert("nikita-1312", no > 0); ++ assert("nikita-1313", data_size >= no * sizeof(directory_entry_format)); ++ assert("nikita-1343", ++ item_length_by_coord(coord) >= ++ (int)(size + data_size + no * sizeof *header)); ++ ++ entries = units(coord); ++ ++ if (pos == entries) ++ dent = address(coord, size); ++ else ++ dent = (char *)entry_at(coord, pos); ++ /* place where new header will be in */ ++ header = header_at(coord, pos); ++ /* free space for new entry headers */ ++ memmove(header + no, header, ++ (unsigned)(address(coord, size) - (char *)header)); ++ /* if adding to the end initialise first new header */ ++ if (pos == entries) { ++ set_offset(coord, pos, (unsigned)size); ++ } ++ ++ /* adjust entry pointer and size */ ++ dent = dent + no * sizeof *header; ++ size += no * sizeof *header; ++ /* free space for new entries */ ++ memmove(dent + data_size, dent, ++ (unsigned)(address(coord, size) - dent)); ++ ++ /* increase counter */ ++ entries += no; ++ put_unaligned(cpu_to_le16((__u16) entries), &formatted_at(coord)->num_of_entries); ++ ++ /* [ 0 ... pos ] entries were shifted by no * ( sizeof *header ) ++ bytes. */ ++ for (i = 0; i <= pos; ++i) ++ adj_offset(coord, i, no * sizeof *header); ++ /* [ pos + no ... +\infty ) entries were shifted by ( no * ++ sizeof *header + data_size ) bytes */ ++ for (i = pos + no; i < entries; ++i) ++ adj_offset(coord, i, no * sizeof *header + data_size); ++ return 0; ++} ++ ++/* insert new @entry into item */ ++static int expand(const coord_t * coord /* coord of item */ , ++ struct cde_entry * entry /* entry to insert */ , ++ int len /* length of @entry data */ , ++ int *pos /* position to insert */ , ++ reiser4_dir_entry_desc * dir_entry /* parameters for new ++ * entry */ ) ++{ ++ cmp_t cmp_res; ++ int datasize; ++ ++ *pos = find(coord, &dir_entry->key, &cmp_res); ++ if (*pos < 0) ++ *pos = units(coord); ++ ++ datasize = sizeof(directory_entry_format); ++ if (is_longname(entry->name->name, entry->name->len)) ++ datasize += entry->name->len + 1; ++ ++ expand_item(coord, *pos, 1, item_length_by_coord(coord) - len, ++ datasize); ++ return 0; ++} ++ ++/* paste body of @entry into item */ ++static int paste_entry(const coord_t * coord /* coord of item */ , ++ struct cde_entry * entry /* new entry */ , ++ int pos /* position to insert */ , ++ reiser4_dir_entry_desc * dir_entry /* parameters for ++ * new entry */ ) ++{ ++ cde_unit_header *header; ++ directory_entry_format *dent; ++ const char *name; ++ int len; ++ ++ header = header_at(coord, pos); ++ dent = entry_at(coord, pos); ++ ++ build_de_id_by_key(&dir_entry->key, &header->hash); ++ build_inode_key_id(entry->obj, &dent->id); ++ /* AUDIT unsafe strcpy() operation! It should be replaced with ++ much less CPU hungry ++ memcpy( ( char * ) dent -> name, entry -> name -> name , entry -> name -> len ); ++ ++ Also a more major thing is that there should be a way to figure out ++ amount of space in dent -> name and be able to check that we are ++ not going to overwrite more than we supposed to */ ++ name = entry->name->name; ++ len = entry->name->len; ++ if (is_longname(name, len)) { ++ strcpy((unsigned char *)dent->name, name); ++ put_unaligned(0, &dent->name[len]); ++ } ++ return 0; ++} ++ ++/* estimate how much space is necessary in item to insert/paste set of entries ++ described in @data. */ ++int estimate_cde(const coord_t * coord /* coord of item */ , ++ const reiser4_item_data * data /* parameters for new item */ ) ++{ ++ struct cde_entry_data *e; ++ int result; ++ int i; ++ ++ e = (struct cde_entry_data *) data->data; ++ ++ assert("nikita-1288", e != NULL); ++ assert("nikita-1289", e->num_of_entries >= 0); ++ ++ if (coord == NULL) ++ /* insert */ ++ result = sizeof(cde_item_format); ++ else ++ /* paste */ ++ result = 0; ++ ++ result += e->num_of_entries * ++ (sizeof(cde_unit_header) + sizeof(directory_entry_format)); ++ for (i = 0; i < e->num_of_entries; ++i) { ++ const char *name; ++ int len; ++ ++ name = e->entry[i].name->name; ++ len = e->entry[i].name->len; ++ assert("nikita-2054", strlen(name) == len); ++ if (is_longname(name, len)) ++ result += len + 1; ++ } ++ ((reiser4_item_data *) data)->length = result; ++ return result; ++} ++ ++/* ->nr_units() method for this item plugin. */ ++pos_in_node_t nr_units_cde(const coord_t * coord /* coord of item */ ) ++{ ++ return units(coord); ++} ++ ++/* ->unit_key() method for this item plugin. */ ++reiser4_key *unit_key_cde(const coord_t * coord /* coord of item */ , ++ reiser4_key * key /* resulting key */ ) ++{ ++ assert("nikita-1452", coord != NULL); ++ assert("nikita-1345", idx_of(coord) < units(coord)); ++ assert("nikita-1346", key != NULL); ++ ++ item_key_by_coord(coord, key); ++ extract_key_from_de_id(extract_dir_id_from_key(key), ++ &header_at(coord, idx_of(coord))->hash, key); ++ return key; ++} ++ ++/* mergeable_cde(): implementation of ->mergeable() item method. ++ ++ Two directory items are mergeable iff they are from the same ++ directory. That simple. ++ ++*/ ++int mergeable_cde(const coord_t * p1 /* coord of first item */ , ++ const coord_t * p2 /* coord of second item */ ) ++{ ++ reiser4_key k1; ++ reiser4_key k2; ++ ++ assert("nikita-1339", p1 != NULL); ++ assert("nikita-1340", p2 != NULL); ++ ++ return ++ (item_plugin_by_coord(p1) == item_plugin_by_coord(p2)) && ++ (extract_dir_id_from_key(item_key_by_coord(p1, &k1)) == ++ extract_dir_id_from_key(item_key_by_coord(p2, &k2))); ++ ++} ++ ++/* ->max_key_inside() method for this item plugin. */ ++reiser4_key *max_key_inside_cde(const coord_t * coord /* coord of item */ , ++ reiser4_key * result /* resulting key */ ) ++{ ++ assert("nikita-1342", coord != NULL); ++ ++ item_key_by_coord(coord, result); ++ set_key_ordering(result, get_key_ordering(reiser4_max_key())); ++ set_key_fulloid(result, get_key_fulloid(reiser4_max_key())); ++ set_key_offset(result, get_key_offset(reiser4_max_key())); ++ return result; ++} ++ ++/* @data contains data which are to be put into tree */ ++int can_contain_key_cde(const coord_t * coord /* coord of item */ , ++ const reiser4_key * key /* key to check */ , ++ const reiser4_item_data * data /* parameters of new ++ * item/unit being ++ * created */ ) ++{ ++ reiser4_key item_key; ++ ++ /* FIXME-VS: do not rely on anything but iplug field of @data. Only ++ data->iplug is initialized */ ++ assert("vs-457", data && data->iplug); ++/* assert( "vs-553", data -> user == 0 );*/ ++ item_key_by_coord(coord, &item_key); ++ ++ return (item_plugin_by_coord(coord) == data->iplug) && ++ (extract_dir_id_from_key(&item_key) == ++ extract_dir_id_from_key(key)); ++} ++ ++#if REISER4_DEBUG ++/* cde_check ->check() method for compressed directory items ++ ++ used for debugging, every item should have here the most complete ++ possible check of the consistency of the item that the inventor can ++ construct ++*/ ++int reiser4_check_cde(const coord_t * coord /* coord of item to check */, ++ const char **error /* where to store error message */) ++{ ++ int i; ++ int result; ++ char *item_start; ++ char *item_end; ++ reiser4_key key; ++ ++ coord_t c; ++ ++ assert("nikita-1357", coord != NULL); ++ assert("nikita-1358", error != NULL); ++ ++ if (!ergo(coord->item_pos != 0, ++ is_dot_key(item_key_by_coord(coord, &key)))) { ++ *error = "CDE doesn't start with dot"; ++ return -1; ++ } ++ item_start = item_body_by_coord(coord); ++ item_end = item_start + item_length_by_coord(coord); ++ ++ coord_dup(&c, coord); ++ result = 0; ++ for (i = 0; i < units(coord); ++i) { ++ directory_entry_format *entry; ++ ++ if ((char *)(header_at(coord, i) + 1) > ++ item_end - units(coord) * sizeof *entry) { ++ *error = "CDE header is out of bounds"; ++ result = -1; ++ break; ++ } ++ entry = entry_at(coord, i); ++ if ((char *)entry < item_start + sizeof(cde_item_format)) { ++ *error = "CDE header is too low"; ++ result = -1; ++ break; ++ } ++ if ((char *)(entry + 1) > item_end) { ++ *error = "CDE header is too high"; ++ result = -1; ++ break; ++ } ++ } ++ ++ return result; ++} ++#endif ++ ++/* ->init() method for this item plugin. */ ++int init_cde(coord_t * coord /* coord of item */ , ++ coord_t * from UNUSED_ARG, reiser4_item_data * data /* structure used for insertion */ ++ UNUSED_ARG) ++{ ++ put_unaligned(cpu_to_le16(0), &formatted_at(coord)->num_of_entries); ++ return 0; ++} ++ ++/* ->lookup() method for this item plugin. */ ++lookup_result lookup_cde(const reiser4_key * key /* key to search for */ , ++ lookup_bias bias /* search bias */ , ++ coord_t * coord /* coord of item to lookup in */ ) ++{ ++ cmp_t last_comp; ++ int pos; ++ ++ reiser4_key utmost_key; ++ ++ assert("nikita-1293", coord != NULL); ++ assert("nikita-1294", key != NULL); ++ ++ CHECKME(coord); ++ ++ if (keygt(item_key_by_coord(coord, &utmost_key), key)) { ++ coord->unit_pos = 0; ++ coord->between = BEFORE_UNIT; ++ return CBK_COORD_NOTFOUND; ++ } ++ pos = find(coord, key, &last_comp); ++ if (pos >= 0) { ++ coord->unit_pos = (int)pos; ++ switch (last_comp) { ++ case EQUAL_TO: ++ coord->between = AT_UNIT; ++ return CBK_COORD_FOUND; ++ case GREATER_THAN: ++ coord->between = BEFORE_UNIT; ++ return RETERR(-ENOENT); ++ case LESS_THAN: ++ default: ++ impossible("nikita-1298", "Broken find"); ++ return RETERR(-EIO); ++ } ++ } else { ++ coord->unit_pos = units(coord) - 1; ++ coord->between = AFTER_UNIT; ++ return (bias == ++ FIND_MAX_NOT_MORE_THAN) ? CBK_COORD_FOUND : ++ CBK_COORD_NOTFOUND; ++ } ++} ++ ++/* ->paste() method for this item plugin. */ ++int paste_cde(coord_t * coord /* coord of item */ , ++ reiser4_item_data * data /* parameters of new unit being ++ * inserted */ , ++ carry_plugin_info * info UNUSED_ARG /* todo carry queue */ ) ++{ ++ struct cde_entry_data *e; ++ int result; ++ int i; ++ ++ CHECKME(coord); ++ e = (struct cde_entry_data *) data->data; ++ ++ result = 0; ++ for (i = 0; i < e->num_of_entries; ++i) { ++ int pos; ++ int phantom_size; ++ ++ phantom_size = data->length; ++ if (units(coord) == 0) ++ phantom_size -= sizeof(cde_item_format); ++ ++ result = ++ expand(coord, e->entry + i, phantom_size, &pos, data->arg); ++ if (result != 0) ++ break; ++ result = paste_entry(coord, e->entry + i, pos, data->arg); ++ if (result != 0) ++ break; ++ } ++ CHECKME(coord); ++ return result; ++} ++ ++/* amount of space occupied by all entries starting from @idx both headers and ++ bodies. */ ++static unsigned int part_size(const coord_t * coord /* coord of item */ , ++ int idx /* index of unit */ ) ++{ ++ assert("nikita-1299", coord != NULL); ++ assert("nikita-1300", idx < (int)units(coord)); ++ ++ return sizeof(cde_item_format) + ++ (idx + 1) * sizeof(cde_unit_header) + offset_of(coord, ++ idx + 1) - ++ offset_of(coord, 0); ++} ++ ++/* how many but not more than @want units of @source can be merged with ++ item in @target node. If pend == append - we try to append last item ++ of @target by first units of @source. If pend == prepend - we try to ++ "prepend" first item in @target by last units of @source. @target ++ node has @free_space bytes of free space. Total size of those units ++ are returned via @size */ ++int can_shift_cde(unsigned free_space /* free space in item */ , ++ coord_t * coord /* coord of source item */ , ++ znode * target /* target node */ , ++ shift_direction pend /* shift direction */ , ++ unsigned *size /* resulting number of shifted bytes */ , ++ unsigned want /* maximal number of bytes to shift */ ) ++{ ++ int shift; ++ ++ CHECKME(coord); ++ if (want == 0) { ++ *size = 0; ++ return 0; ++ } ++ ++ /* pend == SHIFT_LEFT <==> shifting to the left */ ++ if (pend == SHIFT_LEFT) { ++ for (shift = min((int)want - 1, units(coord)); shift >= 0; ++ --shift) { ++ *size = part_size(coord, shift); ++ if (target != NULL) ++ *size -= sizeof(cde_item_format); ++ if (*size <= free_space) ++ break; ++ } ++ shift = shift + 1; ++ } else { ++ int total_size; ++ ++ assert("nikita-1301", pend == SHIFT_RIGHT); ++ ++ total_size = item_length_by_coord(coord); ++ for (shift = units(coord) - want - 1; shift < units(coord) - 1; ++ ++shift) { ++ *size = total_size - part_size(coord, shift); ++ if (target == NULL) ++ *size += sizeof(cde_item_format); ++ if (*size <= free_space) ++ break; ++ } ++ shift = units(coord) - shift - 1; ++ } ++ if (shift == 0) ++ *size = 0; ++ CHECKME(coord); ++ return shift; ++} ++ ++/* ->copy_units() method for this item plugin. */ ++void copy_units_cde(coord_t * target /* coord of target item */ , ++ coord_t * source /* coord of source item */ , ++ unsigned from /* starting unit */ , ++ unsigned count /* how many units to copy */ , ++ shift_direction where_is_free_space /* shift direction */ , ++ unsigned free_space /* free space in item */ ) ++{ ++ char *header_from; ++ char *header_to; ++ ++ char *entry_from; ++ char *entry_to; ++ ++ int pos_in_target; ++ int data_size; ++ int data_delta; ++ int i; ++ ++ assert("nikita-1303", target != NULL); ++ assert("nikita-1304", source != NULL); ++ assert("nikita-1305", (int)from < units(source)); ++ assert("nikita-1307", (int)(from + count) <= units(source)); ++ ++ if (where_is_free_space == SHIFT_LEFT) { ++ assert("nikita-1453", from == 0); ++ pos_in_target = units(target); ++ } else { ++ assert("nikita-1309", (int)(from + count) == units(source)); ++ pos_in_target = 0; ++ memmove(item_body_by_coord(target), ++ (char *)item_body_by_coord(target) + free_space, ++ item_length_by_coord(target) - free_space); ++ } ++ ++ CHECKME(target); ++ CHECKME(source); ++ ++ /* expand @target */ ++ data_size = ++ offset_of(source, (int)(from + count)) - offset_of(source, ++ (int)from); ++ ++ if (units(target) == 0) ++ free_space -= sizeof(cde_item_format); ++ ++ expand_item(target, pos_in_target, (int)count, ++ (int)(item_length_by_coord(target) - free_space), ++ (unsigned)data_size); ++ ++ /* copy first @count units of @source into @target */ ++ data_delta = ++ offset_of(target, pos_in_target) - offset_of(source, (int)from); ++ ++ /* copy entries */ ++ entry_from = (char *)entry_at(source, (int)from); ++ entry_to = (char *)entry_at(source, (int)(from + count)); ++ memmove(entry_at(target, pos_in_target), entry_from, ++ (unsigned)(entry_to - entry_from)); ++ ++ /* copy headers */ ++ header_from = (char *)header_at(source, (int)from); ++ header_to = (char *)header_at(source, (int)(from + count)); ++ memmove(header_at(target, pos_in_target), header_from, ++ (unsigned)(header_to - header_from)); ++ ++ /* update offsets */ ++ for (i = pos_in_target; i < (int)(pos_in_target + count); ++i) ++ adj_offset(target, i, data_delta); ++ CHECKME(target); ++ CHECKME(source); ++} ++ ++/* ->cut_units() method for this item plugin. */ ++int cut_units_cde(coord_t * coord /* coord of item */ , ++ pos_in_node_t from /* start unit pos */ , ++ pos_in_node_t to /* stop unit pos */ , ++ struct carry_cut_data *cdata UNUSED_ARG, ++ reiser4_key * smallest_removed, reiser4_key * new_first) ++{ ++ char *header_from; ++ char *header_to; ++ ++ char *entry_from; ++ char *entry_to; ++ ++ int size; ++ int entry_delta; ++ int header_delta; ++ int i; ++ ++ unsigned count; ++ ++ CHECKME(coord); ++ ++ count = to - from + 1; ++ ++ assert("nikita-1454", coord != NULL); ++ assert("nikita-1455", (int)(from + count) <= units(coord)); ++ ++ if (smallest_removed) ++ unit_key_by_coord(coord, smallest_removed); ++ ++ if (new_first) { ++ coord_t next; ++ ++ /* not everything is cut from item head */ ++ assert("vs-1527", from == 0); ++ assert("vs-1528", to < units(coord) - 1); ++ ++ coord_dup(&next, coord); ++ next.unit_pos++; ++ unit_key_by_coord(&next, new_first); ++ } ++ ++ size = item_length_by_coord(coord); ++ if (count == (unsigned)units(coord)) { ++ return size; ++ } ++ ++ header_from = (char *)header_at(coord, (int)from); ++ header_to = (char *)header_at(coord, (int)(from + count)); ++ ++ entry_from = (char *)entry_at(coord, (int)from); ++ entry_to = (char *)entry_at(coord, (int)(from + count)); ++ ++ /* move headers */ ++ memmove(header_from, header_to, ++ (unsigned)(address(coord, size) - header_to)); ++ ++ header_delta = header_to - header_from; ++ ++ entry_from -= header_delta; ++ entry_to -= header_delta; ++ size -= header_delta; ++ ++ /* copy entries */ ++ memmove(entry_from, entry_to, ++ (unsigned)(address(coord, size) - entry_to)); ++ ++ entry_delta = entry_to - entry_from; ++ size -= entry_delta; ++ ++ /* update offsets */ ++ ++ for (i = 0; i < (int)from; ++i) ++ adj_offset(coord, i, -header_delta); ++ ++ for (i = from; i < units(coord) - (int)count; ++i) ++ adj_offset(coord, i, -header_delta - entry_delta); ++ ++ put_unaligned(cpu_to_le16((__u16) units(coord) - count), ++ &formatted_at(coord)->num_of_entries); ++ ++ if (from == 0) { ++ /* entries from head was removed - move remaining to right */ ++ memmove((char *)item_body_by_coord(coord) + ++ header_delta + entry_delta, item_body_by_coord(coord), ++ (unsigned)size); ++ if (REISER4_DEBUG) ++ memset(item_body_by_coord(coord), 0, ++ (unsigned)header_delta + entry_delta); ++ } else { ++ /* freed space is already at the end of item */ ++ if (REISER4_DEBUG) ++ memset((char *)item_body_by_coord(coord) + size, 0, ++ (unsigned)header_delta + entry_delta); ++ } ++ ++ return header_delta + entry_delta; ++} ++ ++int kill_units_cde(coord_t * coord /* coord of item */ , ++ pos_in_node_t from /* start unit pos */ , ++ pos_in_node_t to /* stop unit pos */ , ++ struct carry_kill_data *kdata UNUSED_ARG, ++ reiser4_key * smallest_removed, reiser4_key * new_first) ++{ ++ return cut_units_cde(coord, from, to, NULL, smallest_removed, new_first); ++} ++ ++/* ->s.dir.extract_key() method for this item plugin. */ ++int extract_key_cde(const coord_t * coord /* coord of item */ , ++ reiser4_key * key /* resulting key */ ) ++{ ++ directory_entry_format *dent; ++ ++ assert("nikita-1155", coord != NULL); ++ assert("nikita-1156", key != NULL); ++ ++ dent = entry_at(coord, idx_of(coord)); ++ return extract_key_from_id(&dent->id, key); ++} ++ ++int ++update_key_cde(const coord_t * coord, const reiser4_key * key, ++ lock_handle * lh UNUSED_ARG) ++{ ++ directory_entry_format *dent; ++ obj_key_id obj_id; ++ int result; ++ ++ assert("nikita-2344", coord != NULL); ++ assert("nikita-2345", key != NULL); ++ ++ dent = entry_at(coord, idx_of(coord)); ++ result = build_obj_key_id(key, &obj_id); ++ if (result == 0) { ++ dent->id = obj_id; ++ znode_make_dirty(coord->node); ++ } ++ return 0; ++} ++ ++/* ->s.dir.extract_name() method for this item plugin. */ ++char *extract_name_cde(const coord_t * coord /* coord of item */ , char *buf) ++{ ++ directory_entry_format *dent; ++ ++ assert("nikita-1157", coord != NULL); ++ ++ dent = entry_at(coord, idx_of(coord)); ++ return extract_dent_name(coord, dent, buf); ++} ++ ++static int cde_bytes(int pasting, const reiser4_item_data * data) ++{ ++ int result; ++ ++ result = data->length; ++ if (!pasting) ++ result -= sizeof(cde_item_format); ++ return result; ++} ++ ++/* ->s.dir.add_entry() method for this item plugin */ ++int add_entry_cde(struct inode *dir /* directory object */ , ++ coord_t * coord /* coord of item */ , ++ lock_handle * lh /* lock handle for insertion */ , ++ const struct dentry *name /* name to insert */ , ++ reiser4_dir_entry_desc * dir_entry /* parameters of new ++ * directory entry */ ) ++{ ++ reiser4_item_data data; ++ struct cde_entry entry; ++ struct cde_entry_data edata; ++ int result; ++ ++ assert("nikita-1656", coord->node == lh->node); ++ assert("nikita-1657", znode_is_write_locked(coord->node)); ++ ++ edata.num_of_entries = 1; ++ edata.entry = &entry; ++ ++ entry.dir = dir; ++ entry.obj = dir_entry->obj; ++ entry.name = &name->d_name; ++ ++ data.data = (char *)&edata; ++ data.user = 0; /* &edata is not user space */ ++ data.iplug = item_plugin_by_id(COMPOUND_DIR_ID); ++ data.arg = dir_entry; ++ assert("nikita-1302", data.iplug != NULL); ++ ++ result = is_dot_key(&dir_entry->key); ++ data.length = estimate_cde(result ? coord : NULL, &data); ++ ++ inode_add_bytes(dir, cde_bytes(result, &data)); ++ ++ if (result) ++ result = insert_by_coord(coord, &data, &dir_entry->key, lh, 0); ++ else ++ result = reiser4_resize_item(coord, &data, &dir_entry->key, ++ lh, 0); ++ return result; ++} ++ ++/* ->s.dir.rem_entry() */ ++int rem_entry_cde(struct inode *dir /* directory of item */ , ++ const struct qstr *name, coord_t * coord /* coord of item */ , ++ lock_handle * lh UNUSED_ARG /* lock handle for ++ * removal */ , ++ reiser4_dir_entry_desc * entry UNUSED_ARG /* parameters of ++ * directory entry ++ * being removed */ ) ++{ ++ coord_t shadow; ++ int result; ++ int length; ++ ON_DEBUG(char buf[DE_NAME_BUF_LEN]); ++ ++ assert("nikita-2870", strlen(name->name) == name->len); ++ assert("nikita-2869", ++ !strcmp(name->name, extract_name_cde(coord, buf))); ++ ++ length = sizeof(directory_entry_format) + sizeof(cde_unit_header); ++ if (is_longname(name->name, name->len)) ++ length += name->len + 1; ++ ++ if (inode_get_bytes(dir) < length) { ++ warning("nikita-2628", "Dir is broke: %llu: %llu", ++ (unsigned long long)get_inode_oid(dir), ++ inode_get_bytes(dir)); ++ ++ return RETERR(-EIO); ++ } ++ ++ /* cut_node() is supposed to take pointers to _different_ ++ coords, because it will modify them without respect to ++ possible aliasing. To work around this, create temporary copy ++ of @coord. ++ */ ++ coord_dup(&shadow, coord); ++ result = ++ kill_node_content(coord, &shadow, NULL, NULL, NULL, NULL, NULL, 0); ++ if (result == 0) { ++ inode_sub_bytes(dir, length); ++ } ++ return result; ++} ++ ++/* ->s.dir.max_name_len() method for this item plugin */ ++int max_name_len_cde(const struct inode *dir /* directory */ ) ++{ ++ return meta_subvol_tree()->nplug->max_item_size() - ++ sizeof(directory_entry_format) - sizeof(cde_item_format) - ++ sizeof(cde_unit_header) - 2; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/cde.h linux-5.10.2/fs/reiser4/plugin/item/cde.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/cde.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/cde.h 2020-12-23 16:07:46.126813246 +0100 +@@ -0,0 +1,87 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Compound directory item. See cde.c for description. */ ++ ++#if !defined( __FS_REISER4_PLUGIN_COMPRESSED_DE_H__ ) ++#define __FS_REISER4_PLUGIN_COMPRESSED_DE_H__ ++ ++#include "../../forward.h" ++#include "../../kassign.h" ++#include "../../dformat.h" ++ ++#include /* for struct inode */ ++#include /* for struct dentry, etc */ ++ ++typedef struct cde_unit_header { ++ de_id hash; ++ d16 offset; ++} cde_unit_header; ++ ++typedef struct cde_item_format { ++ d16 num_of_entries; ++ cde_unit_header entry[0]; ++} cde_item_format; ++ ++struct cde_entry { ++ const struct inode *dir; ++ const struct inode *obj; ++ const struct qstr *name; ++}; ++ ++struct cde_entry_data { ++ int num_of_entries; ++ struct cde_entry *entry; ++}; ++ ++/* plugin->item.b.* */ ++reiser4_key *max_key_inside_cde(const coord_t * coord, reiser4_key * result); ++int can_contain_key_cde(const coord_t * coord, const reiser4_key * key, ++ const reiser4_item_data *); ++int mergeable_cde(const coord_t * p1, const coord_t * p2); ++pos_in_node_t nr_units_cde(const coord_t * coord); ++reiser4_key *unit_key_cde(const coord_t * coord, reiser4_key * key); ++int estimate_cde(const coord_t * coord, const reiser4_item_data * data); ++void print_cde(const char *prefix, coord_t * coord); ++int init_cde(coord_t * coord, coord_t * from, reiser4_item_data * data); ++lookup_result lookup_cde(const reiser4_key * key, lookup_bias bias, ++ coord_t * coord); ++int paste_cde(coord_t * coord, reiser4_item_data * data, ++ carry_plugin_info * info UNUSED_ARG); ++int can_shift_cde(unsigned free_space, coord_t * coord, znode * target, ++ shift_direction pend, unsigned *size, unsigned want); ++void copy_units_cde(coord_t * target, coord_t * source, unsigned from, ++ unsigned count, shift_direction where_is_free_space, ++ unsigned free_space); ++int cut_units_cde(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++int kill_units_cde(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++void print_cde(const char *prefix, coord_t * coord); ++int reiser4_check_cde(const coord_t * coord, const char **error); ++ ++/* plugin->u.item.s.dir.* */ ++int extract_key_cde(const coord_t * coord, reiser4_key * key); ++int update_key_cde(const coord_t * coord, const reiser4_key * key, ++ lock_handle * lh); ++char *extract_name_cde(const coord_t * coord, char *buf); ++int add_entry_cde(struct inode *dir, coord_t * coord, ++ lock_handle * lh, const struct dentry *name, ++ reiser4_dir_entry_desc * entry); ++int rem_entry_cde(struct inode *dir, const struct qstr *name, coord_t * coord, ++ lock_handle * lh, reiser4_dir_entry_desc * entry); ++int max_name_len_cde(const struct inode *dir); ++ ++/* __FS_REISER4_PLUGIN_COMPRESSED_DE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/ctail.c linux-5.10.2/fs/reiser4/plugin/item/ctail.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/ctail.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/ctail.c 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,1747 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* ctails (aka "clustered tails") are items for cryptcompress objects */ ++ ++/* DESCRIPTION: ++ ++Each cryptcompress object is stored on disk as a set of clusters sliced ++into ctails. ++ ++Internal on-disk structure: ++ ++ HEADER (1) Here stored disk cluster shift ++ BODY ++*/ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "item.h" ++#include "../node/node.h" ++#include "../plugin.h" ++#include "../object.h" ++#include "../../znode.h" ++#include "../../carry.h" ++#include "../../tree.h" ++#include "../../inode.h" ++#include "../../super.h" ++#include "../../context.h" ++#include "../../page_cache.h" ++#include "../cluster.h" ++#include "../../flush.h" ++#include "../../tree_walk.h" ++ ++#include ++#include ++#include ++ ++/* return body of ctail item at @coord */ ++static ctail_item_format *ctail_formatted_at(const coord_t * coord) ++{ ++ assert("edward-60", coord != NULL); ++ return item_body_by_coord(coord); ++} ++ ++static int cluster_shift_by_coord(const coord_t * coord) ++{ ++ return get_unaligned(&ctail_formatted_at(coord)->cluster_shift); ++} ++ ++static inline void dclust_set_extension_shift(hint_t * hint) ++{ ++ assert("edward-1270", ++ item_id_by_coord(&hint->ext_coord.coord) == CTAIL_ID); ++ hint->ext_coord.extension.ctail.shift = ++ cluster_shift_by_coord(&hint->ext_coord.coord); ++} ++ ++static loff_t off_by_coord(const coord_t * coord) ++{ ++ reiser4_key key; ++ return get_key_offset(item_key_by_coord(coord, &key)); ++} ++ ++int coord_is_unprepped_ctail(const coord_t * coord) ++{ ++ assert("edward-1233", coord != NULL); ++ assert("edward-1234", item_id_by_coord(coord) == CTAIL_ID); ++ assert("edward-1235", ++ ergo((int)cluster_shift_by_coord(coord) == (int)UCTAIL_SHIFT, ++ nr_units_ctail(coord) == (pos_in_node_t) UCTAIL_NR_UNITS)); ++ ++ return (int)cluster_shift_by_coord(coord) == (int)UCTAIL_SHIFT; ++} ++ ++static cloff_t clust_by_coord(const coord_t * coord, struct inode *inode) ++{ ++ int shift; ++ ++ if (inode != NULL) { ++ shift = inode_cluster_shift(inode); ++ assert("edward-1236", ++ ergo(!coord_is_unprepped_ctail(coord), ++ shift == cluster_shift_by_coord(coord))); ++ } else { ++ assert("edward-1237", !coord_is_unprepped_ctail(coord)); ++ shift = cluster_shift_by_coord(coord); ++ } ++ return off_by_coord(coord) >> shift; ++} ++ ++static int disk_cluster_size(const coord_t * coord) ++{ ++ assert("edward-1156", ++ item_plugin_by_coord(coord) == item_plugin_by_id(CTAIL_ID)); ++ /* calculation of disk cluster size ++ is meaninless if ctail is unprepped */ ++ assert("edward-1238", !coord_is_unprepped_ctail(coord)); ++ ++ return 1 << cluster_shift_by_coord(coord); ++} ++ ++/* true if the key is of first disk cluster item */ ++static int is_disk_cluster_key(const reiser4_key * key, const coord_t * coord) ++{ ++ assert("edward-1239", item_id_by_coord(coord) == CTAIL_ID); ++ ++ return coord_is_unprepped_ctail(coord) || ++ ((get_key_offset(key) & ++ ((loff_t) disk_cluster_size(coord) - 1)) == 0); ++} ++ ++static char *first_unit(coord_t * coord) ++{ ++ /* FIXME: warning: pointer of type `void *' used in arithmetic */ ++ return (char *)item_body_by_coord(coord) + sizeof(ctail_item_format); ++} ++ ++/* plugin->u.item.b.max_key_inside : ++ tail_max_key_inside */ ++ ++/* plugin->u.item.b.can_contain_key */ ++int can_contain_key_ctail(const coord_t * coord, const reiser4_key * key, ++ const reiser4_item_data * data) ++{ ++ reiser4_key item_key; ++ ++ if (item_plugin_by_coord(coord) != data->iplug) ++ return 0; ++ ++ item_key_by_coord(coord, &item_key); ++ if (get_key_locality(key) != get_key_locality(&item_key) || ++ get_key_objectid(key) != get_key_objectid(&item_key)) ++ return 0; ++ if (get_key_offset(&item_key) + nr_units_ctail(coord) != ++ get_key_offset(key)) ++ return 0; ++ if (is_disk_cluster_key(key, coord)) ++ /* ++ * can not merge at the beginning ++ * of a logical cluster in a file ++ */ ++ return 0; ++ return 1; ++} ++ ++/* plugin->u.item.b.mergeable */ ++int mergeable_ctail(const coord_t * p1, const coord_t * p2) ++{ ++ reiser4_key key1, key2; ++ ++ assert("edward-62", item_id_by_coord(p1) == CTAIL_ID); ++ assert("edward-61", plugin_of_group(item_plugin_by_coord(p1), ++ FILE_BODY_ITEM_TYPE)); ++ ++ if (item_id_by_coord(p2) != CTAIL_ID) { ++ /* second item is of another type */ ++ return 0; ++ } ++ item_key_by_coord(p1, &key1); ++ item_key_by_coord(p2, &key2); ++ if (get_key_locality(&key1) != get_key_locality(&key2) || ++ get_key_objectid(&key1) != get_key_objectid(&key2) || ++ get_key_type(&key1) != get_key_type(&key2)) { ++ /* items of different objects */ ++ return 0; ++ } ++ if (get_key_offset(&key1) + nr_units_ctail(p1) != get_key_offset(&key2)) ++ /* not adjacent items */ ++ return 0; ++ if (is_disk_cluster_key(&key2, p2)) ++ /* ++ * can not merge at the beginning ++ * of a logical cluster in a file ++ */ ++ return 0; ++ return 1; ++} ++ ++/* plugin->u.item.b.nr_units */ ++pos_in_node_t nr_units_ctail(const coord_t * coord) ++{ ++ return (item_length_by_coord(coord) - ++ sizeof(ctail_formatted_at(coord)->cluster_shift)); ++} ++ ++/* plugin->u.item.b.estimate: ++ estimate how much space is needed to insert/paste @data->length bytes ++ into ctail at @coord */ ++int estimate_ctail(const coord_t * coord /* coord of item */ , ++ const reiser4_item_data * ++ data /* parameters for new item */ ) ++{ ++ if (coord == NULL) ++ /* insert */ ++ return (sizeof(ctail_item_format) + data->length); ++ else ++ /* paste */ ++ return data->length; ++} ++ ++/* ->init() method for this item plugin. */ ++int init_ctail(coord_t * to /* coord of item */ , ++ coord_t * from /* old_item */ , ++ reiser4_item_data * data /* structure used for insertion */ ) ++{ ++ int cluster_shift; /* cpu value to convert */ ++ ++ if (data) { ++ assert("edward-463", data->length > sizeof(ctail_item_format)); ++ cluster_shift = *((int *)(data->arg)); ++ data->length -= sizeof(ctail_item_format); ++ } else { ++ assert("edward-464", from != NULL); ++ assert("edward-855", ctail_ok(from)); ++ cluster_shift = (int)(cluster_shift_by_coord(from)); ++ } ++ put_unaligned((d8)cluster_shift, &ctail_formatted_at(to)->cluster_shift); ++ assert("edward-856", ctail_ok(to)); ++ return 0; ++} ++ ++/* plugin->u.item.b.lookup: ++ NULL: We are looking for item keys only */ ++ ++#if REISER4_DEBUG ++int ctail_ok(const coord_t * coord) ++{ ++ return coord_is_unprepped_ctail(coord) || ++ cluster_shift_ok(cluster_shift_by_coord(coord)); ++} ++ ++/* plugin->u.item.b.check */ ++int check_ctail(const coord_t * coord, const char **error) ++{ ++ if (!ctail_ok(coord)) { ++ if (error) ++ *error = "bad cluster shift in ctail"; ++ return 1; ++ } ++ return 0; ++} ++#endif ++ ++/* plugin->u.item.b.paste */ ++int ++paste_ctail(coord_t * coord, reiser4_item_data * data, ++ carry_plugin_info * info UNUSED_ARG) ++{ ++ unsigned old_nr_units; ++ ++ assert("edward-268", data->data != NULL); ++ /* copy only from kernel space */ ++ assert("edward-66", data->user == 0); ++ ++ old_nr_units = ++ item_length_by_coord(coord) - sizeof(ctail_item_format) - ++ data->length; ++ ++ /* ctail items never get pasted in the middle */ ++ ++ if (coord->unit_pos == 0 && coord->between == AT_UNIT) { ++ ++ /* paste at the beginning when create new item */ ++ assert("edward-450", ++ item_length_by_coord(coord) == ++ data->length + sizeof(ctail_item_format)); ++ assert("edward-451", old_nr_units == 0); ++ } else if (coord->unit_pos == old_nr_units - 1 ++ && coord->between == AFTER_UNIT) { ++ ++ /* paste at the end */ ++ coord->unit_pos++; ++ } else ++ impossible("edward-453", "bad paste position"); ++ ++ memcpy(first_unit(coord) + coord->unit_pos, data->data, data->length); ++ ++ assert("edward-857", ctail_ok(coord)); ++ ++ return 0; ++} ++ ++/* plugin->u.item.b.fast_paste */ ++ ++/* ++ * plugin->u.item.b.can_shift ++ * ++ * Return number of units that can be shifted; ++ * Store space (in bytes) occupied by those units in @size. ++ */ ++int can_shift_ctail(unsigned free_space, coord_t *source, ++ znode * target, shift_direction direction UNUSED_ARG, ++ unsigned *size, unsigned want) ++{ ++ /* make sure that that we do not want to shift more than we have */ ++ assert("edward-68", want > 0 && want <= nr_units_ctail(source)); ++ ++ *size = min(want, free_space); ++ ++ if (!target) { ++ /* ++ * new item will be created ++ */ ++ if (*size <= sizeof(ctail_item_format)) { ++ /* ++ * can not shift only ctail header ++ */ ++ *size = 0; ++ return 0; ++ } ++ return *size - sizeof(ctail_item_format); ++ } ++ else ++ /* ++ * shifting to the mergeable item ++ */ ++ return *size; ++} ++ ++/* ++ * plugin->u.item.b.copy_units ++ * cooperates with ->can_shift() ++ */ ++void copy_units_ctail(coord_t * target, coord_t * source, ++ unsigned from, unsigned count /* units */ , ++ shift_direction where_is_free_space, ++ unsigned free_space /* bytes */ ) ++{ ++ /* make sure that item @target is expanded already */ ++ assert("edward-69", (unsigned)item_length_by_coord(target) >= count); ++ assert("edward-70", free_space == count || free_space == count + 1); ++ ++ assert("edward-858", ctail_ok(source)); ++ ++ if (where_is_free_space == SHIFT_LEFT) { ++ /* ++ * append item @target with @count first bytes ++ * of @source: this restriction came from ordinary tails ++ */ ++ assert("edward-71", from == 0); ++ assert("edward-860", ctail_ok(target)); ++ ++ memcpy(first_unit(target) + nr_units_ctail(target) - count, ++ first_unit(source), count); ++ } else { ++ /* ++ * target item is moved to right already ++ */ ++ reiser4_key key; ++ ++ assert("edward-72", nr_units_ctail(source) == from + count); ++ ++ if (free_space == count) { ++ init_ctail(target, source, NULL); ++ } else { ++ /* ++ * shifting to a mergeable item ++ */ ++ assert("edward-862", ctail_ok(target)); ++ } ++ memcpy(first_unit(target), first_unit(source) + from, count); ++ ++ assert("edward-863", ctail_ok(target)); ++ /* ++ * new units are inserted before first unit ++ * in an item, therefore, we have to update ++ * item key ++ */ ++ item_key_by_coord(source, &key); ++ set_key_offset(&key, get_key_offset(&key) + from); ++ ++ node_plugin_by_node(target->node)->update_item_key(target, ++ &key, ++ NULL /*info */); ++ } ++} ++ ++/* plugin->u.item.b.create_hook */ ++int create_hook_ctail(const coord_t * coord, void *arg) ++{ ++ assert("edward-864", znode_is_loaded(coord->node)); ++ ++ znode_set_convertible(coord->node); ++ return 0; ++} ++ ++/* plugin->u.item.b.kill_hook */ ++int kill_hook_ctail(const coord_t * coord, pos_in_node_t from, ++ pos_in_node_t count, carry_kill_data * kdata) ++{ ++ struct inode *inode; ++ ++ assert("edward-1157", item_id_by_coord(coord) == CTAIL_ID); ++ assert("edward-291", znode_is_write_locked(coord->node)); ++ ++ inode = kdata->inode; ++ if (inode) { ++ reiser4_key key; ++ struct cryptcompress_info * info; ++ cloff_t index; ++ ++ item_key_by_coord(coord, &key); ++ info = cryptcompress_inode_data(inode); ++ index = off_to_clust(get_key_offset(&key), inode); ++ ++ if (from == 0) { ++ info->trunc_index = index; ++ if (is_disk_cluster_key(&key, coord)) { ++ /* ++ * first item of disk cluster is to be killed ++ */ ++ truncate_complete_page_cluster( ++ inode, index, kdata->params.truncate); ++ inode_sub_bytes(inode, ++ inode_cluster_size(inode)); ++ } ++ } ++ } ++ return 0; ++} ++ ++/* for shift_hook_ctail(), ++ return true if the first disk cluster item has dirty child ++*/ ++static int ctail_convertible(const coord_t * coord) ++{ ++ int result; ++ reiser4_key key; ++ jnode *child = NULL; ++ ++ assert("edward-477", coord != NULL); ++ assert("edward-478", item_id_by_coord(coord) == CTAIL_ID); ++ ++ if (coord_is_unprepped_ctail(coord)) ++ /* unprepped ctail should be converted */ ++ return 1; ++ ++ item_key_by_coord(coord, &key); ++ child = jlookup(get_key_objectid(&key), off_to_pg(off_by_coord(coord))); ++ if (!child) ++ return 0; ++ result = JF_ISSET(child, JNODE_DIRTY); ++ jput(child); ++ return result; ++} ++ ++/* FIXME-EDWARD */ ++/* plugin->u.item.b.shift_hook */ ++int shift_hook_ctail(const coord_t * item /* coord of item */ , ++ unsigned from UNUSED_ARG /* start unit */ , ++ unsigned count UNUSED_ARG /* stop unit */ , ++ znode * old_node /* old parent */ ) ++{ ++ assert("edward-479", item != NULL); ++ assert("edward-480", item->node != old_node); ++ ++ if (!znode_convertible(old_node) || znode_convertible(item->node)) ++ return 0; ++ if (ctail_convertible(item)) ++ znode_set_convertible(item->node); ++ return 0; ++} ++ ++static int ++cut_or_kill_ctail_units(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ int cut, void *p, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ pos_in_node_t count; /* number of units to cut */ ++ char *item; ++ ++ count = to - from + 1; ++ item = item_body_by_coord(coord); ++ ++ assert("edward-74", ergo(from != 0, to == coord_last_unit_pos(coord))); ++ ++ if (smallest_removed) { ++ /* store smallest key removed */ ++ item_key_by_coord(coord, smallest_removed); ++ set_key_offset(smallest_removed, ++ get_key_offset(smallest_removed) + from); ++ } ++ ++ if (new_first) { ++ assert("vs-1531", from == 0); ++ ++ item_key_by_coord(coord, new_first); ++ set_key_offset(new_first, ++ get_key_offset(new_first) + from + count); ++ } ++ ++ if (!cut) ++ kill_hook_ctail(coord, from, 0, (struct carry_kill_data *)p); ++ ++ if (from == 0) { ++ if (count != nr_units_ctail(coord)) { ++ /* part of item is removed, so move free space at the beginning ++ of the item and update item key */ ++ reiser4_key key; ++ memcpy(item + to + 1, item, sizeof(ctail_item_format)); ++ item_key_by_coord(coord, &key); ++ set_key_offset(&key, get_key_offset(&key) + count); ++ node_plugin_by_node(coord->node)->update_item_key(coord, ++ &key, ++ NULL); ++ } else { ++ /* cut_units should not be called to cut evrything */ ++ assert("vs-1532", ergo(cut, 0)); ++ /* whole item is cut, so more then amount of space occupied ++ by units got freed */ ++ count += sizeof(ctail_item_format); ++ } ++ } ++ return count; ++} ++ ++/* plugin->u.item.b.cut_units */ ++int ++cut_units_ctail(coord_t * item, pos_in_node_t from, pos_in_node_t to, ++ carry_cut_data * cdata, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ return cut_or_kill_ctail_units(item, from, to, 1, NULL, ++ smallest_removed, new_first); ++} ++ ++/* plugin->u.item.b.kill_units */ ++int ++kill_units_ctail(coord_t * item, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *kdata, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ return cut_or_kill_ctail_units(item, from, to, 0, kdata, ++ smallest_removed, new_first); ++} ++ ++/* plugin->u.item.s.file.read */ ++int read_ctail(struct file *file UNUSED_ARG, flow_t * f, hint_t * hint) ++{ ++ uf_coord_t *uf_coord; ++ coord_t *coord; ++ ++ uf_coord = &hint->ext_coord; ++ coord = &uf_coord->coord; ++ assert("edward-127", f->user == 0); ++ assert("edward-129", coord && coord->node); ++ assert("edward-130", coord_is_existing_unit(coord)); ++ assert("edward-132", znode_is_loaded(coord->node)); ++ ++ /* start read only from the beginning of ctail */ ++ assert("edward-133", coord->unit_pos == 0); ++ /* read only whole ctails */ ++ assert("edward-135", nr_units_ctail(coord) <= f->length); ++ ++ assert("edward-136", reiser4_schedulable()); ++ assert("edward-886", ctail_ok(coord)); ++ ++ if (f->data) ++ memcpy(f->data, (char *)first_unit(coord), ++ (size_t) nr_units_ctail(coord)); ++ ++ dclust_set_extension_shift(hint); ++ mark_page_accessed(znode_page(coord->node)); ++ move_flow_forward(f, nr_units_ctail(coord)); ++ ++ return 0; ++} ++ ++/** ++ * Prepare transform stream with plain text for page ++ * @page taking into account synchronization issues. ++ */ ++static int ctail_read_disk_cluster(struct cluster_handle * clust, ++ struct inode * inode, struct page * page, ++ znode_lock_mode mode) ++{ ++ int result; ++ ++ assert("edward-1450", mode == ZNODE_READ_LOCK || ZNODE_WRITE_LOCK); ++ assert("edward-671", clust->hint != NULL); ++ assert("edward-140", clust->dstat == INVAL_DISK_CLUSTER); ++ assert("edward-672", cryptcompress_inode_ok(inode)); ++ assert("edward-1527", PageLocked(page)); ++ ++ unlock_page(page); ++ ++ /* set input stream */ ++ result = grab_tfm_stream(inode, &clust->tc, INPUT_STREAM); ++ if (result) { ++ lock_page(page); ++ return result; ++ } ++ result = find_disk_cluster(clust, inode, 1 /* read items */, mode); ++ lock_page(page); ++ if (result) ++ return result; ++ /* ++ * at this point we have locked position in the tree ++ */ ++ assert("edward-1528", znode_is_any_locked(clust->hint->lh.node)); ++ ++ if (page->mapping != inode->i_mapping) { ++ /* page was truncated */ ++ reiser4_unset_hint(clust->hint); ++ reset_cluster_params(clust); ++ return AOP_TRUNCATED_PAGE; ++ } ++ if (PageUptodate(page)) { ++ /* disk cluster can be obsolete, don't use it! */ ++ reiser4_unset_hint(clust->hint); ++ reset_cluster_params(clust); ++ return 0; ++ } ++ if (clust->dstat == FAKE_DISK_CLUSTER || ++ clust->dstat == UNPR_DISK_CLUSTER || ++ clust->dstat == TRNC_DISK_CLUSTER) { ++ /* ++ * this information about disk cluster will be valid ++ * as long as we keep the position in the tree locked ++ */ ++ tfm_cluster_set_uptodate(&clust->tc); ++ return 0; ++ } ++ /* now prepare output stream.. */ ++ result = grab_coa(&clust->tc, inode_compression_plugin(inode)); ++ if (result) ++ return result; ++ /* ..and fill this with plain text */ ++ result = reiser4_inflate_cluster(clust, inode); ++ if (result) ++ return result; ++ /* ++ * The stream is ready! It won't be obsolete as ++ * long as we keep last disk cluster item locked. ++ */ ++ tfm_cluster_set_uptodate(&clust->tc); ++ return 0; ++} ++ ++/* ++ * fill one page with plain text. ++ */ ++int do_readpage_ctail(struct inode * inode, struct cluster_handle * clust, ++ struct page *page, znode_lock_mode mode) ++{ ++ int ret; ++ unsigned cloff; ++ char *data; ++ size_t to_page; ++ struct tfm_cluster * tc = &clust->tc; ++ ++ assert("edward-212", PageLocked(page)); ++ ++ if (unlikely(page->mapping != inode->i_mapping)) ++ return AOP_TRUNCATED_PAGE; ++ if (PageUptodate(page)) ++ goto exit; ++ to_page = pbytes(page_index(page), inode); ++ if (to_page == 0) { ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ goto exit; ++ } ++ if (!tfm_cluster_is_uptodate(&clust->tc)) { ++ clust->index = pg_to_clust(page->index, inode); ++ ++ /* this will unlock/lock the page */ ++ ret = ctail_read_disk_cluster(clust, inode, page, mode); ++ ++ assert("edward-212", PageLocked(page)); ++ if (ret) ++ return ret; ++ ++ /* refresh bytes */ ++ to_page = pbytes(page_index(page), inode); ++ if (to_page == 0) { ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ goto exit; ++ } ++ } ++ if (PageUptodate(page)) ++ /* somebody else fill it already */ ++ goto exit; ++ ++ assert("edward-119", tfm_cluster_is_uptodate(tc)); ++ assert("edward-1529", znode_is_any_locked(clust->hint->lh.node)); ++ ++ switch (clust->dstat) { ++ case UNPR_DISK_CLUSTER: ++ /* ++ * Page is not uptodate and item cluster is unprepped: ++ * this must not ever happen. ++ */ ++ warning("edward-1632", ++ "Bad item cluster %lu (Inode %llu). Fsck?", ++ clust->index, ++ (unsigned long long)get_inode_oid(inode)); ++ return RETERR(-EIO); ++ case TRNC_DISK_CLUSTER: ++ /* ++ * Race with truncate! ++ * We resolve it in favour of the last one (the only way, ++ * as in this case plain text is unrecoverable) ++ */ ++ case FAKE_DISK_CLUSTER: ++ /* fill the page by zeroes */ ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ break; ++ case PREP_DISK_CLUSTER: ++ /* fill page by transformed stream with plain text */ ++ assert("edward-1058", !PageUptodate(page)); ++ assert("edward-120", tc->len <= inode_cluster_size(inode)); ++ ++ /* page index in this logical cluster */ ++ cloff = pg_to_off_to_cloff(page->index, inode); ++ ++ data = kmap(page); ++ memcpy(data, tfm_stream_data(tc, OUTPUT_STREAM) + cloff, to_page); ++ memset(data + to_page, 0, (size_t) PAGE_SIZE - to_page); ++ flush_dcache_page(page); ++ kunmap(page); ++ SetPageUptodate(page); ++ break; ++ default: ++ impossible("edward-1169", "bad disk cluster state"); ++ } ++ exit: ++ return 0; ++} ++ ++/* plugin->u.item.s.file.readpage */ ++int readpage_ctail(void *vp, struct page *page) ++{ ++ int result; ++ hint_t * hint; ++ struct cluster_handle * clust = vp; ++ ++ assert("edward-114", clust != NULL); ++ assert("edward-115", PageLocked(page)); ++ assert("edward-116", !PageUptodate(page)); ++ assert("edward-118", page->mapping && page->mapping->host); ++ assert("edward-867", !tfm_cluster_is_uptodate(&clust->tc)); ++ ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) { ++ unlock_page(page); ++ return RETERR(-ENOMEM); ++ } ++ clust->hint = hint; ++ result = load_file_hint(clust->file, hint); ++ if (result) { ++ kfree(hint); ++ unlock_page(page); ++ return result; ++ } ++ assert("vs-25", hint->ext_coord.lh == &hint->lh); ++ ++ result = do_readpage_ctail(page->mapping->host, clust, page, ++ ZNODE_READ_LOCK); ++ assert("edward-213", PageLocked(page)); ++ assert("edward-1163", ergo(!result, PageUptodate(page))); ++ ++ unlock_page(page); ++ done_lh(&hint->lh); ++ hint->ext_coord.valid = 0; ++ save_file_hint(clust->file, hint); ++ kfree(hint); ++ tfm_cluster_clr_uptodate(&clust->tc); ++ ++ return result; ++} ++ ++/* Helper function for ->readpages() */ ++static int ctail_read_page_cluster(struct cluster_handle * clust, ++ struct inode *inode) ++{ ++ int i; ++ int result; ++ assert("edward-779", clust != NULL); ++ assert("edward-1059", clust->win == NULL); ++ assert("edward-780", inode != NULL); ++ ++ result = prepare_page_cluster(inode, clust, READ_OP); ++ if (result) ++ return result; ++ ++ assert("edward-781", !tfm_cluster_is_uptodate(&clust->tc)); ++ ++ for (i = 0; i < clust->nr_pages; i++) { ++ struct page *page = clust->pages[i]; ++ lock_page(page); ++ result = do_readpage_ctail(inode, clust, page, ZNODE_READ_LOCK); ++ unlock_page(page); ++ if (result) ++ break; ++ } ++ tfm_cluster_clr_uptodate(&clust->tc); ++ put_page_cluster(clust, inode, READ_OP); ++ return result; ++} ++ ++/* filler for read_cache_pages() */ ++static int ctail_readpages_filler(void * data, struct page * page) ++{ ++ int ret = 0; ++ struct cluster_handle * clust = data; ++ struct inode * inode = file_inode(clust->file); ++ ++ assert("edward-1525", page->mapping == inode->i_mapping); ++ ++ if (PageUptodate(page)) { ++ unlock_page(page); ++ return 0; ++ } ++ if (pbytes(page_index(page), inode) == 0) { ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ unlock_page(page); ++ return 0; ++ } ++ move_cluster_forward(clust, inode, page->index); ++ unlock_page(page); ++ /* ++ * read the whole page cluster ++ */ ++ ret = ctail_read_page_cluster(clust, inode); ++ ++ assert("edward-869", !tfm_cluster_is_uptodate(&clust->tc)); ++ return ret; ++} ++ ++/* ++ * We populate a bit more then upper readahead suggests: ++ * with each nominated page we read the whole page cluster ++ * this page belongs to. ++ */ ++int readpages_ctail(struct file *file, struct address_space *mapping, ++ struct list_head *pages) ++{ ++ int ret = 0; ++ hint_t *hint; ++ struct cluster_handle clust; ++ struct inode *inode = mapping->host; ++ ++ assert("edward-1521", inode == file_inode(file)); ++ ++ cluster_init_read(&clust, NULL); ++ clust.file = file; ++ hint = kmalloc(sizeof(*hint), reiser4_ctx_gfp_mask_get()); ++ if (hint == NULL) { ++ warning("vs-28", "failed to allocate hint"); ++ ret = RETERR(-ENOMEM); ++ goto exit1; ++ } ++ clust.hint = hint; ++ ret = load_file_hint(clust.file, hint); ++ if (ret) { ++ warning("edward-1522", "failed to load hint"); ++ goto exit2; ++ } ++ assert("vs-26", hint->ext_coord.lh == &hint->lh); ++ ret = alloc_cluster_pgset(&clust, cluster_nrpages(inode)); ++ if (ret) { ++ warning("edward-1523", "failed to alloc pgset"); ++ goto exit3; ++ } ++ ret = read_cache_pages(mapping, pages, ctail_readpages_filler, &clust); ++ ++ assert("edward-870", !tfm_cluster_is_uptodate(&clust.tc)); ++ exit3: ++ done_lh(&hint->lh); ++ save_file_hint(file, hint); ++ hint->ext_coord.valid = 0; ++ exit2: ++ kfree(hint); ++ exit1: ++ put_cluster_handle(&clust); ++ return ret; ++} ++ ++reiser4_key *append_key_ctail(const coord_t *coord, reiser4_key *key) ++{ ++ assert("edward-1241", item_id_by_coord(coord) == CTAIL_ID); ++ assert("edward-1242", cluster_shift_ok(cluster_shift_by_coord(coord))); ++ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, ((__u64) (clust_by_coord(coord, NULL)) + 1) ++ << cluster_shift_by_coord(coord)); ++ return key; ++} ++ ++static int insert_unprepped_ctail(struct cluster_handle * clust, ++ struct inode *inode) ++{ ++ int result; ++ char buf[UCTAIL_NR_UNITS]; ++ reiser4_item_data data; ++ reiser4_key key; ++ int shift = (int)UCTAIL_SHIFT; ++ ++ memset(buf, 0, (size_t) UCTAIL_NR_UNITS); ++ result = build_body_key_cryptcompress(inode, ++ clust_to_off(clust->index, inode), ++ &key); ++ if (result) ++ return result; ++ data.user = 0; ++ data.iplug = item_plugin_by_id(CTAIL_ID); ++ data.arg = &shift; ++ data.length = sizeof(ctail_item_format) + (size_t) UCTAIL_NR_UNITS; ++ data.data = buf; ++ ++ result = insert_by_coord(&clust->hint->ext_coord.coord, ++ &data, &key, clust->hint->ext_coord.lh, 0); ++ return result; ++} ++ ++static int ++insert_cryptcompress_flow(coord_t * coord, lock_handle * lh, flow_t * f, ++ int cluster_shift) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ reiser4_item_data *data; ++ carry_op *op; ++ ++ pool = ++ init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(*data)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ data = (reiser4_item_data *) (lowest_level + 3); ++ ++ assert("edward-466", coord->between == AFTER_ITEM ++ || coord->between == AFTER_UNIT || coord->between == BEFORE_ITEM ++ || coord->between == EMPTY_NODE ++ || coord->between == BEFORE_UNIT); ++ ++ if (coord->between == AFTER_UNIT) { ++ coord->unit_pos = 0; ++ coord->between = AFTER_ITEM; ++ } ++ op = reiser4_post_carry(lowest_level, COP_INSERT_FLOW, coord->node, ++ 0 /* operate directly on coord -> node */); ++ if (IS_ERR(op) || (op == NULL)) { ++ done_carry_pool(pool); ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ } ++ data->user = 0; ++ data->iplug = item_plugin_by_id(CTAIL_ID); ++ data->arg = &cluster_shift; ++ ++ data->length = 0; ++ data->data = NULL; ++ ++ op->u.insert_flow.flags = ++ COPI_SWEEP | ++ COPI_DONT_SHIFT_LEFT | ++ COPI_DONT_SHIFT_RIGHT; ++ op->u.insert_flow.insert_point = coord; ++ op->u.insert_flow.flow = f; ++ op->u.insert_flow.data = data; ++ op->u.insert_flow.new_nodes = 0; ++ ++ lowest_level->track_type = CARRY_TRACK_CHANGE; ++ lowest_level->tracked = lh; ++ ++ result = reiser4_carry(lowest_level, NULL); ++ done_carry_pool(pool); ++ ++ return result; ++} ++ ++/* Implementation of CRC_APPEND_ITEM mode of ctail conversion */ ++static int insert_cryptcompress_flow_in_place(coord_t * coord, ++ lock_handle * lh, flow_t * f, ++ int cluster_shift) ++{ ++ int ret; ++ coord_t pos; ++ lock_handle lock; ++ ++ assert("edward-484", ++ coord->between == AT_UNIT || coord->between == AFTER_ITEM); ++ assert("edward-485", item_id_by_coord(coord) == CTAIL_ID); ++ ++ coord_dup(&pos, coord); ++ pos.unit_pos = 0; ++ pos.between = AFTER_ITEM; ++ ++ init_lh(&lock); ++ copy_lh(&lock, lh); ++ ++ ret = insert_cryptcompress_flow(&pos, &lock, f, cluster_shift); ++ done_lh(&lock); ++ assert("edward-1347", znode_is_write_locked(lh->node)); ++ assert("edward-1228", !ret); ++ return ret; ++} ++ ++/* Implementation of CRC_OVERWRITE_ITEM mode of ctail conversion */ ++static int overwrite_ctail(coord_t * coord, flow_t * f) ++{ ++ unsigned count; ++ ++ assert("edward-269", f->user == 0); ++ assert("edward-270", f->data != NULL); ++ assert("edward-271", f->length > 0); ++ assert("edward-272", coord_is_existing_unit(coord)); ++ assert("edward-273", coord->unit_pos == 0); ++ assert("edward-274", znode_is_write_locked(coord->node)); ++ assert("edward-275", reiser4_schedulable()); ++ assert("edward-467", item_id_by_coord(coord) == CTAIL_ID); ++ assert("edward-1243", ctail_ok(coord)); ++ ++ count = nr_units_ctail(coord); ++ ++ if (count > f->length) ++ count = f->length; ++ memcpy(first_unit(coord), f->data, count); ++ move_flow_forward(f, count); ++ coord->unit_pos += count; ++ return 0; ++} ++ ++/* Implementation of CRC_CUT_ITEM mode of ctail conversion: ++ cut ctail (part or whole) starting from next unit position */ ++static int cut_ctail(coord_t * coord) ++{ ++ coord_t stop; ++ ++ assert("edward-435", coord->between == AT_UNIT && ++ coord->item_pos < coord_num_items(coord) && ++ coord->unit_pos <= coord_num_units(coord)); ++ ++ if (coord->unit_pos == coord_num_units(coord)) ++ /* nothing to cut */ ++ return 0; ++ coord_dup(&stop, coord); ++ stop.unit_pos = coord_last_unit_pos(coord); ++ ++ return cut_node_content(coord, &stop, NULL, NULL, NULL); ++} ++ ++int ctail_insert_unprepped_cluster(struct cluster_handle * clust, ++ struct inode * inode) ++{ ++ int result; ++ assert("edward-1244", inode != NULL); ++ assert("edward-1245", clust->hint != NULL); ++ assert("edward-1246", clust->dstat == FAKE_DISK_CLUSTER); ++ assert("edward-1247", clust->reserved == 1); ++ ++ result = get_disk_cluster_locked(clust, inode, ZNODE_WRITE_LOCK); ++ if (cbk_errored(result)) ++ return result; ++ assert("edward-1249", result == CBK_COORD_NOTFOUND); ++ assert("edward-1250", znode_is_write_locked(clust->hint->lh.node)); ++ ++ assert("edward-1295", ++ clust->hint->ext_coord.lh->node == ++ clust->hint->ext_coord.coord.node); ++ ++ coord_set_between_clusters(&clust->hint->ext_coord.coord); ++ ++ result = insert_unprepped_ctail(clust, inode); ++ all_grabbed2free(); ++ ++ assert("edward-1251", !result); ++ assert("edward-1252", cryptcompress_inode_ok(inode)); ++ assert("edward-1253", znode_is_write_locked(clust->hint->lh.node)); ++ assert("edward-1254", ++ reiser4_subvol_clustered_blocks(get_meta_subvol()) != 0); ++ assert("edward-1255", ++ znode_convertible(clust->hint->ext_coord.coord.node)); ++ ++ return result; ++} ++ ++/* plugin->u.item.f.scan */ ++int scan_ctail(flush_scan * scan) ++{ ++ int result = 0; ++ struct page *page; ++ struct inode *inode; ++ jnode *node = scan->node; ++ ++ assert("edward-227", scan->node != NULL); ++ assert("edward-228", jnode_is_cluster_page(scan->node)); ++ assert("edward-639", znode_is_write_locked(scan->parent_lock.node)); ++ ++ page = jnode_page(node); ++ inode = page->mapping->host; ++ ++ if (!reiser4_scanning_left(scan)) ++ return result; ++ ++ if (!znode_convertible(scan->parent_lock.node)) { ++ if (JF_ISSET(scan->node, JNODE_DIRTY)) ++ znode_set_convertible(scan->parent_lock.node); ++ else { ++ warning("edward-681", ++ "cluster page is already processed"); ++ return -EAGAIN; ++ } ++ } ++ return result; ++} ++ ++/* If true, this function attaches children */ ++static int should_attach_convert_idata(flush_pos_t * pos) ++{ ++ int result; ++ assert("edward-431", pos != NULL); ++ assert("edward-432", pos->child == NULL); ++ assert("edward-619", znode_is_write_locked(pos->coord.node)); ++ assert("edward-470", ++ item_plugin_by_coord(&pos->coord) == ++ item_plugin_by_id(CTAIL_ID)); ++ ++ /* check for leftmost child */ ++ utmost_child_ctail(&pos->coord, LEFT_SIDE, &pos->child); ++ ++ if (!pos->child) ++ return 0; ++ spin_lock_jnode(pos->child); ++ result = (JF_ISSET(pos->child, JNODE_DIRTY) && ++ pos->child->atom == ZJNODE(pos->coord.node)->atom); ++ spin_unlock_jnode(pos->child); ++ if (!result && pos->child) { ++ /* existing child isn't to attach, clear up this one */ ++ jput(pos->child); ++ pos->child = NULL; ++ } ++ return result; ++} ++ ++/** ++ * Collect all needed information about the object here, ++ * as in-memory inode can be evicted from memory before ++ * disk update completion. ++ */ ++static int init_convert_data_ctail(struct convert_item_info * idata, ++ struct inode *inode) ++{ ++ assert("edward-813", idata != NULL); ++ assert("edward-814", inode != NULL); ++ ++ idata->cluster_shift = inode_cluster_shift(inode); ++ idata->d_cur = DC_FIRST_ITEM; ++ idata->d_next = DC_INVALID_STATE; ++ ++ return 0; ++} ++ ++static int alloc_item_convert_data(struct convert_info * sq) ++{ ++ assert("edward-816", sq != NULL); ++ assert("edward-817", sq->itm == NULL); ++ ++ sq->itm = kmalloc(sizeof(*sq->itm), reiser4_ctx_gfp_mask_get()); ++ if (sq->itm == NULL) ++ return RETERR(-ENOMEM); ++ init_lh(&sq->right_lock); ++ sq->right_locked = 0; ++ return 0; ++} ++ ++static void free_item_convert_data(struct convert_info * sq) ++{ ++ assert("edward-818", sq != NULL); ++ assert("edward-819", sq->itm != NULL); ++ assert("edward-820", sq->iplug != NULL); ++ ++ done_lh(&sq->right_lock); ++ sq->right_locked = 0; ++ kfree(sq->itm); ++ sq->itm = NULL; ++ return; ++} ++ ++static struct convert_info *alloc_convert_data(void) ++{ ++ struct convert_info *info; ++ ++ info = kmalloc(sizeof(*info), reiser4_ctx_gfp_mask_get()); ++ if (info != NULL) { ++ memset(info, 0, sizeof(*info)); ++ cluster_init_write(&info->clust, NULL); ++ } ++ return info; ++} ++ ++static void reset_convert_data(struct convert_info *info) ++{ ++ info->clust.tc.hole = 0; ++} ++ ++void free_convert_data(flush_pos_t * pos) ++{ ++ struct convert_info *sq; ++ ++ assert("edward-823", pos != NULL); ++ assert("edward-824", pos->sq != NULL); ++ ++ sq = pos->sq; ++ if (sq->itm) ++ free_item_convert_data(sq); ++ put_cluster_handle(&sq->clust); ++ kfree(pos->sq); ++ pos->sq = NULL; ++ return; ++} ++ ++static int init_item_convert_data(flush_pos_t * pos, struct inode *inode) ++{ ++ struct convert_info *sq; ++ ++ assert("edward-825", pos != NULL); ++ assert("edward-826", pos->sq != NULL); ++ assert("edward-827", item_convert_data(pos) != NULL); ++ assert("edward-828", inode != NULL); ++ ++ sq = pos->sq; ++ memset(sq->itm, 0, sizeof(*sq->itm)); ++ ++ /* iplug->init_convert_data() */ ++ return init_convert_data_ctail(sq->itm, inode); ++} ++ ++/* create and attach disk cluster info used by 'convert' phase of the flush ++ squalloc() */ ++static int attach_convert_idata(flush_pos_t * pos, struct inode *inode) ++{ ++ int ret = 0; ++ struct convert_item_info *info; ++ struct cluster_handle *clust; ++ ++ assert("edward-248", pos != NULL); ++ assert("edward-249", pos->child != NULL); ++ assert("edward-251", inode != NULL); ++ assert("edward-682", cryptcompress_inode_ok(inode)); ++ assert("edward-252", ++ inode_file_plugin(inode) == ++ file_plugin_by_id(CRYPTCOMPRESS_FILE_PLUGIN_ID)); ++ assert("edward-473", ++ item_plugin_by_coord(&pos->coord) == ++ item_plugin_by_id(CTAIL_ID)); ++ ++ if (!pos->sq) { ++ pos->sq = alloc_convert_data(); ++ if (!pos->sq) ++ return RETERR(-ENOMEM); ++ } ++ else ++ reset_convert_data(pos->sq); ++ ++ clust = &pos->sq->clust; ++ ++ ret = set_cluster_by_page(clust, ++ jnode_page(pos->child), ++ MAX_CLUSTER_NRPAGES); ++ if (ret) ++ goto err; ++ ++ assert("edward-829", pos->sq != NULL); ++ assert("edward-250", item_convert_data(pos) == NULL); ++ ++ pos->sq->iplug = item_plugin_by_id(CTAIL_ID); ++ ++ ret = alloc_item_convert_data(pos->sq); ++ if (ret) ++ goto err; ++ ret = init_item_convert_data(pos, inode); ++ if (ret) ++ goto err; ++ info = item_convert_data(pos); ++ ++ ret = checkout_logical_cluster(clust, pos->child, inode); ++ if (ret) ++ goto err; ++ ++ reiser4_deflate_cluster(clust, inode); ++ inc_item_convert_count(pos); ++ ++ /* prepare flow for insertion */ ++ flow_by_inode_cryptcompress(inode, ++ (const char __user *)tfm_stream_data(&clust->tc, ++ OUTPUT_STREAM), ++ 0, /* kernel space */ ++ clust->tc.len, ++ clust_to_off(clust->index, inode), ++ WRITE_OP, &info->flow); ++ if (clust->tc.hole) ++ info->flow.length = 0; ++ ++ jput(pos->child); ++ return 0; ++ err: ++ jput(pos->child); ++ free_convert_data(pos); ++ return ret; ++} ++ ++/* clear up disk cluster info */ ++static void detach_convert_idata(struct convert_info * sq) ++{ ++ struct convert_item_info *info; ++ ++ assert("edward-253", sq != NULL); ++ assert("edward-840", sq->itm != NULL); ++ ++ info = sq->itm; ++ assert("edward-1212", info->flow.length == 0); ++ ++ free_item_convert_data(sq); ++ return; ++} ++ ++/* plugin->u.item.f.utmost_child */ ++ ++/* This function sets leftmost child for a first cluster item, ++ if the child exists, and NULL in other cases. ++ NOTE-EDWARD: Do not call this for RIGHT_SIDE */ ++ ++int utmost_child_ctail(const coord_t * coord, sideof side, jnode ** child) ++{ ++ reiser4_key key; ++ ++ item_key_by_coord(coord, &key); ++ ++ assert("edward-257", coord != NULL); ++ assert("edward-258", child != NULL); ++ assert("edward-259", side == LEFT_SIDE); ++ assert("edward-260", ++ item_plugin_by_coord(coord) == item_plugin_by_id(CTAIL_ID)); ++ ++ if (!is_disk_cluster_key(&key, coord)) ++ *child = NULL; ++ else ++ *child = jlookup(get_key_objectid(item_key_by_coord(coord, ++ &key)), ++ off_to_pg(get_key_offset(&key))); ++ return 0; ++} ++ ++/* ++ * Set status (d_next) of the first item at the right neighbor ++ * ++ * If the current position is the last item in the node, then ++ * look at its first item at the right neighbor (skip empty nodes). ++ * Note, that right neighbors may be not dirty because of races. ++ * If so, make it dirty and set convertible flag. ++ */ ++static int pre_convert_ctail(flush_pos_t * pos) ++{ ++ int ret = 0; ++ int stop = 0; ++ znode *slider; ++ lock_handle slider_lh; ++ lock_handle right_lh; ++ ++ assert("edward-1232", !node_is_empty(pos->coord.node)); ++ assert("edward-1014", ++ pos->coord.item_pos < coord_num_items(&pos->coord)); ++ assert("edward-1015", convert_data_attached(pos)); ++ assert("edward-1611", ++ item_convert_data(pos)->d_cur != DC_INVALID_STATE); ++ assert("edward-1017", ++ item_convert_data(pos)->d_next == DC_INVALID_STATE); ++ ++ /* ++ * In the following two cases we don't need ++ * to look at right neighbor ++ */ ++ if (item_convert_data(pos)->d_cur == DC_AFTER_CLUSTER) { ++ /* ++ * cluster is over, so the first item of the right ++ * neighbor doesn't belong to this cluster ++ */ ++ return 0; ++ } ++ if (pos->coord.item_pos < coord_num_items(&pos->coord) - 1) { ++ /* ++ * current position is not the last item in the node, ++ * so the first item of the right neighbor doesn't ++ * belong to this cluster ++ */ ++ return 0; ++ } ++ /* ++ * Look at right neighbor. ++ * Note that concurrent truncate is not a problem ++ * since we have locked the beginning of the cluster. ++ */ ++ slider = pos->coord.node; ++ init_lh(&slider_lh); ++ init_lh(&right_lh); ++ ++ while (!stop) { ++ coord_t coord; ++ ++ ret = reiser4_get_right_neighbor(&right_lh, ++ slider, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (ret) ++ break; ++ slider = right_lh.node; ++ ret = zload(slider); ++ if (ret) ++ break; ++ coord_init_before_first_item(&coord, slider); ++ ++ if (node_is_empty(slider)) { ++ warning("edward-1641", "Found empty right neighbor"); ++ znode_set_convertible(slider); ++ /* ++ * skip this node, ++ * go rightward ++ */ ++ stop = 0; ++ } else if (same_disk_cluster(&pos->coord, &coord)) { ++ ++ item_convert_data(pos)->d_next = DC_CHAINED_ITEM; ++ ++ if (!znode_convertible(slider)) { ++ /* ++ warning("edward-1272", ++ "next slum item mergeable, " ++ "but znode %p isn't convertible\n", ++ lh.node); ++ */ ++ znode_set_convertible(slider); ++ } ++ stop = 1; ++ convert_data(pos)->right_locked = 1; ++ } else { ++ item_convert_data(pos)->d_next = DC_AFTER_CLUSTER; ++ stop = 1; ++ convert_data(pos)->right_locked = 1; ++ } ++ zrelse(slider); ++ done_lh(&slider_lh); ++ move_lh(&slider_lh, &right_lh); ++ } ++ if (convert_data(pos)->right_locked) ++ /* ++ * Store locked right neighbor in ++ * the conversion info. Otherwise, ++ * we won't be able to access it, ++ * if the current node gets deleted ++ * during conversion ++ */ ++ move_lh(&convert_data(pos)->right_lock, &slider_lh); ++ done_lh(&slider_lh); ++ done_lh(&right_lh); ++ ++ if (ret == -E_NO_NEIGHBOR) { ++ item_convert_data(pos)->d_next = DC_AFTER_CLUSTER; ++ ret = 0; ++ } ++ assert("edward-1610", ++ ergo(ret != 0, ++ item_convert_data(pos)->d_next == DC_INVALID_STATE)); ++ return ret; ++} ++ ++/* ++ * do some post-conversion actions; ++ * detach conversion data if there is nothing to convert anymore ++ */ ++static void post_convert_ctail(flush_pos_t * pos, ++ ctail_convert_mode_t mode, int old_nr_items) ++{ ++ switch (mode) { ++ case CTAIL_CUT_ITEM: ++ assert("edward-1214", item_convert_data(pos)->flow.length == 0); ++ assert("edward-1215", ++ coord_num_items(&pos->coord) == old_nr_items || ++ coord_num_items(&pos->coord) == old_nr_items - 1); ++ ++ if (item_convert_data(pos)->d_next == DC_CHAINED_ITEM) ++ /* ++ * the next item belongs to this cluster, ++ * and should be also killed ++ */ ++ break; ++ if (coord_num_items(&pos->coord) != old_nr_items) { ++ /* ++ * the latest item in the ++ * cluster has been killed, ++ */ ++ detach_convert_idata(pos->sq); ++ if (!node_is_empty(pos->coord.node)) ++ /* ++ * make sure the next item will be scanned ++ */ ++ coord_init_before_item(&pos->coord); ++ break; ++ } ++ /* fall through */ ++ case CTAIL_APPEND_ITEM: ++ /* ++ * in the append mode the whole flow has been inserted ++ * (see COP_INSERT_FLOW primitive) ++ */ ++ assert("edward-434", item_convert_data(pos)->flow.length == 0); ++ detach_convert_idata(pos->sq); ++ break; ++ case CTAIL_OVERWRITE_ITEM: ++ if (coord_is_unprepped_ctail(&pos->coord)) { ++ /* ++ * the first (unprepped) ctail has been overwritten; ++ * convert it to the prepped one ++ */ ++ assert("edward-1259", ++ cluster_shift_ok(item_convert_data(pos)-> ++ cluster_shift)); ++ put_unaligned((d8)item_convert_data(pos)->cluster_shift, ++ &ctail_formatted_at(&pos->coord)-> ++ cluster_shift); ++ } ++ break; ++ default: ++ impossible("edward-1609", "Bad ctail conversion mode"); ++ } ++} ++ ++static int assign_conversion_mode(flush_pos_t * pos, ctail_convert_mode_t *mode) ++{ ++ int ret = 0; ++ ++ *mode = CTAIL_INVAL_CONVERT_MODE; ++ ++ if (!convert_data_attached(pos)) { ++ if (should_attach_convert_idata(pos)) { ++ struct inode *inode; ++ gfp_t old_mask = get_current_context()->gfp_mask; ++ ++ assert("edward-264", pos->child != NULL); ++ assert("edward-265", jnode_page(pos->child) != NULL); ++ assert("edward-266", ++ jnode_page(pos->child)->mapping != NULL); ++ ++ inode = jnode_page(pos->child)->mapping->host; ++ ++ assert("edward-267", inode != NULL); ++ /* ++ * attach new convert item info ++ */ ++ get_current_context()->gfp_mask |= __GFP_NOFAIL; ++ ret = attach_convert_idata(pos, inode); ++ get_current_context()->gfp_mask = old_mask; ++ pos->child = NULL; ++ if (ret == -E_REPEAT) { ++ /* ++ * jnode became clean, or there is no dirty ++ * pages (nothing to update in disk cluster) ++ */ ++ warning("edward-1021", ++ "convert_ctail: nothing to attach"); ++ ret = 0; ++ goto dont_convert; ++ } ++ if (ret) ++ goto dont_convert; ++ ++ if (pos->sq->clust.tc.hole) { ++ assert("edward-1634", ++ item_convert_data(pos)->flow.length == 0); ++ /* ++ * new content is filled with zeros - ++ * we punch a hole using cut (not kill) ++ * primitive, so attached pages won't ++ * be truncated ++ */ ++ *mode = CTAIL_CUT_ITEM; ++ } ++ else ++ /* ++ * this is the first ctail in the cluster, ++ * so it (may be only its head) should be ++ * overwritten ++ */ ++ *mode = CTAIL_OVERWRITE_ITEM; ++ } else ++ /* ++ * non-convertible item ++ */ ++ goto dont_convert; ++ } else { ++ /* ++ * use old convert info ++ */ ++ struct convert_item_info *idata; ++ idata = item_convert_data(pos); ++ ++ switch (idata->d_cur) { ++ case DC_FIRST_ITEM: ++ case DC_CHAINED_ITEM: ++ if (idata->flow.length) ++ *mode = CTAIL_OVERWRITE_ITEM; ++ else ++ *mode = CTAIL_CUT_ITEM; ++ break; ++ case DC_AFTER_CLUSTER: ++ if (idata->flow.length) ++ *mode = CTAIL_APPEND_ITEM; ++ else { ++ /* ++ * nothing to update anymore ++ */ ++ detach_convert_idata(pos->sq); ++ goto dont_convert; ++ } ++ break; ++ default: ++ impossible("edward-1018", ++ "wrong current item state"); ++ ret = RETERR(-EIO); ++ goto dont_convert; ++ } ++ } ++ /* ++ * ok, ctail will be converted ++ */ ++ assert("edward-433", convert_data_attached(pos)); ++ assert("edward-1022", ++ pos->coord.item_pos < coord_num_items(&pos->coord)); ++ return 0; ++ dont_convert: ++ return ret; ++} ++ ++/* ++ * perform an operation on the ctail item in ++ * accordance with assigned conversion @mode ++ */ ++static int do_convert_ctail(flush_pos_t * pos, ctail_convert_mode_t mode) ++{ ++ int result = 0; ++ struct convert_item_info * info; ++ ++ assert("edward-468", pos != NULL); ++ assert("edward-469", pos->sq != NULL); ++ assert("edward-845", item_convert_data(pos) != NULL); ++ ++ info = item_convert_data(pos); ++ assert("edward-679", info->flow.data != NULL); ++ ++ switch (mode) { ++ case CTAIL_APPEND_ITEM: ++ assert("edward-1229", info->flow.length != 0); ++ assert("edward-1256", ++ cluster_shift_ok(cluster_shift_by_coord(&pos->coord))); ++ /* ++ * insert flow without balancing ++ * (see comments to convert_node()) ++ */ ++ result = insert_cryptcompress_flow_in_place(&pos->coord, ++ &pos->lock, ++ &info->flow, ++ info->cluster_shift); ++ break; ++ case CTAIL_OVERWRITE_ITEM: ++ assert("edward-1230", info->flow.length != 0); ++ overwrite_ctail(&pos->coord, &info->flow); ++ if (info->flow.length != 0) ++ break; ++ /* fall through */ ++ /* cut the rest of item (if any) */ ++ case CTAIL_CUT_ITEM: ++ assert("edward-1231", info->flow.length == 0); ++ result = cut_ctail(&pos->coord); ++ break; ++ default: ++ result = RETERR(-EIO); ++ impossible("edward-244", "bad ctail conversion mode"); ++ } ++ return result; ++} ++ ++/* ++ * plugin->u.item.f.convert ++ * ++ * Convert ctail items at flush time ++ */ ++int convert_ctail(flush_pos_t * pos) ++{ ++ int ret; ++ int old_nr_items; ++ ctail_convert_mode_t mode; ++ ++ assert("edward-1020", pos != NULL); ++ assert("edward-1213", coord_num_items(&pos->coord) != 0); ++ assert("edward-1257", item_id_by_coord(&pos->coord) == CTAIL_ID); ++ assert("edward-1258", ctail_ok(&pos->coord)); ++ assert("edward-261", pos->coord.node != NULL); ++ ++ old_nr_items = coord_num_items(&pos->coord); ++ /* ++ * detach old conversion data and ++ * attach a new one, if needed ++ */ ++ ret = assign_conversion_mode(pos, &mode); ++ if (ret || mode == CTAIL_INVAL_CONVERT_MODE) { ++ assert("edward-1633", !convert_data_attached(pos)); ++ return ret; ++ } ++ /* ++ * find out the status of the right neighbor ++ */ ++ ret = pre_convert_ctail(pos); ++ if (ret) { ++ detach_convert_idata(pos->sq); ++ return ret; ++ } ++ ret = do_convert_ctail(pos, mode); ++ if (ret) { ++ detach_convert_idata(pos->sq); ++ return ret; ++ } ++ /* ++ * detach old conversion data if needed ++ */ ++ post_convert_ctail(pos, mode, old_nr_items); ++ return 0; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/ctail.h linux-5.10.2/fs/reiser4/plugin/item/ctail.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/ctail.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/ctail.h 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,103 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Ctail items are fragments (or bodies) of special tipe to provide ++ optimal storage of encrypted and(or) compressed files. */ ++ ++ ++#if !defined( __FS_REISER4_CTAIL_H__ ) ++#define __FS_REISER4_CTAIL_H__ ++ ++/* Disk format of ctail item */ ++typedef struct ctail_item_format { ++ /* packed shift; ++ if its value is different from UCTAIL_SHIFT (see below), then ++ size of disk cluster is calculated as (1 << cluster_shift) */ ++ d8 cluster_shift; ++ /* ctail body */ ++ d8 body[0]; ++} __attribute__ ((packed)) ctail_item_format; ++ ++/* "Unprepped" disk cluster is represented by a single ctail item ++ with the following "magic" attributes: */ ++/* "magic" cluster_shift */ ++#define UCTAIL_SHIFT 0xff ++/* How many units unprepped ctail item has */ ++#define UCTAIL_NR_UNITS 1 ++ ++/* The following is a set of various item states in a disk cluster. ++ Disk cluster is a set of items whose keys belong to the interval ++ [dc_key , dc_key + disk_cluster_size - 1] */ ++typedef enum { ++ DC_INVALID_STATE = 0, ++ DC_FIRST_ITEM = 1, ++ DC_CHAINED_ITEM = 2, ++ DC_AFTER_CLUSTER = 3 ++} dc_item_stat; ++ ++/* ctail-specific extension. ++ In particular this describes parameters of disk cluster an item belongs to */ ++struct ctail_coord_extension { ++ int shift; /* this contains cluster_shift extracted from ++ ctail_item_format (above), or UCTAIL_SHIFT ++ (the last one is the "magic" of unprepped disk clusters)*/ ++ int dsize; /* size of a prepped disk cluster */ ++ int ncount; /* count of nodes occupied by a disk cluster */ ++}; ++ ++struct cut_list; ++ ++/* plugin->item.b.* */ ++ ++int can_contain_key_ctail(const coord_t *, const reiser4_key *, ++ const reiser4_item_data *); ++int mergeable_ctail(const coord_t * p1, const coord_t * p2); ++pos_in_node_t nr_units_ctail(const coord_t * coord); ++int estimate_ctail(const coord_t * coord, const reiser4_item_data * data); ++void print_ctail(const char *prefix, coord_t * coord); ++lookup_result lookup_ctail(const reiser4_key *, lookup_bias, coord_t *); ++ ++int paste_ctail(coord_t * coord, reiser4_item_data * data, ++ carry_plugin_info * info UNUSED_ARG); ++int init_ctail(coord_t *, coord_t *, reiser4_item_data *); ++int can_shift_ctail(unsigned free_space, coord_t * coord, ++ znode * target, shift_direction pend, unsigned *size, ++ unsigned want); ++void copy_units_ctail(coord_t * target, coord_t * source, unsigned from, ++ unsigned count, shift_direction where_is_free_space, ++ unsigned free_space); ++int cut_units_ctail(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ carry_cut_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++int kill_units_ctail(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ carry_kill_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++int ctail_ok(const coord_t * coord); ++int check_ctail(const coord_t * coord, const char **error); ++ ++/* plugin->u.item.s.* */ ++int read_ctail(struct file *, flow_t *, hint_t *); ++int readpage_ctail(void *, struct page *); ++int readpages_ctail(struct file *, struct address_space *, struct list_head *); ++reiser4_key *append_key_ctail(const coord_t *, reiser4_key *); ++int create_hook_ctail(const coord_t * coord, void *arg); ++int kill_hook_ctail(const coord_t *, pos_in_node_t, pos_in_node_t, ++ carry_kill_data *); ++int shift_hook_ctail(const coord_t *, unsigned, unsigned, znode *); ++ ++/* plugin->u.item.f */ ++int utmost_child_ctail(const coord_t *, sideof, jnode **); ++int scan_ctail(flush_scan *); ++int convert_ctail(flush_pos_t *); ++size_t inode_scaled_cluster_size(struct inode *); ++ ++#endif /* __FS_REISER4_CTAIL_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent.c linux-5.10.2/fs/reiser4/plugin/item/extent.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent.c 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,203 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "item.h" ++#include "../../key.h" ++#include "../../super.h" ++#include "../../carry.h" ++#include "../../inode.h" ++#include "../../page_cache.h" ++#include "../../flush.h" ++#include "../object.h" ++ ++/* prepare structure reiser4_item_data. It is used to put one extent unit into tree */ ++/* Audited by: green(2002.06.13) */ ++reiser4_item_data *init_new_extent(item_id extent_id, reiser4_item_data *data, ++ void *ext_unit, int nr_extents) ++{ ++ data->data = ext_unit; ++ /* data->data is kernel space */ ++ data->user = 0; ++ data->length = sizeof(reiser4_extent) * nr_extents; ++ data->arg = NULL; ++ data->iplug = item_plugin_by_id(extent_id); ++ return data; ++} ++ ++/* how many bytes are addressed by @nr first extents of the extent item */ ++reiser4_block_nr reiser4_extent_size_at(const coord_t * coord, pos_in_node_t nr) ++{ ++ pos_in_node_t i; ++ reiser4_block_nr blocks; ++ reiser4_extent *ext; ++ ++ ext = item_body_by_coord(coord); ++ assert("vs-263", nr <= nr_units_extent(coord)); ++ ++ blocks = 0; ++ for (i = 0; i < nr; i++, ext++) { ++ blocks += extent_get_width(ext); ++ } ++ ++ return blocks * current_blocksize; ++} ++ ++reiser4_block_nr reiser4_extent_size(const coord_t *coord) ++{ ++ return reiser4_extent_size_at(coord, nr_units_extent(coord)); ++} ++ ++extent_state state_of_extent(reiser4_extent * ext) ++{ ++ switch ((int)extent_get_start(ext)) { ++ case 0: ++ return HOLE_EXTENT; ++ case 1: ++ return UNALLOCATED_EXTENT; ++ default: ++ break; ++ } ++ return ALLOCATED_EXTENT; ++} ++ ++int extent_is_unallocated(const coord_t * item) ++{ ++ assert("jmacd-5133", item_is_extent(item)); ++ ++ return state_of_extent(extent_by_coord(item)) == UNALLOCATED_EXTENT; ++} ++ ++/* set extent's start and width */ ++void reiser4_set_extent(reiser4_subvol *subv, reiser4_extent *ext, ++ reiser4_block_nr start, reiser4_block_nr width) ++{ ++ extent_set_start(subv, ext, start); ++ extent_set_width(subv, ext, width); ++} ++ ++/** ++ * replace_extent_unit - overwrite extent unit and paste 1 or 2 after it ++ * @un_extent: coordinate of extent to be overwritten ++ * @lh: need better comment ++ * @key: need better comment ++ * @exts_to_add: data prepared for insertion into tree ++ * @replace: need better comment ++ * @flags: need better comment ++ * @return_insert_position: need better comment ++ * ++ * Overwrites one extent, pastes 1 or 2 more ones after overwritten one. If ++ * @return_inserted_position is 1 - @un_extent and @lh are returned set to ++ * first of newly inserted units, if it is 0 - @un_extent and @lh are returned ++ * set to extent which was overwritten. ++ */ ++int replace_extent_unit(item_id extent_id, struct replace_handle *h, ++ int return_inserted_position) ++{ ++ int result; ++ znode *orig_znode; ++ /*ON_DEBUG(reiser4_extent orig_ext);*/ /* this is for debugging */ ++ ++ assert("vs-990", coord_is_existing_unit(h->coord)); ++ assert("vs-1375", znode_is_write_locked(h->coord->node)); ++ assert("vs-1426", extent_get_width(&h->overwrite) != 0); ++ assert("vs-1427", extent_get_width(&h->new_extents[0]) != 0); ++ assert("vs-1427", ergo(h->nr_new_extents == 2, ++ extent_get_width(&h->new_extents[1]) != 0)); ++ ++ /* compose structure for paste */ ++ init_new_extent(extent_id, &h->item, ++ &h->new_extents[0], h->nr_new_extents); ++ ++ coord_dup(&h->coord_after, h->coord); ++ init_lh(&h->lh_after); ++ copy_lh(&h->lh_after, h->lh); ++ reiser4_tap_init(&h->watch, &h->coord_after, &h->lh_after, ZNODE_WRITE_LOCK); ++ reiser4_tap_monitor(&h->watch); ++ ++ ON_DEBUG(h->orig_ext = *extent_by_coord(h->coord)); ++ orig_znode = h->coord->node; ++ ++#if REISER4_DEBUG ++ /* make sure that key is set properly */ ++ unit_key_by_coord(h->coord, &h->tmp); ++ set_key_offset(&h->tmp, ++ get_key_offset(&h->tmp) + ++ extent_get_width(&h->overwrite) * current_blocksize); ++ assert("vs-1080", keyeq(&h->tmp, &h->paste_key)); ++#endif ++ ++ /* set insert point after unit to be replaced */ ++ h->coord->between = AFTER_UNIT; ++ ++ result = insert_into_item(h->coord, return_inserted_position ? h->lh : NULL, ++ &h->paste_key, &h->item, h->flags); ++ if (!result) { ++ /* now we have to replace the unit after which new units were ++ inserted. Its position is tracked by @watch */ ++ reiser4_extent *ext; ++ znode *node; ++ ++ node = h->coord_after.node; ++ if (node != orig_znode) { ++ coord_clear_iplug(&h->coord_after); ++ result = zload(node); ++ } ++ ++ if (likely(!result)) { ++ ext = extent_by_coord(&h->coord_after); ++ ++ assert("vs-987", znode_is_loaded(node)); ++ assert("vs-988", !memcmp(ext, &h->orig_ext, sizeof(*ext))); ++ ++ /* overwrite extent unit */ ++ memcpy(ext, &h->overwrite, sizeof(reiser4_extent)); ++ znode_make_dirty(node); ++ ++ if (node != orig_znode) ++ zrelse(node); ++ ++ if (return_inserted_position == 0) { ++ /* coord and lh are to be set to overwritten ++ extent */ ++ assert("vs-1662", ++ WITH_DATA(node, !memcmp(&h->overwrite, ++ extent_by_coord( ++ &h->coord_after), ++ sizeof(reiser4_extent)))); ++ ++ *h->coord = h->coord_after; ++ done_lh(h->lh); ++ copy_lh(h->lh, &h->lh_after); ++ } else { ++ /* h->coord and h->lh are to be set to first of ++ inserted units */ ++ assert("vs-1663", ++ WITH_DATA(h->coord->node, ++ !memcmp(&h->new_extents[0], ++ extent_by_coord(h->coord), ++ sizeof(reiser4_extent)))); ++ assert("vs-1664", h->lh->node == h->coord->node); ++ } ++ } ++ } ++ reiser4_tap_done(&h->watch); ++ ++ return result; ++} ++ ++lock_handle *znode_lh(znode *node) ++{ ++ assert("vs-1371", znode_is_write_locked(node)); ++ assert("vs-1372", znode_is_wlocked_once(node)); ++ return list_entry(node->lock.owners.next, lock_handle, owners_link); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent_file_ops.c linux-5.10.2/fs/reiser4/plugin/item/extent_file_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent_file_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent_file_ops.c 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,1461 @@ ++/* COPYRIGHT 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "item.h" ++#include "../../inode.h" ++#include "../../page_cache.h" ++#include "../object.h" ++#include "../volume/volume.h" ++#include ++ ++static inline reiser4_extent *ext_by_offset(const znode *node, int offset) ++{ ++ reiser4_extent *ext; ++ ++ ext = (reiser4_extent *) (zdata(node) + offset); ++ return ext; ++} ++ ++static inline reiser4_extent *ext_by_ext_coord(const uf_coord_t *uf_coord) ++{ ++ return ext_by_offset(uf_coord->coord.node, ++ uf_coord->extension.extent.ext_offset); ++} ++ ++/** ++ * verify coord extension @uf_coord against @key: ++ * ++ * Makes sure that all fields of @uf_coord are set properly. ++ * If @key is specified - check whether @uf_coord is set correspondingly. ++ */ ++void check_uf_coord(const uf_coord_t *uf_coord, const reiser4_key *key) ++{ ++#if REISER4_DEBUG ++ const coord_t *coord; ++ const struct extent_coord_extension *ext_coord; ++ reiser4_extent *ext; ++ reiser4_key coord_key; ++ ++ coord = &uf_coord->coord; ++ unit_key_by_coord(coord, &coord_key); ++ ++ ext_coord = &uf_coord->extension.extent; ++ ext = ext_by_offset(coord->node, uf_coord->extension.extent.ext_offset); ++ ++ assert("edward-2047", ++ WITH_DATA(coord->node, ++ (uf_coord->valid == 1 && ++ coord_is_iplug_set(coord) && ++ item_is_extent(coord) && ++ ext_coord->nr_units == nr_units_extent(coord) && ++ ext == extent_by_coord(coord) && ++ ext_coord->width == extent_get_width(ext) && ++ coord->unit_pos < ext_coord->nr_units && ++ ext_coord->pos_in_unit < ext_coord->width && ++ memcmp(ext, &ext_coord->extent, ++ sizeof(reiser4_extent)) == 0))); ++ if (key) { ++ set_key_offset(&coord_key, ++ get_key_offset(&coord_key) + ++ (uf_coord->extension.extent. ++ pos_in_unit << PAGE_SHIFT)); ++ set_key_ordering(&coord_key, get_key_ordering(key)); ++ assert("edward-2326", keyeq(key, &coord_key)); ++ } ++#endif ++} ++ ++#if REISER4_DEBUG ++ ++/** ++ * return 1 if offset @off is inside of extent unit pointed to by @coord. ++ * Set pos_in_unit inside of unit correspondingly ++ */ ++static int offset_is_in_unit(const coord_t *coord, loff_t off) ++{ ++ reiser4_key unit_key; ++ __u64 unit_off; ++ reiser4_extent *ext; ++ ++ ext = extent_by_coord(coord); ++ ++ unit_key_extent(coord, &unit_key); ++ unit_off = get_key_offset(&unit_key); ++ if (off < unit_off) ++ return 0; ++ if (off >= (unit_off + (current_blocksize * extent_get_width(ext)))) ++ return 0; ++ return 1; ++} ++ ++static int coord_matches_key_extent(struct inode *inode, ++ const coord_t *coord, ++ const reiser4_key *key) ++{ ++ reiser4_key item_key; ++ item_plugin *iplug; ++ ++ assert("vs-771", coord_is_existing_unit(coord)); ++ assert("edward-2090", item_is_extent(coord)); ++ ++ iplug = item_plugin_by_coord(coord); ++ /* ++ * check that in simple volumes logical order coincides with ++ * physical order ++ */ ++ assert("vs-1258", ++ ergo(current_vol_plug() == ++ volume_plugin_by_id(SIMPLE_VOLUME_ID), ++ keylt(key, iplug->s.file.append_key(coord, &item_key)))); ++ assert("vs-1259", ++ ergo(current_vol_plug() == ++ volume_plugin_by_id(SIMPLE_VOLUME_ID), ++ keyge(key, item_key_by_coord(coord, &item_key)))); ++ ++ return offset_is_in_unit(coord, get_key_offset(key)); ++} ++#endif ++ ++static int can_append(const reiser4_key *key, const coord_t *coord) ++{ ++ reiser4_key append_key; ++ ++ return keyeq(key, append_key_extent(coord, &append_key)); ++} ++ ++static int append_hole_unix_file(coord_t *coord, lock_handle *lh, ++ const reiser4_key *key) ++{ ++ reiser4_key append_key; ++ reiser4_block_nr hole_width; ++ reiser4_extent *ext, new_ext; ++ reiser4_item_data idata; ++ ++ /* last item of file may have to be appended with hole */ ++ assert("vs-708", znode_get_level(coord->node) == TWIG_LEVEL); ++ assert("vs-714", item_id_by_coord(coord) == EXTENT40_POINTER_ID); ++ /* ++ * construct key of first byte which is not addressed by the ++ * last extent ++ */ ++ append_key_extent(coord, &append_key); ++ assert("edward-2324", keyle(&append_key, key)); ++ /* ++ * extent item has to be appended with hole. Calculate length of that ++ * hole ++ */ ++ hole_width = ((get_key_offset(key) - get_key_offset(&append_key) + ++ current_blocksize - 1) >> current_blocksize_bits); ++ assert("vs-954", hole_width > 0); ++ ++ /* set coord after last unit */ ++ coord_init_after_item_end(coord); ++ ++ /* get last extent in the item */ ++ ext = extent_by_coord(coord); ++ if (state_of_extent(ext) == HOLE_EXTENT) { ++ /* ++ * last extent of a file is hole extent. Widen that extent by ++ * @hole_width blocks. Note that we do not worry about ++ * overflowing - extent width is 64 bits ++ */ ++ reiser4_set_extent(get_meta_subvol(), ext, HOLE_EXTENT_START, ++ extent_get_width(ext) + hole_width); ++ znode_make_dirty(coord->node); ++ return 0; ++ } ++ /* ++ * append last item of the file with hole extent unit ++ */ ++ assert("vs-713", (state_of_extent(ext) == ALLOCATED_EXTENT || ++ state_of_extent(ext) == UNALLOCATED_EXTENT)); ++ ++ reiser4_set_extent(get_meta_subvol(), &new_ext, ++ HOLE_EXTENT_START, hole_width); ++ init_new_extent(EXTENT40_POINTER_ID, &idata, &new_ext, 1); ++ return insert_into_item(coord, lh, &append_key, &idata, 0); ++} ++ ++/** ++ * @twig: longterm locked twig node ++ */ ++void check_jnodes(znode *twig, const reiser4_key *key, int count) ++{ ++ coord_t coord; ++ reiser4_key node_key, jnode_key; ++ ++ if (current_vol_plug() != volume_plugin_by_id(SIMPLE_VOLUME_ID)) ++ return; ++ ++ jnode_key = *key; ++ ++ assert("edward-2094", twig != NULL); ++ assert("edward-2095", znode_get_level(twig) == TWIG_LEVEL); ++ assert("edward-2096", znode_is_write_locked(twig)); ++ ++ zload(twig); ++ /* get the smallest key in twig node */ ++ coord_init_first_unit(&coord, twig); ++ assert("edward-2097", ++ item_is_extent(&coord) || item_is_internal(&coord)); ++ ++ unit_key_by_coord(&coord, &node_key); ++ assert("edward-2098", keyle(&node_key, &jnode_key)); ++ ++ /* get the greatest key in the twig node */ ++ coord_init_last_unit(&coord, twig); ++ assert("edward-2099", ++ item_is_extent(&coord) || item_is_internal(&coord)); ++ ++ unit_key_by_coord(&coord, &node_key); ++ ++ if (item_is_extent(&coord)) ++ item_plugin_by_coord(&coord)->s.file.append_key(&coord, ++ &node_key); ++ set_key_offset(&jnode_key, ++ get_key_offset(&jnode_key) + ++ (loff_t)count * PAGE_SIZE - 1); ++ assert("edward-2100", keylt(&jnode_key, &node_key)); ++ zrelse(twig); ++} ++ ++/** ++ * append last file item ++ * @uf_coord: coord to start insertion from ++ * @jnodes: array of jnodes ++ * @count: number of jnodes in the array ++ * ++ * There is already at least one extent item of file @inode in the tree. ++ * Append the last of them with unallocated extent unit of width @count. ++ * Assign fake block numbers to jnodes corresponding to the inserted extent. ++ */ ++static int append_last_extent(uf_coord_t *uf_coord, const reiser4_key *key, ++ jnode **jnodes, int count) ++{ ++ int result; ++ reiser4_extent new_ext; ++ reiser4_item_data idata; ++ coord_t *coord; ++ struct extent_coord_extension *ext_coord; ++ reiser4_extent *ext; ++ reiser4_block_nr block; ++ jnode *node; ++ int i; ++ struct atom_brick_info *abi; ++ ++ coord = &uf_coord->coord; ++ ext_coord = &uf_coord->extension.extent; ++ ext = ext_by_ext_coord(uf_coord); ++ ++ /* check correctness of position in the item */ ++ assert("vs-228", coord->unit_pos == coord_last_unit_pos(coord)); ++ assert("vs-1311", coord->between == AFTER_UNIT); ++ assert("vs-1302", ext_coord->pos_in_unit == ext_coord->width - 1); ++ ++ if (!can_append(key, coord)) { ++ /* hole extent has to be inserted */ ++ result = append_hole_unix_file(coord, uf_coord->lh, key); ++ uf_coord->valid = 0; ++ return result; ++ } ++ if (count == 0) ++ return 0; ++ assert("", get_key_offset(key) == (loff_t)index_jnode(jnodes[0]) * PAGE_SIZE); ++ ++ inode_add_blocks(mapping_jnode(jnodes[0])->host, count); ++ ++ switch (state_of_extent(ext)) { ++ case UNALLOCATED_EXTENT: ++ /* ++ * last extent unit of the file is unallocated one ++ * Increase its width by @count ++ */ ++ reiser4_set_extent(get_meta_subvol(), ext, ++ UNALLOCATED_EXTENT_START, ++ extent_get_width(ext) + count); ++ znode_make_dirty(coord->node); ++ ++ /* update coord extension */ ++ ext_coord->width += count; ++ ext_coord->pos_in_unit += count; ++ ON_DEBUG(extent_set_width(get_meta_subvol(), ++ &uf_coord->extension.extent.extent, ++ ext_coord->width)); ++ break; ++ case HOLE_EXTENT: ++ case ALLOCATED_EXTENT: ++ /* ++ * last extent unit of the file is either hole or allocated ++ * one. Append one unallocated extent of width @count ++ */ ++ reiser4_set_extent(get_meta_subvol(), &new_ext, ++ UNALLOCATED_EXTENT_START, count); ++ init_new_extent(EXTENT40_POINTER_ID, &idata, &new_ext, 1); ++ result = insert_into_item(coord, uf_coord->lh, key, &idata, 0); ++ uf_coord->valid = 0; ++ if (result) ++ return result; ++ break; ++ ++ default: ++ return RETERR(-EIO); ++ } ++ /* ++ * make sure that we hold long term locked twig node containing all ++ * jnodes we are about to capture ++ */ ++ ON_DEBUG(check_jnodes(uf_coord->lh->node, key, count)); ++ /* ++ * assign fake block numbers to all jnodes. FIXME: make sure whether ++ * twig node containing inserted extent item is locked ++ */ ++ result = check_insert_atom_brick_info(get_meta_subvol()->id, &abi); ++ if (result) ++ return result; ++ ++ for (i = 0; i < count; i ++) { ++ node = jnodes[i]; ++ block = fake_blocknr_unformatted(1, get_meta_subvol()); ++ spin_lock_jnode(node); ++ JF_SET(node, JNODE_CREATED); ++ ++ jnode_set_subvol(node, get_meta_subvol()); ++ jnode_set_block(node, &block); ++ ++ result = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(result != 0); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ } ++ return count; ++} ++ ++static int insert_first_hole(coord_t *coord, lock_handle *lh, ++ const reiser4_key *key) ++{ ++ reiser4_extent new_ext; ++ reiser4_item_data idata; ++ reiser4_key item_key; ++ reiser4_block_nr hole_width; ++ ++ /* @coord must be set for inserting of new item */ ++ assert("vs-711", coord_is_between_items(coord)); ++ ++ item_key = *key; ++ set_key_offset(&item_key, 0ull); ++ ++ hole_width = ((get_key_offset(key) + current_blocksize - 1) >> ++ current_blocksize_bits); ++ assert("vs-710", hole_width > 0); ++ /* ++ * compose body of hole extent and insert item into tree ++ */ ++ reiser4_set_extent(get_meta_subvol(), &new_ext, ++ HOLE_EXTENT_START, hole_width); ++ init_new_extent(EXTENT40_POINTER_ID, &idata, &new_ext, 1); ++ return insert_extent_by_coord(coord, &idata, &item_key, lh); ++} ++ ++ ++/** ++ * insert first file item ++ * @inode: inode of file ++ * @uf_coord: coord to start insertion from ++ * @jnodes: array of jnodes ++ * @count: number of jnodes in the array ++ * @inode: ++ * ++ * There are no items of file @inode in the tree yet. Insert unallocated extent ++ * of width @count into tree or hole extent if writing not to the ++ * beginning. Assign fake block numbers to jnodes corresponding to the inserted ++ * unallocated extent. Returns number of jnodes or error code. ++ */ ++static int insert_first_extent(uf_coord_t *uf_coord, const reiser4_key *key, ++ jnode **jnodes, int count, struct inode *inode) ++{ ++ int result; ++ int i; ++ reiser4_extent new_ext; ++ reiser4_item_data idata; ++ reiser4_block_nr block; ++ struct unix_file_info *uf_info; ++ jnode *node; ++ struct atom_brick_info *abi; ++ ++ /* first extent insertion starts at leaf level */ ++ assert("vs-719", znode_get_level(uf_coord->coord.node) == LEAF_LEVEL); ++ assert("vs-711", coord_is_between_items(&uf_coord->coord)); ++ ++ if (get_key_offset(key) != 0) { ++ result = insert_first_hole(&uf_coord->coord, uf_coord->lh, key); ++ uf_coord->valid = 0; ++ uf_info = unix_file_inode_data(inode); ++ ++ /* ++ * first item insertion is only possible when writing to empty ++ * file or performing tail conversion ++ */ ++ assert("", (uf_info->container == UF_CONTAINER_EMPTY || ++ (reiser4_inode_get_flag(inode, ++ REISER4_PART_MIXED) && ++ reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)))); ++ ++ /* if file was empty - update its state */ ++ if (result == 0 && uf_info->container == UF_CONTAINER_EMPTY) ++ uf_info->container = UF_CONTAINER_EXTENTS; ++ return result; ++ } ++ if (count == 0) ++ return 0; ++ ++ inode_add_blocks(mapping_jnode(jnodes[0])->host, count); ++ ++ /* ++ * prepare for tree modification: compose body of item and item data ++ * structure needed for insertion ++ */ ++ reiser4_set_extent(get_meta_subvol(), &new_ext, ++ UNALLOCATED_EXTENT_START, count); ++ init_new_extent(EXTENT40_POINTER_ID, &idata, &new_ext, 1); ++ ++ /* insert extent item into the tree */ ++ result = insert_extent_by_coord(&uf_coord->coord, &idata, key, ++ uf_coord->lh); ++ if (result) ++ return result; ++ ++ /* ++ * make sure that we hold long term locked twig node containing all ++ * jnodes we are about to capture ++ */ ++ ON_DEBUG(check_jnodes(uf_coord->lh->node, key, count)); ++ /* ++ * assign fake block numbers to all jnodes, capture and mark them dirty ++ */ ++ result = check_insert_atom_brick_info(get_meta_subvol()->id, &abi); ++ if (result) ++ return result; ++ ++ block = fake_blocknr_unformatted(count, get_meta_subvol()); ++ for (i = 0; i < count; i ++, block ++) { ++ node = jnodes[i]; ++ spin_lock_jnode(node); ++ JF_SET(node, JNODE_CREATED); ++ /* ++ * unix file plugin stores everything in meta-data brick ++ */ ++ jnode_set_subvol(node, get_meta_subvol()); ++ jnode_set_block(node, &block); ++ ++ result = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(result != 0); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ } ++ ++ /* ++ * invalidate coordinate, research must be performed to continue ++ * because write will continue on twig level ++ */ ++ uf_coord->valid = 0; ++ return count; ++} ++ ++/** ++ * replace hole extent with unallocated and holes ++ * @uf_coord: ++ * @key: ++ * @node: ++ * @h: structure containing coordinate, lock handle, key, etc ++ * ++ * Creates an unallocated extent of width 1 within a hole. In worst case two ++ * additional extents can be created. ++ */ ++static int plug_hole(uf_coord_t *uf_coord, const reiser4_key *key, int *how) ++{ ++ struct replace_handle rh; ++ reiser4_extent *ext; ++ reiser4_block_nr width, pos_in_unit; ++ coord_t *coord; ++ struct extent_coord_extension *ext_coord; ++ int return_inserted_position; ++ ++ check_uf_coord(uf_coord, key); ++ ++ rh.coord = coord_by_uf_coord(uf_coord); ++ rh.lh = uf_coord->lh; ++ rh.flags = 0; ++ ++ coord = coord_by_uf_coord(uf_coord); ++ ext_coord = ext_coord_by_uf_coord(uf_coord); ++ ext = ext_by_ext_coord(uf_coord); ++ ++ width = ext_coord->width; ++ pos_in_unit = ext_coord->pos_in_unit; ++ ++ *how = 0; ++ if (width == 1) { ++ reiser4_set_extent(get_meta_subvol(), ext, ++ UNALLOCATED_EXTENT_START, 1); ++ znode_make_dirty(coord->node); ++ /* update uf_coord */ ++ ON_DEBUG(ext_coord->extent = *ext); ++ *how = 1; ++ return 0; ++ } else if (pos_in_unit == 0) { ++ /* we deal with first element of extent */ ++ if (coord->unit_pos) { ++ /* there is an extent to the left */ ++ if (state_of_extent(ext - 1) == UNALLOCATED_EXTENT) { ++ /* ++ * left neighboring unit is an unallocated ++ * extent. Increase its width and decrease ++ * width of hole ++ */ ++ extent_set_width(get_meta_subvol(), ext - 1, ++ extent_get_width(ext - 1) + 1); ++ extent_set_width(get_meta_subvol(), ext, ++ width - 1); ++ znode_make_dirty(coord->node); ++ ++ /* update coord extension */ ++ coord->unit_pos--; ++ ext_coord->width = extent_get_width(ext - 1); ++ ext_coord->pos_in_unit = ext_coord->width - 1; ++ ext_coord->ext_offset -= sizeof(reiser4_extent); ++ ON_DEBUG(ext_coord->extent = ++ *extent_by_coord(coord)); ++ *how = 2; ++ return 0; ++ } ++ } ++ /* extent for replace */ ++ reiser4_set_extent(get_meta_subvol(), &rh.overwrite, ++ UNALLOCATED_EXTENT_START, 1); ++ /* extent to be inserted */ ++ reiser4_set_extent(get_meta_subvol(), &rh.new_extents[0], ++ HOLE_EXTENT_START, ++ width - 1); ++ rh.nr_new_extents = 1; ++ ++ /* have replace_extent_unit() to return with @coord and ++ @uf_coord->lh set to unit which was replaced */ ++ return_inserted_position = 0; ++ *how = 3; ++ } else if (pos_in_unit == width - 1) { ++ /* we deal with last element of extent */ ++ if (coord->unit_pos < nr_units_extent(coord) - 1) { ++ /* there is an extent unit to the right */ ++ if (state_of_extent(ext + 1) == UNALLOCATED_EXTENT) { ++ /* ++ * right neighboring unit is an unallocated ++ * extent. Increase its width and decrease ++ * width of hole ++ */ ++ extent_set_width(get_meta_subvol(), ++ ext + 1, ++ extent_get_width(ext + 1) + 1); ++ extent_set_width(get_meta_subvol(), ++ ext, width - 1); ++ znode_make_dirty(coord->node); ++ ++ /* update coord extension */ ++ coord->unit_pos++; ++ ext_coord->width = extent_get_width(ext + 1); ++ ext_coord->pos_in_unit = 0; ++ ext_coord->ext_offset += sizeof(reiser4_extent); ++ ON_DEBUG(ext_coord->extent = ++ *extent_by_coord(coord)); ++ *how = 4; ++ return 0; ++ } ++ } ++ /* extent for replace */ ++ reiser4_set_extent(get_meta_subvol(), &rh.overwrite, ++ HOLE_EXTENT_START, width - 1); ++ /* extent to be inserted */ ++ reiser4_set_extent(get_meta_subvol(), &rh.new_extents[0], ++ UNALLOCATED_EXTENT_START, 1); ++ rh.nr_new_extents = 1; ++ ++ /* have replace_extent_unit() to return with @coord and ++ @uf_coord->lh set to unit which was inserted */ ++ return_inserted_position = 1; ++ *how = 5; ++ } else { ++ /* extent for replace */ ++ reiser4_set_extent(get_meta_subvol(), &rh.overwrite, ++ HOLE_EXTENT_START, pos_in_unit); ++ /* extents to be inserted */ ++ reiser4_set_extent(get_meta_subvol(), &rh.new_extents[0], ++ UNALLOCATED_EXTENT_START, 1); ++ reiser4_set_extent(get_meta_subvol(), &rh.new_extents[1], ++ HOLE_EXTENT_START, width - pos_in_unit - 1); ++ rh.nr_new_extents = 2; ++ ++ /* have replace_extent_unit() to return with @coord and ++ @uf_coord->lh set to first of units which were inserted */ ++ return_inserted_position = 1; ++ *how = 6; ++ } ++ unit_key_by_coord(coord, &rh.paste_key); ++ set_key_offset(&rh.paste_key, get_key_offset(&rh.paste_key) + ++ extent_get_width(&rh.overwrite) * current_blocksize); ++ ++ uf_coord->valid = 0; ++ return replace_extent_unit(EXTENT40_POINTER_ID, ++ &rh, return_inserted_position); ++} ++ ++/** ++ * If @node corresponds to hole extent - create unallocated extent for it and ++ * assign fake block number. If @node corresponds to allocated extent - assign ++ * block number of jnode ++ */ ++static int overwrite_one_block(uf_coord_t *uf_coord, const reiser4_key *key, ++ jnode *node, int *hole_plugged) ++{ ++ int result; ++ struct extent_coord_extension *ext_coord; ++ reiser4_extent *ext; ++ reiser4_block_nr block; ++ int how; ++ ++ assert("vs-1312", uf_coord->coord.between == AT_UNIT); ++ ++ result = 0; ++ ext_coord = ext_coord_by_uf_coord(uf_coord); ++ check_uf_coord(uf_coord, NULL); ++ ext = ext_by_ext_coord(uf_coord); ++ assert("", state_of_extent(ext) != UNALLOCATED_EXTENT); ++ ++ switch (state_of_extent(ext)) { ++ case ALLOCATED_EXTENT: ++ assert("edward-2215", node->subvol == get_meta_subvol()); ++ ++ block = extent_get_start(ext) + ext_coord->pos_in_unit; ++ break; ++ ++ case HOLE_EXTENT: ++ assert("edward-2216", node->subvol == NULL); ++ ++ inode_add_blocks(mapping_jnode(node)->host, 1); ++ result = plug_hole(uf_coord, key, &how); ++ if (result) ++ return result; ++ block = fake_blocknr_unformatted(1, get_meta_subvol()); ++ if (hole_plugged) ++ *hole_plugged = 1; ++ JF_SET(node, JNODE_CREATED); ++ jnode_set_subvol(node, get_meta_subvol()); ++ break; ++ ++ default: ++ return RETERR(-EIO); ++ } ++ ++ jnode_set_block(node, &block); ++ return 0; ++} ++ ++/** ++ * move_coord - move coordinate forward ++ * @uf_coord: ++ * ++ * Move coordinate one data block pointer forward. Return 1 if coord is set to ++ * the last one already or is invalid. ++ */ ++static int move_coord(uf_coord_t *uf_coord) ++{ ++ struct extent_coord_extension *ext_coord; ++ ++ if (uf_coord->valid == 0) ++ return 1; ++ ext_coord = &uf_coord->extension.extent; ++ ext_coord->pos_in_unit ++; ++ if (ext_coord->pos_in_unit < ext_coord->width) ++ /* coordinate moved within the unit */ ++ return 0; ++ ++ /* end of unit is reached. Try to move to next unit */ ++ ext_coord->pos_in_unit = 0; ++ uf_coord->coord.unit_pos ++; ++ if (uf_coord->coord.unit_pos < ext_coord->nr_units) { ++ /* coordinate moved to next unit */ ++ ext_coord->ext_offset += sizeof(reiser4_extent); ++ ext_coord->width = ++ extent_get_width(ext_by_offset ++ (uf_coord->coord.node, ++ ext_coord->ext_offset)); ++ ON_DEBUG(ext_coord->extent = ++ *ext_by_offset(uf_coord->coord.node, ++ ext_coord->ext_offset)); ++ return 0; ++ } ++ /* end of item is reached */ ++ uf_coord->valid = 0; ++ return 1; ++} ++ ++/** ++ * Process @count logical blocks of a file. ++ * Returns number of handled jnodes. ++ */ ++static int overwrite_extent(uf_coord_t *uf_coord, const reiser4_key *key, ++ jnode **jnodes, int count, int *plugged_hole) ++{ ++ int result; ++ reiser4_key k; ++ int i; ++ jnode *node; ++ struct atom_brick_info *abi; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ result = check_insert_atom_brick_info(subv->id, &abi); ++ if (result) ++ return result; ++ ++ k = *key; ++ for (i = 0; i < count; i ++) { ++ node = jnodes[i]; ++ if (*jnode_get_block(node) == 0) { ++ result = overwrite_one_block(uf_coord, &k, ++ node, plugged_hole); ++ if (result) ++ return result; ++ } ++ /* ++ * make sure that we hold long term locked twig node containing ++ * all jnodes we are about to capture ++ */ ++ ON_DEBUG(check_jnodes(uf_coord->lh->node, &k, 1)); ++ /* ++ * assign fake block numbers to all jnodes, capture and mark ++ * them dirty ++ */ ++ spin_lock_jnode(node); ++ result = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(result != 0); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ ++ if (uf_coord->valid == 0) ++ return i + 1; ++ ++ check_uf_coord(uf_coord, &k); ++ ++ if (move_coord(uf_coord)) { ++ /* ++ * failed to move to the next node pointer. Either end ++ * of file or end of twig node is reached. In the later ++ * case we might go to the right neighbor. ++ */ ++ uf_coord->valid = 0; ++ return i + 1; ++ } ++ /* update key for next iteration */ ++ ++ set_key_offset(&k, get_key_offset(&k) + PAGE_SIZE); ++ } ++ return count; ++} ++ ++int update_extent_unix_file(struct inode *inode, jnode *node, ++ loff_t pos, int *plugged_hole) ++{ ++ int result; ++ znode *loaded; ++ uf_coord_t uf_coord; ++ coord_t *coord; ++ lock_handle lh; ++ reiser4_key key; ++ ++ assert("", reiser4_lock_counters()->d_refs == 0); ++ ++ build_body_key_unix_file(inode, pos, &key); ++ ++ init_uf_coord(&uf_coord, &lh); ++ coord = &uf_coord.coord; ++ result = find_file_item_nohint(coord, &lh, &key, ++ ZNODE_WRITE_LOCK, inode); ++ if (IS_CBKERR(result)) { ++ assert("", reiser4_lock_counters()->d_refs == 0); ++ return result; ++ } ++ ++ result = zload(coord->node); ++ BUG_ON(result != 0); ++ loaded = coord->node; ++ ++ if (coord->between == AFTER_UNIT) { ++ /* ++ * append existing extent item with unallocated extent ++ */ ++ init_coord_extension_extent(&uf_coord, ++ get_key_offset(&key)); ++ result = append_last_extent(&uf_coord, &key, &node, 1); ++ } else if (coord->between == AT_UNIT) { ++ /* ++ * overwrite existing extent ++ * FIXME: not optimal yet. Will be optimized if new ++ * write will show performance win. ++ */ ++ init_coord_extension_extent(&uf_coord, ++ get_key_offset(&key)); ++ result = overwrite_extent(&uf_coord, &key, ++ &node, 1, plugged_hole); ++ } else { ++ /* ++ * there are no items of this file in the tree yet. ++ * Create first item of the file inserting one ++ * unallocated extent ++ */ ++ result = insert_first_extent(&uf_coord, &key, &node, 1, inode); ++ } ++ assert("edward-2048", result == 1 || result < 0); ++ ++ zrelse(loaded); ++ done_lh(&lh); ++ assert("edward-2049", reiser4_lock_counters()->d_refs == 0); ++ ++ return (result == 1) ? 0 : result; ++} ++ ++static int update_extents_unix_file(struct file *file, struct inode *inode, ++ jnode **jnodes, int count, loff_t pos) ++{ ++ struct hint hint; ++ reiser4_key key; ++ int result; ++ znode *loaded; ++ ++ result = load_file_hint(file, &hint); ++ BUG_ON(result != 0); ++ ++ if (count != 0) ++ /* ++ * count == 0 is special case: expanding truncate ++ */ ++ pos = (loff_t)index_jnode(jnodes[0]) << PAGE_SHIFT; ++ build_body_key_unix_file(inode, pos, &key); ++ ++ assert("", reiser4_lock_counters()->d_refs == 0); ++ ++ do { ++ result = find_file_item(&hint, &key, ZNODE_WRITE_LOCK, inode); ++ if (IS_CBKERR(result)) { ++ assert("", reiser4_lock_counters()->d_refs == 0); ++ return result; ++ } ++ ++ result = zload(hint.ext_coord.coord.node); ++ BUG_ON(result != 0); ++ loaded = hint.ext_coord.coord.node; ++ ++ if (hint.ext_coord.coord.between == AFTER_UNIT) { ++ /* ++ * append existing extent item with unallocated extent ++ * of width nr_jnodes ++ */ ++ if (hint.ext_coord.valid == 0) ++ /* NOTE: get statistics on this */ ++ init_coord_extension_extent(&hint.ext_coord, ++ get_key_offset(&key)); ++ result = append_last_extent(&hint.ext_coord, ++ &key, jnodes, count); ++ } else if (hint.ext_coord.coord.between == AT_UNIT) { ++ /* ++ * overwrite ++ * not optimal yet. Will be optimized if new write will ++ * show performance win. ++ */ ++ if (hint.ext_coord.valid == 0) ++ /* NOTE: get statistics on this */ ++ init_coord_extension_extent(&hint.ext_coord, ++ get_key_offset(&key)); ++ result = overwrite_extent(&hint.ext_coord, &key, ++ jnodes, count, NULL); ++ } else { ++ /* ++ * there are no items of this file in the tree ++ * yet. Create first item of the file inserting one ++ * unallocated extent of * width nr_jnodes ++ */ ++ result = insert_first_extent(&hint.ext_coord, &key, ++ jnodes, count, inode); ++ } ++ zrelse(loaded); ++ if (result < 0) { ++ done_lh(hint.ext_coord.lh); ++ break; ++ } ++ ++ jnodes += result; ++ count -= result; ++ set_key_offset(&key, get_key_offset(&key) + result * PAGE_SIZE); ++ ++ /* seal and unlock znode */ ++ if (hint.ext_coord.valid) ++ reiser4_set_hint(&hint, &key, ZNODE_WRITE_LOCK); ++ else ++ reiser4_unset_hint(&hint); ++ ++ } while (count > 0); ++ ++ save_file_hint(file, &hint); ++ assert("", reiser4_lock_counters()->d_refs == 0); ++ return result; ++} ++ ++/** ++ * Estimate and reserve space for extent write operation ++ * @inode: inode of the file to write to; ++ * @offset: write position; ++ * @count: number of written pages. ++ */ ++static int reserve_write_extent(struct inode *inode, int count) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ reiser4_tree *tree = &subv->tree; ++ /* ++ * to write @count pages to a file by extents we have to reserve disk ++ * space for: ++ * ++ * 1. find_file_item() may have to insert empty node to the tree ++ * (empty leaf node between two extent items). This requires: ++ * (a) 1 block for the leaf node; ++ * (b) number of formatted blocks which are necessary to perform ++ * insertion of an internal item into twig level. ++ * ++ * 2. for each of written pages there might be needed: ++ * (a) 1 unformatted block for the page itself; ++ * (b) number of blocks which might be necessary to insert or ++ * paste to an extent item. ++ * ++ * 3. stat data update ++ */ ++ grab_space_enable(); ++ return reiser4_grab_space(count /* for 2(a) */ + ++ estimate_one_insert_item(tree) + ++ count * estimate_one_insert_into_item(tree) + ++ estimate_one_insert_item(tree), BA_CAN_COMMIT, subv); ++} ++ ++/* ++ * filemap_copy_from_user no longer exists in generic code, because it ++ * is deadlocky (copying from user while holding the page lock is bad). ++ * As a temporary fix for reiser4, just define it here. ++ */ ++size_t filemap_copy_from_user(struct page *page, unsigned long offset, ++ const char __user *buf, unsigned bytes) ++{ ++ char *kaddr; ++ int left; ++ ++ kaddr = kmap_atomic(page); ++ left = __copy_from_user_inatomic(kaddr + offset, buf, bytes); ++ kunmap_atomic(kaddr); ++ ++ if (left != 0) { ++ /* Do it the slow way */ ++ kaddr = kmap(page); ++ left = __copy_from_user(kaddr + offset, buf, bytes); ++ kunmap(page); ++ } ++ return bytes - left; ++} ++ ++/** ++ * @file: file to write to ++ * @buf: address of user-space buffer ++ * @count: number of bytes to write ++ * @pos: position in file to write to ++ */ ++ssize_t write_extent_unix_file(struct file *file, struct inode *inode, ++ const char __user *buf, size_t count, ++ loff_t *pos) ++{ ++ int have_to_update_extent; ++ int nr_pages; ++ int nr_dirty = 0; ++ struct page *page; ++ jnode *jnodes[DEFAULT_WRITE_GRANULARITY + 1]; ++ unsigned long index; ++ unsigned long end; ++ int i; ++ int to_page, page_off; ++ size_t written; ++ size_t left = count; ++ int result = 0; ++ /* ++ * calculate number of pages which are to be written ++ */ ++ index = *pos >> PAGE_SHIFT; ++ end = ((*pos + count - 1) >> PAGE_SHIFT); ++ nr_pages = end - index + 1; ++ assert("edward-2293", nr_pages <= DEFAULT_WRITE_GRANULARITY + 1); ++ ++ if (reserve_write_extent(inode, nr_pages)) ++ return RETERR(-ENOSPC); ++ ++ if (count == 0) { ++ /* case of expanding truncate */ ++ update_extents_unix_file(file, inode, jnodes, 0, *pos); ++ return 0; ++ } ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ /* get pages and jnodes */ ++ for (i = 0; i < nr_pages; i ++) { ++ page = find_or_create_page(inode->i_mapping, index + i, ++ reiser4_ctx_gfp_mask_get()); ++ if (page == NULL) { ++ nr_pages = i; ++ result = RETERR(-ENOMEM); ++ goto out; ++ } ++ jnodes[i] = jnode_of_page(page); ++ if (IS_ERR(jnodes[i])) { ++ unlock_page(page); ++ put_page(page); ++ nr_pages = i; ++ result = RETERR(-ENOMEM); ++ goto out; ++ } ++ /* prevent jnode and page from disconnecting */ ++ JF_SET(jnodes[i], JNODE_WRITE_PREPARED); ++ unlock_page(page); ++ } ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ have_to_update_extent = 0; ++ ++ page_off = (*pos & (PAGE_SIZE - 1)); ++ for (i = 0; i < nr_pages; i ++) { ++ to_page = PAGE_SIZE - page_off; ++ if (to_page > left) ++ to_page = left; ++ page = jnode_page(jnodes[i]); ++ if (page_offset(page) < inode->i_size && ++ !PageUptodate(page) && to_page != PAGE_SIZE) { ++ /* ++ * the above is not optimal for partial write to last ++ * page of file when file size is not at boundary of ++ * page ++ */ ++ lock_page(page); ++ if (!PageUptodate(page)) { ++ result = readpage_unix_file(NULL, page); ++ assert("edward-2050", result == 0); ++ BUG_ON(result != 0); ++ /* wait for read completion */ ++ lock_page(page); ++ BUG_ON(!PageUptodate(page)); ++ } else ++ result = 0; ++ unlock_page(page); ++ } ++ ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ fault_in_pages_readable(buf, to_page); ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ lock_page(page); ++ if (!PageUptodate(page) && to_page != PAGE_SIZE) ++ zero_user_segments(page, 0, page_off, ++ page_off + to_page, ++ PAGE_SIZE); ++ ++ written = filemap_copy_from_user(page, page_off, buf, to_page); ++ if (unlikely(written != to_page)) { ++ unlock_page(page); ++ result = RETERR(-EFAULT); ++ break; ++ } ++ ++ flush_dcache_page(page); ++ set_page_dirty_notag(page); ++ unlock_page(page); ++ nr_dirty++; ++ ++ mark_page_accessed(page); ++ SetPageUptodate(page); ++ ++ if (jnodes[i]->blocknr == 0) ++ have_to_update_extent ++; ++ ++ page_off = 0; ++ buf += to_page; ++ left -= to_page; ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ } ++ if (have_to_update_extent) { ++ result = update_extents_unix_file(file, inode, ++ jnodes, nr_dirty, *pos); ++ ++ assert("edward-2278", result == -ENOSPC || result >= 0); ++ if (result < 0) ++ goto out; ++ } else { ++ for (i = 0; i < nr_dirty; i ++) { ++ struct atom_brick_info *abi; ++ assert("edward-1983", jnodes[i]->subvol != NULL); ++ ++ spin_lock_jnode(jnodes[i]); ++ result = reiser4_try_capture(jnodes[i], ++ ZNODE_WRITE_LOCK, 0); ++ spin_unlock_jnode(jnodes[i]); ++ BUG_ON(result != 0); ++ ++ result = check_insert_atom_brick_info(jnodes[i]->subvol->id, ++ &abi); ++ if (result) ++ goto out; ++ ++ spin_lock_jnode(jnodes[i]); ++ jnode_make_dirty_locked(jnodes[i]); ++ spin_unlock_jnode(jnodes[i]); ++ } ++ } ++ out: ++ for (i = 0; i < nr_pages; i ++) { ++ put_page(jnode_page(jnodes[i])); ++ JF_CLR(jnodes[i], JNODE_WRITE_PREPARED); ++ jput(jnodes[i]); ++ } ++ /* ++ * the only errors handled so far is ENOMEM and ++ * EFAULT on copy_from_user ++ */ ++ return (count - left) ? (count - left) : result; ++} ++ ++int __reiser4_readpage_extent(const coord_t *coord, ++ reiser4_extent *ext, reiser4_block_nr pos, ++ struct page *page) ++{ ++ jnode *j; ++ struct address_space *mapping; ++ unsigned long index; ++ oid_t oid; ++ int state; ++ reiser4_block_nr block; ++ ++ mapping = page->mapping; ++ oid = get_inode_oid(mapping->host); ++ index = page->index; ++ state = (ext != NULL ? state_of_extent(ext) : HOLE_EXTENT); ++ ++ switch (state) { ++ case HOLE_EXTENT: ++ j = jfind(mapping, index); ++ if (j == NULL) { ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ unlock_page(page); ++ return 0; ++ } ++ spin_lock_jnode(j); ++ if (!jnode_page(j)) { ++ jnode_attach_page(j, page); ++ } else { ++ BUG_ON(jnode_page(j) != page); ++ assert("vs-1504", jnode_page(j) == page); ++ } ++ block = *jnode_get_io_block(j); ++ spin_unlock_jnode(j); ++ if (block == 0) { ++ zero_user(page, 0, PAGE_SIZE); ++ SetPageUptodate(page); ++ unlock_page(page); ++ jput(j); ++ return 0; ++ } ++ /* ++ * page was eflushed previously ++ * (currently eflush is not supported) ++ */ ++ assert("edward-2213", 0); ++ break; ++ case ALLOCATED_EXTENT: ++ j = jnode_of_page(page); ++ if (IS_ERR(j)) ++ return PTR_ERR(j); ++ /* ++ * set "IO address" - a pair (subvolume, block number) ++ */ ++ if (j->subvol == NULL) ++ jnode_set_subvol(j, find_data_subvol(coord)); ++ else ++ assert("edward-2217", ++ j->subvol == find_data_subvol(coord)); ++ ++ if (*jnode_get_block(j) == 0) { ++ reiser4_block_nr blocknr; ++ ++ blocknr = extent_get_start(ext) + pos; ++ jnode_set_block(j, &blocknr); ++ } else ++ assert("vs-1403", ++ j->blocknr == extent_get_start(ext) + pos); ++ break; ++ ++ case UNALLOCATED_EXTENT: ++ assert("edward-2214", 0); ++ j = jfind(mapping, index); ++ assert("nikita-2688", j); ++ assert("vs-1426", jnode_page(j) == NULL); ++ ++ spin_lock_jnode(j); ++ jnode_attach_page(j, page); ++ spin_unlock_jnode(j); ++ break; ++ ++ default: ++ warning("vs-957", "wrong extent\n"); ++ return RETERR(-EIO); ++ } ++ BUG_ON(j == 0); ++ reiser4_page_io(page, j, READ, reiser4_ctx_gfp_mask_get()); ++ jput(j); ++ return 0; ++} ++ ++int read_extent_unix_file(struct file *file, flow_t *flow, hint_t *hint) ++{ ++ int result; ++ struct page *page; ++ unsigned long page_idx; ++ unsigned long page_off; /* offset within the page to start read from */ ++ unsigned long page_cnt; /* bytes which can be read from the page which ++ contains file_off */ ++ struct address_space *mapping; ++ loff_t file_off; /* offset in a file to start read from */ ++ uf_coord_t *uf_coord; ++ coord_t *coord; ++ struct extent_coord_extension *ext_coord; ++ char *kaddr; ++ ++ assert("vs-1353", current_blocksize == PAGE_SIZE); ++ assert("vs-572", flow->user == 1); ++ assert("vs-1351", flow->length > 0); ++ ++ uf_coord = &hint->ext_coord; ++ ++ check_uf_coord(uf_coord, NULL); ++ assert("vs-33", uf_coord->lh == &hint->lh); ++ ++ coord = &uf_coord->coord; ++ assert("vs-1119", znode_is_rlocked(coord->node)); ++ assert("vs-1120", znode_is_loaded(coord->node)); ++ assert("vs-1256", coord_matches_key_extent(file_inode(file), ++ coord, &flow->key)); ++ mapping = file_inode(file)->i_mapping; ++ ext_coord = &uf_coord->extension.extent; ++ ++ file_off = get_key_offset(&flow->key); ++ page_off = (unsigned long)(file_off & (PAGE_SIZE - 1)); ++ page_cnt = PAGE_SIZE - page_off; ++ ++ page_idx = (unsigned long)(file_off >> PAGE_SHIFT); ++ ++ /* we start having twig node read locked. However, we do not want to ++ keep that lock all the time readahead works. So, set a seal and ++ release twig node. */ ++ reiser4_set_hint(hint, &flow->key, ZNODE_READ_LOCK); ++ /* &hint->lh is done-ed */ ++ ++ do { ++ reiser4_txn_restart_current(); ++ page = read_mapping_page(mapping, page_idx, file); ++ if (IS_ERR(page)) ++ return PTR_ERR(page); ++ lock_page(page); ++ if (!PageUptodate(page)) { ++ unlock_page(page); ++ put_page(page); ++ warning("jmacd-97178", ++ "extent_read: page is not up to date"); ++ return RETERR(-EIO); ++ } ++ mark_page_accessed(page); ++ unlock_page(page); ++ ++ /* If users can be writing to this page using arbitrary virtual ++ addresses, take care about potential aliasing before reading ++ the page on the kernel side. ++ */ ++ if (mapping_writably_mapped(mapping)) ++ flush_dcache_page(page); ++ ++ assert("nikita-3034", reiser4_schedulable()); ++ ++ /* number of bytes which are to be read from the page */ ++ if (page_cnt > flow->length) ++ page_cnt = flow->length; ++ ++ result = fault_in_pages_writeable(flow->data, page_cnt); ++ if (result) { ++ put_page(page); ++ return RETERR(-EFAULT); ++ } ++ ++ kaddr = kmap_atomic(page); ++ result = __copy_to_user_inatomic(flow->data, ++ kaddr + page_off, page_cnt); ++ kunmap_atomic(kaddr); ++ if (result != 0) { ++ kaddr = kmap(page); ++ result = __copy_to_user(flow->data, ++ kaddr + page_off, page_cnt); ++ kunmap(page); ++ if (unlikely(result)) ++ return RETERR(-EFAULT); ++ } ++ put_page(page); ++ ++ /* increase (flow->key) offset, ++ * update (flow->data) user area pointer ++ */ ++ move_flow_forward(flow, page_cnt); ++ ++ page_off = 0; ++ page_idx++; ++ ++ } while (flow->length); ++ return 0; ++} ++ ++/** ++ * reiser4_read->unix_file_read->page_cache_readahead-> ++ * ->reiser4_readpage_dispatch->readpage_unix_file-> ++ * ->reiser4_readpage_extent ++ * or ++ * filemap_fault->reiser4_readpage_dispatch->readpage_unix_file-> ++ * ->reiser4_readpage_extent ++ * ++ * At the beginning: coord->node is read locked, zloaded, page is ++ * locked, coord is set to existing unit inside of extent item (it ++ * is not necessary that coord matches to page->index) ++ */ ++int reiser4_readpage_extent(void *vp, struct page *page) ++{ ++ uf_coord_t *uf_coord = vp; ++ ON_DEBUG(coord_t * coord = &uf_coord->coord); ++ ON_DEBUG(reiser4_key key); ++ ++ assert("vs-1040", PageLocked(page)); ++ assert("vs-1050", !PageUptodate(page)); ++ assert("vs-1039", page->mapping && page->mapping->host); ++ ++ assert("vs-1044", znode_is_loaded(coord->node)); ++ assert("vs-758", item_is_extent(coord)); ++ assert("vs-1046", coord_is_existing_unit(coord)); ++ assert("vs-1045", znode_is_rlocked(coord->node)); ++ assert("vs-1047", ++ page->mapping->host->i_ino == ++ get_key_objectid(item_key_by_coord(coord, &key))); ++ check_uf_coord(uf_coord, NULL); ++ ++ return __reiser4_readpage_extent(&uf_coord->coord, ++ ext_by_ext_coord(uf_coord), ++ uf_coord->extension.extent.pos_in_unit, ++ page); ++} ++ ++int get_block_address_extent(const coord_t *coord, sector_t block, ++ sector_t *result) ++{ ++ reiser4_extent *ext; ++ ++ if (!coord_is_existing_unit(coord)) ++ return RETERR(-EINVAL); ++ ++ ext = extent_by_coord(coord); ++ ++ if (state_of_extent(ext) != ALLOCATED_EXTENT) ++ /* FIXME: bad things may happen if it is unallocated extent */ ++ *result = 0; ++ else { ++ reiser4_key key; ++ ++ unit_key_by_coord(coord, &key); ++ assert("vs-1645", ++ block >= get_key_offset(&key) >> current_blocksize_bits); ++ assert("vs-1646", ++ block < ++ (get_key_offset(&key) >> current_blocksize_bits) + ++ extent_get_width(ext)); ++ *result = ++ extent_get_start(ext) + (block - ++ (get_key_offset(&key) >> ++ current_blocksize_bits)); ++ } ++ return 0; ++} ++ ++reiser4_key *append_key_extent(const coord_t *coord, reiser4_key *key) ++{ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, get_key_offset(key) + reiser4_extent_size(coord)); ++ ++ assert("vs-610", get_key_offset(key) && ++ (get_key_offset(key) & (current_blocksize - 1)) == 0); ++ return key; ++} ++ ++/* plugin->u.item.s.file.init_coord_extension */ ++void init_coord_extension_extent(uf_coord_t * uf_coord, loff_t lookuped) ++{ ++ coord_t *coord; ++ struct extent_coord_extension *ext_coord; ++ reiser4_key key; ++ loff_t offset; ++ ++ assert("vs-1295", uf_coord->valid == 0); ++ ++ coord = &uf_coord->coord; ++ assert("vs-1288", coord_is_iplug_set(coord)); ++ assert("vs-1327", znode_is_loaded(coord->node)); ++ ++ if (coord->between != AFTER_UNIT && coord->between != AT_UNIT) ++ return; ++ ++ ext_coord = &uf_coord->extension.extent; ++ ext_coord->nr_units = nr_units_extent(coord); ++ ext_coord->ext_offset = ++ (char *)extent_by_coord(coord) - zdata(coord->node); ++ ext_coord->width = extent_get_width(extent_by_coord(coord)); ++ ON_DEBUG(ext_coord->extent = *extent_by_coord(coord)); ++ uf_coord->valid = 1; ++ ++ /* pos_in_unit is the only uninitialized field in extended coord */ ++ if (coord->between == AFTER_UNIT) { ++ assert("vs-1330", ++ coord->unit_pos == nr_units_extent(coord) - 1); ++ ++ ext_coord->pos_in_unit = ext_coord->width - 1; ++ } else { ++ /* AT_UNIT */ ++ unit_key_by_coord(coord, &key); ++ offset = get_key_offset(&key); ++ ++ assert("vs-1328", offset <= lookuped); ++ assert("vs-1329", ++ lookuped < ++ offset + ext_coord->width * current_blocksize); ++ ext_coord->pos_in_unit = ++ ((lookuped - offset) >> current_blocksize_bits); ++ } ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent_flush_ops.c linux-5.10.2/fs/reiser4/plugin/item/extent_flush_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent_flush_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent_flush_ops.c 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,759 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "item.h" ++#include "../../tree.h" ++#include "../../jnode.h" ++#include "../../super.h" ++#include "../../flush.h" ++#include "../../carry.h" ++#include "../object.h" ++ ++#include ++ ++static reiser4_block_nr extent_unit_start(const coord_t * item); ++ ++/* Return either first or last extent (depending on @side) of the item ++ @coord is set to. Set @pos_in_unit either to first or to last block ++ of extent. */ ++static reiser4_extent *extent_utmost_ext(const coord_t * coord, sideof side, ++ reiser4_block_nr * pos_in_unit) ++{ ++ reiser4_extent *ext; ++ ++ if (side == LEFT_SIDE) { ++ /* get first extent of item */ ++ ext = extent_item(coord); ++ *pos_in_unit = 0; ++ } else { ++ /* get last extent of item and last position within it */ ++ assert("vs-363", side == RIGHT_SIDE); ++ ext = extent_item(coord) + coord_last_unit_pos(coord); ++ *pos_in_unit = extent_get_width(ext) - 1; ++ } ++ ++ return ext; ++} ++ ++/** ++ * item_plugin->f.utmost_child ++ * ++ * Return the child. Coord is set to extent item. ++ * Find jnode corresponding either to first or to ++ * last unformatted node pointed by the item ++ */ ++int utmost_child_extent(const coord_t *coord, sideof side, jnode **childp) ++{ ++ reiser4_extent *ext; ++ reiser4_block_nr pos_in_unit; ++ reiser4_subvol *data_subv; ++ ++ assert("edward-1851", item_is_extent(coord)); ++ ++ data_subv = find_data_subvol(coord); ++ ext = extent_utmost_ext(coord, side, &pos_in_unit); ++ ++ switch (state_of_extent(ext)) { ++ case HOLE_EXTENT: ++ *childp = NULL; ++ return 0; ++ case ALLOCATED_EXTENT: ++ case UNALLOCATED_EXTENT: ++ break; ++ default: ++ impossible("vs-1417", "Bad state of extent (%d)", ++ state_of_extent(ext)); ++ BUG_ON(1); ++ } ++ { ++ reiser4_key key; ++ loff_t offset; ++ unsigned long index; ++ /* ++ * offset of the first or next after last (depending on ++ * @side) byte addressed by the extent ++ */ ++ offset = get_key_offset(item_key_by_coord(coord, &key)); ++ if (side == RIGHT_SIDE) ++ offset += reiser4_extent_size(coord); ++ ++ assert("vs-544", (offset >> PAGE_SHIFT) < ~0ul); ++ /* ++ * index of first or last (depending on @side) page ++ * addressed by the extent ++ */ ++ index = (unsigned long)(offset >> PAGE_SHIFT); ++ if (side == RIGHT_SIDE) ++ index--; ++ ++ *childp = jlookup(get_key_objectid(&key), index); ++ } ++ return 0; ++} ++ ++/* item_plugin->f.utmost_child_real_block */ ++/* Return the child's block, if allocated. */ ++int ++utmost_child_real_block_extent(const coord_t * coord, sideof side, ++ reiser4_block_nr * block) ++{ ++ reiser4_extent *ext; ++ ++ ext = extent_by_coord(coord); ++ ++ switch (state_of_extent(ext)) { ++ case ALLOCATED_EXTENT: ++ *block = extent_get_start(ext); ++ if (side == RIGHT_SIDE) ++ *block += extent_get_width(ext) - 1; ++ break; ++ case HOLE_EXTENT: ++ case UNALLOCATED_EXTENT: ++ *block = 0; ++ break; ++ default: ++ /* this should never happen */ ++ assert("vs-1418", 0); ++ } ++ ++ return 0; ++} ++ ++/* item_plugin->f.scan */ ++/* Performs leftward scanning starting from an unformatted node and its parent coordinate. ++ This scan continues, advancing the parent coordinate, until either it encounters a ++ formatted child or it finishes scanning this node. ++ ++ If unallocated, the entire extent must be dirty and in the same atom. (Actually, I'm ++ not sure this is last property (same atom) is enforced, but it should be the case since ++ one atom must write the parent and the others must read the parent, thus fusing?). In ++ any case, the code below asserts this case for unallocated extents. Unallocated ++ extents are thus optimized because we can skip to the endpoint when scanning. ++ ++ It returns control to reiser4_scan_extent, handles these terminating conditions, ++ e.g., by loading the next twig. ++*/ ++int reiser4_scan_extent(flush_scan * scan) ++{ ++ coord_t coord; ++ jnode *neighbor; ++ unsigned long scan_index, unit_index, unit_width, scan_max, scan_dist; ++ reiser4_block_nr unit_start; ++ __u64 oid; ++ reiser4_key key; ++ int ret = 0, allocated, incr; ++ ++ if (!JF_ISSET(scan->node, JNODE_DIRTY)) { ++ /* ++ * Race with truncate, this node is already truncated ++ */ ++ scan->stop = 1; ++ return 0; ++ } ++ coord_dup(&coord, &scan->parent_coord); ++ ++ assert("jmacd-1404", !reiser4_scan_finished(scan)); ++ assert("jmacd-1405", jnode_get_level(scan->node) == LEAF_LEVEL); ++ assert("jmacd-1406", jnode_is_unformatted(scan->node)); ++ /* ++ * The scan_index variable corresponds to the current page index ++ * of the unformatted block scan position ++ */ ++ scan_index = index_jnode(scan->node); ++ ++ assert("jmacd-7889", item_is_extent(&coord)); ++ repeat: ++ oid = get_key_objectid(item_key_by_coord(&coord, &key)); ++ ++ allocated = !extent_is_unallocated(&coord); ++ /* ++ * Get the values of this extent unit: ++ */ ++ unit_index = extent_unit_index(&coord); ++ unit_width = extent_unit_width(&coord); ++ unit_start = extent_unit_start(&coord); ++ ++ assert("jmacd-7187", unit_width > 0); ++ assert("jmacd-7188", scan_index >= unit_index); ++ assert("jmacd-7189", scan_index <= unit_index + unit_width - 1); ++ /* ++ * Depending on the scan direction, we set different maximum values ++ * for scan_index (scan_max) and the number of nodes that would be ++ * passed if the scan goes the entire way (scan_dist). Incr is an ++ * integer reflecting the incremental direction of scan_index ++ */ ++ if (reiser4_scanning_left(scan)) { ++ scan_max = unit_index; ++ scan_dist = scan_index - unit_index; ++ incr = -1; ++ } else { ++ scan_max = unit_index + unit_width - 1; ++ scan_dist = scan_max - unit_index; ++ incr = +1; ++ } ++ /* ++ * If the extent is allocated we have to check each of its blocks. ++ * If the extent is unallocated we can skip to the scan_max ++ */ ++ if (allocated) { ++ do { ++ neighbor = jlookup(oid, scan_index); ++ if (neighbor == NULL) ++ goto stop_same_parent; ++ ++ if (scan->node != neighbor && ++ !reiser4_scan_goto(scan, neighbor)) { ++ /* ++ * @neighbor was jput() by reiser4_scan_goto ++ */ ++ goto stop_same_parent; ++ } ++ ret = move_scan_pos(scan, neighbor, 1, &coord); ++ if (ret != 0) { ++ goto exit; ++ } ++ /* ++ * reference to @neighbor is stored in @scan, no need ++ * to jput() ++ */ ++ scan_index += incr; ++ } while (incr + scan_max != scan_index); ++ } else { ++ /* ++ * Optimized case for unallocated extents, skip to the end ++ */ ++ neighbor = jlookup(oid, scan_max /*index */); ++ if (neighbor == NULL) { ++ /* ++ * Race with truncate ++ */ ++ scan->stop = 1; ++ ret = 0; ++ goto exit; ++ ++ } else if (!reiser4_scan_goto(scan, neighbor)) { ++ /* ++ * @neighbor was jput() by reiser4_scan_goto ++ */ ++ goto stop_same_parent; ++ } ++ assert("zam-1043", ++ reiser4_blocknr_is_fake(jnode_get_block(neighbor))); ++ ++ ret = move_scan_pos(scan, neighbor, scan_dist, &coord); ++ if (ret != 0) { ++ goto exit; ++ } ++ } ++ if (coord_sideof_unit(&coord, scan->direction) == 0 && ++ item_is_extent(&coord)) { ++ /* ++ * Continue as long as there are more extent units ++ */ ++ scan_index = extent_unit_index(&coord) + ++ (reiser4_scanning_left(scan) ? ++ extent_unit_width(&coord) - 1 : 0); ++ goto repeat; ++ } ++ if (0) { ++ stop_same_parent: ++ /* ++ * In this case, we leave coord set to the parent of scan->node ++ */ ++ scan->stop = 1; ++ } else { ++ /* ++ * scan to be continued, ++ * coord is set to the next item which is either off-the-end ++ * of the node or not an extent ++ */ ++ assert("jmacd-8912", scan->stop == 0); ++ assert("jmacd-7812", ++ (coord_is_after_sideof_unit(&coord, scan->direction) || ++ !item_is_extent(&coord))); ++ } ++ ret = 0; ++ exit: ++ return ret; ++} ++ ++/** ++ * When on flush time unallocated extent is to be replaced with allocated one ++ * it may happen that one unallocated extent will have to be replaced with set ++ * of allocated extents. In this case insert_into_item will be called which may ++ * have to add new nodes into tree. Space for that is taken from inviolable ++ * reserve (5%). ++ */ ++static reiser4_block_nr reserve_replace(reiser4_subvol *subv) ++{ ++ reiser4_block_nr grabbed, needed; ++ ++ grabbed = ctx_subvol_grabbed(get_current_context(), subv->id); ++ needed = estimate_one_insert_into_item(&subv->tree); ++ check_me("vpf-340", ++ !reiser4_grab_space_force(needed, BA_RESERVED, subv)); ++ return grabbed; ++} ++ ++/* Block offset of first block addressed by unit */ ++__u64 extent_unit_index(const coord_t * item) ++{ ++ reiser4_key key; ++ ++ assert("vs-648", coord_is_existing_unit(item)); ++ unit_key_by_coord(item, &key); ++ return get_key_offset(&key) >> current_blocksize_bits; ++} ++ ++/* AUDIT shouldn't return value be of reiser4_block_nr type? ++ Josh's answer: who knows? Is a "number of blocks" the same type as "block offset"? */ ++__u64 extent_unit_width(const coord_t * item) ++{ ++ assert("vs-649", coord_is_existing_unit(item)); ++ return width_by_coord(item); ++} ++ ++/* Starting block location of this unit */ ++static reiser4_block_nr extent_unit_start(const coord_t * item) ++{ ++ return extent_get_start(extent_by_coord(item)); ++} ++ ++/** ++ * Split extent unit specified by @coord into 2 extent units ++ * ++ * @pos: position to split; ++ * @adv_to_right: if true, then set @coord to the right extent unit, ++ * otherwise, to the left one ++ */ ++int split_extent_unit(coord_t *coord, reiser4_block_nr pos_in_unit, ++ int return_inserted_pos) ++{ ++ int result; ++ struct replace_handle *h; ++ item_id extent_id; ++ reiser4_extent *ext; ++ reiser4_dblock_nr start1, start2; ++ reiser4_block_nr was_grabbed; ++ ++ ext = extent_by_coord(coord); ++ extent_id = item_id_by_coord(coord); ++ ++ assert("edward-2119", extent_get_width(ext) > pos_in_unit); ++ ++ start1 = start2 = extent_get_start(ext); ++ if (unlikely(start1 == HOLE_EXTENT_START)) ++ return -EIO; ++ else if (start1 != UNALLOCATED_EXTENT_START) ++ /* allocated extent */ ++ start2 += pos_in_unit; ++ ++ h = kmalloc(sizeof(*h), reiser4_ctx_gfp_mask_get()); ++ if (h == NULL) ++ return RETERR(-ENOMEM); ++ h->coord = coord; ++ h->lh = znode_lh(coord->node); ++ h->pkey = &h->key; ++ unit_key_by_coord(coord, h->pkey); ++ set_key_offset(h->pkey, ++ (get_key_offset(h->pkey) + ++ pos_in_unit * current_blocksize)); ++ ++ reiser4_set_extent(find_data_subvol(coord), &h->overwrite, ++ start1, pos_in_unit); ++ reiser4_set_extent(find_data_subvol(coord), &h->new_extents[0], ++ start2, extent_get_width(ext) - pos_in_unit); ++ h->nr_new_extents = 1; ++ h->flags = COPI_DONT_SHIFT_LEFT; ++ h->paste_key = h->key; ++ /* ++ * reserve space for extent unit paste, @grabbed is reserved before ++ */ ++ was_grabbed = reserve_replace(get_meta_subvol()); ++ result = replace_extent_unit(extent_id, h, return_inserted_pos); ++ /* restore reserved */ ++ grabbed2free_mark(was_grabbed, get_meta_subvol()); ++ kfree(h); ++ return result; ++} ++ ++/** ++ * Pre-condition: We want to replace extent @ext by extent @replace. ++ * Try to merge @replace with previous extent of the item (if there is one). ++ * Return 1 if merging succeeded, 0 - otherwise. ++ */ ++static int try_to_merge_with_left(coord_t *coord, reiser4_extent *ext, ++ reiser4_extent *replace) ++{ ++ reiser4_key key; ++ ++ assert("vs-1415", extent_by_coord(coord) == ext); ++ ++ if (coord->unit_pos == 0 || ++ state_of_extent(ext - 1) != ALLOCATED_EXTENT) ++ /* ++ * left neighbor of @ext either does not exist ++ * or is not allocated extent ++ */ ++ return 0; ++ unit_key_by_coord(coord, &key); ++ ++ if (extent_get_start(ext - 1) + extent_get_width(ext - 1) != ++ extent_get_start(replace)) ++ return 0; ++ /* ++ * we can glue, widen previous unit ++ */ ++ extent_set_width(find_data_subvol(coord), ext - 1, ++ extent_get_width(ext - 1) + extent_get_width(replace)); ++ ++ if (extent_get_width(ext) != extent_get_width(replace)) { ++ /* make current extent narrower */ ++ if (state_of_extent(ext) == ALLOCATED_EXTENT) ++ extent_set_start(find_data_subvol(coord), ext, ++ extent_get_start(ext) + ++ extent_get_width(replace)); ++ extent_set_width(find_data_subvol(coord), ext, ++ extent_get_width(ext) - ++ extent_get_width(replace)); ++ } else { ++ /* ++ * current extent completely glued with its left ++ * neighbor, remove it ++ */ ++ coord_t from, to; ++ ++ coord_dup(&from, coord); ++ from.unit_pos = nr_units_extent(coord) - 1; ++ coord_dup(&to, &from); ++ /* ++ * Currently extent can be cut either from the ++ * beginning or from the end. Our unit can be ++ * in the middle, however. So we work around ++ * this. Move place which got freed after unit ++ * removal to end of item ++ */ ++ memmove(ext, ext + 1, ++ (from.unit_pos - ++ coord->unit_pos) * sizeof(reiser4_extent)); ++ /* ++ * wipe part of item which is going to be cut, so that ++ * check_node() will not be confused ++ */ ++ cut_node_content(&from, &to, NULL, NULL, NULL); ++ } ++ znode_make_dirty(coord->node); ++ /* move coord back */ ++ coord->unit_pos--; ++ return 1; ++} ++ ++/** ++ * convert_extent_unit - replace extent with 2 ones ++ * @coord: coordinate of extent to be replaced ++ * @replace: extent to overwrite the one @coord is set to ++ * ++ * Overwrites extent @coord is set to and paste one extent unit after ++ * overwritten one if @replace is shorter than initial extent ++ */ ++int convert_extent_unit(coord_t *coord, reiser4_extent *replace) ++{ ++ int result; ++ struct replace_handle *h; ++ reiser4_extent *ext; ++ item_id extent_id; ++ reiser4_block_nr start, width, new_width; ++ reiser4_block_nr was_grabbed; ++ extent_state state; ++ ++ ext = extent_by_coord(coord); ++ extent_id = item_id_by_coord(coord); ++ state = state_of_extent(ext); ++ start = extent_get_start(ext); ++ width = extent_get_width(ext); ++ new_width = extent_get_width(replace); ++ ++ assert("vs-1458", (state == UNALLOCATED_EXTENT || ++ state == ALLOCATED_EXTENT)); ++ assert("vs-1459", width >= new_width); ++ ++ if (try_to_merge_with_left(coord, ext, replace)) { ++ /* ++ * @replace was merged with left neighbor. ++ * Current unit is either removed or narrowed ++ */ ++ if (width == new_width && ++ coord->unit_pos < coord_last_unit_pos(coord)) { ++ coord_t tcoord; ++ coord_dup(&tcoord, coord); ++ tcoord.unit_pos ++; ++ /* ++ * Current unit has been removed and now @coord ++ * is pointing out to the unit that it was merged ++ * with. Here it can happen that the last one is ++ * mergeable with the right unit (pointed out by ++ * @tcoord). If so, then merge them. ++ */ ++ try_to_merge_with_left(&tcoord, ++ extent_by_coord(&tcoord), ++ extent_by_coord(&tcoord)); ++ } ++ return 0; ++ } ++ if (width == new_width) { ++ /* ++ * replace current extent with @replace ++ */ ++ *ext = *replace; ++ /* ++ * After replacing it can happen that the unit is ++ * mergeable with the right unit (if there is one). ++ * If so, then merge them. ++ */ ++ if (coord->unit_pos < coord_last_unit_pos(coord)) { ++ coord_t tcoord; ++ coord_dup(&tcoord, coord); ++ tcoord.unit_pos ++; ++ ++ try_to_merge_with_left(&tcoord, ++ extent_by_coord(&tcoord), ++ extent_by_coord(&tcoord)); ++ } ++ znode_make_dirty(coord->node); ++ return 0; ++ } ++ ++ h = kmalloc(sizeof(*h), reiser4_ctx_gfp_mask_get()); ++ if (h == NULL) ++ return RETERR(-ENOMEM); ++ h->coord = coord; ++ h->lh = znode_lh(coord->node); ++ h->pkey = &h->key; ++ unit_key_by_coord(coord, h->pkey); ++ set_key_offset(h->pkey, ++ (get_key_offset(h->pkey) + new_width * current_blocksize)); ++ h->overwrite = *replace; ++ ++ /* replace @ext with @replace and padding extent */ ++ reiser4_set_extent(find_data_subvol(coord), ++ &h->new_extents[0], ++ (state == ALLOCATED_EXTENT) ? ++ (start + new_width) : ++ UNALLOCATED_EXTENT_START, ++ width - new_width); ++ h->nr_new_extents = 1; ++ h->flags = COPI_DONT_SHIFT_LEFT; ++ h->paste_key = h->key; ++ ++ /* reserve space for extent unit paste, @grabbed is reserved before */ ++ was_grabbed = reserve_replace(get_meta_subvol()); ++ result = replace_extent_unit(extent_id, h, 0 /* leave @coord set ++ to overwritten ++ extent */); ++ /* restore reserved */ ++ grabbed2free_mark(was_grabbed, get_meta_subvol()); ++ kfree(h); ++ return result; ++} ++ ++/** ++ * assign_real_blocknrs ++ * @flush_pos: ++ * @oid: objectid of file jnodes to assign block number to belongs to ++ * @index: first jnode on the range ++ * @count: number of jnodes to assign block numbers to ++ * @first: start of allocated block range ++ * ++ * Assigns block numbers to each of @count jnodes. Index of first jnode is ++ * @index. Jnodes get lookuped with jlookup. ++ */ ++void assign_real_blocknrs(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, reiser4_block_nr count, ++ reiser4_block_nr first, reiser4_subvol *subv) ++{ ++ unsigned long i; ++ txn_atom *atom; ++ int nr; ++ ++ atom = atom_locked_by_fq(flush_pos->fq); ++ assert("vs-1468", atom); ++ BUG_ON(atom == NULL); ++ ++ nr = 0; ++ for (i = 0; i < count; ++i, ++index) { ++ jnode *node; ++ ++ node = jlookup(oid, index); ++ assert("", node != NULL); ++ BUG_ON(node == NULL); ++ ++ spin_lock_jnode(node); ++ assert("", !jnode_is_flushprepped(node)); ++ assert("vs-1475", node->atom == atom); ++ assert("vs-1476", atomic_read(&node->x_count) > 0); ++ ++ JF_CLR(node, JNODE_FLUSH_RESERVED); ++ assert("edward-2218", node->subvol != NULL); ++ jnode_set_block(node, &first); ++ unformatted_make_reloc(node, flush_pos->fq); ++ ON_DEBUG(count_jnode(node->atom, node, NODE_LIST(node), ++ FQ_LIST, 0)); ++ spin_unlock_jnode(node); ++ first++; ++ ++ atomic_dec(&node->x_count); ++ nr ++; ++ } ++ ++ spin_unlock_atom(atom); ++ return; ++} ++ ++/** ++ * Find out how many adjacent blocks of an allocated extent (specified ++ * by @index and @count) belong to the atom and are not "flushprepped". ++ * It is used by the flush procedure when making reallocation decisions ++ */ ++int allocated_extent_slum_size(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, unsigned long count) ++{ ++ unsigned long i; ++ txn_atom *atom; ++ int nr; ++ ++ atom = atom_locked_by_fq(reiser4_pos_fq(flush_pos)); ++ assert("vs-1468", atom); ++ ++ nr = 0; ++ ++ for (i = 0; i < count; ++i, ++index) { ++ jnode *node; ++ ++ node = jlookup(oid, index); ++ if (!node) ++ break; ++ ++ if (jnode_check_flushprepped(node)) { ++ atomic_dec(&node->x_count); ++ break; ++ } ++ if (node->atom != atom) { ++ /* ++ * this is possible on overwrite: extent_write may ++ * capture several unformatted nodes without capturing ++ * any formatted nodes. ++ */ ++ atomic_dec(&node->x_count); ++ break; ++ } ++ assert("vs-1476", atomic_read(&node->x_count) > 1); ++ atomic_dec(&node->x_count); ++ nr ++; ++ } ++ spin_unlock_atom(atom); ++ return nr; ++} ++ ++static inline int are_units_mergeable(reiser4_extent *left, ++ reiser4_extent *right) ++{ ++ if (state_of_extent(left) != state_of_extent(right)) ++ return 0; ++ switch (state_of_extent(left)) { ++ case HOLE_EXTENT: ++ return 1; ++ case ALLOCATED_EXTENT: ++ return extent_get_start(left) + extent_get_width(left) == ++ extent_get_start(right); ++ default: ++ impossible("edward-2092", "Bad extent state (%d)", ++ state_of_extent(left)); ++ return 0; ++ } ++} ++ ++/** ++ * Copy an extent unit @ext at position @coord to the end of ++ * node @dst. ++ * @key is the key of that extent unit. ++ * ++ * It may have to either insert new item after the last one, ++ * or append last item, or modify last unit of last item to ++ * have greater width. If there is no enough spece on the @dst ++ * then return -E_NODE_FULL ++ */ ++int shift_extent_left_begin(znode *dst, const coord_t *coord, ++ const reiser4_key *key, reiser4_extent *ext) ++{ ++ int result; ++ coord_t dst_coord; ++ cop_insert_flag flags; ++ reiser4_item_data data; ++ ++ coord_init_last_unit(&dst_coord, dst); ++ dst_coord.between = AFTER_UNIT; ++ ++ flags = COPI_DONT_SHIFT_LEFT | ++ COPI_DONT_SHIFT_RIGHT | COPI_DONT_ALLOCATE; ++ ++ if (!are_items_mergeable(&dst_coord, coord)) ++ /* ++ * create a new item ++ */ ++ result = insert_by_coord(&dst_coord, ++ init_new_extent(item_id_by_coord(coord), ++ &data, ext, 1), ++ key, NULL /*lh */ , flags); ++ else { ++ /* ++ * push to existing item ++ */ ++ reiser4_extent *dst_ext; ++ assert("edward-2091", item_is_extent(&dst_coord)); ++ ++ dst_ext = extent_by_coord(&dst_coord); ++ ++ if (are_units_mergeable(dst_ext, ext)) { ++ /* ++ * fast paste ++ */ ++ extent_set_width(find_data_subvol(&dst_coord), dst_ext, ++ extent_get_width(dst_ext) + ++ extent_get_width(ext)); ++ znode_make_dirty(dst); ++ return 0; ++ } ++ /* paste */ ++ result = insert_into_item(&dst_coord, NULL /*lh */, key, ++ init_new_extent(item_id_by_coord(coord), ++ &data, ext, 1), ++ flags); ++ } ++ assert("vs-438", result == 0 || result == -E_NODE_FULL); ++ return result; ++} ++ ++/* ++ * complete shifting started by shift_extent_left_begin(). Cut the original unit. ++ */ ++int shift_extent_left_complete(coord_t *to, reiser4_key *to_key, ++ znode *left) ++{ ++ coord_t from; ++ reiser4_key from_key; ++ ++ coord_init_first_unit(&from, to->node); ++ item_key_by_coord(&from, &from_key); ++ ++ return cut_node_content(&from, to, &from_key, to_key, NULL); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent.h linux-5.10.2/fs/reiser4/plugin/item/extent.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent.h 2020-12-23 16:07:46.127813261 +0100 +@@ -0,0 +1,252 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#ifndef __REISER4_EXTENT_H__ ++#define __REISER4_EXTENT_H__ ++ ++/* on disk extent */ ++typedef struct { ++ reiser4_dblock_nr start; ++ reiser4_dblock_nr width; ++} reiser4_extent; ++ ++struct extent_stat { ++ int unallocated_units; ++ int unallocated_blocks; ++ int allocated_units; ++ int allocated_blocks; ++ int hole_units; ++ int hole_blocks; ++}; ++ ++/* extents in an extent item can be either holes, or unallocated or allocated ++ extents */ ++typedef enum { ++ HOLE_EXTENT, ++ UNALLOCATED_EXTENT, ++ ALLOCATED_EXTENT ++} extent_state; ++ ++#define HOLE_EXTENT_START 0 ++#define UNALLOCATED_EXTENT_START 1 ++ ++struct extent_coord_extension { ++ reiser4_block_nr pos_in_unit; ++ reiser4_block_nr width; /* width of current unit */ ++ pos_in_node_t nr_units; /* number of units */ ++ int ext_offset; /* offset from the beginning of zdata() */ ++ unsigned long expected_page; ++#if REISER4_DEBUG ++ reiser4_extent extent; ++#endif ++}; ++ ++/* macros to set/get fields of on-disk extent */ ++static inline reiser4_block_nr extent_get_start(const reiser4_extent * ext) ++{ ++ return le64_to_cpu(ext->start); ++} ++ ++static inline reiser4_block_nr extent_get_width(const reiser4_extent * ext) ++{ ++ return le64_to_cpu(ext->width); ++} ++ ++extern __u64 reiser4_subvol_block_count(const reiser4_subvol *); ++ ++static inline void extent_set_start(reiser4_subvol *subv, reiser4_extent *ext, ++ reiser4_block_nr start) ++{ ++ static_assert(sizeof(ext->start) == 8); ++ ++ assert("edward-2269", subv != NULL); ++ assert("nikita-2510", ergo(start > 1, ++ start < reiser4_subvol_block_count(subv))); ++ ++ put_unaligned(cpu_to_le64(start), &ext->start); ++} ++ ++static inline void extent_set_width(reiser4_subvol *subv, ++ reiser4_extent *ext, ++ reiser4_block_nr width) ++{ ++ static_assert(sizeof(ext->width) == 8); ++ assert("edward-2270", width > 0); ++ assert("edward-2271", subv != NULL); ++ ++ put_unaligned(cpu_to_le64(width), &ext->width); ++ ++ assert("nikita-2511", ++ ergo(extent_get_start(ext) > 1, ++ extent_get_start(ext) + width <= ++ reiser4_subvol_block_count(subv))); ++} ++ ++#define extent_item(coord) \ ++({ \ ++ assert("nikita-3143", item_is_extent(coord)); \ ++ ((reiser4_extent *)item_body_by_coord (coord)); \ ++}) ++ ++#define extent_by_coord(coord) \ ++({ \ ++ assert("nikita-3144", item_is_extent(coord)); \ ++ (extent_item (coord) + (coord)->unit_pos); \ ++}) ++ ++#define width_by_coord(coord) \ ++({ \ ++ assert("nikita-3145", item_is_extent(coord)); \ ++ extent_get_width (extent_by_coord(coord)); \ ++}) ++ ++struct carry_cut_data; ++struct carry_kill_data; ++ ++/* plugin->u.item.b.* */ ++reiser4_key *max_key_inside_extent(const coord_t *, reiser4_key *); ++int can_contain_key_extent(const coord_t * coord, const reiser4_key * key, ++ const reiser4_item_data *); ++int mergeable_extent40(const coord_t *p1, const coord_t *p2); ++int mergeable_extent41(const coord_t *p1, const coord_t *p2); ++pos_in_node_t nr_units_extent(const coord_t *); ++lookup_result lookup_extent(const reiser4_key *, lookup_bias, coord_t *); ++void init_coord_extent(coord_t *); ++int init_extent(coord_t *, reiser4_item_data *); ++int paste_extent(coord_t *, reiser4_item_data *, carry_plugin_info *); ++int can_shift_extent(unsigned free_space, ++ coord_t * source, znode * target, shift_direction, ++ unsigned *size, unsigned want); ++void copy_units_extent(coord_t * target, coord_t * source, unsigned from, ++ unsigned count, shift_direction where_is_free_space, ++ unsigned free_space); ++size_t merge_units_extent(coord_t *left, coord_t *right); ++int kill_hook_extent(const coord_t *, pos_in_node_t from, pos_in_node_t count, ++ struct carry_kill_data *); ++int create_hook_extent(const coord_t * coord, void *arg); ++int cut_units_extent(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++int kill_units_extent(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++reiser4_key *unit_key_extent(const coord_t *, reiser4_key *); ++reiser4_key *max_unit_key_extent(const coord_t *, reiser4_key *); ++void print_extent(const char *, coord_t *); ++int utmost_child_extent(const coord_t * coord, sideof side, jnode ** child); ++int utmost_child_real_block_extent(const coord_t * coord, sideof side, ++ reiser4_block_nr * block); ++void item_stat_extent(const coord_t * coord, void *vp); ++int reiser4_check_extent(const coord_t * coord, const char **error); ++ ++/* plugin->u.item.s.file */ ++ssize_t write_extent_unix_file(struct file *, struct inode * inode, ++ const char __user *, size_t, loff_t *); ++ssize_t write_extent_stripe(struct file *, struct inode * inode, ++ const char __user *, size_t, loff_t *, ++ unsigned flags); ++int read_extent_unix_file(struct file *, flow_t *, hint_t *); ++int read_extent_stripe(struct file *, flow_t *, hint_t *); ++int readpage_extent_stripe(void *, struct page *); ++int reiser4_readpage_extent(void *, struct page *); ++int __reiser4_readpage_extent(const coord_t *coord, reiser4_extent *, ++ reiser4_block_nr, struct page *); ++reiser4_key *append_key_extent(const coord_t *, reiser4_key *); ++void init_coord_extension_extent(uf_coord_t *, loff_t offset); ++int get_block_address_extent(const coord_t *, sector_t block, ++ sector_t * result); ++ ++/* plugin->u.item.s.vol */ ++int reiser4_migrate_extent(coord_t *coord, reiser4_key *, lock_handle *lh, ++ struct inode *inode, loff_t *done_off, u64 *dst_id); ++/* these are used in flush.c ++ FIXME-VS: should they be somewhere in item_plugin? */ ++int allocate_extent_item_in_place(coord_t *, lock_handle *, flush_pos_t * pos); ++int allocate_and_copy_extent(znode * left, coord_t * right, flush_pos_t * pos, ++ reiser4_key * stop_key); ++ ++int extent_is_unallocated(const coord_t * item); /* True if this extent is unallocated (i.e., not a hole, not allocated). */ ++__u64 extent_unit_index(const coord_t * item); /* Block offset of this unit. */ ++__u64 extent_unit_width(const coord_t * item); /* Number of blocks in this unit. */ ++ ++/* plugin->u.item.f. */ ++int reiser4_scan_extent(flush_scan * scan); ++ ++reiser4_item_data *init_new_extent(item_id extent_id, reiser4_item_data *data, ++ void *ext_unit, int nr_extents); ++reiser4_block_nr reiser4_extent_size_at(const coord_t *coord, pos_in_node_t nr); ++reiser4_block_nr reiser4_extent_size(const coord_t *coord); ++extent_state state_of_extent(reiser4_extent * ext); ++void reiser4_set_extent(reiser4_subvol *subv, reiser4_extent *, ++ reiser4_block_nr start, reiser4_block_nr width); ++int update_extent_unix_file(struct inode *, jnode *, loff_t pos, ++ int *plugged_hole); ++int update_extent_stripe(hint_t *hint, struct inode *, jnode *, int *plugged_hole, ++ unsigned flags); ++ ++#include "../../coord.h" ++#include "../../lock.h" ++#include "../../tap.h" ++ ++struct replace_handle { ++ /* these are to be set before calling replace_extent_unit */ ++ coord_t *coord; ++ lock_handle *lh; ++ reiser4_key key; ++ reiser4_key *pkey; ++ reiser4_extent overwrite; ++ reiser4_extent new_extents[2]; ++ int nr_new_extents; ++ unsigned flags; ++ ++ /* these are used by replace_extent_unit */ ++ reiser4_item_data item; ++ coord_t coord_after; ++ lock_handle lh_after; ++ tap_t watch; ++ reiser4_key paste_key; ++#if REISER4_DEBUG ++ reiser4_extent orig_ext; ++ reiser4_key tmp; ++#endif ++}; ++ ++/* ++ * this structure is kmalloced before calling make_extent to avoid ++ * excessive stack consumption on plug_hole->replace_extent_unit() ++ */ ++struct make_extent_handle { ++ uf_coord_t *uf_coord; ++ reiser4_block_nr blocknr; ++ int created; ++ struct inode *inode; ++ union { ++ struct { ++ } append; ++ struct replace_handle replace; ++ } u; ++}; ++ ++int replace_extent_unit(item_id extent_id, struct replace_handle *, ++ int return_inserted_position); ++lock_handle *znode_lh(znode *); ++ ++/* the reiser4 repacker support */ ++struct repacker_cursor; ++extern int process_extent_backward_for_repacking(tap_t *, ++ struct repacker_cursor *); ++extern int mark_extent_for_repacking(tap_t *, int); ++ ++#define coord_by_uf_coord(uf_coord) (&((uf_coord)->coord)) ++#define ext_coord_by_uf_coord(uf_coord) (&((uf_coord)->extension.extent)) ++ ++/* __REISER4_EXTENT_H__ */ ++#endif ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent_item_ops.c linux-5.10.2/fs/reiser4/plugin/item/extent_item_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent_item_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent_item_ops.c 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,989 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "item.h" ++#include "../../inode.h" ++#include "../../tree_walk.h" /* check_sibling_list() */ ++#include "../../page_cache.h" ++#include "../../carry.h" ++ ++/* item_plugin->b.max_key_inside */ ++reiser4_key *max_key_inside_extent(const coord_t * coord, reiser4_key * key) ++{ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, get_key_offset(reiser4_max_key())); ++ return key; ++} ++ ++/* item_plugin->b.can_contain_key ++ this checks whether @key of @data is matching to position set by @coord */ ++int ++can_contain_key_extent(const coord_t * coord, const reiser4_key * key, ++ const reiser4_item_data * data) ++{ ++ reiser4_key item_key; ++ ++ if (item_plugin_by_coord(coord) != data->iplug) ++ return 0; ++ ++ item_key_by_coord(coord, &item_key); ++ if (get_key_locality(key) != get_key_locality(&item_key) || ++ get_key_objectid(key) != get_key_objectid(&item_key) || ++ get_key_ordering(key) != get_key_ordering(&item_key)) ++ return 0; ++ ++ return 1; ++} ++ ++/** ++ * Check if extent @p1 of type @extent_id is mergeable with @p2 ++ */ ++static inline int mergeable_extent(item_id extent_id, ++ const coord_t *p1, const coord_t *p2) ++{ ++ reiser4_key key1, key2; ++ ++ assert("vs-299", item_id_by_coord(p1) == extent_id); ++ /* ++ * FIXME-VS: Which is it? Assert or return 0 ++ */ ++ if (item_id_by_coord(p2) != extent_id) ++ return 0; ++ ++ item_key_by_coord(p1, &key1); ++ item_key_by_coord(p2, &key2); ++ ++ if (get_key_locality(&key1) != get_key_locality(&key2) || ++ get_key_objectid(&key1) != get_key_objectid(&key2) || ++ get_key_ordering(&key1) != get_key_ordering(&key2) || ++ get_key_type(&key1) != get_key_type(&key2)) ++ return 0; ++ if (get_key_offset(&key1) + ++ reiser4_extent_size_at(p1, nr_units_extent(p1)) != ++ get_key_offset(&key2)) ++ return 0; ++ return 1; ++} ++ ++/** ++ * item_plugin->b.mergeable ++ */ ++int mergeable_extent40(const coord_t *p1, const coord_t *p2) ++{ ++ return mergeable_extent(EXTENT40_POINTER_ID, p1, p2); ++} ++ ++int mergeable_extent41(const coord_t *p1, const coord_t *p2) ++{ ++ return mergeable_extent(EXTENT41_POINTER_ID, p1, p2); ++} ++ ++/* item_plugin->b.nr_units */ ++pos_in_node_t nr_units_extent(const coord_t * coord) ++{ ++ /* length of extent item has to be multiple of extent size */ ++ assert("vs-1424", ++ (item_length_by_coord(coord) % sizeof(reiser4_extent)) == 0); ++ return item_length_by_coord(coord) / sizeof(reiser4_extent); ++} ++ ++/* item_plugin->b.lookup */ ++lookup_result ++lookup_extent(const reiser4_key * key, lookup_bias bias UNUSED_ARG, ++ coord_t * coord) ++{ /* znode and item_pos are ++ set to an extent item to ++ look through */ ++ reiser4_key item_key; ++ reiser4_block_nr lookuped, offset; ++ unsigned i, nr_units; ++ reiser4_extent *ext; ++ unsigned blocksize; ++ unsigned char blocksize_bits; ++ ++ item_key_by_coord(coord, &item_key); ++ offset = get_key_offset(&item_key); ++ ++ /* key we are looking for must be greater than key of item @coord */ ++ assert("vs-414", keygt(key, &item_key)); ++ ++ assert("umka-99945", ++ !keygt(key, max_key_inside_extent(coord, &item_key))); ++ ++ ext = extent_item(coord); ++ assert("vs-1350", (char *)ext == (zdata(coord->node) + coord->offset)); ++ ++ blocksize = current_blocksize; ++ blocksize_bits = current_blocksize_bits; ++ ++ /* offset we are looking for */ ++ lookuped = get_key_offset(key); ++ ++ nr_units = nr_units_extent(coord); ++ /* go through all extents until the one which address given offset */ ++ for (i = 0; i < nr_units; i++, ext++) { ++ offset += (extent_get_width(ext) << blocksize_bits); ++ if (offset > lookuped) { ++ /* desired byte is somewhere in this extent */ ++ coord->unit_pos = i; ++ coord->between = AT_UNIT; ++ return CBK_COORD_FOUND; ++ } ++ } ++ ++ /* set coord after last unit */ ++ coord->unit_pos = nr_units - 1; ++ coord->between = AFTER_UNIT; ++ return CBK_COORD_FOUND; ++} ++ ++/* item_plugin->b.paste ++ item @coord is set to has been appended with @data->length of free ++ space. data->data contains data to be pasted into the item in position ++ @coord->in_item.unit_pos. It must fit into that free space. ++ @coord must be set between units. ++*/ ++int ++paste_extent(coord_t * coord, reiser4_item_data * data, ++ carry_plugin_info * info UNUSED_ARG) ++{ ++ unsigned old_nr_units; ++ reiser4_extent *ext; ++ int item_length; ++ ++ ext = extent_item(coord); ++ item_length = item_length_by_coord(coord); ++ old_nr_units = (item_length - data->length) / sizeof(reiser4_extent); ++ ++ /* this is also used to copy extent into newly created item, so ++ old_nr_units could be 0 */ ++ assert("vs-260", item_length >= data->length); ++ ++ /* make sure that coord is set properly */ ++ assert("vs-35", ++ ((!coord_is_existing_unit(coord)) ++ || (!old_nr_units && !coord->unit_pos))); ++ ++ /* first unit to be moved */ ++ switch (coord->between) { ++ case AFTER_UNIT: ++ coord->unit_pos++; ++ /* fall through */ ++ case BEFORE_UNIT: ++ coord->between = AT_UNIT; ++ break; ++ case AT_UNIT: ++ assert("vs-331", !old_nr_units && !coord->unit_pos); ++ break; ++ default: ++ impossible("vs-330", "coord is set improperly"); ++ } ++ ++ /* prepare space for new units */ ++ memmove(ext + coord->unit_pos + data->length / sizeof(reiser4_extent), ++ ext + coord->unit_pos, ++ (old_nr_units - coord->unit_pos) * sizeof(reiser4_extent)); ++ ++ /* copy new data from kernel space */ ++ assert("vs-556", data->user == 0); ++ memcpy(ext + coord->unit_pos, data->data, (unsigned)data->length); ++ ++ /* after paste @coord is set to first of pasted units */ ++ assert("vs-332", coord_is_existing_unit(coord)); ++ assert("vs-333", ++ !memcmp(data->data, extent_by_coord(coord), ++ (unsigned)data->length)); ++ return 0; ++} ++ ++/* item_plugin->b.can_shift */ ++int ++can_shift_extent(unsigned free_space, coord_t * source, ++ znode * target UNUSED_ARG, shift_direction pend UNUSED_ARG, ++ unsigned *size, unsigned want) ++{ ++ *size = item_length_by_coord(source); ++ if (*size > free_space) ++ /* never split a unit of extent item */ ++ *size = free_space - free_space % sizeof(reiser4_extent); ++ ++ /* we can shift *size bytes, calculate how many do we want to shift */ ++ if (*size > want * sizeof(reiser4_extent)) ++ *size = want * sizeof(reiser4_extent); ++ ++ if (*size % sizeof(reiser4_extent) != 0) ++ impossible("vs-119", "Wrong extent size: %i %zd", *size, ++ sizeof(reiser4_extent)); ++ return *size / sizeof(reiser4_extent); ++ ++} ++ ++/* item_plugin->b.copy_units */ ++void ++copy_units_extent(coord_t * target, coord_t * source, ++ unsigned from, unsigned count, ++ shift_direction where_is_free_space, unsigned free_space) ++{ ++ char *from_ext, *to_ext; ++ ++ assert("vs-217", free_space == count * sizeof(reiser4_extent)); ++ ++ from_ext = item_body_by_coord(source); ++ to_ext = item_body_by_coord(target); ++ ++ if (where_is_free_space == SHIFT_LEFT) { ++ assert("vs-215", from == 0); ++ ++ /* At this moment, item length was already updated in the item ++ header by shifting code, hence nr_units_extent() will ++ return "new" number of units---one we obtain after copying ++ units. ++ */ ++ to_ext += ++ (nr_units_extent(target) - count) * sizeof(reiser4_extent); ++ } else { ++ reiser4_key key; ++ coord_t coord; ++ ++ assert("vs-216", ++ from + count == coord_last_unit_pos(source) + 1); ++ ++ from_ext += item_length_by_coord(source) - free_space; ++ ++ /* new units are inserted before first unit in an item, ++ therefore, we have to update item key */ ++ coord = *source; ++ coord.unit_pos = from; ++ unit_key_extent(&coord, &key); ++ ++ node_plugin_by_node(target->node)->update_item_key(target, &key, ++ NULL /*info */); ++ } ++ ++ memcpy(to_ext, from_ext, free_space); ++} ++ ++/** ++ * item_plugin->b.merge_units. See comment in item.h ++ * Don't use this function in other contexts. ++ */ ++size_t merge_units_extent(coord_t *left, coord_t *right) ++{ ++ coord_t uleft, uright; ++ reiser4_extent *ext_left; ++ reiser4_extent *ext_right; ++ size_t tail_size; ++ ++ assert("edward-2129", item_is_extent(left)); ++ assert("edward-2135", item_is_extent(right)); ++ ++ coord_dup(&uleft, left); ++ uleft.unit_pos = coord_num_units(left) - 1; ++ uleft.between = AT_UNIT; ++ ++ coord_dup(&uright, right); ++ uright.unit_pos = 0; ++ uright.between = AT_UNIT; ++ ++ ext_left = extent_by_coord(&uleft); ++ ext_right = extent_by_coord(&uright); ++ ++ assert("edward-2136", ext_right == ext_left + 1); ++ ++ if ((state_of_extent(ext_left) != state_of_extent(ext_right)) || ++ ((state_of_extent(ext_left) == ALLOCATED_EXTENT) && ++ (extent_get_start(ext_left) + extent_get_width(ext_left) != ++ extent_get_start(ext_right)))) ++ /* units are not mergeable */ ++ return 0; ++ /* ++ * widen @ext_left ++ */ ++ extent_set_width(find_data_subvol(&uleft), ext_left, ++ extent_get_width(ext_left) + ++ extent_get_width(ext_right)); ++ /* ++ * move units at the right of @ext_right to the left. ++ * This will drop @ext_right and make the node inconsistent ++ * (see the comment above) ++ */ ++ tail_size = sizeof(reiser4_extent) * (coord_num_units(right) - 1); ++ memmove(ext_right, ext_right + 1, tail_size); ++ return sizeof(reiser4_extent); ++} ++ ++/* item_plugin->b.create_hook ++ @arg is znode of leaf node for which we need to update right delimiting key */ ++int create_hook_extent(const coord_t * coord, void *arg) ++{ ++ coord_t *child_coord; ++ znode *node; ++ reiser4_key key; ++ reiser4_tree *tree; ++ ++ if (!arg) ++ return 0; ++ ++ child_coord = arg; ++ tree = znode_get_tree(coord->node); ++ ++ assert("nikita-3246", znode_get_level(child_coord->node) == LEAF_LEVEL); ++ ++ write_lock_tree(); ++ write_lock_dk(tree); ++ /* find a node on the left level for which right delimiting key has to ++ be updated */ ++ if (coord_wrt(child_coord) == COORD_ON_THE_LEFT) { ++ assert("vs-411", znode_is_left_connected(child_coord->node)); ++ node = child_coord->node->left; ++ } else { ++ assert("vs-412", coord_wrt(child_coord) == COORD_ON_THE_RIGHT); ++ node = child_coord->node; ++ assert("nikita-3314", node != NULL); ++ } ++ ++ if (node != NULL) { ++ znode_set_rd_key(node, item_key_by_coord(coord, &key)); ++ ++ assert("nikita-3282", check_sibling_list(node)); ++ /* break sibling links */ ++ if (ZF_ISSET(node, JNODE_RIGHT_CONNECTED) && node->right) { ++ ON_DEBUG(node->right->left_version = ++ atomic_inc_return(&delim_key_version); ++ node->right_version = ++ atomic_inc_return(&delim_key_version);); ++ ++ node->right->left = NULL; ++ node->right = NULL; ++ } ++ } ++ write_unlock_dk(tree); ++ write_unlock_tree(); ++ return 0; ++} ++ ++#define ITEM_TAIL_KILLED 0 ++#define ITEM_HEAD_KILLED 1 ++#define ITEM_KILLED 2 ++ ++/** ++ * item_plugin->b.kill_hook ++ * this is called when @count units starting from @from-th ++ * one are going to be removed ++ */ ++int kill_hook_extent(const coord_t *coord, pos_in_node_t from, ++ pos_in_node_t count, struct carry_kill_data *kdata) ++{ ++ reiser4_extent *ext; ++ reiser4_block_nr start, length; ++ const reiser4_key *pfrom_key, *pto_key; ++ struct inode *inode; ++ reiser4_tree *tree; ++ pgoff_t from_off, to_off, offset, skip; ++ int retval; ++ reiser4_subvol *subv; ++ ++ /* these are located in memory kmalloc-ed by kill_node_content */ ++ reiser4_key *min_item_key, *max_item_key, *from_key, *to_key, *key; ++ coord_t *dup, *next; ++ ++ assert("edward-1850", item_is_extent(coord)); ++ assert("zam-811", znode_is_write_locked(coord->node)); ++ assert("nikita-3315", kdata != NULL); ++ assert("vs-34", kdata->buf != NULL); ++ ++ subv = find_data_subvol(coord); ++ tree = &subv->tree; ++ ++ /* map structures to kdata->buf */ ++ min_item_key = (reiser4_key *) (kdata->buf); ++ max_item_key = min_item_key + 1; ++ from_key = max_item_key + 1; ++ to_key = from_key + 1; ++ key = to_key + 1; ++ dup = (coord_t *) (key + 1); ++ next = dup + 1; ++ ++ item_key_by_coord(coord, min_item_key); ++ max_item_key_by_coord(coord, max_item_key); ++ ++ if (kdata->params.from_key) { ++ pfrom_key = kdata->params.from_key; ++ pto_key = kdata->params.to_key; ++ } else { ++ assert("vs-1549", from == coord->unit_pos); ++ unit_key_by_coord(coord, from_key); ++ pfrom_key = from_key; ++ ++ coord_dup(dup, coord); ++ dup->unit_pos = from + count - 1; ++ max_unit_key_by_coord(dup, to_key); ++ pto_key = to_key; ++ } ++ /* ++ * Evaluate, which part of the item is to be removed. ++ * Only 3 cases are possible: ++ * ++ * 1. pfrom_key <= min_item_key && max_item_key <= pto_key ++ * ++ * from/to: *********** ++ * item: +++++ ++ * ++ * item to be removed completely ++ * ++ * 2. min_item_key < pfrom_key ++ * ++ * from/to: *********** ++ * item: +++++ ++ * ++ * tail of the item to be removed ++ * ++ * 3. max_item_key > pto_key; ++ * ++ * from/to: *********** ++ * item: +++++ ++ * ++ * head of the item to be removed ++ */ ++ if (keyle(pfrom_key, min_item_key) && keyle(max_item_key, pto_key)) { ++ znode *left, *right; ++ ++ /* item is to be removed completely */ ++ assert("nikita-3316", kdata->left != NULL ++ && kdata->right != NULL); ++ ++ left = kdata->left->node; ++ right = kdata->right->node; ++ ++ /* we have to do two things: ++ * ++ * 1. link left and right formatted neighbors of ++ * extent being removed, and ++ * ++ * 2. update their delimiting keys. ++ * ++ * atomicity of these operations is protected by ++ * taking dk-lock and tree-lock. ++ */ ++ /* if neighbors of item being removed are znodes - ++ * link them */ ++ write_lock_tree(); ++ write_lock_dk(tree); ++ link_left_and_right(left, right); ++ if (left) { ++ /* update right delimiting key of left ++ * neighbor of extent item */ ++ /*coord_t next; ++ reiser4_key key; */ ++ ++ coord_dup(next, coord); ++ ++ if (coord_next_item(next)) ++ *key = *znode_get_rd_key(coord->node); ++ else ++ item_key_by_coord(next, key); ++ znode_set_rd_key(left, key); ++ } ++ write_unlock_dk(tree); ++ write_unlock_tree(); ++ ++ from_off = ++ get_key_offset(min_item_key) >> PAGE_SHIFT; ++ to_off = ++ (get_key_offset(max_item_key) + ++ 1) >> PAGE_SHIFT; ++ retval = ITEM_KILLED; ++ ++ } else if (keylt(min_item_key, pfrom_key)) { ++ /* ++ * tail of item is to be removed ++ */ ++ from_off = ++ (get_key_offset(pfrom_key) + PAGE_SIZE - ++ 1) >> PAGE_SHIFT; ++ to_off = ++ (get_key_offset(max_item_key) + ++ 1) >> PAGE_SHIFT; ++ retval = ITEM_TAIL_KILLED; ++ } else { ++ assert("edward-2419", keylt(pto_key, max_item_key)); ++ /* ++ * head of item is to be removed ++ */ ++ assert("vs-1572", ++ (get_key_offset(pfrom_key) & (PAGE_SIZE - 1)) == ++ 0); ++ assert("vs-1573", ++ ((get_key_offset(pto_key) + 1) & (PAGE_SIZE - ++ 1)) == 0); ++ ++ if (kdata->left->node) { ++ /* update right delimiting key of left neighbor of extent item */ ++ /*reiser4_key key; */ ++ ++ *key = *pto_key; ++ set_key_offset(key, get_key_offset(pto_key) + 1); ++ ++ write_lock_dk(tree); ++ znode_set_rd_key(kdata->left->node, key); ++ write_unlock_dk(tree); ++ } ++ ++ from_off = get_key_offset(pfrom_key) >> PAGE_SHIFT; ++ to_off = (get_key_offset(pto_key) + 1) >> PAGE_SHIFT; ++ retval = ITEM_HEAD_KILLED; ++ } ++ ++ inode = kdata->inode; ++ assert("vs-1545", inode != NULL); ++ if (inode != NULL && ++ !reiser4_inode_get_flag(inode, REISER4_FILE_IN_MIGRATION)) ++ /* ++ * take care of pages and jnodes corresponding ++ * to the part of item being killed ++ */ ++ reiser4_invalidate_pages(inode->i_mapping, from_off, ++ to_off - from_off, ++ kdata->params.truncate); ++ ext = extent_item(coord) + from; ++ offset = ++ (get_key_offset(min_item_key) + ++ reiser4_extent_size_at(coord, from)) >> PAGE_SHIFT; ++ ++ assert("vs-1551", from_off >= offset); ++ assert("vs-1552", from_off - offset <= extent_get_width(ext)); ++ skip = from_off - offset; ++ offset = from_off; ++ ++ while (offset < to_off) { ++ length = extent_get_width(ext) - skip; ++ if (state_of_extent(ext) == HOLE_EXTENT) { ++ skip = 0; ++ offset += length; ++ ext++; ++ continue; ++ } ++ ++ if (offset + length > to_off) { ++ length = to_off - offset; ++ } ++ ++ inode_sub_blocks(inode, length); ++ ++ if (state_of_extent(ext) == UNALLOCATED_EXTENT) { ++ /* ++ * some jnodes corresponding to this unallocated extent ++ */ ++ fake_allocated2free(length, 0 /* unformatted */, subv); ++ skip = 0; ++ offset += length; ++ ext++; ++ continue; ++ } ++ ++ assert("vs-1218", state_of_extent(ext) == ALLOCATED_EXTENT); ++ ++ if (length != 0) { ++ start = extent_get_start(ext) + skip; ++ /* ++ * BA_DEFER bit parameter is turned on because blocks ++ * which get freed are not safe to be freed immediately ++ */ ++ reiser4_dealloc_blocks(&start, &length, ++ 0, /* not used */ ++ BA_DEFER, /* unformatted with defer */ ++ subv); ++ } ++ skip = 0; ++ offset += length; ++ ext++; ++ } ++ return retval; ++} ++ ++/* item_plugin->b.kill_units */ ++int ++kill_units_extent(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *kdata, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ reiser4_extent *ext; ++ reiser4_key item_key; ++ pos_in_node_t count; ++ reiser4_key from_key, to_key; ++ const reiser4_key *pfrom_key, *pto_key; ++ loff_t off; ++ int result; ++ ++ assert("vs-1541", ++ ((kdata->params.from_key == NULL && kdata->params.to_key == NULL) ++ || (kdata->params.from_key != NULL ++ && kdata->params.to_key != NULL))); ++ ++ if (kdata->params.from_key) { ++ pfrom_key = kdata->params.from_key; ++ pto_key = kdata->params.to_key; ++ } else { ++ coord_t dup; ++ ++ /* calculate key range of kill */ ++ assert("vs-1549", from == coord->unit_pos); ++ unit_key_by_coord(coord, &from_key); ++ pfrom_key = &from_key; ++ ++ coord_dup(&dup, coord); ++ dup.unit_pos = to; ++ max_unit_key_by_coord(&dup, &to_key); ++ pto_key = &to_key; ++ } ++ ++ item_key_by_coord(coord, &item_key); ++ ++#if REISER4_DEBUG ++ { ++ reiser4_key max_item_key; ++ ++ max_item_key_by_coord(coord, &max_item_key); ++ ++ if (new_first) { ++ /* head of item is to be cut */ ++ assert("vs-1542", keyeq(pfrom_key, &item_key)); ++ assert("vs-1538", keylt(pto_key, &max_item_key)); ++ } else { ++ /* tail of item is to be cut */ ++ assert("vs-1540", keygt(pfrom_key, &item_key)); ++ assert("vs-1543", !keylt(pto_key, &max_item_key)); ++ } ++ } ++#endif ++ ++ if (smallest_removed) ++ *smallest_removed = *pfrom_key; ++ ++ if (new_first) { ++ /* item head is cut. Item key will change. This new key is calculated here */ ++ assert("vs-1556", ++ (get_key_offset(pto_key) & (PAGE_SIZE - 1)) == ++ (PAGE_SIZE - 1)); ++ *new_first = *pto_key; ++ set_key_offset(new_first, get_key_offset(new_first) + 1); ++ } ++ ++ count = to - from + 1; ++ result = kill_hook_extent(coord, from, count, kdata); ++ if (result == ITEM_TAIL_KILLED) { ++ assert("vs-1553", ++ get_key_offset(pfrom_key) >= ++ get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, from)); ++ off = ++ get_key_offset(pfrom_key) - ++ (get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, from)); ++ if (off) { ++ /* unit @from is to be cut partially. Its width decreases */ ++ ext = extent_item(coord) + from; ++ extent_set_width(find_data_subvol(coord), ext, ++ (off + PAGE_SIZE - ++ 1) >> PAGE_SHIFT); ++ count--; ++ } ++ } else { ++ __u64 max_to_offset; ++ __u64 rest; ++ ++ assert("vs-1575", result == ITEM_HEAD_KILLED); ++ assert("", from == 0); ++ assert("", ++ ((get_key_offset(pto_key) + 1) & (PAGE_SIZE - ++ 1)) == 0); ++ assert("", ++ get_key_offset(pto_key) + 1 > ++ get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, to)); ++ max_to_offset = ++ get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, to + 1) - 1; ++ assert("", get_key_offset(pto_key) <= max_to_offset); ++ ++ rest = ++ (max_to_offset - ++ get_key_offset(pto_key)) >> PAGE_SHIFT; ++ if (rest) { ++ /* unit @to is to be cut partially */ ++ ext = extent_item(coord) + to; ++ ++ assert("", extent_get_width(ext) > rest); ++ ++ if (state_of_extent(ext) == ALLOCATED_EXTENT) ++ extent_set_start(find_data_subvol(coord), ext, ++ extent_get_start(ext) + ++ (extent_get_width(ext) - ++ rest)); ++ ++ extent_set_width(find_data_subvol(coord), ext, rest); ++ count--; ++ } ++ } ++ return count * sizeof(reiser4_extent); ++} ++ ++/* item_plugin->b.cut_units ++ this is too similar to kill_units_extent */ ++int ++cut_units_extent(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *cdata, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ reiser4_extent *ext; ++ reiser4_key item_key; ++ pos_in_node_t count; ++ reiser4_key from_key, to_key; ++ const reiser4_key *pfrom_key, *pto_key; ++ loff_t off; ++ ++ assert("vs-1541", ++ ((cdata->params.from_key == NULL && cdata->params.to_key == NULL) ++ || (cdata->params.from_key != NULL ++ && cdata->params.to_key != NULL))); ++ ++ if (cdata->params.from_key) { ++ pfrom_key = cdata->params.from_key; ++ pto_key = cdata->params.to_key; ++ } else { ++ coord_t dup; ++ ++ /* calculate key range of kill */ ++ coord_dup(&dup, coord); ++ dup.unit_pos = from; ++ unit_key_by_coord(&dup, &from_key); ++ ++ dup.unit_pos = to; ++ max_unit_key_by_coord(&dup, &to_key); ++ ++ pfrom_key = &from_key; ++ pto_key = &to_key; ++ } ++ ++ assert("vs-1555", ++ (get_key_offset(pfrom_key) & (PAGE_SIZE - 1)) == 0); ++ assert("vs-1556", ++ (get_key_offset(pto_key) & (PAGE_SIZE - 1)) == ++ (PAGE_SIZE - 1)); ++ ++ item_key_by_coord(coord, &item_key); ++ ++#if REISER4_DEBUG ++ { ++ reiser4_key max_item_key; ++ ++ assert("vs-1584", ++ get_key_locality(pfrom_key) == ++ get_key_locality(&item_key)); ++ assert("vs-1585", ++ get_key_type(pfrom_key) == get_key_type(&item_key)); ++ assert("vs-1586", ++ get_key_objectid(pfrom_key) == ++ get_key_objectid(&item_key)); ++ assert("vs-1587", ++ get_key_ordering(pfrom_key) == ++ get_key_ordering(&item_key)); ++ ++ max_item_key_by_coord(coord, &max_item_key); ++ ++ if (new_first != NULL) { ++ /* head of item is to be cut */ ++ assert("vs-1542", keyeq(pfrom_key, &item_key)); ++ assert("vs-1538", keylt(pto_key, &max_item_key)); ++ } else { ++ /* tail of item is to be cut */ ++ assert("vs-1540", keygt(pfrom_key, &item_key)); ++ assert("vs-1543", keyeq(pto_key, &max_item_key)); ++ } ++ } ++#endif ++ ++ if (smallest_removed) ++ *smallest_removed = *pfrom_key; ++ ++ if (new_first) { ++ /* item head is cut. Item key will change. This new key is calculated here */ ++ *new_first = *pto_key; ++ set_key_offset(new_first, get_key_offset(new_first) + 1); ++ } ++ ++ count = to - from + 1; ++ ++ assert("vs-1553", ++ get_key_offset(pfrom_key) >= ++ get_key_offset(&item_key) + reiser4_extent_size_at(coord, from)); ++ off = ++ get_key_offset(pfrom_key) - (get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, from)); ++ if (off) { ++ /* tail of unit @from is to be cut partially. Its width decreases */ ++ assert("vs-1582", new_first == NULL); ++ ext = extent_item(coord) + from; ++ extent_set_width(find_data_subvol(coord), ext, ++ off >> PAGE_SHIFT); ++ count--; ++ } ++ ++ assert("vs-1554", ++ get_key_offset(pto_key) <= ++ get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, to + 1) - 1); ++ off = ++ (get_key_offset(&item_key) + ++ reiser4_extent_size_at(coord, to + 1) - 1) - ++ get_key_offset(pto_key); ++ if (off) { ++ /* @to_key is smaller than max key of unit @to. Unit @to will not be removed. It gets start increased ++ and width decreased. */ ++ assert("vs-1583", (off & (PAGE_SIZE - 1)) == 0); ++ ext = extent_item(coord) + to; ++ if (state_of_extent(ext) == ALLOCATED_EXTENT) ++ extent_set_start(find_data_subvol(coord), ext, ++ extent_get_start(ext) + ++ (extent_get_width(ext) - ++ (off >> PAGE_SHIFT))); ++ ++ extent_set_width(find_data_subvol(coord), ext, ++ (off >> PAGE_SHIFT)); ++ count--; ++ } ++ return count * sizeof(reiser4_extent); ++} ++ ++/* item_plugin->b.unit_key */ ++reiser4_key *unit_key_extent(const coord_t * coord, reiser4_key * key) ++{ ++ assert("vs-300", coord_is_existing_unit(coord)); ++ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, ++ (get_key_offset(key) + ++ reiser4_extent_size_at(coord, coord->unit_pos))); ++ ++ return key; ++} ++ ++/* item_plugin->b.max_unit_key */ ++reiser4_key *max_unit_key_extent(const coord_t * coord, reiser4_key * key) ++{ ++ assert("vs-300", coord_is_existing_unit(coord)); ++ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, ++ (get_key_offset(key) + ++ reiser4_extent_size_at(coord, coord->unit_pos + 1) - 1)); ++ return key; ++} ++ ++#if REISER4_DEBUG ++ ++/* item_plugin->b.check ++ used for debugging, every item should have here the most complete ++ possible check of the consistency of the item that the inventor can ++ construct ++*/ ++int reiser4_check_extent(const coord_t *coord /* coord of item to check */, ++ const char **error /* where to store error message */) ++{ ++ reiser4_extent *ext, *first; ++ unsigned i, j; ++ reiser4_block_nr blk_cnt; ++ unsigned num_units; ++ oid_t oid; ++ reiser4_key key; ++ coord_t scan; ++ reiser4_subvol *subv; ++ ++ assert("vs-933", REISER4_DEBUG); ++ ++ if (znode_get_level(coord->node) != TWIG_LEVEL) { ++ *error = "Extent on the wrong level"; ++ return -1; ++ } ++ if (item_length_by_coord(coord) % sizeof(reiser4_extent) != 0) { ++ *error = "Wrong item size"; ++ return -1; ++ } ++ ext = first = extent_item(coord); ++ num_units = coord_num_units(coord); ++ item_key_by_coord(coord, &key); ++ oid = get_key_objectid(&key); ++ coord_dup(&scan, coord); ++ subv = find_data_subvol(coord); ++ blk_cnt = reiser4_subvol_block_count(subv); ++ ++ for (i = 0; i < num_units; ++i, ++ext) { ++ __u64 index; ++ reiser4_block_nr start, width; ++ ++ scan.unit_pos = i; ++ index = extent_unit_index(&scan); ++ /* ++ * check that all jnodes are present for the unallocated ++ * extent and that subvolumes are set properly ++ */ ++ if (state_of_extent(ext) == UNALLOCATED_EXTENT) { ++ for (j = 0; j < extent_get_width(ext); j++) { ++ jnode *node; ++ ++ node = jlookup(oid, index + j); ++ if (node == NULL) { ++ print_coord("scan", &scan, 0); ++ *error = "Jnode missing"; ++ return -1; ++ } ++ jput(node); ++ } ++ } ++ start = extent_get_start(ext); ++ if (start < 2) ++ continue; ++ /* ++ * extent is allocated one ++ */ ++ width = extent_get_width(ext); ++ if (start >= blk_cnt) { ++ *error = "Start too large"; ++ return -1; ++ } ++ if (start + width > blk_cnt) { ++ *error = "End too large"; ++ return -1; ++ } ++ /* ++ * make sure that this extent does not overlap ++ * with other allocated extents extents ++ */ ++ for (j = 0; j < i; j++) { ++ if (state_of_extent(first + j) != ALLOCATED_EXTENT) ++ continue; ++ if (!((extent_get_start(ext) >= ++ extent_get_start(first + j) + ++ extent_get_width(first + j)) || ++ (extent_get_start(ext) + ++ extent_get_width(ext) <= ++ extent_get_start(first + j)))) { ++ *error = "Extent overlaps with others"; ++ return -1; ++ } ++ } ++ } ++ return 0; ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent_stripe_ops.c linux-5.10.2/fs/reiser4/plugin/item/extent_stripe_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent_stripe_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent_stripe_ops.c 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,701 @@ ++/* ++ Copyright (c) 2018-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include "item.h" ++#include "../../inode.h" ++#include "../../page_cache.h" ++#include "../object.h" ++#include "../volume/volume.h" ++#include ++ ++void check_uf_coord(const uf_coord_t *uf_coord, const reiser4_key *key); ++void check_jnodes(znode *twig, const reiser4_key *key, int count); ++size_t filemap_copy_from_user(struct page *page, unsigned long offset, ++ const char __user *buf, unsigned bytes); ++int find_stripe_item(hint_t *hint, const reiser4_key *key, ++ znode_lock_mode lock_mode, struct inode *inode); ++reiser4_block_nr estimate_write_stripe_meta(int count); ++int update_item_key(coord_t *target, const reiser4_key *key); ++ ++int try_merge_with_right_item(coord_t *left) ++{ ++ coord_t right; ++ ++ coord_dup(&right, left); ++ ++ if (coord_next_item(&right)) ++ /* ++ * there is no items at the right ++ */ ++ return 0; ++ if (are_items_mergeable(left, &right)) { ++ node_plugin_by_node(left->node)->merge_items(left, &right); ++ znode_make_dirty(left->node); ++ } ++ return 0; ++} ++ ++int try_merge_with_left_item(coord_t *right) ++{ ++ coord_t left; ++ ++ coord_dup(&left, right); ++ ++ if (coord_prev_item(&left)) ++ /* ++ * there is no items at the left ++ */ ++ return 0; ++ ++ if (are_items_mergeable(&left, right)) { ++ node_plugin_by_node(left.node)->merge_items(&left, right); ++ znode_make_dirty(right->node); ++ } ++ return 0; ++} ++ ++static inline int can_push_left(const coord_t *coord, const reiser4_key *key) ++{ ++ reiser4_key akey; ++ ++ return keyeq(key, append_key_extent(coord, &akey)); ++} ++ ++static inline int can_push_right(const coord_t *coord, const reiser4_key *key) ++{ ++ coord_t right; ++ reiser4_key ikey; ++ reiser4_key pkey; ++ ++ coord_dup(&right, coord); ++ ++ if (coord_next_item(&right)) ++ /* ++ * there is no items at the right ++ */ ++ return 0; ++ ++ memcpy(&pkey, key, sizeof(*key)); ++ set_key_offset(&pkey, get_key_offset(key) + PAGE_SIZE); ++ ++ return keyeq(&pkey, item_key_by_coord(&right, &ikey)); ++} ++ ++/** ++ * Place a pointer to one unallocated physical block to the storage tree ++ * ++ * @key: key of the pointer to push ++ * @uf_coord: location to push (was found by coord_by_key()) ++ * ++ * Pre-condition: the logical block is not yet represented by any pointer ++ * in the storage tree (thus, the procedure looks like "plugging a hole") ++ * ++ * First, try to push the pointer to existing items. If impossible, then ++ * create a new extent item ++ */ ++static int plug_hole_stripe(coord_t *coord, lock_handle *lh, ++ const reiser4_key *key) ++{ ++ int ret = 0; ++ reiser4_extent *ext; ++ reiser4_extent new_ext; ++ reiser4_item_data idata; ++ //ON_DEBUG(const char *error); ++ ++ assert("edward-2052", !coord_is_existing_unit(coord)); ++ ++ if (coord->between != AFTER_UNIT) { ++ /* ++ * there is no file items at the left (in physical ++ * order), thus we are on the leaf level, where the ++ * search procedure has landed. So, use a carry_extent ++ * primitive to insert a new extent item. ++ */ ++ znode *twig_node; ++ assert("edward-2053", znode_is_loaded(coord->node)); ++ assert("edward-2054", coord->node->level == LEAF_LEVEL); ++ BUG_ON(coord->node->level != LEAF_LEVEL); ++ ++ reiser4_set_extent(subvol_by_key(key), &new_ext, ++ UNALLOCATED_EXTENT_START, 1); ++ init_new_extent(EXTENT41_POINTER_ID, &idata, &new_ext, 1); ++ ret = insert_extent_by_coord(coord, &idata, key, lh); ++ if (ret) ++ return ret; ++ /* ++ * A new extent item has been inserted on the twig level. ++ * To merge it with an item at the right we need to find ++ * the insertion point, as carry_extent primitive doesn't ++ * provide it (only lock handle). ++ */ ++ twig_node = lh->node; ++ assert("edward-2073", twig_node != coord->node); ++ ++ ret = zload(twig_node); ++ if (ret) ++ return ret; ++ coord_init_zero(coord); ++ ret = node_plugin_by_node(twig_node)->lookup(twig_node, ++ key, ++ FIND_EXACT, ++ coord); ++ BUG_ON(ret != NS_FOUND); ++ assert("edward-2074", twig_node == coord->node); ++ ++ try_merge_with_right_item(coord); ++#if 0 ++ assert("edward-2352", ++ check_node40(twig_node, ++ REISER4_NODE_TREE_STABLE, &error) == 0); ++#endif ++ zrelse(twig_node); ++ return 0; ++ } ++ /* ++ * We are on the twig level. ++ * First, try to push the pointer to existing extent items ++ */ ++ assert("edward-2057", item_is_extent(coord)); ++ ++ if (can_push_left(coord, key)) { ++ /* ++ * push to the end of current item ++ */ ++ coord->unit_pos = coord_last_unit_pos(coord); ++ ext = extent_by_coord(coord); ++ ++ assert("edward-2267", ++ subvol_by_key(key) == find_data_subvol(coord)); ++ ++ if ((state_of_extent(ext) == UNALLOCATED_EXTENT)) { ++ /* ++ * fast paste without carry ++ */ ++ extent_set_width(subvol_by_key(key), ext, ++ extent_get_width(ext) + 1); ++ znode_make_dirty(coord->node); ++ } else { ++ /* ++ * paste with possible carry ++ */ ++ coord->between = AFTER_UNIT; ++ reiser4_set_extent(subvol_by_key(key), &new_ext, ++ UNALLOCATED_EXTENT_START, 1); ++ init_new_extent(EXTENT41_POINTER_ID, ++ &idata, &new_ext, 1); ++ ret = insert_into_item(coord, lh, key, &idata, 0); ++ if (ret) ++ return ret; ++ } ++ return WITH_DATA(lh->node, try_merge_with_right_item(coord)); ++ ++ } else if (can_push_right(coord, key)) { ++ /* ++ * push to the beginning of the item at right ++ */ ++ coord_next_item(coord); ++ ext = extent_by_coord(coord); ++ ++ if ((state_of_extent(ext) == UNALLOCATED_EXTENT)) { ++ /* ++ * fast paste ++ */ ++ extent_set_width(subvol_by_key(key), ext, ++ extent_get_width(ext) + 1); ++ /* ++ * since we push to the beginning of item, ++ * we need to update its key ++ */ ++ return update_item_key(coord, key); ++ } else { ++ /* ++ * paste with possible carry ++ */ ++ coord->between = BEFORE_UNIT; ++ reiser4_set_extent(subvol_by_key(key), &new_ext, ++ UNALLOCATED_EXTENT_START, 1); ++ init_new_extent(EXTENT41_POINTER_ID, ++ &idata, &new_ext, 1); ++ return insert_into_item(coord, lh, key, &idata, 0); ++ } ++ /* ++ * note that resulted item is not mergeable with an item ++ * at the left (otherwise we would fall to can_push_left() ++ * branch above) ++ */ ++ } else { ++ /* ++ * we can't push to existing items, so create a new one ++ */ ++ reiser4_set_extent(subvol_by_key(key), &new_ext, ++ UNALLOCATED_EXTENT_START, 1); ++ init_new_extent(EXTENT41_POINTER_ID, &idata, &new_ext, 1); ++ ret = insert_by_coord(coord, &idata, key, lh, 0); ++ if (ret) ++ return ret; ++ /* ++ * it could happen that the newly created item got ++ * to neighbor node, where it is mergeable with an ++ * item at the right ++ */ ++ return WITH_DATA(lh->node, try_merge_with_right_item(coord)); ++ } ++} ++ ++static int __update_extent_stripe(uf_coord_t *uf_coord, const reiser4_key *key, ++ jnode *node, int *hole_plugged, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ reiser4_block_nr block; ++ struct atom_brick_info *abi; ++ ++ assert("edward-2468", subv == current_origin(get_key_ordering(key))); ++ assert("edward-2220", node->subvol == NULL || node->subvol == subv); ++ ++ if (uf_coord->coord.between != AT_UNIT) { ++ /* ++ * block pointer is not represented by any item in the tree ++ */ ++ if (*jnode_get_block(node)) { ++ /* ++ * FIXME: explain in details appearance of such jnodes ++ */ ++ spin_lock_jnode(node); ++ node->blocknr = 0; ++ node->subvol = NULL; ++ reiser4_uncapture_jnode(node); ++ } ++ assert("edward-2469", node->subvol == NULL); ++ ++ uf_coord->valid = 0; ++ inode_add_blocks(mapping_jnode(node)->host, 1); ++ ret = plug_hole_stripe(&uf_coord->coord, uf_coord->lh, key); ++ if (ret) ++ return ret; ++ ++ block = fake_blocknr_unformatted(1, subv); ++ jnode_set_block(node, &block); ++ jnode_set_subvol(node, subv); ++ ++ if (hole_plugged) ++ *hole_plugged = 1; ++ JF_SET(node, JNODE_CREATED); ++ ++ } else if (*jnode_get_block(node) == 0) { ++ reiser4_extent *ext; ++ struct extent_coord_extension *ext_coord; ++ ++ assert("edward-2470", node->subvol == NULL); ++ ++ ext_coord = ext_coord_by_uf_coord(uf_coord); ++ check_uf_coord(uf_coord, NULL); ++ ext = (reiser4_extent *)(zdata(uf_coord->coord.node) + ++ uf_coord->extension.extent.ext_offset); ++ if (state_of_extent(ext) != ALLOCATED_EXTENT) ++ return RETERR(-EIO); ++ ++ block = extent_get_start(ext) + ext_coord->pos_in_unit; ++ jnode_set_block(node, &block); ++ jnode_set_subvol(node, subv); ++ } ++ /* ++ * make sure that locked twig node contains jnode ++ * we are about to capture ++ */ ++ ON_DEBUG(check_jnodes(uf_coord->lh->node, key, 1)); ++ ++ ret = check_insert_atom_brick_info(node->subvol->id, &abi); ++ if (ret) ++ return ret; ++ ++ spin_lock_jnode(node); ++ ret = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(ret != 0); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++#if REISER4_DEBUG ++ if (uf_coord->valid) ++ check_uf_coord(uf_coord, key); ++#endif ++ return 0; ++} ++ ++/** ++ * Determine on which brick a data page will be stored, ++ * and reserve space on that brick. ++ */ ++static int locate_reserve_data(coord_t *coord, lock_handle *lh, ++ reiser4_key *key, struct inode *inode, ++ loff_t pos, jnode *node, ++ reiser4_subvol **loc, unsigned flags) ++{ ++ int ret; ++ ++ if (coord->between == AT_UNIT) { ++ ret = zload(coord->node); ++ if (ret) ++ return ret; ++ *loc = find_data_subvol(coord); ++ zrelse(coord->node); ++ assert("edward-2360", ++ ergo(node->subvol, node->subvol == *loc)); ++ } else if (reiser4_is_set(reiser4_get_current_sb(), ++ REISER4_PROXY_IO) && ++ !(flags & UPX_PROXY_FULL)) ++ *loc = get_proxy_subvol(); ++ else ++ *loc = calc_data_subvol(inode, pos); ++ ++ assert("edward-2361", *loc != NULL); ++ /* ++ * Now we can reserve space on @loc. ++ * Note that in the case of truncate the space ++ * has been already reserved in shorten_stripe() ++ */ ++ if (flags & UPX_TRUNCATE) ++ return 0; ++ grab_space_enable(); ++ return reiser4_grab_space(1 /* count */, ++ 0 /* flags */, ++ *loc /* where */); ++} ++ ++#define FAST_SEQ_WRITE (1) ++ ++/** ++ * Update file body after writing @count blocks at offset @pos. ++ * Return 0 on success. ++ */ ++int update_extent_stripe(struct hint *hint, struct inode *inode, ++ jnode *node, int *plugged_hole, unsigned flags) ++{ ++ int ret = 0; ++ reiser4_key key; ++ loff_t off; ++ znode *loaded; ++ reiser4_subvol *dsubv = NULL; ++ ++ off = ((loff_t)index_jnode(node) << PAGE_SHIFT); ++ /* ++ * construct non-precise key ++ */ ++ build_body_key_stripe(inode, off, &key); ++ ++#if FAST_SEQ_WRITE ++ ret = find_stripe_item(hint, &key, ZNODE_WRITE_LOCK, inode); ++#else ++ ret = find_file_item_nohint(&hint->ext_coord.coord, ++ hint->ext_coord.lh, &key, ++ ZNODE_WRITE_LOCK, inode); ++#endif ++ if (IS_CBKERR(ret)) ++ return RETERR(-EIO); ++ /* ++ * reserve space for data ++ */ ++ ret = locate_reserve_data(&hint->ext_coord.coord, ++ hint->ext_coord.lh, &key, ++ inode, off, node, ++ &dsubv, flags); ++ if (ret) { ++ done_lh(hint->ext_coord.lh); ++ return ret; ++ } ++ assert("edward-2284", dsubv != NULL); ++ assert("edward-2362", ++ ergo(node->subvol, node->subvol == dsubv)); ++ /* ++ * Now when we know location of data block, make key precise ++ */ ++ set_key_ordering(&key, dsubv->id); ++ ++ loaded = hint->ext_coord.coord.node; ++ ret = zload(loaded); ++ if (ret) { ++ done_lh(hint->ext_coord.lh); ++ return ret; ++ } ++ if (hint->ext_coord.coord.between == AT_UNIT && ++ !hint->ext_coord.valid) ++ init_coord_extension_extent(&hint->ext_coord, ++ get_key_offset(&key)); ++ /* ++ * "overwrite" a block pointer, or create a new one, ++ * if it doesn't exist ++ */ ++ ret = __update_extent_stripe(&hint->ext_coord, &key, node, ++ plugged_hole, dsubv); ++ zrelse(loaded); ++ if (ret == -ENOSPC) { ++ done_lh(hint->ext_coord.lh); ++ return ret; ++ } else if (ret) { ++ reiser4_unset_hint(hint); ++ return ret; ++ } ++ loaded = hint->lh.node; ++ ret = zload(loaded); ++ if (unlikely(ret)) { ++ done_lh(hint->ext_coord.lh); ++ return ret; ++ } ++ /* ++ * at this point a block pointer with @key always ++ * exists in the storage tree ++ */ ++ if (hint->ext_coord.valid == 0) { ++ hint->ext_coord.coord.between = AT_UNIT; ++ init_coord_extension_extent(&hint->ext_coord, ++ get_key_offset(&key)); ++ } ++ /* ++ * @hint->ext_coord points out to the block pointer ++ * we have just processed. ++ * Seal the coord and unlock znode. ++ */ ++ reiser4_set_hint(hint, &key, ZNODE_WRITE_LOCK); ++ zrelse(loaded); ++ /* ++ * Update key for the next iteration. ++ * We don't know location of the next data block, ++ * so set maximal ordering value. ++ */ ++ set_key_offset(&key, off + PAGE_SIZE); ++ set_key_ordering(&key, KEY_ORDERING_MASK); ++ return 0; ++} ++ ++int find_or_create_extent_stripe(struct page *page, unsigned flags) ++{ ++ int ret; ++ struct inode *inode; ++ int plugged_hole = 0; ++ struct hint hint; ++ jnode *node; ++ ++ assert("edward-2372", page->mapping && page->mapping->host); ++ ++ hint_init_zero(&hint); ++ inode = page->mapping->host; ++ ++ lock_page(page); ++ node = jnode_of_page(page); ++ if (IS_ERR(node)) { ++ unlock_page(page); ++ return PTR_ERR(node); ++ } ++ JF_SET(node, JNODE_WRITE_PREPARED); ++ unlock_page(page); ++ ++ ret = update_extent_stripe(&hint, inode, node, ++ &plugged_hole, flags); ++ JF_CLR(node, JNODE_WRITE_PREPARED); ++ ++ if (ret) { ++ jput(node); ++ warning("edward-1549", ++ "failed to update extent (%d)", ret); ++ return ret; ++ } ++ if (plugged_hole) ++ reiser4_update_sd(inode); ++ ++ BUG_ON(node->atom == NULL); ++ ++ if (get_current_context()->entd) { ++ entd_context *ent = get_entd_context(inode->i_sb); ++ ++ if (ent->cur_request->page == page) ++ /* ++ * the following reference will be ++ * dropped in reiser4_writeout ++ */ ++ ent->cur_request->node = jref(node); ++ } ++ jput(node); ++ return 0; ++} ++ ++/* ++ * Non-exclusive access to the file must be acquired ++ */ ++ssize_t write_extent_stripe(struct file *file, struct inode *inode, ++ const char __user *buf, size_t count, ++ loff_t *pos, unsigned flags) ++{ ++ int nr_pages; ++ int nr_dirty = 0; ++ struct page *page; ++ jnode *jnodes[DEFAULT_WRITE_GRANULARITY + 1]; ++ unsigned long index; ++ unsigned long end; ++ int i; ++ int to_page, page_off; ++ size_t left = count; ++ int ret = 0; ++ struct hint hint; ++ ++ if (count == 0) ++ return 0; ++ ++ ret = load_file_hint(file, &hint); ++ if (ret) ++ return ret; ++ /* ++ * calculate number of pages which are to be written ++ */ ++ index = *pos >> PAGE_SHIFT; ++ end = ((*pos + count - 1) >> PAGE_SHIFT); ++ nr_pages = end - index + 1; ++ assert("edward-2363", nr_pages <= DEFAULT_WRITE_GRANULARITY + 1); ++ ++ if (count == 0) ++ return 0; ++ /* ++ * First of all reserve space on meta-data brick. ++ * In particular, it is needed to "drill" the leaf level ++ * by search procedure. ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(estimate_write_stripe_meta(nr_pages), ++ 0, /* flags */ ++ get_meta_subvol() /* where */); ++ if (ret) ++ return ret; ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ /* get pages and jnodes */ ++ for (i = 0; i < nr_pages; i ++) { ++ page = find_or_create_page(inode->i_mapping, index + i, ++ reiser4_ctx_gfp_mask_get()); ++ if (page == NULL) { ++ nr_pages = i; ++ ret = RETERR(-ENOMEM); ++ goto out; ++ } ++ jnodes[i] = jnode_of_page(page); ++ if (IS_ERR(jnodes[i])) { ++ unlock_page(page); ++ put_page(page); ++ nr_pages = i; ++ ret = RETERR(-ENOMEM); ++ goto out; ++ } ++ /* prevent jnode and page from disconnecting */ ++ JF_SET(jnodes[i], JNODE_WRITE_PREPARED); ++ unlock_page(page); ++ } ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ page_off = (*pos & (PAGE_SIZE - 1)); ++ for (i = 0; i < nr_pages; i ++) { ++ size_t written; ++ to_page = PAGE_SIZE - page_off; ++ if (to_page > left) ++ to_page = left; ++ page = jnode_page(jnodes[i]); ++ if (page_offset(page) < inode->i_size && ++ !PageUptodate(page) && to_page != PAGE_SIZE) { ++ /* ++ * the above is not optimal for partial write to last ++ * page of file when file size is not at boundary of ++ * page ++ */ ++ lock_page(page); ++ if (!PageUptodate(page)) { ++ ret = readpage_stripe(NULL, page); ++ assert("edward-2364", ret == 0); ++ BUG_ON(ret != 0); ++ /* wait for read completion */ ++ lock_page(page); ++ BUG_ON(!PageUptodate(page)); ++ } else ++ ret = 0; ++ unlock_page(page); ++ } ++ ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ fault_in_pages_readable(buf, to_page); ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ ++ lock_page(page); ++ if (!PageUptodate(page) && to_page != PAGE_SIZE) ++ zero_user_segments(page, 0, page_off, ++ page_off + to_page, ++ PAGE_SIZE); ++ ++ written = filemap_copy_from_user(page, page_off, buf, to_page); ++ if (unlikely(written != to_page)) { ++ unlock_page(page); ++ ret = RETERR(-EFAULT); ++ break; ++ } ++ ++ flush_dcache_page(page); ++ set_page_dirty_notag(page); ++ unlock_page(page); ++ nr_dirty ++; ++ ++ mark_page_accessed(page); ++ SetPageUptodate(page); ++ ++ page_off = 0; ++ buf += to_page; ++ left -= to_page; ++ BUG_ON(get_current_context()->trans->atom != NULL); ++ } ++ ++ left = count; ++ page_off = (*pos & (PAGE_SIZE - 1)); ++ ++ for (i = 0; i < nr_dirty; i ++) { ++ to_page = PAGE_SIZE - page_off; ++ if (to_page > left) ++ to_page = left; ++ ++ assert("edward-2063", reiser4_lock_counters()->d_refs == 0); ++ ++ ret = update_extent_stripe(&hint, inode, jnodes[i], ++ NULL, flags); ++ ++ assert("edward-2065", reiser4_lock_counters()->d_refs == 0); ++ assert("edward-2365", ++ ret == -ENOSPC || ret == -EBUSY || ret >= 0); ++ ++ if (ret) ++ break; ++ page_off = 0; ++ left -= to_page; ++ } ++ out: ++ for (i = 0; i < nr_pages; i ++) { ++ put_page(jnode_page(jnodes[i])); ++ JF_CLR(jnodes[i], JNODE_WRITE_PREPARED); ++ jput(jnodes[i]); ++ } ++ if (!ret) ++ save_file_hint(file, &hint); ++ /* ++ * the only errors handled so far is ENOMEM and ++ * EFAULT on copy_from_user ++ */ ++ return (count - left) ? (count - left) : ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/extent_volume_ops.c linux-5.10.2/fs/reiser4/plugin/item/extent_volume_ops.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/extent_volume_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/extent_volume_ops.c 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,788 @@ ++/* ++ Copyright (c) 2017-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include "item.h" ++#include "../../inode.h" ++#include "../../page_cache.h" ++#include "../object.h" ++#include "../volume/volume.h" ++ ++#define MIGRATION_GRANULARITY (8192) ++ ++int try_merge_with_right_item(coord_t *left); ++int try_merge_with_left_item(coord_t *right); ++int split_extent_unit(coord_t *coord, reiser4_block_nr pos, int adv_to_right); ++int update_item_key(coord_t *target, const reiser4_key *key); ++ ++/* ++ * primitive migration operations over item ++ */ ++enum migration_primitive_id { ++ INVALID_ACTION = 0, ++ MIGRATE_EXTENT = 1, ++ SPLIT_EXTENT = 2, ++ SKIP_EXTENT = 3 ++}; ++ ++struct extent_migrate_context { ++ enum migration_primitive_id act; ++ struct page **pages; ++ int nr_pages; ++ coord_t *coord; ++ reiser4_key *key; /* key of extent item to be migrated */ ++ struct inode *inode; ++ u32 new_loc; ++ loff_t stop_off; /* offset of the leftmost byte to be migrated ++ in the iteration */ ++ loff_t done_off; /* offset of the latest byte migrated in the ++ iteration */ ++ reiser4_block_nr blocks_migrated; ++ reiser4_block_nr unit_split_pos; /* position in unit */ ++ lock_handle *lh; ++ unsigned int migrate_whole_item:1; ++ unsigned int stop:1; ++}; ++ ++struct extent_ra_ctx { ++ const coord_t *coord; ++ reiser4_extent *ext; ++ reiser4_block_nr off; ++}; ++ ++/** ++ * read page pointed out by extent item ++ */ ++static int filler(void *data, struct page *page) ++{ ++ struct extent_ra_ctx *ra_ctx = data; ++ ++ return __reiser4_readpage_extent(ra_ctx->coord, ra_ctx->ext, ++ ra_ctx->off, page); ++} ++ ++/** ++ * read all pages pointed out by extent unit @ext starting from @off ++ * @idx: index of the first page pointed out by extent unit ++ */ ++static int readpages_extent_unit(const coord_t *coord, reiser4_extent *ext, ++ reiser4_block_nr off_in_unit, ++ struct address_space *mapping, pgoff_t idx, ++ struct page **pages, int off_in_pages) ++{ ++ int i; ++ int ret; ++ struct extent_ra_ctx ra_ctx; ++ int nr_pages = extent_get_width(ext) - off_in_unit; ++ ++ ra_ctx.coord = coord; ++ ra_ctx.ext = ext; ++ ra_ctx.off = off_in_unit; ++ ++ for (i = 0; i < nr_pages; i++) { ++ struct page *page; ++ page = read_cache_page(mapping, idx + off_in_unit + i, ++ filler, &ra_ctx); ++ if (IS_ERR(page)) { ++ ret = PTR_ERR(page); ++ nr_pages = i; ++ goto error; ++ } ++ pages[i + off_in_pages] = page; ++ ra_ctx.off ++; ++ } ++ return 0; ++ error: ++ for (i = 0; i < nr_pages; i++) ++ put_page(pages[i + off_in_pages]); ++ return ret; ++} ++ ++/** ++ * read and pin pages pointed out by extent item at @coord ++ * starting from offset @off ++ */ ++static int readpages_extent_item(const coord_t *coord, loff_t off, ++ struct address_space *mapping, ++ struct extent_migrate_context *mctx) ++{ ++ int i; ++ int ret; ++ int nr_pages = 0; ++ reiser4_key key; /* key of the first unit to read from */ ++ coord_t iter_coord; ++ reiser4_block_nr pos_in_unit; ++ pgoff_t idx; ++ ++ coord_dup(&iter_coord, coord); ++ unit_key_by_coord(coord, &key); ++ ++ pos_in_unit = 0; ++ if (get_key_offset(&key) < off) { ++ /* ++ * read from the middle of unit ++ */ ++ pos_in_unit = mctx->unit_split_pos; ++ assert("edward-2403", ++ pos_in_unit == ++ (off - get_key_offset(&key)) >> PAGE_SHIFT); ++ } ++ idx = get_key_offset(&key) >> PAGE_SHIFT; ++ ++ while (iter_coord.unit_pos <= coord_last_unit_pos(&iter_coord)) { ++ reiser4_extent *ext = extent_by_coord(&iter_coord); ++ ++ assert("edward-2404", pos_in_unit < extent_get_width(ext)); ++ ++ ret = readpages_extent_unit(coord, ext, pos_in_unit, mapping, ++ idx, mctx->pages, nr_pages); ++ if (ret) ++ goto error; ++ ++ nr_pages += (extent_get_width(ext) - pos_in_unit); ++ idx += extent_get_width(ext); ++ iter_coord.unit_pos += 1; ++ pos_in_unit = 0; ++ } ++ assert("edward-2405", nr_pages == mctx->nr_pages); ++ return 0; ++ error: ++ for (i = 0; i < nr_pages; i++) ++ put_page(mctx->pages[i]); ++ return ret; ++} ++ ++/** ++ * "cut off" a number of unformatted blocks at the end of extent item ++ * specified by @coord. ++ * @from_off: offset to cut from. ++ */ ++static int cut_off_tail(coord_t *coord, struct inode *inode, ++ loff_t from_off) ++{ ++ reiser4_key from, to; ++ coord_t from_coord; ++ coord_t to_coord; ++ ++ coord_dup(&from_coord, coord); ++ ++ coord_dup(&to_coord, coord); ++ to_coord.between = AT_UNIT; ++ to_coord.unit_pos = coord_last_unit_pos(coord); ++ ++ item_key_by_coord(coord, &to); ++ set_key_offset(&to, get_key_offset(&to) + ++ reiser4_extent_size(coord) - 1); ++ ++ from = to; ++ set_key_offset(&from, from_off); ++ ++ return kill_node_content(&from_coord, &to_coord, &from, &to, ++ NULL, NULL, inode, 0); ++} ++ ++static int migrate_blocks(struct extent_migrate_context *mctx) ++{ ++ int i; ++ int ret; ++ reiser4_key key; ++ reiser4_extent new_ext; ++ reiser4_item_data idata; ++ reiser4_block_nr block; ++ int nr_jnodes = 0; ++ coord_t *coord = mctx->coord; ++ znode *loaded; ++ reiser4_subvol *new_subv = current_origin(mctx->new_loc); ++ struct atom_brick_info *abi; ++ ON_DEBUG(reiser4_key check_key); ++ ON_DEBUG(const char *error); ++ ++ assert("edward-2406", ++ equi(mctx->migrate_whole_item, ++ keyeq(unit_key_by_coord(coord, &check_key), mctx->key) && ++ mctx->stop_off == get_key_offset(mctx->key))); ++ /* ++ * Reserve space on the new data brick. ++ * Balancing procedure is allowed to fail with ENOSPC. ++ */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(mctx->nr_pages, 0, new_subv); ++ if (ret) ++ return ret; ++ ret = readpages_extent_item(coord, mctx->stop_off, ++ mctx->inode->i_mapping, mctx); ++ if (ret) ++ return ret; ++ ++ memcpy(&key, mctx->key, sizeof(key)); ++ set_key_offset(&key, mctx->stop_off); ++ set_key_ordering(&key, mctx->new_loc); ++ ++ for (i = 0; i < mctx->nr_pages; i++) { ++ struct page *page = mctx->pages[i]; ++ jnode *node; ++ ++ assert("edward-2407", page != NULL); ++ assert("edward-2408", ++ page->index == (mctx->stop_off >> PAGE_SHIFT) + i); ++ lock_page(page); ++ node = jnode_of_page(page); ++ if (IS_ERR(node)) { ++ nr_jnodes = i; ++ unlock_page(page); ++ ret = PTR_ERR(node); ++ goto error; ++ } ++ JF_SET(node, JNODE_WRITE_PREPARED); ++ unlock_page(page); ++ ++ } ++ nr_jnodes = mctx->nr_pages; ++ ++ if (mctx->migrate_whole_item) { ++ reiser4_extent *ext; ++ ++ assert("edward-2464", coord->unit_pos == 0); ++ assert("edward-2465", mctx->stop_off == ++ get_key_offset(item_key_by_coord(coord, &check_key))); ++ /* ++ * cut all units except the first one; ++ * deallocate all blocks, pointed out by that first unit; ++ * set that unit as unallocated extent of proper width; ++ * update item's key to point out to the new brick; ++ * try to merge the resulted item with the item at left ++ * and right. ++ */ ++ if (nr_units_extent(coord) > 1) { ++ ret = cut_off_tail(coord, mctx->inode, mctx->stop_off + ++ reiser4_extent_size_at(coord, 1)); ++ if (ret) ++ goto error; ++ } ++ loaded = coord->node; ++ ret = zload(loaded); ++ if (ret) ++ goto error; ++ ++ ext = extent_by_coord(coord); ++ if (state_of_extent(ext) == ALLOCATED_EXTENT) { ++ reiser4_block_nr start = extent_get_start(ext); ++ reiser4_block_nr len = extent_get_width(ext); ++ ++ reiser4_dealloc_blocks(&start, ++ &len, ++ 0, BA_DEFER, ++ find_data_subvol(coord)); ++ } ++ reiser4_set_extent(new_subv, ext, ++ UNALLOCATED_EXTENT_START, nr_jnodes); ++ ret = update_item_key(coord, &key); ++ if (ret) { ++ zrelse(loaded); ++ goto error; ++ } ++ try_merge_with_right_item(coord); ++ try_merge_with_left_item(coord); ++ assert("edward-2466", ++ check_node40(coord->node, ++ REISER4_NODE_TREE_STABLE, &error) == 0); ++ zrelse(loaded); ++ } else { ++ /* ++ * cut of tail, insert a new item at the end ++ */ ++ ret = cut_off_tail(coord, mctx->inode, mctx->stop_off); ++ if (ret) ++ goto error; ++ ++ coord_init_after_item(coord); ++ ++ reiser4_set_extent(new_subv, &new_ext, ++ UNALLOCATED_EXTENT_START, mctx->nr_pages); ++ init_new_extent(EXTENT41_POINTER_ID, &idata, &new_ext, 1); ++ ret = insert_by_coord(coord, &idata, &key, mctx->lh, 0); ++ if (ret) ++ goto error; ++ ++ loaded = coord->node; ++ ret = zload(loaded); ++ if (ret) ++ goto error; ++ assert("edward-2416", ++ keyeq(&key, item_key_by_coord(coord, &check_key))); ++ assert("edward-2424", ++ reiser4_extent_size(coord) == mctx->nr_pages << PAGE_SHIFT); ++ ++ try_merge_with_right_item(coord); ++ ++ assert("edward-2425", ++ check_node40(coord->node, ++ REISER4_NODE_TREE_STABLE, &error) == 0); ++ zrelse(loaded); ++ } ++ /* ++ * Capture jnodes, set new addresses for them, ++ * and make them dirty. At flush time all the ++ * blocks will get new location on the new brick. ++ */ ++ ret = check_insert_atom_brick_info(new_subv->id, &abi); ++ if (ret) ++ goto error; ++ block = fake_blocknr_unformatted(mctx->nr_pages, new_subv); ++ ++ for (i = 0; i < mctx->nr_pages; i++, block++) { ++ jnode *node = jprivate(mctx->pages[i]); ++ ++ assert("edward-2417", node != NULL); ++ ++ set_page_dirty_notag(mctx->pages[i]); ++ ++ spin_lock_jnode(node); ++ JF_SET(node, JNODE_CREATED); ++ JF_CLR(node, JNODE_WRITE_PREPARED); ++ ++ node->subvol = new_subv; ++ jnode_set_block(node, &block); ++ ++ ret = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(ret != 0); ++ ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ ++ jput(node); ++ put_page(mctx->pages[i]); ++ } ++ return 0; ++ error: ++ for (i = 0; i < mctx->nr_pages; i++) { ++ if (i < nr_jnodes) ++ jput(jprivate(mctx->pages[i])); ++ put_page(mctx->pages[i]); ++ } ++ return ret; ++} ++ ++static int do_migrate_extent(struct extent_migrate_context *mctx) ++{ ++ int ret = 0; ++ lock_handle *lh = mctx->lh; ++ coord_t *coord = mctx->coord; ++ znode *loaded; ++ ++ assert("edward-2106", coord->node == lh->node); ++ assert("edward-2128", ++ get_key_ordering(mctx->key) != mctx->new_loc); ++ ++ ret = zload(coord->node); ++ if (ret) ++ return ret; ++ loaded = coord->node; ++ ++ mctx->nr_pages = (get_key_offset(mctx->key) + ++ reiser4_extent_size(coord) - ++ mctx->stop_off) >> PAGE_SHIFT; ++ mctx->pages = reiser4_vmalloc(sizeof(mctx->pages) * mctx->nr_pages); ++ if (!mctx->pages) { ++ zrelse(loaded); ++ return RETERR(-ENOMEM); ++ } ++ ret = migrate_blocks(mctx); ++ ++ vfree(mctx->pages); ++ zrelse(loaded); ++ done_lh(lh); ++ if (ret) ++ return ret; ++ mctx->done_off = mctx->stop_off; ++ mctx->blocks_migrated += mctx->nr_pages; ++ ++ reiser4_throttle_write(mctx->inode); ++ /* ++ * Release the rest of blocks we grabbed for the fulfilled ++ * iteration. ++ */ ++ all_grabbed2free(); ++ /* ++ * The next migrate-split iteration starts here. ++ * Grab disk space for meta-data blocks in this iteration. We grab ++ * from reserved area, as rebalancing can be launched on a volume ++ * with no free space. ++ */ ++ ret = reserve_migration_iter(); ++ if (ret) ++ return ret; ++ if (mctx->migrate_whole_item) { ++ /* ++ * no more blocks to be migrated in this item ++ */ ++ mctx->stop = 1; ++ return 0; ++ } ++ /* ++ * go to the leftmost non-processed item ++ */ ++ assert("edward-2418", mctx->done_off != 0); ++ ++ set_key_offset(mctx->key, mctx->done_off - 1); ++ ret = find_file_item_nohint(coord, lh, mctx->key, ++ ZNODE_WRITE_LOCK, mctx->inode); ++ if (ret) { ++ /* ++ * item not found (killed by concurrent ++ * truncate, or error happened) ++ */ ++ warning("edward-2318", ++ "Item not found after migration (%d)", ret); ++ done_lh(lh); ++ if (!IS_CBKERR(ret)) { ++ ret = 0; ++ mctx->stop = 1; ++ } ++ return ret; ++ } ++ /* ++ * reset @mctx->key, as the item could be changed ++ * while we had keeping the lock released. ++ */ ++ ret = zload(coord->node); ++ if (ret) ++ return ret; ++ item_key_by_coord(coord, mctx->key); ++ zrelse(coord->node); ++ return 0; ++} ++ ++/** ++ * Create a new extent item right after the item specified by @coord ++ * and move the tail part of the last one to that newly created item. It can ++ * involve carry, if there is no free space on the node. Subtle! ++ * ++ * @unit_split_pos: splitting position in the unit. ++ * The pair @coord and @unit_split_pos defines splitting position in the item. ++ * If @unit_split_pos != 0, then the unit at @coord will be split at ++ * @unit_split_pos offset and its right part will start the new item. ++ * Otherwise, we'll split at the unit boundary and the unit at @coord will be ++ * moved to the head of the new item. ++ * ++ * Upon successfull completion: ++ * if @unit_split_pos != 0, then @coord points out to the same unit, which ++ * became smaller after split. Otherwise, @coord points out to the preceding ++ * unit. ++ */ ++static int split_extent_item(coord_t *coord, reiser4_block_nr unit_split_pos) ++{ ++ int ret; ++ coord_t cut_from; ++ coord_t cut_to; ++ char *tail_copy; ++ char *tail_orig; ++ int tail_num_units; ++ int tail_len; ++ reiser4_item_data idata; ++ reiser4_key split_key; ++ reiser4_key item_key; ++ ON_DEBUG(reiser4_key check_key); ++ ++ assert("edward-2109", znode_is_loaded(coord->node)); ++ assert("edward-2143", ergo(unit_split_pos == 0, coord->unit_pos > 0)); ++ ++ memset(&idata, 0, sizeof(idata)); ++ item_key_by_coord(coord, &item_key); ++ unit_key_by_coord(coord, &split_key); ++ set_key_offset(&split_key, ++ get_key_offset(&split_key) + ++ (unit_split_pos << current_blocksize_bits)); ++ ++ if (unit_split_pos != 0) { ++ /* ++ * start from splitting the unit. ++ * NOTE: it may change the item @coord (specifically, split ++ * it and move its part to the right neighbor ++ */ ++ ret = split_extent_unit(coord, unit_split_pos, ++ 0 /* stay on the original position */); ++ if (ret) ++ return ret; ++ assert("edward-2110", ++ keyeq(&item_key, item_key_by_coord(coord, &check_key))); ++ /* ++ * check if it was the case of item splitting at desired offset ++ * (see the comment above). ++ */ ++ if (reiser4_extent_size(coord) == ++ get_key_offset(&split_key) - get_key_offset(&item_key)) ++ /* ++ * item was split at specified offset - nothing to do ++ * any more ++ */ ++ return 0; ++ assert("edward-2426", reiser4_extent_size(coord) > ++ get_key_offset(&split_key) - get_key_offset(&item_key)); ++ /* ++ * unit at @coord decreased, number of units in the item ++ * got incremented ++ */ ++ tail_orig = ++ node_plugin_by_node(coord->node)->item_by_coord(coord) + ++ (coord->unit_pos + 1) * sizeof(reiser4_extent); ++ tail_num_units = coord_num_units(coord) - coord->unit_pos - 1; ++ } else { ++ /* ++ * none of the units is subjected to splitting - ++ * we'll split the item at units boundary. ++ */ ++ tail_orig = ++ node_plugin_by_node(coord->node)->item_by_coord(coord) + ++ coord->unit_pos * sizeof(reiser4_extent); ++ tail_num_units = coord_num_units(coord) - coord->unit_pos; ++ } ++ assert("edward-2427", tail_num_units > 0); ++ ++ tail_len = tail_num_units * sizeof(reiser4_extent); ++ ++ tail_copy = kmalloc(tail_len, reiser4_ctx_gfp_mask_get()); ++ if (!tail_copy) ++ return -ENOMEM; ++ memcpy(tail_copy, tail_orig, tail_len); ++ /* ++ * cut off the tail from the original item ++ */ ++ coord_dup(&cut_from, coord); ++ if (unit_split_pos) ++ /* the original unit was split */ ++ cut_from.unit_pos ++; ++ coord_dup(&cut_to, coord); ++ cut_to.unit_pos = coord_num_units(coord) - 1; ++ /* ++ * cut the original tail ++ */ ++ cut_node_content(&cut_from, &cut_to, NULL, NULL, NULL); ++ /* make sure that @coord is valid after cut operation */ ++ if (unit_split_pos == 0) ++ coord->unit_pos --; ++ ++ assert("edward-2428", ++ get_key_offset(item_key_by_coord(coord, &check_key)) + ++ reiser4_extent_size(coord) == get_key_offset(&split_key)); ++ /* ++ * finally, create a new item ++ */ ++ init_new_extent(item_id_by_coord(&cut_from), ++ &idata, tail_copy, tail_num_units); ++ coord_init_after_item(&cut_from); ++ ++ ret = insert_by_coord(&cut_from, &idata, &split_key, ++ 0 /* lh */, COPI_DONT_SHIFT_LEFT); ++ kfree(tail_copy); ++ return 0; ++} ++ ++static int do_split_extent(struct extent_migrate_context *mctx) ++{ ++ int ret; ++ znode *loaded; ++ ++ loaded = mctx->coord->node; ++ ret = zload(loaded); ++ if (ret) ++ return ret; ++ ret = split_extent_item(mctx->coord, mctx->unit_split_pos); ++ zrelse(loaded); ++ return ret; ++} ++ ++static void init_migration_context(struct extent_migrate_context *mctx, ++ struct inode *inode, coord_t *coord, ++ reiser4_key *key, lock_handle *lh) ++{ ++ memset(mctx, 0, sizeof(*mctx)); ++ mctx->coord = coord; ++ mctx->key = key; ++ mctx->inode = inode; ++ mctx->lh = lh; ++} ++ ++static void reset_migration_context(struct extent_migrate_context *mctx) ++{ ++ mctx->act = INVALID_ACTION; ++ mctx->nr_pages = 0; ++ mctx->stop = 0; ++ mctx->unit_split_pos = 0; ++ mctx->blocks_migrated = 0; ++ mctx->migrate_whole_item = 0; ++} ++ ++/** ++ * Assign primitive migration operation over the given item ++ * specified by @mctx.coord ++ */ ++static void what_to_do(struct extent_migrate_context *mctx, u64 *dst_id) ++{ ++ loff_t off1, off2; ++ loff_t split_off; ++ ++ coord_t *coord; ++ lookup_result ret; ++ struct inode *inode = mctx->inode; ++ reiser4_key split_key; ++ int skip; ++ ++ coord = mctx->coord; ++ zload(coord->node); ++ coord_clear_iplug(coord); ++ reset_migration_context(mctx); ++ /* ++ * calculate offsets of leftmost and rightmost bytes ++ * pointed out by the item ++ */ ++ off1 = get_key_offset(mctx->key); ++ off2 = off1 + reiser4_extent_size(coord) - 1; ++ mctx->new_loc = ++ dst_id != NULL ? *dst_id : calc_data_subvol(inode, off2)->id; ++ skip = (mctx->new_loc == get_key_ordering(mctx->key)); ++ /* ++ * find split offset in the item, i.e. maximal offset, so that ++ * data bytes at (offset - 1) and (offset) belong to different ++ * bricks in the logical volume with the new configuration. ++ */ ++ split_off = off2 - (off2 & (current_stripe_size - 1)); ++ while (off1 < split_off) { ++ split_off -= current_stripe_size; ++ if (calc_data_subvol(inode, split_off)->id != mctx->new_loc) { ++ split_off += current_stripe_size; ++ goto split_off_found; ++ } ++ if (!skip && (off2 - split_off + 1 >= ++ MIGRATION_GRANULARITY << PAGE_SHIFT)) { ++ /* ++ * split offset is not found, but the extent ++ * is too large, so we have to migrate a part ++ * of the item ++ */ ++ split_off += current_stripe_size; ++ goto split_off_found; ++ } ++ } ++ /* ++ * split offset not found. The whole item is either ++ * to be migrated, or to be skipped ++ */ ++ coord->unit_pos = 0; ++ mctx->stop_off = off1; ++ if (skip) { ++ mctx->stop = 1; ++ mctx->act = SKIP_EXTENT; ++ } else { ++ mctx->migrate_whole_item = 1; ++ mctx->act = MIGRATE_EXTENT; ++ } ++ zrelse(coord->node); ++ return; ++ split_off_found: ++ /* ++ * set current position to the found split offset ++ */ ++ assert("edward-2112", (off1 < split_off) && ++ (split_off < off1 + reiser4_extent_size(coord))); ++ ++ mctx->stop_off = split_off; ++ ++ memcpy(&split_key, mctx->key, sizeof(split_key)); ++ set_key_offset(&split_key, split_off); ++ ret = lookup_extent(&split_key, FIND_EXACT, coord); ++ ++ assert("edward-2113", ret == CBK_COORD_FOUND); ++ assert("edward-2114", coord->between == AT_UNIT); ++ ++ unit_key_by_coord(coord, &split_key); ++ ++ assert("edward-2115", get_key_offset(&split_key) <= split_off); ++ mctx->unit_split_pos = ++ (split_off - get_key_offset(&split_key)) >> PAGE_SHIFT; ++ ++ zrelse(coord->node); ++ if (skip) { ++ /* ++ * The item to be split, its right part to be ++ * skipped, and the left part to be processed in ++ * the next iteration of migrate_extent(). ++ */ ++ mctx->act = SPLIT_EXTENT; ++ } else { ++ /* ++ * Only a part of item should be migrated. ++ * In this case the regular split operation is not ++ * needed. ++ */ ++ mctx->migrate_whole_item = 0; ++ mctx->act = MIGRATE_EXTENT; ++ } ++ return; ++} ++ ++int reiser4_migrate_extent(coord_t *coord, reiser4_key *key, ++ lock_handle *lh, struct inode *inode, ++ loff_t *done_off, u64 *dst_id) ++{ ++ int ret = 0; ++ reiser4_block_nr blocks_migrated = 0; ++ struct extent_migrate_context mctx; ++ ++ init_migration_context(&mctx, inode, coord, key, lh); ++ ++ while (!mctx.stop) { ++ what_to_do(&mctx, dst_id); ++ switch(mctx.act) { ++ case SKIP_EXTENT: ++ ret = zload(mctx.coord->node); ++ if (ret) ++ goto out; ++ try_merge_with_right_item(mctx.coord); ++ zrelse(mctx.coord->node); ++ *done_off = mctx.stop_off; ++ goto out; ++ case SPLIT_EXTENT: ++ ret = do_split_extent(&mctx); ++ if (ret) ++ goto out; ++ continue; ++ case MIGRATE_EXTENT: ++ /* ++ * Resource-intensive. The maximun number of ++ * blocks to migrate at once is determined by ++ * MIGRATION_GRANULARITY ++ */ ++ ret = do_migrate_extent(&mctx); ++ if (ret) ++ goto out; ++ assert("edward-2351", mctx.blocks_migrated > 0); ++ *done_off = mctx.done_off; ++ ++ blocks_migrated += mctx.blocks_migrated; ++ break; ++ default: ++ impossible("edward-2116", ++ "Bad migrate action id %d", mctx.act); ++ } ++ } ++ out: ++ done_lh(lh); ++ return ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 80 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/internal.c linux-5.10.2/fs/reiser4/plugin/item/internal.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/internal.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/internal.c 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,406 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Implementation of internal-item plugin methods. */ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "internal.h" ++#include "item.h" ++#include "../node/node.h" ++#include "../plugin.h" ++#include "../../jnode.h" ++#include "../../znode.h" ++#include "../../tree_walk.h" ++#include "../../tree_mod.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../../block_alloc.h" ++ ++/* see internal.h for explanation */ ++ ++/* plugin->u.item.b.mergeable */ ++int mergeable_internal(const coord_t * p1 UNUSED_ARG /* first item */ , ++ const coord_t * p2 UNUSED_ARG /* second item */ ) ++{ ++ /* internal items are not mergeable */ ++ return 0; ++} ++ ++/* ->lookup() method for internal items */ ++lookup_result lookup_internal(const reiser4_key * key /* key to look up */ , ++ lookup_bias bias UNUSED_ARG /* lookup bias */ , ++ coord_t * coord /* coord of item */ ) ++{ ++ reiser4_key ukey; ++ ++ switch (keycmp(unit_key_by_coord(coord, &ukey), key)) { ++ default: ++ impossible("", "keycmp()?!"); ++ case LESS_THAN: ++ /* FIXME-VS: AFTER_ITEM used to be here. But with new coord ++ item plugin can not be taken using coord set this way */ ++ assert("vs-681", coord->unit_pos == 0); ++ coord->between = AFTER_UNIT; ++ /* fall through */ ++ case EQUAL_TO: ++ return CBK_COORD_FOUND; ++ case GREATER_THAN: ++ return CBK_COORD_NOTFOUND; ++ } ++} ++ ++/* return body of internal item at @coord */ ++static internal_item_layout *internal_at(const coord_t * coord /* coord of ++ * item */ ) ++{ ++ assert("nikita-607", coord != NULL); ++ assert("nikita-1650", ++ item_plugin_by_coord(coord) == ++ item_plugin_by_id(NODE_POINTER_ID)); ++ return (internal_item_layout *) item_body_by_coord(coord); ++} ++ ++void reiser4_update_internal(const coord_t * coord, ++ const reiser4_block_nr * blocknr) ++{ ++ internal_item_layout *item = internal_at(coord); ++ //assert("nikita-2959", reiser4_blocknr_is_sane(blocknr)); ++ ++ put_unaligned(cpu_to_le64(*blocknr), &item->pointer); ++} ++ ++/* return child block number stored in the internal item at @coord */ ++static reiser4_block_nr pointer_at(const coord_t * coord /* coord of item */ ) ++{ ++ assert("nikita-608", coord != NULL); ++ return le64_to_cpu(get_unaligned(&internal_at(coord)->pointer)); ++} ++ ++/* get znode pointed to by internal @item */ ++static znode *znode_at(const coord_t * item /* coord of item */ , ++ znode * parent /* parent node */ ) ++{ ++ return child_znode(item, parent, 1, 0); ++} ++ ++/* store pointer from internal item into "block". Implementation of ++ ->down_link() method */ ++void down_link_internal(const coord_t * coord /* coord of item */ , ++ const reiser4_key * key UNUSED_ARG /* key to get ++ * pointer for */ , ++ reiser4_block_nr * block /* resulting block number */ ) ++{ ++ ON_DEBUG(reiser4_key item_key); ++ ++ assert("nikita-609", coord != NULL); ++ assert("nikita-611", block != NULL); ++ assert("nikita-612", (key == NULL) || ++ /* twig horrors */ ++ (znode_get_level(coord->node) == TWIG_LEVEL) ++ || keyle(item_key_by_coord(coord, &item_key), key)); ++ ++ *block = pointer_at(coord); ++ //assert("nikita-2960", reiser4_blocknr_is_sane(block)); ++} ++ ++/* Get the child's block number, or 0 if the block is unallocated. */ ++int ++utmost_child_real_block_internal(const coord_t * coord, sideof side UNUSED_ARG, ++ reiser4_block_nr * block) ++{ ++ assert("jmacd-2059", coord != NULL); ++ ++ *block = pointer_at(coord); ++ //assert("nikita-2961", reiser4_blocknr_is_sane(block)); ++ ++ if (reiser4_blocknr_is_fake(block)) { ++ *block = 0; ++ } ++ ++ return 0; ++} ++ ++/* Return the child. */ ++int ++utmost_child_internal(const coord_t * coord, sideof side UNUSED_ARG, ++ jnode ** childp) ++{ ++ reiser4_block_nr block = pointer_at(coord); ++ znode *child; ++ ++ assert("jmacd-2059", childp != NULL); ++ //assert("nikita-2962", reiser4_blocknr_is_sane(&block)); ++ ++ child = zlook(znode_get_tree(coord->node), &block); ++ ++ if (IS_ERR(child)) { ++ return PTR_ERR(child); ++ } ++ ++ *childp = ZJNODE(child); ++ ++ return 0; ++} ++ ++#if REISER4_DEBUG ++ ++static void check_link(znode * left, znode * right) ++{ ++ znode *scan; ++ ++ for (scan = left; scan != right; scan = scan->right) { ++ if (ZF_ISSET(scan, JNODE_RIP)) ++ break; ++ if (znode_is_right_connected(scan) && scan->right != NULL) { ++ if (ZF_ISSET(scan->right, JNODE_RIP)) ++ break; ++ assert("nikita-3285", ++ znode_is_left_connected(scan->right)); ++ assert("nikita-3265", ++ ergo(scan != left, ++ ZF_ISSET(scan, JNODE_HEARD_BANSHEE))); ++ assert("nikita-3284", scan->right->left == scan); ++ } else ++ break; ++ } ++} ++ ++int check__internal(const coord_t * coord, const char **error) ++{ ++ reiser4_block_nr blk; ++ znode *child; ++ coord_t cpy; ++ ++ blk = pointer_at(coord); ++#if 0 ++ if (!reiser4_blocknr_is_sane(&blk)) { ++ *error = "Invalid pointer"; ++ return -1; ++ } ++#endif ++ coord_dup(&cpy, coord); ++ child = znode_at(&cpy, cpy.node); ++ if (child != NULL) { ++ znode *left_child; ++ znode *right_child; ++ ++ left_child = right_child = NULL; ++ ++ assert("nikita-3256", znode_invariant(child)); ++ if (coord_prev_item(&cpy) == 0 && item_is_internal(&cpy)) { ++ left_child = znode_at(&cpy, cpy.node); ++ if (left_child != NULL) { ++ read_lock_tree(); ++ check_link(left_child, child); ++ read_unlock_tree(); ++ zput(left_child); ++ } ++ } ++ coord_dup(&cpy, coord); ++ if (coord_next_item(&cpy) == 0 && item_is_internal(&cpy)) { ++ right_child = znode_at(&cpy, cpy.node); ++ if (right_child != NULL) { ++ read_lock_tree(); ++ check_link(child, right_child); ++ read_unlock_tree(); ++ zput(right_child); ++ } ++ } ++ zput(child); ++ } ++ return 0; ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++/* return true only if this item really points to "block" */ ++/* Audited by: green(2002.06.14) */ ++int has_pointer_to_internal(const coord_t * coord /* coord of item */ , ++ const reiser4_block_nr * block /* block number to ++ * check */ ) ++{ ++ assert("nikita-613", coord != NULL); ++ assert("nikita-614", block != NULL); ++ ++ return pointer_at(coord) == *block; ++} ++ ++/* hook called by ->create_item() method of node plugin after new internal ++ item was just created. ++ ++ This is point where pointer to new node is inserted into tree. Initialize ++ parent pointer in child znode, insert child into sibling list and slum. ++ ++*/ ++int create_hook_internal(const coord_t * item /* coord of item */ , ++ void *arg /* child's left neighbor, if any */ ) ++{ ++ znode *child; ++ __u64 child_ptr; ++ ++ assert("nikita-1252", item != NULL); ++ assert("nikita-1253", item->node != NULL); ++ assert("nikita-1181", znode_get_level(item->node) > LEAF_LEVEL); ++ assert("nikita-1450", item->unit_pos == 0); ++ ++ /* ++ * preparing to item insertion build_child_ptr_data sets pointer to ++ * data to be inserted to jnode's blocknr which is in cpu byte ++ * order. Node's create_item simply copied those data. As result we ++ * have child pointer in cpu's byte order. Convert content of internal ++ * item to little endian byte order. ++ */ ++ child_ptr = get_unaligned((__u64 *)item_body_by_coord(item)); ++ reiser4_update_internal(item, &child_ptr); ++ ++ child = znode_at(item, item->node); ++ if (child != NULL && !IS_ERR(child)) { ++ znode *left; ++ int result = 0; ++ reiser4_tree *tree; ++ ++ left = arg; ++ tree = znode_get_tree(item->node); ++ write_lock_tree(); ++ write_lock_dk(tree); ++ assert("nikita-1400", (child->in_parent.node == NULL) ++ || (znode_above_root(child->in_parent.node))); ++ ++item->node->c_count; ++ coord_to_parent_coord(item, &child->in_parent); ++ sibling_list_insert_nolock(child, left); ++ ++ assert("nikita-3297", ZF_ISSET(child, JNODE_ORPHAN)); ++ ZF_CLR(child, JNODE_ORPHAN); ++ ++ if ((left != NULL) && !keyeq(znode_get_rd_key(left), ++ znode_get_rd_key(child))) { ++ znode_set_rd_key(child, znode_get_rd_key(left)); ++ } ++ write_unlock_dk(tree); ++ write_unlock_tree(); ++ zput(child); ++ return result; ++ } else { ++ if (child == NULL) ++ child = ERR_PTR(-EIO); ++ return PTR_ERR(child); ++ } ++} ++ ++/* hook called by ->cut_and_kill() method of node plugin just before internal ++ item is removed. ++ ++ This is point where empty node is removed from the tree. Clear parent ++ pointer in child, and mark node for pending deletion. ++ ++ Node will be actually deleted later and in several installations: ++ ++ . when last lock on this node will be released, node will be removed from ++ the sibling list and its lock will be invalidated ++ ++ . when last reference to this node will be dropped, bitmap will be updated ++ and node will be actually removed from the memory. ++ ++*/ ++int kill_hook_internal(const coord_t * item /* coord of item */ , ++ pos_in_node_t from UNUSED_ARG /* start unit */ , ++ pos_in_node_t count UNUSED_ARG /* stop unit */ , ++ struct carry_kill_data *p UNUSED_ARG) ++{ ++ znode *child; ++ int result = 0; ++ ++ assert("nikita-1222", item != NULL); ++ assert("nikita-1224", from == 0); ++ assert("nikita-1225", count == 1); ++ ++ child = znode_at(item, item->node); ++ if (child == NULL) ++ return 0; ++ if (IS_ERR(child)) ++ return PTR_ERR(child); ++ result = zload(child); ++ if (result) { ++ zput(child); ++ return result; ++ } ++ if (node_is_empty(child)) { ++ reiser4_tree *tree; ++ ++ assert("nikita-1397", znode_is_write_locked(child)); ++ assert("nikita-1398", child->c_count == 0); ++ assert("nikita-2546", ZF_ISSET(child, JNODE_HEARD_BANSHEE)); ++ ++ tree = znode_get_tree(item->node); ++ write_lock_tree(); ++ init_parent_coord(&child->in_parent, NULL); ++ --item->node->c_count; ++ write_unlock_tree(); ++ } else { ++ warning("nikita-1223", ++ "Cowardly refuse to remove link to non-empty node"); ++ result = RETERR(-EIO); ++ } ++ zrelse(child); ++ zput(child); ++ return result; ++} ++ ++/* hook called by ->shift() node plugin method when iternal item was just ++ moved from one node to another. ++ ++ Update parent pointer in child and c_counts in old and new parent ++ ++*/ ++int shift_hook_internal(const coord_t * item /* coord of item */ , ++ unsigned from UNUSED_ARG /* start unit */ , ++ unsigned count UNUSED_ARG /* stop unit */ , ++ znode * old_node /* old parent */ ) ++{ ++ znode *child; ++ znode *new_node; ++ reiser4_tree *tree; ++ ++ assert("nikita-1276", item != NULL); ++ assert("nikita-1277", from == 0); ++ assert("nikita-1278", count == 1); ++ assert("nikita-1451", item->unit_pos == 0); ++ ++ new_node = item->node; ++ assert("nikita-2132", new_node != old_node); ++ tree = znode_get_tree(item->node); ++ child = child_znode(item, old_node, 1, 0); ++ if (child == NULL) ++ return 0; ++ if (!IS_ERR(child)) { ++ write_lock_tree(); ++ ++new_node->c_count; ++ assert("nikita-1395", znode_parent(child) == old_node); ++ assert("nikita-1396", old_node->c_count > 0); ++ coord_to_parent_coord(item, &child->in_parent); ++ assert("nikita-1781", znode_parent(child) == new_node); ++ assert("nikita-1782", ++ check_tree_pointer(item, child) == NS_FOUND); ++ --old_node->c_count; ++ write_unlock_tree(); ++ zput(child); ++ return 0; ++ } else ++ return PTR_ERR(child); ++} ++ ++/* plugin->u.item.b.max_key_inside - not defined */ ++/* plugin->u.item.b.nr_units - item.c:single_unit */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/internal.h linux-5.10.2/fs/reiser4/plugin/item/internal.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/internal.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/internal.h 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,57 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* Internal item contains down-link to the child of the internal/twig ++ node in a tree. It is internal items that are actually used during ++ tree traversal. */ ++ ++#if !defined( __FS_REISER4_PLUGIN_ITEM_INTERNAL_H__ ) ++#define __FS_REISER4_PLUGIN_ITEM_INTERNAL_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++ ++/* on-disk layout of internal item */ ++typedef struct internal_item_layout { ++ /* 0 */ reiser4_dblock_nr pointer; ++ /* 4 */ ++} internal_item_layout; ++ ++struct cut_list; ++ ++int mergeable_internal(const coord_t * p1, const coord_t * p2); ++lookup_result lookup_internal(const reiser4_key * key, lookup_bias bias, ++ coord_t * coord); ++/* store pointer from internal item into "block". Implementation of ++ ->down_link() method */ ++extern void down_link_internal(const coord_t * coord, const reiser4_key * key, ++ reiser4_block_nr * block); ++extern int has_pointer_to_internal(const coord_t * coord, ++ const reiser4_block_nr * block); ++extern int create_hook_internal(const coord_t * item, void *arg); ++extern int kill_hook_internal(const coord_t * item, pos_in_node_t from, ++ pos_in_node_t count, struct carry_kill_data *); ++extern int shift_hook_internal(const coord_t * item, unsigned from, ++ unsigned count, znode * old_node); ++extern void reiser4_print_internal(const char *prefix, coord_t * coord); ++ ++extern int utmost_child_internal(const coord_t * coord, sideof side, ++ jnode ** child); ++int utmost_child_real_block_internal(const coord_t * coord, sideof side, ++ reiser4_block_nr * block); ++ ++extern void reiser4_update_internal(const coord_t * coord, ++ const reiser4_block_nr * blocknr); ++/* FIXME: reiserfs has check_internal */ ++extern int check__internal(const coord_t * coord, const char **error); ++ ++/* __FS_REISER4_PLUGIN_ITEM_INTERNAL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/item.c linux-5.10.2/fs/reiser4/plugin/item/item.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/item.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/item.c 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,804 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* definition of item plugins. */ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "../plugin_header.h" ++#include "sde.h" ++#include "internal.h" ++#include "item.h" ++#include "static_stat.h" ++#include "../plugin.h" ++#include "../../znode.h" ++#include "../../tree.h" ++#include "../../context.h" ++#include "ctail.h" ++ ++/* return pointer to item body */ ++void item_body_by_coord_hard(coord_t * coord /* coord to query */ ) ++{ ++ assert("nikita-324", coord != NULL); ++ assert("nikita-325", coord->node != NULL); ++ assert("nikita-326", znode_is_loaded(coord->node)); ++ assert("nikita-3200", coord->offset == INVALID_OFFSET); ++ ++ coord->offset = ++ node_plugin_by_node(coord->node)->item_by_coord(coord) - ++ zdata(coord->node); ++ ON_DEBUG(coord->body_v = coord->node->times_locked); ++} ++ ++void *item_body_by_coord_easy(const coord_t * coord /* coord to query */ ) ++{ ++ return zdata(coord->node) + coord->offset; ++} ++ ++#if REISER4_DEBUG ++ ++int item_body_is_valid(const coord_t * coord) ++{ ++ return ++ coord->offset == ++ node_plugin_by_node(coord->node)->item_by_coord(coord) - ++ zdata(coord->node); ++} ++ ++#endif ++ ++/* return length of item at @coord */ ++pos_in_node_t item_length_by_coord(const coord_t * coord /* coord to query */ ) ++{ ++ int len; ++ ++ assert("nikita-327", coord != NULL); ++ assert("nikita-328", coord->node != NULL); ++ assert("nikita-329", znode_is_loaded(coord->node)); ++ ++ len = node_plugin_by_node(coord->node)->length_by_coord(coord); ++ return len; ++} ++ ++void obtain_item_plugin(const coord_t * coord) ++{ ++ assert("nikita-330", coord != NULL); ++ assert("nikita-331", coord->node != NULL); ++ assert("nikita-332", znode_is_loaded(coord->node)); ++ ++ coord_set_iplug((coord_t *) coord, ++ node_plugin_by_node(coord->node)-> ++ plugin_by_coord(coord)); ++ assert("nikita-2479", ++ coord_iplug(coord) == ++ node_plugin_by_node(coord->node)->plugin_by_coord(coord)); ++} ++ ++/* return id of item */ ++/* Audited by: green(2002.06.15) */ ++item_id item_id_by_coord(const coord_t * coord /* coord to query */ ) ++{ ++ assert("vs-539", coord != NULL); ++ assert("vs-538", coord->node != NULL); ++ assert("vs-537", znode_is_loaded(coord->node)); ++ assert("vs-536", item_plugin_by_coord(coord) != NULL); ++ assert("vs-540", ++ item_id_by_plugin(item_plugin_by_coord(coord)) < LAST_ITEM_ID); ++ ++ return item_id_by_plugin(item_plugin_by_coord(coord)); ++} ++ ++/* return key of item at @coord */ ++/* Audited by: green(2002.06.15) */ ++reiser4_key *item_key_by_coord(const coord_t * coord /* coord to query */ , ++ reiser4_key * key /* result */ ) ++{ ++ assert("nikita-338", coord != NULL); ++ assert("nikita-339", coord->node != NULL); ++ assert("nikita-340", znode_is_loaded(coord->node)); ++ ++ return node_plugin_by_node(coord->node)->key_at(coord, key); ++} ++ ++/* this returns max key in the item */ ++reiser4_key *max_item_key_by_coord(const coord_t * coord /* coord to query */ , ++ reiser4_key * key /* result */ ) ++{ ++ coord_t last; ++ ++ assert("nikita-338", coord != NULL); ++ assert("nikita-339", coord->node != NULL); ++ assert("nikita-340", znode_is_loaded(coord->node)); ++ ++ /* make coord pointing to last item's unit */ ++ coord_dup(&last, coord); ++ last.unit_pos = coord_num_units(&last) - 1; ++ assert("vs-1560", coord_is_existing_unit(&last)); ++ ++ max_unit_key_by_coord(&last, key); ++ return key; ++} ++ ++/* return key of unit at @coord */ ++reiser4_key *unit_key_by_coord(const coord_t * coord /* coord to query */ , ++ reiser4_key * key /* result */ ) ++{ ++ assert("nikita-772", coord != NULL); ++ assert("nikita-774", coord->node != NULL); ++ assert("nikita-775", znode_is_loaded(coord->node)); ++ ++ if (item_plugin_by_coord(coord)->b.unit_key != NULL) ++ return item_plugin_by_coord(coord)->b.unit_key(coord, key); ++ else ++ return item_key_by_coord(coord, key); ++} ++ ++/* return the biggest key contained the unit @coord */ ++reiser4_key *max_unit_key_by_coord(const coord_t * coord /* coord to query */ , ++ reiser4_key * key /* result */ ) ++{ ++ assert("nikita-772", coord != NULL); ++ assert("nikita-774", coord->node != NULL); ++ assert("nikita-775", znode_is_loaded(coord->node)); ++ ++ if (item_plugin_by_coord(coord)->b.max_unit_key != NULL) ++ return item_plugin_by_coord(coord)->b.max_unit_key(coord, key); ++ else ++ return unit_key_by_coord(coord, key); ++} ++ ++/* ->max_key_inside() method for items consisting of exactly one key (like ++ stat-data) */ ++static reiser4_key *max_key_inside_single_key(const coord_t * ++ coord /* coord of item */ , ++ reiser4_key * ++ result /* resulting key */ ) ++{ ++ assert("nikita-604", coord != NULL); ++ ++ /* coord -> key is starting key of this item and it has to be already ++ filled in */ ++ return unit_key_by_coord(coord, result); ++} ++ ++/* ->nr_units() method for items consisting of exactly one unit always */ ++pos_in_node_t ++nr_units_single_unit(const coord_t * coord UNUSED_ARG /* coord of item */ ) ++{ ++ return 1; ++} ++ ++static int ++paste_no_paste(coord_t * coord UNUSED_ARG, ++ reiser4_item_data * data UNUSED_ARG, ++ carry_plugin_info * info UNUSED_ARG) ++{ ++ return 0; ++} ++ ++/* default ->fast_paste() method */ ++static int ++agree_to_fast_op(const coord_t * coord UNUSED_ARG /* coord of item */ ) ++{ ++ return 1; ++} ++ ++int item_can_contain_key(const coord_t * item /* coord of item */ , ++ const reiser4_key * key /* key to check */ , ++ const reiser4_item_data * data /* parameters of item ++ * being created */ ) ++{ ++ item_plugin *iplug; ++ reiser4_key min_key_in_item; ++ reiser4_key max_key_in_item; ++ ++ assert("nikita-1658", item != NULL); ++ assert("nikita-1659", key != NULL); ++ ++ iplug = item_plugin_by_coord(item); ++ if (iplug->b.can_contain_key != NULL) ++ return iplug->b.can_contain_key(item, key, data); ++ else { ++ assert("nikita-1681", iplug->b.max_key_inside != NULL); ++ item_key_by_coord(item, &min_key_in_item); ++ iplug->b.max_key_inside(item, &max_key_in_item); ++ ++ /* can contain key if ++ min_key_in_item <= key && ++ key <= max_key_in_item ++ */ ++ return keyle(&min_key_in_item, key) ++ && keyle(key, &max_key_in_item); ++ } ++} ++ ++/* mergeable method for non mergeable items */ ++static int ++not_mergeable(const coord_t * i1 UNUSED_ARG, const coord_t * i2 UNUSED_ARG) ++{ ++ return 0; ++} ++ ++/* return 0 if @item1 and @item2 are not mergeable, !0 - otherwise */ ++int are_items_mergeable(const coord_t * i1 /* coord of first item */ , ++ const coord_t * i2 /* coord of second item */ ) ++{ ++ item_plugin *iplug; ++ reiser4_key k1; ++ reiser4_key k2; ++ ++ assert("nikita-1336", i1 != NULL); ++ assert("nikita-1337", i2 != NULL); ++ ++ iplug = item_plugin_by_coord(i1); ++ assert("nikita-1338", iplug != NULL); ++ ++ /* NOTE-NIKITA are_items_mergeable() is also called by assertions in ++ shifting code when nodes are in "suspended" state. */ ++ assert("nikita-1663", ++ keyle(item_key_by_coord(i1, &k1), item_key_by_coord(i2, &k2))); ++ ++ if (iplug->b.mergeable != NULL) { ++ return iplug->b.mergeable(i1, i2); ++ } else if (iplug->b.max_key_inside != NULL) { ++ iplug->b.max_key_inside(i1, &k1); ++ item_key_by_coord(i2, &k2); ++ ++ /* mergeable if ->max_key_inside() >= key of i2; */ ++ return keyge(iplug->b.max_key_inside(i1, &k1), ++ item_key_by_coord(i2, &k2)); ++ } else { ++ item_key_by_coord(i1, &k1); ++ item_key_by_coord(i2, &k2); ++ ++ return ++ (get_key_locality(&k1) == get_key_locality(&k2)) && ++ (get_key_objectid(&k1) == get_key_objectid(&k2)) ++ && (iplug == item_plugin_by_coord(i2)); ++ } ++} ++ ++int item_is_extent(const coord_t *item) ++{ ++ assert("vs-482", coord_is_existing_item(item)); ++ return ++ item_id_by_coord(item) == EXTENT40_POINTER_ID || ++ item_id_by_coord(item) == EXTENT41_POINTER_ID; ++} ++ ++int item_is_tail(const coord_t * item) ++{ ++ assert("vs-482", coord_is_existing_item(item)); ++ return item_id_by_coord(item) == FORMATTING_ID; ++} ++ ++#if REISER4_DEBUG ++ ++int item_is_statdata(const coord_t * item) ++{ ++ assert("vs-516", coord_is_existing_item(item)); ++ return plugin_of_group(item_plugin_by_coord(item), STAT_DATA_ITEM_TYPE); ++} ++ ++int item_is_ctail(const coord_t * item) ++{ ++ assert("edward-1816", coord_is_existing_item(item)); ++ return item_id_by_coord(item) == CTAIL_ID; ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++static int change_item(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ /* cannot change constituent item (sd, or dir_item) */ ++ return RETERR(-EINVAL); ++} ++ ++static reiser4_plugin_ops item_plugin_ops = { ++ .init = NULL, ++ .load = NULL, ++ .save_len = NULL, ++ .save = NULL, ++ .change = change_item ++}; ++ ++item_plugin item_plugins[LAST_ITEM_ID] = { ++ [STATIC_STAT_DATA_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = STATIC_STAT_DATA_ID, ++ .groups = (1 << STAT_DATA_ITEM_TYPE), ++ .pops = &item_plugin_ops, ++ .label = "sd", ++ .desc = "stat-data", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_single_key, ++ .can_contain_key = NULL, ++ .mergeable = not_mergeable, ++ .nr_units = nr_units_single_unit, ++ .lookup = NULL, ++ .init = NULL, ++ .paste = paste_no_paste, ++ .fast_paste = NULL, ++ .can_shift = NULL, ++ .copy_units = NULL, ++ .create_hook = NULL, ++ .kill_hook = NULL, ++ .shift_hook = NULL, ++ .cut_units = NULL, ++ .kill_units = NULL, ++ .unit_key = NULL, ++ .max_unit_key = NULL, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = NULL ++#endif ++ }, ++ .f = { ++ .utmost_child = NULL, ++ .utmost_child_real_block = NULL, ++ .update = NULL, ++ .scan = NULL, ++ .convert = NULL ++ }, ++ .s = { ++ .sd = { ++ .init_inode = init_inode_static_sd, ++ .save_len = save_len_static_sd, ++ .save = save_static_sd ++ } ++ } ++ }, ++ [SIMPLE_DIR_ENTRY_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = SIMPLE_DIR_ENTRY_ID, ++ .groups = (1 << DIR_ENTRY_ITEM_TYPE), ++ .pops = &item_plugin_ops, ++ .label = "de", ++ .desc = "directory entry", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_single_key, ++ .can_contain_key = NULL, ++ .mergeable = NULL, ++ .nr_units = nr_units_single_unit, ++ .lookup = NULL, ++ .init = NULL, ++ .paste = NULL, ++ .fast_paste = NULL, ++ .can_shift = NULL, ++ .copy_units = NULL, ++ .create_hook = NULL, ++ .kill_hook = NULL, ++ .shift_hook = NULL, ++ .cut_units = NULL, ++ .kill_units = NULL, ++ .unit_key = NULL, ++ .max_unit_key = NULL, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = NULL ++#endif ++ }, ++ .f = { ++ .utmost_child = NULL, ++ .utmost_child_real_block = NULL, ++ .update = NULL, ++ .scan = NULL, ++ .convert = NULL ++ }, ++ .s = { ++ .dir = { ++ .extract_key = extract_key_de, ++ .update_key = update_key_de, ++ .extract_name = extract_name_de, ++ .extract_file_type = extract_file_type_de, ++ .add_entry = add_entry_de, ++ .rem_entry = rem_entry_de, ++ .max_name_len = max_name_len_de ++ } ++ } ++ }, ++ [COMPOUND_DIR_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = COMPOUND_DIR_ID, ++ .groups = (1 << DIR_ENTRY_ITEM_TYPE), ++ .pops = &item_plugin_ops, ++ .label = "cde", ++ .desc = "compressed directory entry", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_cde, ++ .can_contain_key = can_contain_key_cde, ++ .mergeable = mergeable_cde, ++ .nr_units = nr_units_cde, ++ .lookup = lookup_cde, ++ .init = init_cde, ++ .paste = paste_cde, ++ .fast_paste = agree_to_fast_op, ++ .can_shift = can_shift_cde, ++ .copy_units = copy_units_cde, ++ .create_hook = NULL, ++ .kill_hook = NULL, ++ .shift_hook = NULL, ++ .cut_units = cut_units_cde, ++ .kill_units = kill_units_cde, ++ .unit_key = unit_key_cde, ++ .max_unit_key = unit_key_cde, ++ .estimate = estimate_cde, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = reiser4_check_cde ++#endif ++ }, ++ .f = { ++ .utmost_child = NULL, ++ .utmost_child_real_block = NULL, ++ .update = NULL, ++ .scan = NULL, ++ .convert = NULL ++ }, ++ .s = { ++ .dir = { ++ .extract_key = extract_key_cde, ++ .update_key = update_key_cde, ++ .extract_name = extract_name_cde, ++ .extract_file_type = extract_file_type_de, ++ .add_entry = add_entry_cde, ++ .rem_entry = rem_entry_cde, ++ .max_name_len = max_name_len_cde ++ } ++ } ++ }, ++ [NODE_POINTER_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = NODE_POINTER_ID, ++ .groups = (1 << INTERNAL_ITEM_TYPE), ++ .pops = NULL, ++ .label = "internal", ++ .desc = "internal item", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = NULL, ++ .can_contain_key = NULL, ++ .mergeable = mergeable_internal, ++ .nr_units = nr_units_single_unit, ++ .lookup = lookup_internal, ++ .init = NULL, ++ .paste = NULL, ++ .fast_paste = NULL, ++ .can_shift = NULL, ++ .copy_units = NULL, ++ .create_hook = create_hook_internal, ++ .kill_hook = kill_hook_internal, ++ .shift_hook = shift_hook_internal, ++ .cut_units = NULL, ++ .kill_units = NULL, ++ .unit_key = NULL, ++ .max_unit_key = NULL, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = check__internal ++#endif ++ }, ++ .f = { ++ .utmost_child = utmost_child_internal, ++ .utmost_child_real_block = ++ utmost_child_real_block_internal, ++ .update = reiser4_update_internal, ++ .scan = NULL, ++ .convert = NULL ++ }, ++ .s = { ++ .internal = { ++ .down_link = down_link_internal, ++ .has_pointer_to = has_pointer_to_internal ++ } ++ } ++ }, ++ [EXTENT40_POINTER_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = EXTENT40_POINTER_ID, ++ .groups = (1 << FILE_BODY_ITEM_TYPE), ++ .pops = NULL, ++ .label = "extent40", ++ .desc = "simple extent pointer", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_extent, ++ .can_contain_key = can_contain_key_extent, ++ .mergeable = mergeable_extent40, ++ .nr_units = nr_units_extent, ++ .lookup = lookup_extent, ++ .init = NULL, ++ .paste = paste_extent, ++ .fast_paste = agree_to_fast_op, ++ .can_shift = can_shift_extent, ++ .create_hook = create_hook_extent, ++ .copy_units = copy_units_extent, ++ .kill_hook = kill_hook_extent, ++ .shift_hook = NULL, ++ .cut_units = cut_units_extent, ++ .kill_units = kill_units_extent, ++ .unit_key = unit_key_extent, ++ .max_unit_key = max_unit_key_extent, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = reiser4_check_extent ++#endif ++ }, ++ .f = { ++ .utmost_child = utmost_child_extent, ++ .utmost_child_real_block = ++ utmost_child_real_block_extent, ++ .update = NULL, ++ .scan = reiser4_scan_extent, ++ .convert = NULL, ++ }, ++ .v = { ++ .migrate = NULL ++ }, ++ .s = { ++ .file = { ++ .get_block = get_block_address_extent, ++ .append_key = append_key_extent, ++ .init_coord_extension = ++ init_coord_extension_extent ++ } ++ } ++ }, ++ [EXTENT41_POINTER_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = EXTENT41_POINTER_ID, ++ .groups = (1 << FILE_BODY_ITEM_TYPE), ++ .pops = NULL, ++ .label = "extent41", ++ .desc = "distributed extent pointer", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_extent, ++ .can_contain_key = can_contain_key_extent, ++ .mergeable = mergeable_extent41, /* differs */ ++ .nr_units = nr_units_extent, ++ .lookup = lookup_extent, ++ .init = NULL, ++ .paste = paste_extent, ++ .fast_paste = agree_to_fast_op, ++ .can_shift = can_shift_extent, ++ .create_hook = create_hook_extent, ++ .copy_units = copy_units_extent, ++ .merge_units = merge_units_extent, ++ .kill_hook = kill_hook_extent, ++ .shift_hook = NULL, ++ .cut_units = cut_units_extent, ++ .kill_units = kill_units_extent, ++ .unit_key = unit_key_extent, ++ .max_unit_key = max_unit_key_extent, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = reiser4_check_extent ++#endif ++ }, ++ .f = { ++ .utmost_child = utmost_child_extent, ++ .utmost_child_real_block = ++ utmost_child_real_block_extent, ++ .update = NULL, ++ .scan = reiser4_scan_extent, ++ .convert = NULL, ++ }, ++ .v = { ++ .migrate = reiser4_migrate_extent ++ }, ++ .s = { ++ .file = { ++ .get_block = get_block_address_extent, ++ .append_key = append_key_extent, ++ .init_coord_extension = ++ init_coord_extension_extent ++ } ++ } ++ }, ++ [FORMATTING_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = FORMATTING_ID, ++ .groups = (1 << FILE_BODY_ITEM_TYPE), ++ .pops = NULL, ++ .label = "body", ++ .desc = "body (or tail?) item", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_tail, ++ .can_contain_key = can_contain_key_tail, ++ .mergeable = mergeable_tail, ++ .nr_units = nr_units_tail, ++ .lookup = lookup_tail, ++ .init = NULL, ++ .paste = paste_tail, ++ .fast_paste = agree_to_fast_op, ++ .can_shift = can_shift_tail, ++ .create_hook = NULL, ++ .copy_units = copy_units_tail, ++ .kill_hook = kill_hook_tail, ++ .shift_hook = NULL, ++ .cut_units = cut_units_tail, ++ .kill_units = kill_units_tail, ++ .unit_key = unit_key_tail, ++ .max_unit_key = unit_key_tail, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = NULL ++#endif ++ }, ++ .f = { ++ .utmost_child = NULL, ++ .utmost_child_real_block = NULL, ++ .update = NULL, ++ .scan = NULL, ++ .convert = NULL ++ }, ++ .s = { ++ .file = { ++ .get_block = get_block_address_tail, ++ .append_key = append_key_tail, ++ .init_coord_extension = ++ init_coord_extension_tail ++ } ++ } ++ }, ++ [CTAIL_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = CTAIL_ID, ++ .groups = (1 << FILE_BODY_ITEM_TYPE), ++ .pops = NULL, ++ .label = "ctail", ++ .desc = "cryptcompress tail item", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = max_key_inside_tail, ++ .can_contain_key = can_contain_key_ctail, ++ .mergeable = mergeable_ctail, ++ .nr_units = nr_units_ctail, ++ .lookup = NULL, ++ .init = init_ctail, ++ .paste = paste_ctail, ++ .fast_paste = agree_to_fast_op, ++ .can_shift = can_shift_ctail, ++ .create_hook = create_hook_ctail, ++ .copy_units = copy_units_ctail, ++ .kill_hook = kill_hook_ctail, ++ .shift_hook = shift_hook_ctail, ++ .cut_units = cut_units_ctail, ++ .kill_units = kill_units_ctail, ++ .unit_key = unit_key_tail, ++ .max_unit_key = unit_key_tail, ++ .estimate = estimate_ctail, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = check_ctail ++#endif ++ }, ++ .f = { ++ .utmost_child = utmost_child_ctail, ++ /* FIXME-EDWARD: write this */ ++ .utmost_child_real_block = NULL, ++ .update = NULL, ++ .scan = scan_ctail, ++ .convert = convert_ctail ++ }, ++ .s = { ++ .file = { ++ .get_block = get_block_address_tail, ++ .append_key = append_key_ctail, ++ .init_coord_extension = ++ init_coord_extension_tail ++ } ++ } ++ }, ++ [BLACK_BOX_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = BLACK_BOX_ID, ++ .groups = (1 << OTHER_ITEM_TYPE), ++ .pops = NULL, ++ .label = "blackbox", ++ .desc = "black box item", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = NULL, ++ .can_contain_key = NULL, ++ .mergeable = not_mergeable, ++ .nr_units = nr_units_single_unit, ++ /* to need for ->lookup method */ ++ .lookup = NULL, ++ .init = NULL, ++ .paste = NULL, ++ .fast_paste = NULL, ++ .can_shift = NULL, ++ .copy_units = NULL, ++ .create_hook = NULL, ++ .kill_hook = NULL, ++ .shift_hook = NULL, ++ .cut_units = NULL, ++ .kill_units = NULL, ++ .unit_key = NULL, ++ .max_unit_key = NULL, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = NULL ++#endif ++ } ++ }, ++ [BRICK_SYMBOL_ID] = { ++ .h = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .id = BRICK_SYMBOL_ID, ++ .groups = (1 << OTHER_ITEM_TYPE), ++ .pops = NULL, ++ .label = "brick symbol", ++ .desc = "brick identifier", ++ .linkage = {NULL, NULL} ++ }, ++ .b = { ++ .max_key_inside = NULL, ++ .can_contain_key = NULL, ++ .mergeable = not_mergeable, ++ .nr_units = nr_units_single_unit, ++ .lookup = NULL, ++ .init = NULL, ++ .paste = NULL, ++ .fast_paste = NULL, ++ .can_shift = NULL, ++ .copy_units = NULL, ++ .create_hook = NULL, ++ .kill_hook = NULL, ++ .shift_hook = NULL, ++ .cut_units = NULL, ++ .kill_units = NULL, ++ .unit_key = NULL, ++ .max_unit_key = NULL, ++ .estimate = NULL, ++ .item_data_by_flow = NULL, ++#if REISER4_DEBUG ++ .check = NULL ++#endif ++ } ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/item.h linux-5.10.2/fs/reiser4/plugin/item/item.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/item.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/item.h 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,414 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* first read balance.c comments before reading this */ ++ ++/* An item_plugin implements all of the operations required for ++ balancing that are item specific. */ ++ ++/* an item plugin also implements other operations that are specific to that ++ item. These go into the item specific operations portion of the item ++ handler, and all of the item specific portions of the item handler are put ++ into a union. */ ++ ++#if !defined( __REISER4_ITEM_H__ ) ++#define __REISER4_ITEM_H__ ++ ++#include "../../forward.h" ++#include "../plugin_header.h" ++#include "../../dformat.h" ++#include "../../seal.h" ++#include "../../plugin/file/file.h" ++ ++#include /* for struct file, struct inode */ ++#include /* for struct page */ ++#include /* for struct dentry */ ++ ++typedef enum { ++ STAT_DATA_ITEM_TYPE, ++ DIR_ENTRY_ITEM_TYPE, ++ INTERNAL_ITEM_TYPE, ++ FILE_BODY_ITEM_TYPE, ++ OTHER_ITEM_TYPE ++} item_type_id; ++ ++/* this is the part of each item plugin that all items are expected to ++ support or at least explicitly fail to support by setting the ++ pointer to null. */ ++struct balance_ops { ++ /* operations called by balancing ++ ++ It is interesting to consider that some of these item ++ operations could be given sources or targets that are not ++ really items in nodes. This could be ok/useful. ++ ++ */ ++ /* maximal key that can _possibly_ be occupied by this item ++ ++ When inserting, and node ->lookup() method (called by ++ coord_by_key()) reaches an item after binary search, ++ the ->max_key_inside() item plugin method is used to determine ++ whether new item should pasted into existing item ++ (new_key<=max_key_inside()) or new item has to be created ++ (new_key>max_key_inside()). ++ ++ For items that occupy exactly one key (like stat-data) ++ this method should return this key. For items that can ++ grow indefinitely (extent, directory item) this should ++ return reiser4_max_key(). ++ ++ For example extent with the key ++ ++ (LOCALITY,4,OBJID,STARTING-OFFSET), and length BLK blocks, ++ ++ ->max_key_inside is (LOCALITY,4,OBJID,0xffffffffffffffff), and ++ */ ++ reiser4_key *(*max_key_inside) (const coord_t *, reiser4_key *); ++ ++ /* true if item @coord can merge data at @key. */ ++ int (*can_contain_key) (const coord_t *, const reiser4_key *, ++ const reiser4_item_data *); ++ /* mergeable() - check items for mergeability ++ ++ Optional method. Returns true if two items can be merged. ++ ++ */ ++ int (*mergeable) (const coord_t *, const coord_t *); ++ ++ /* number of atomic things in an item. ++ NOTE FOR CONTRIBUTORS: use a generic method ++ nr_units_single_unit() for solid (atomic) items, as ++ tree operations use it as a criterion of solidness ++ (see is_solid_item macro) */ ++ pos_in_node_t(*nr_units) (const coord_t *); ++ ++ /* search within item for a unit within the item, and return a ++ pointer to it. This can be used to calculate how many ++ bytes to shrink an item if you use pointer arithmetic and ++ compare to the start of the item body if the item's data ++ are continuous in the node, if the item's data are not ++ continuous in the node, all sorts of other things are maybe ++ going to break as well. */ ++ lookup_result(*lookup) (const reiser4_key *, lookup_bias, coord_t *); ++ /* method called by ode_plugin->create_item() to initialise new ++ item */ ++ int (*init) (coord_t * target, coord_t * from, ++ reiser4_item_data * data); ++ /* method called (e.g., by reiser4_resize_item()) to place new data ++ into item when it grows */ ++ int (*paste) (coord_t *, reiser4_item_data *, carry_plugin_info *); ++ /* return true if paste into @coord is allowed to skip ++ carry. That is, if such paste would require any changes ++ at the parent level ++ */ ++ int (*fast_paste) (const coord_t *); ++ /* how many but not more than @want units of @source can be ++ shifted into @target node. If pend == append - we try to ++ append last item of @target by first units of @source. If ++ pend == prepend - we try to "prepend" first item in @target ++ by last units of @source. @target node has @free_space ++ bytes of free space. Total size of those units are returned ++ via @size. ++ ++ @target is not NULL if shifting to the mergeable item and ++ NULL is new item will be created during shifting. ++ */ ++ int (*can_shift) (unsigned free_space, coord_t *, ++ znode *, shift_direction, unsigned *size, ++ unsigned want); ++ ++ /* starting off @from-th unit of item @source append or ++ prepend @count units to @target. @target has been already ++ expanded by @free_space bytes. That must be exactly what is ++ needed for those items in @target. If @where_is_free_space ++ == SHIFT_LEFT - free space is at the end of @target item, ++ othersize - it is in the beginning of it. */ ++ void (*copy_units) (coord_t *, coord_t *, ++ unsigned from, unsigned count, ++ shift_direction where_is_free_space, ++ unsigned free_space); ++ /* ++ * try to merge rightmost unit of item @left with the leftmost ++ * unit of neighboring item @right located on the same node. ++ * Return freed space. Must not fail. For performance reasons ++ * this method leaves the node in inconsistent state and should ++ * be called only in the context of ->merge_items() method of ++ * node plugin. Must not be called in other ones.*/ ++ size_t (*merge_units) (coord_t *left, coord_t *right); ++ ++ int (*create_hook) (const coord_t *, void *); ++ /* do whatever is necessary to do when @count units starting ++ from @from-th one are removed from the tree */ ++ /* FIXME-VS: this is used to be here for, in particular, ++ extents and items of internal type to free blocks they point ++ to at the same time with removing items from a ++ tree. Problems start, however, when dealloc_block fails due ++ to some reason. Item gets removed, but blocks it pointed to ++ are not freed. It is not clear how to fix this for items of ++ internal type because a need to remove internal item may ++ appear in the middle of balancing, and there is no way to ++ undo changes made. OTOH, if space allocator involves ++ balancing to perform dealloc_block - this will probably ++ break balancing due to deadlock issues ++ */ ++ int (*kill_hook) (const coord_t *, pos_in_node_t from, ++ pos_in_node_t count, struct carry_kill_data *); ++ int (*shift_hook) (const coord_t *, unsigned from, unsigned count, ++ znode * _node); ++ ++ /* unit @*from contains @from_key. unit @*to contains @to_key. Cut all keys between @from_key and @to_key ++ including boundaries. When units are cut from item beginning - move space which gets freed to head of ++ item. When units are cut from item end - move freed space to item end. When units are cut from the middle of ++ item - move freed space to item head. Return amount of space which got freed. Save smallest removed key in ++ @smallest_removed if it is not 0. Save new first item key in @new_first_key if it is not 0 ++ */ ++ int (*cut_units) (coord_t *, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *, ++ reiser4_key * smallest_removed, ++ reiser4_key * new_first_key); ++ ++ /* like cut_units, except that these units are removed from the ++ tree, not only from a node */ ++ int (*kill_units) (coord_t *, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *, ++ reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++ ++ /* if @key_of_coord == 1 - returned key of coord, otherwise - ++ key of unit is returned. If @coord is not set to certain ++ unit - ERR_PTR(-ENOENT) is returned */ ++ reiser4_key *(*unit_key) (const coord_t *, reiser4_key *); ++ reiser4_key *(*max_unit_key) (const coord_t *, reiser4_key *); ++ /* estimate how much space is needed for paste @data into item at ++ @coord. if @coord==0 - estimate insertion, otherwise - estimate ++ pasting ++ */ ++ int (*estimate) (const coord_t *, const reiser4_item_data *); ++ ++ /* converts flow @f to item data. @coord == 0 on insert */ ++ int (*item_data_by_flow) (const coord_t *, const flow_t *, ++ reiser4_item_data *); ++ ++ /*void (*show) (struct seq_file *, coord_t *); */ ++ ++#if REISER4_DEBUG ++ /* used for debugging, every item should have here the most ++ complete possible check of the consistency of the item that ++ the inventor can construct */ ++ int (*check) (const coord_t *, const char **error); ++#endif ++ ++}; ++ ++struct flush_ops { ++ /* return the right or left child of @coord, only if it is in memory */ ++ int (*utmost_child) (const coord_t *, sideof side, jnode ** child); ++ ++ /* return whether the right or left child of @coord has a non-fake ++ block number. */ ++ int (*utmost_child_real_block) (const coord_t *, sideof side, ++ reiser4_block_nr *); ++ /* relocate child at @coord to the @block */ ++ void (*update) (const coord_t *, const reiser4_block_nr *); ++ /* count unformatted nodes per item for leave relocation policy, etc.. */ ++ int (*scan) (flush_scan * scan); ++ /* convert item by flush */ ++ int (*convert) (flush_pos_t * pos); ++}; ++ ++struct volume_ops{ ++ /* ++ * migrate unformatted blocks pointed out by item at @coord, starting ++ * from right to left. Upon sucessfull completion @done_off contains ++ * offset of the leftmost processed byte. @key is the key of the item ++ */ ++ int (*migrate)(coord_t *coord, reiser4_key *key, ++ lock_handle *lh, struct inode *inode, loff_t *done_off, ++ u64 *dst_id); ++}; ++ ++/* operations specific to the directory item */ ++struct dir_entry_iops { ++ /* extract stat-data key from directory entry at @coord and place it ++ into @key. */ ++ int (*extract_key) (const coord_t *, reiser4_key * key); ++ /* update object key in item. */ ++ int (*update_key) (const coord_t *, const reiser4_key *, lock_handle *); ++ /* extract name from directory entry at @coord and return it */ ++ char *(*extract_name) (const coord_t *, char *buf); ++ /* extract file type (DT_* stuff) from directory entry at @coord and ++ return it */ ++ unsigned (*extract_file_type) (const coord_t *); ++ int (*add_entry) (struct inode * dir, ++ coord_t *, lock_handle *, ++ const struct dentry * name, ++ reiser4_dir_entry_desc * entry); ++ int (*rem_entry) (struct inode * dir, const struct qstr * name, ++ coord_t *, lock_handle *, ++ reiser4_dir_entry_desc * entry); ++ int (*max_name_len) (const struct inode * dir); ++}; ++ ++/* ++ * item specific methods called by regular file plugins ++ */ ++struct file_iops{ ++ int (*get_block) (const coord_t *, sector_t, sector_t *); ++ /* ++ * key of first byte which is not addressed by the item ++ * @coord is set to, but is mergeable with that item. ++ * ++ * For example, for extent item with the key ++ * ++ * (LOCALITY,4,OBJID,STARTING-OFFSET), and length BLK blocks, ++ * ++ * ->append_key is ++ * ++ * (LOCALITY,4,OBJID,STARTING-OFFSET + BLK * block_size) ++ */ ++ reiser4_key *(*append_key) (const coord_t *, reiser4_key *); ++ void (*init_coord_extension) (uf_coord_t *, loff_t); ++}; ++ ++/* operations specific to items of stat data type */ ++struct sd_iops { ++ int (*init_inode) (struct inode * inode, char *sd, int len); ++ int (*save_len) (struct inode * inode); ++ int (*save) (struct inode * inode, char **area); ++}; ++ ++/* operations specific to internal item */ ++struct internal_iops{ ++ /* all tree traversal want to know from internal item is where ++ to go next. */ ++ void (*down_link) (const coord_t * coord, ++ const reiser4_key * key, reiser4_block_nr * block); ++ /* check that given internal item contains given pointer. */ ++ int (*has_pointer_to) (const coord_t * coord, ++ const reiser4_block_nr * block); ++}; ++ ++struct item_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* methods common for all item types */ ++ struct balance_ops b; /* balance operations */ ++ struct flush_ops f; /* flush operates with items via this methods */ ++ struct volume_ops v; /* volume operations */ ++ ++ /* methods specific to particular type of item */ ++ union { ++ struct dir_entry_iops dir; ++ struct file_iops file; ++ struct sd_iops sd; ++ struct internal_iops internal; ++ } s; ++}; ++ ++#define is_solid_item(iplug) ((iplug)->b.nr_units == nr_units_single_unit) ++ ++static inline item_id item_id_by_plugin(item_plugin * plugin) ++{ ++ return plugin->h.id; ++} ++ ++static inline char get_iplugid(item_plugin * iplug) ++{ ++ assert("nikita-2838", iplug != NULL); ++ assert("nikita-2839", iplug->h.id < 0xff); ++ return (char)item_id_by_plugin(iplug); ++} ++ ++extern unsigned long znode_times_locked(const znode * z); ++ ++static inline void coord_set_iplug(coord_t * coord, item_plugin * iplug) ++{ ++ assert("nikita-2837", coord != NULL); ++ assert("nikita-2838", iplug != NULL); ++ coord->iplugid = get_iplugid(iplug); ++ ON_DEBUG(coord->plug_v = znode_times_locked(coord->node)); ++} ++ ++static inline item_plugin *coord_iplug(const coord_t * coord) ++{ ++ assert("nikita-2833", coord != NULL); ++ assert("nikita-2834", coord->iplugid != INVALID_PLUGID); ++ assert("nikita-3549", coord->plug_v == znode_times_locked(coord->node)); ++ return (item_plugin *) plugin_by_id(REISER4_ITEM_PLUGIN_TYPE, ++ coord->iplugid); ++} ++ ++extern int item_can_contain_key(const coord_t * item, const reiser4_key * key, ++ const reiser4_item_data *); ++extern int are_items_mergeable(const coord_t * i1, const coord_t * i2); ++extern int item_is_extent(const coord_t *); ++extern int item_is_tail(const coord_t *); ++extern int item_is_statdata(const coord_t * item); ++extern int item_is_ctail(const coord_t *); ++ ++extern pos_in_node_t item_length_by_coord(const coord_t * coord); ++extern pos_in_node_t nr_units_single_unit(const coord_t * coord); ++extern item_id item_id_by_coord(const coord_t * coord /* coord to query */ ); ++extern reiser4_key *item_key_by_coord(const coord_t * coord, reiser4_key * key); ++extern reiser4_key *max_item_key_by_coord(const coord_t *, reiser4_key *); ++extern reiser4_key *unit_key_by_coord(const coord_t * coord, reiser4_key * key); ++extern reiser4_key *max_unit_key_by_coord(const coord_t * coord, ++ reiser4_key * key); ++extern void obtain_item_plugin(const coord_t * coord); ++ ++#if defined(REISER4_DEBUG) ++extern int znode_is_loaded(const znode * node); ++#endif ++ ++/* return plugin of item at @coord */ ++static inline item_plugin *item_plugin_by_coord(const coord_t * ++ coord /* coord to query */ ) ++{ ++ assert("nikita-330", coord != NULL); ++ assert("nikita-331", coord->node != NULL); ++ assert("nikita-332", znode_is_loaded(coord->node)); ++ ++ if (unlikely(!coord_is_iplug_set(coord))) ++ obtain_item_plugin(coord); ++ return coord_iplug(coord); ++} ++ ++/* this returns true if item is of internal type */ ++static inline int item_is_internal(const coord_t * item) ++{ ++ assert("vs-483", coord_is_existing_item(item)); ++ return plugin_of_group(item_plugin_by_coord(item), INTERNAL_ITEM_TYPE); ++} ++ ++extern void item_body_by_coord_hard(coord_t * coord); ++extern void *item_body_by_coord_easy(const coord_t * coord); ++#if REISER4_DEBUG ++extern int item_body_is_valid(const coord_t * coord); ++#endif ++ ++/* return pointer to item body */ ++static inline void *item_body_by_coord(const coord_t * ++ coord /* coord to query */ ) ++{ ++ assert("nikita-324", coord != NULL); ++ assert("nikita-325", coord->node != NULL); ++ assert("nikita-326", znode_is_loaded(coord->node)); ++ ++ if (coord->offset == INVALID_OFFSET) ++ item_body_by_coord_hard((coord_t *) coord); ++ assert("nikita-3201", item_body_is_valid(coord)); ++ assert("nikita-3550", coord->body_v == znode_times_locked(coord->node)); ++ return item_body_by_coord_easy(coord); ++} ++ ++/* __REISER4_ITEM_H__ */ ++#endif ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/Makefile linux-5.10.2/fs/reiser4/plugin/item/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/item/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/Makefile 2020-12-23 16:07:46.128813275 +0100 +@@ -0,0 +1,17 @@ ++obj-$(CONFIG_REISER4_FS) += item_plugins.o ++ ++item_plugins-objs := \ ++ item.o \ ++ static_stat.o \ ++ sde.o \ ++ cde.o \ ++ blackbox.o \ ++ brick_symbol.o \ ++ internal.o \ ++ tail.o \ ++ ctail.o \ ++ extent.o \ ++ extent_item_ops.o \ ++ extent_file_ops.o \ ++ extent_stripe_ops.o \ ++ extent_flush_ops.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/sde.c linux-5.10.2/fs/reiser4/plugin/item/sde.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/sde.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/sde.c 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,186 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Directory entry implementation */ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../coord.h" ++#include "sde.h" ++#include "item.h" ++#include "../plugin.h" ++#include "../../znode.h" ++#include "../../carry.h" ++#include "../../tree.h" ++#include "../../inode.h" ++ ++#include /* for struct inode */ ++#include /* for struct dentry */ ++ ++/* ->extract_key() method of simple directory item plugin. */ ++int extract_key_de(const coord_t * coord /* coord of item */ , ++ reiser4_key * key /* resulting key */ ) ++{ ++ directory_entry_format *dent; ++ ++ assert("nikita-1458", coord != NULL); ++ assert("nikita-1459", key != NULL); ++ ++ dent = (directory_entry_format *) item_body_by_coord(coord); ++ assert("nikita-1158", item_length_by_coord(coord) >= (int)sizeof *dent); ++ return extract_key_from_id(&dent->id, key); ++} ++ ++int ++update_key_de(const coord_t * coord, const reiser4_key * key, ++ lock_handle * lh UNUSED_ARG) ++{ ++ directory_entry_format *dent; ++ obj_key_id obj_id; ++ int result; ++ ++ assert("nikita-2342", coord != NULL); ++ assert("nikita-2343", key != NULL); ++ ++ dent = (directory_entry_format *) item_body_by_coord(coord); ++ result = build_obj_key_id(key, &obj_id); ++ if (result == 0) { ++ dent->id = obj_id; ++ znode_make_dirty(coord->node); ++ } ++ return 0; ++} ++ ++char *extract_dent_name(const coord_t * coord, directory_entry_format * dent, ++ char *buf) ++{ ++ reiser4_key key; ++ ++ unit_key_by_coord(coord, &key); ++ if (get_key_type(&key) != KEY_FILE_NAME_MINOR) ++ reiser4_print_address("oops", znode_get_block(coord->node)); ++ if (!is_longname_key(&key)) { ++ if (is_dot_key(&key)) ++ return (char *)"."; ++ else ++ return extract_name_from_key(&key, buf); ++ } else ++ return (char *)dent->name; ++} ++ ++/* ->extract_name() method of simple directory item plugin. */ ++char *extract_name_de(const coord_t * coord /* coord of item */ , char *buf) ++{ ++ directory_entry_format *dent; ++ ++ assert("nikita-1460", coord != NULL); ++ ++ dent = (directory_entry_format *) item_body_by_coord(coord); ++ return extract_dent_name(coord, dent, buf); ++} ++ ++/* ->extract_file_type() method of simple directory item plugin. */ ++unsigned extract_file_type_de(const coord_t * coord UNUSED_ARG /* coord of ++ * item */ ) ++{ ++ assert("nikita-1764", coord != NULL); ++ /* we don't store file type in the directory entry yet. ++ ++ But see comments at kassign.h:obj_key_id ++ */ ++ return DT_UNKNOWN; ++} ++ ++int add_entry_de(struct inode *dir /* directory of item */ , ++ coord_t * coord /* coord of item */ , ++ lock_handle * lh /* insertion lock handle */ , ++ const struct dentry *de /* name to add */ , ++ reiser4_dir_entry_desc * entry /* parameters of new directory ++ * entry */ ) ++{ ++ reiser4_item_data data; ++ directory_entry_format *dent; ++ int result; ++ const char *name; ++ int len; ++ int longname; ++ ++ name = de->d_name.name; ++ len = de->d_name.len; ++ assert("nikita-1163", strlen(name) == len); ++ ++ longname = is_longname(name, len); ++ ++ data.length = sizeof *dent; ++ if (longname) ++ data.length += len + 1; ++ data.data = NULL; ++ data.user = 0; ++ data.iplug = item_plugin_by_id(SIMPLE_DIR_ENTRY_ID); ++ ++ inode_add_bytes(dir, data.length); ++ ++ result = insert_by_coord(coord, &data, &entry->key, lh, 0 /*flags */ ); ++ if (result != 0) ++ return result; ++ ++ dent = (directory_entry_format *) item_body_by_coord(coord); ++ build_inode_key_id(entry->obj, &dent->id); ++ if (longname) { ++ memcpy(dent->name, name, len); ++ put_unaligned(0, &dent->name[len]); ++ } ++ return 0; ++} ++ ++int rem_entry_de(struct inode *dir /* directory of item */ , ++ const struct qstr *name UNUSED_ARG, ++ coord_t * coord /* coord of item */ , ++ lock_handle * lh UNUSED_ARG /* lock handle for ++ * removal */ , ++ reiser4_dir_entry_desc * entry UNUSED_ARG /* parameters of ++ * directory entry ++ * being removed */ ) ++{ ++ coord_t shadow; ++ int result; ++ int length; ++ ++ length = item_length_by_coord(coord); ++ if (inode_get_bytes(dir) < length) { ++ warning("nikita-2627", "Dir is broke: %llu: %llu", ++ (unsigned long long)get_inode_oid(dir), ++ inode_get_bytes(dir)); ++ ++ return RETERR(-EIO); ++ } ++ ++ /* cut_node() is supposed to take pointers to _different_ ++ coords, because it will modify them without respect to ++ possible aliasing. To work around this, create temporary copy ++ of @coord. ++ */ ++ coord_dup(&shadow, coord); ++ result = ++ kill_node_content(coord, &shadow, NULL, NULL, NULL, NULL, NULL, 0); ++ if (result == 0) { ++ inode_sub_bytes(dir, length); ++ } ++ return result; ++} ++ ++int max_name_len_de(const struct inode *dir) ++{ ++ return meta_subvol_tree()->nplug->max_item_size() - ++ sizeof(directory_entry_format) - 2; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/sde.h linux-5.10.2/fs/reiser4/plugin/item/sde.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/sde.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/sde.h 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,66 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Directory entry. */ ++ ++#if !defined( __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ ) ++#define __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "../../kassign.h" ++#include "../../key.h" ++ ++#include ++#include /* for struct dentry */ ++ ++typedef struct directory_entry_format { ++ /* key of object stat-data. It's not necessary to store whole ++ key here, because it's always key of stat-data, so minor ++ packing locality and offset can be omitted here. But this ++ relies on particular key allocation scheme for stat-data, so, ++ for extensibility sake, whole key can be stored here. ++ ++ We store key as array of bytes, because we don't want 8-byte ++ alignment of dir entries. ++ */ ++ obj_key_id id; ++ /* file name. Null terminated string. */ ++ d8 name[0]; ++} directory_entry_format; ++ ++void print_de(const char *prefix, coord_t * coord); ++int extract_key_de(const coord_t * coord, reiser4_key * key); ++int update_key_de(const coord_t * coord, const reiser4_key * key, ++ lock_handle * lh); ++char *extract_name_de(const coord_t * coord, char *buf); ++unsigned extract_file_type_de(const coord_t * coord); ++int add_entry_de(struct inode *dir, coord_t * coord, ++ lock_handle * lh, const struct dentry *name, ++ reiser4_dir_entry_desc * entry); ++int rem_entry_de(struct inode *dir, const struct qstr *name, coord_t * coord, ++ lock_handle * lh, reiser4_dir_entry_desc * entry); ++int max_name_len_de(const struct inode *dir); ++ ++int de_rem_and_shrink(struct inode *dir, coord_t * coord, int length); ++ ++char *extract_dent_name(const coord_t * coord, ++ directory_entry_format * dent, char *buf); ++ ++#if REISER4_LARGE_KEY ++#define DE_NAME_BUF_LEN (24) ++#else ++#define DE_NAME_BUF_LEN (16) ++#endif ++ ++/* __FS_REISER4_PLUGIN_DIRECTORY_ENTRY_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/static_stat.c linux-5.10.2/fs/reiser4/plugin/item/static_stat.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/static_stat.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/static_stat.c 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,1113 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* stat data manipulation. */ ++ ++#include "../../forward.h" ++#include "../../super.h" ++#include "../../vfs_ops.h" ++#include "../../inode.h" ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../object.h" ++#include "../plugin.h" ++#include "../plugin_header.h" ++#include "static_stat.h" ++#include "item.h" ++ ++#include ++#include ++ ++/* see static_stat.h for explanation */ ++ ++/* helper function used while we are dumping/loading inode/plugin state ++ to/from the stat-data. */ ++ ++static void move_on(int *length /* space remaining in stat-data */ , ++ char **area /* current coord in stat data */ , ++ int size_of /* how many bytes to move forward */ ) ++{ ++ assert("nikita-615", length != NULL); ++ assert("nikita-616", area != NULL); ++ ++ *length -= size_of; ++ *area += size_of; ++ ++ assert("nikita-617", *length >= 0); ++} ++ ++/* helper function used while loading inode/plugin state from stat-data. ++ Complain if there is less space in stat-data than was expected. ++ Can only happen on disk corruption. */ ++static int not_enough_space(struct inode *inode /* object being processed */ , ++ const char *where /* error message */ ) ++{ ++ assert("nikita-618", inode != NULL); ++ ++ warning("nikita-619", "Not enough space in %llu while loading %s", ++ (unsigned long long)get_inode_oid(inode), where); ++ ++ return RETERR(-EINVAL); ++} ++ ++/* helper function used while loading inode/plugin state from ++ stat-data. Call it if invalid plugin id was found. */ ++static int unknown_plugin(reiser4_plugin_id id /* invalid id */ , ++ struct inode *inode /* object being processed */ ) ++{ ++ warning("nikita-620", "Unknown plugin %i in %llu", ++ id, (unsigned long long)get_inode_oid(inode)); ++ ++ return RETERR(-EINVAL); ++} ++ ++/* this is installed as ->init_inode() method of ++ item_plugins[ STATIC_STAT_DATA_IT ] (fs/reiser4/plugin/item/item.c). ++ Copies data from on-disk stat-data format into inode. ++ Handles stat-data extensions. */ ++/* was sd_load */ ++int init_inode_static_sd(struct inode *inode /* object being processed */ , ++ char *sd /* stat-data body */ , ++ int len /* length of stat-data */ ) ++{ ++ int result; ++ int bit; ++ int chunk; ++ __u16 mask; ++ __u64 bigmask; ++ reiser4_stat_data_base *sd_base; ++ reiser4_inode *state; ++ ++ assert("nikita-625", inode != NULL); ++ assert("nikita-626", sd != NULL); ++ ++ result = 0; ++ sd_base = (reiser4_stat_data_base *) sd; ++ state = reiser4_inode_data(inode); ++ mask = le16_to_cpu(get_unaligned(&sd_base->extmask)); ++ bigmask = mask; ++ reiser4_inode_set_flag(inode, REISER4_SDLEN_KNOWN); ++ ++ move_on(&len, &sd, sizeof *sd_base); ++ for (bit = 0, chunk = 0; ++ mask != 0 || bit <= LAST_IMPORTANT_SD_EXTENSION; ++ ++bit, mask >>= 1) { ++ if (((bit + 1) % 16) != 0) { ++ /* handle extension */ ++ sd_ext_plugin *sdplug; ++ ++ if (bit >= LAST_SD_EXTENSION) { ++ warning("vpf-1904", ++ "No such extension %i in inode %llu", ++ bit, ++ (unsigned long long) ++ get_inode_oid(inode)); ++ ++ result = RETERR(-EINVAL); ++ break; ++ } ++ ++ sdplug = sd_ext_plugin_by_id(bit); ++ if (sdplug == NULL) { ++ warning("nikita-627", ++ "No such extension %i in inode %llu", ++ bit, ++ (unsigned long long) ++ get_inode_oid(inode)); ++ ++ result = RETERR(-EINVAL); ++ break; ++ } ++ if (mask & 1) { ++ assert("nikita-628", sdplug->present); ++ /* alignment is not supported in node layout ++ plugin yet. ++ result = align( inode, &len, &sd, ++ sdplug -> alignment ); ++ if( result != 0 ) ++ return result; */ ++ result = sdplug->present(inode, &sd, &len); ++ } else if (sdplug->absent != NULL) ++ result = sdplug->absent(inode); ++ if (result) ++ break; ++ /* else, we are looking at the last bit in 16-bit ++ portion of bitmask */ ++ } else if (mask & 1) { ++ /* next portion of bitmask */ ++ if (len < (int)sizeof(d16)) { ++ warning("nikita-629", ++ "No space for bitmap in inode %llu", ++ (unsigned long long) ++ get_inode_oid(inode)); ++ ++ result = RETERR(-EINVAL); ++ break; ++ } ++ mask = le16_to_cpu(get_unaligned((d16 *)sd)); ++ bigmask <<= 16; ++ bigmask |= mask; ++ move_on(&len, &sd, sizeof(d16)); ++ ++chunk; ++ if (chunk == 3) { ++ if (!(mask & 0x8000)) { ++ /* clear last bit */ ++ mask &= ~0x8000; ++ continue; ++ } ++ /* too much */ ++ warning("nikita-630", ++ "Too many extensions in %llu", ++ (unsigned long long) ++ get_inode_oid(inode)); ++ ++ result = RETERR(-EINVAL); ++ break; ++ } ++ } else ++ /* bitmask exhausted */ ++ break; ++ } ++ state->extmask = bigmask; ++ /* common initialisations */ ++ if (len - (bit / 16 * sizeof(d16)) > 0) { ++ /* alignment in save_len_static_sd() is taken into account ++ -edward */ ++ warning("nikita-631", "unused space in inode %llu", ++ (unsigned long long)get_inode_oid(inode)); ++ } ++ ++ return result; ++} ++ ++/* estimates size of stat-data required to store inode. ++ Installed as ->save_len() method of ++ item_plugins[ STATIC_STAT_DATA_IT ] (fs/reiser4/plugin/item/item.c). */ ++/* was sd_len */ ++int save_len_static_sd(struct inode *inode /* object being processed */ ) ++{ ++ unsigned int result; ++ __u64 mask; ++ int bit; ++ ++ assert("nikita-632", inode != NULL); ++ ++ result = sizeof(reiser4_stat_data_base); ++ mask = reiser4_inode_data(inode)->extmask; ++ for (bit = 0; mask != 0; ++bit, mask >>= 1) { ++ if (mask & 1) { ++ sd_ext_plugin *sdplug; ++ ++ sdplug = sd_ext_plugin_by_id(bit); ++ assert("nikita-633", sdplug != NULL); ++ /* ++ no aligment support ++ result += ++ reiser4_round_up(result, sdplug -> alignment) - ++ result; ++ */ ++ result += sdplug->save_len(inode); ++ } ++ } ++ result += bit / 16 * sizeof(d16); ++ return result; ++} ++ ++/* saves inode into stat-data. ++ Installed as ->save() method of ++ item_plugins[ STATIC_STAT_DATA_IT ] (fs/reiser4/plugin/item/item.c). */ ++/* was sd_save */ ++int save_static_sd(struct inode *inode /* object being processed */ , ++ char **area /* where to save stat-data */ ) ++{ ++ int result; ++ __u64 emask; ++ int bit; ++ unsigned int len; ++ reiser4_stat_data_base *sd_base; ++ ++ assert("nikita-634", inode != NULL); ++ assert("nikita-635", area != NULL); ++ ++ result = 0; ++ emask = reiser4_inode_data(inode)->extmask; ++ sd_base = (reiser4_stat_data_base *) * area; ++ put_unaligned(cpu_to_le16((__u16)(emask & 0xffff)), &sd_base->extmask); ++ /*cputod16((unsigned)(emask & 0xffff), &sd_base->extmask);*/ ++ ++ *area += sizeof *sd_base; ++ len = 0xffffffffu; ++ for (bit = 0; emask != 0; ++bit, emask >>= 1) { ++ if (emask & 1) { ++ if ((bit + 1) % 16 != 0) { ++ sd_ext_plugin *sdplug; ++ sdplug = sd_ext_plugin_by_id(bit); ++ assert("nikita-636", sdplug != NULL); ++ /* no alignment support yet ++ align( inode, &len, area, ++ sdplug -> alignment ); */ ++ result = sdplug->save(inode, area); ++ if (result) ++ break; ++ } else { ++ put_unaligned(cpu_to_le16((__u16)(emask & 0xffff)), ++ (d16 *)(*area)); ++ /*cputod16((unsigned)(emask & 0xffff), ++ (d16 *) * area);*/ ++ *area += sizeof(d16); ++ } ++ } ++ } ++ return result; ++} ++ ++/* stat-data extension handling functions. */ ++ ++static int present_lw_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ , ++ int *len /* remaining length */ ) ++{ ++ if (*len >= (int)sizeof(reiser4_light_weight_stat)) { ++ reiser4_light_weight_stat *sd_lw; ++ ++ sd_lw = (reiser4_light_weight_stat *) * area; ++ ++ inode->i_mode = le16_to_cpu(get_unaligned(&sd_lw->mode)); ++ set_nlink(inode, le32_to_cpu(get_unaligned(&sd_lw->nlink))); ++ inode->i_size = le64_to_cpu(get_unaligned(&sd_lw->size)); ++ if ((inode->i_mode & S_IFMT) == (S_IFREG | S_IFIFO)) { ++ inode->i_mode &= ~S_IFIFO; ++ reiser4_inode_set_flag(inode, ++ REISER4_FAKE_IMODE_ONDISK); ++ } ++ move_on(len, area, sizeof *sd_lw); ++ return 0; ++ } else ++ return not_enough_space(inode, "lw sd"); ++} ++ ++static int save_len_lw_sd(struct inode *inode UNUSED_ARG /* object being ++ * processed */ ) ++{ ++ return sizeof(reiser4_light_weight_stat); ++} ++ ++static int save_lw_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ ) ++{ ++ reiser4_light_weight_stat *sd; ++ mode_t delta; ++ ++ assert("nikita-2705", inode != NULL); ++ assert("nikita-2706", area != NULL); ++ assert("nikita-2707", *area != NULL); ++ ++ sd = (reiser4_light_weight_stat *) * area; ++ ++ delta = (reiser4_inode_get_flag(inode, ++ REISER4_FAKE_IMODE_ONDISK) ? S_IFIFO : 0); ++ put_unaligned(cpu_to_le16(inode->i_mode | delta), &sd->mode); ++ put_unaligned(cpu_to_le32(inode->i_nlink), &sd->nlink); ++ put_unaligned(cpu_to_le64((__u64) inode->i_size), &sd->size); ++ *area += sizeof *sd; ++ return 0; ++} ++ ++static int present_unix_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ , ++ int *len /* remaining length */ ) ++{ ++ assert("nikita-637", inode != NULL); ++ assert("nikita-638", area != NULL); ++ assert("nikita-639", *area != NULL); ++ assert("nikita-640", len != NULL); ++ assert("nikita-641", *len > 0); ++ ++ if (*len >= (int)sizeof(reiser4_unix_stat)) { ++ reiser4_unix_stat *sd; ++ ++ sd = (reiser4_unix_stat *) * area; ++ ++ i_uid_write(inode, le32_to_cpu(get_unaligned(&sd->uid))); ++ i_gid_write(inode, le32_to_cpu(get_unaligned(&sd->gid))); ++ inode->i_atime.tv_sec = le32_to_cpu(get_unaligned(&sd->atime)); ++ inode->i_mtime.tv_sec = le32_to_cpu(get_unaligned(&sd->mtime)); ++ inode->i_ctime.tv_sec = le32_to_cpu(get_unaligned(&sd->ctime)); ++ if (S_ISBLK(inode->i_mode) || S_ISCHR(inode->i_mode)) ++ inode->i_rdev = le64_to_cpu(get_unaligned(&sd->u.rdev)); ++ else ++ inode_set_bytes(inode, (loff_t) le64_to_cpu(get_unaligned(&sd->u.bytes))); ++ move_on(len, area, sizeof *sd); ++ return 0; ++ } else ++ return not_enough_space(inode, "unix sd"); ++} ++ ++static int absent_unix_sd(struct inode *inode /* object being processed */ ) ++{ ++ i_uid_write(inode, get_super_private(inode->i_sb)->default_uid); ++ i_gid_write(inode, get_super_private(inode->i_sb)->default_gid); ++ inode->i_atime = inode->i_mtime = inode->i_ctime = current_time(inode); ++ inode_set_bytes(inode, inode->i_size); ++ /* mark inode as lightweight, so that caller (lookup_common) will ++ complete initialisation by copying [ug]id from a parent. */ ++ reiser4_inode_set_flag(inode, REISER4_LIGHT_WEIGHT); ++ return 0; ++} ++ ++/* Audited by: green(2002.06.14) */ ++static int save_len_unix_sd(struct inode *inode UNUSED_ARG /* object being ++ * processed */ ) ++{ ++ return sizeof(reiser4_unix_stat); ++} ++ ++static int save_unix_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ ) ++{ ++ reiser4_unix_stat *sd; ++ ++ assert("nikita-642", inode != NULL); ++ assert("nikita-643", area != NULL); ++ assert("nikita-644", *area != NULL); ++ ++ sd = (reiser4_unix_stat *) * area; ++ put_unaligned(cpu_to_le32(i_uid_read(inode)), &sd->uid); ++ put_unaligned(cpu_to_le32(i_gid_read(inode)), &sd->gid); ++ put_unaligned(cpu_to_le32((__u32) inode->i_atime.tv_sec), &sd->atime); ++ put_unaligned(cpu_to_le32((__u32) inode->i_ctime.tv_sec), &sd->ctime); ++ put_unaligned(cpu_to_le32((__u32) inode->i_mtime.tv_sec), &sd->mtime); ++ if (S_ISBLK(inode->i_mode) || S_ISCHR(inode->i_mode)) ++ put_unaligned(cpu_to_le64(inode->i_rdev), &sd->u.rdev); ++ else ++ put_unaligned(cpu_to_le64((__u64) inode_get_bytes(inode)), &sd->u.bytes); ++ *area += sizeof *sd; ++ return 0; ++} ++ ++static int ++present_large_times_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ , ++ int *len /* remaining length */ ) ++{ ++ if (*len >= (int)sizeof(reiser4_large_times_stat)) { ++ reiser4_large_times_stat *sd_lt; ++ ++ sd_lt = (reiser4_large_times_stat *) * area; ++ ++ inode->i_atime.tv_nsec = le32_to_cpu(get_unaligned(&sd_lt->atime)); ++ inode->i_mtime.tv_nsec = le32_to_cpu(get_unaligned(&sd_lt->mtime)); ++ inode->i_ctime.tv_nsec = le32_to_cpu(get_unaligned(&sd_lt->ctime)); ++ ++ move_on(len, area, sizeof *sd_lt); ++ return 0; ++ } else ++ return not_enough_space(inode, "large times sd"); ++} ++ ++static int ++save_len_large_times_sd(struct inode *inode UNUSED_ARG ++ /* object being processed */ ) ++{ ++ return sizeof(reiser4_large_times_stat); ++} ++ ++static int ++save_large_times_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ ) ++{ ++ reiser4_large_times_stat *sd; ++ ++ assert("nikita-2817", inode != NULL); ++ assert("nikita-2818", area != NULL); ++ assert("nikita-2819", *area != NULL); ++ ++ sd = (reiser4_large_times_stat *) * area; ++ ++ put_unaligned(cpu_to_le32((__u32) inode->i_atime.tv_nsec), &sd->atime); ++ put_unaligned(cpu_to_le32((__u32) inode->i_ctime.tv_nsec), &sd->ctime); ++ put_unaligned(cpu_to_le32((__u32) inode->i_mtime.tv_nsec), &sd->mtime); ++ ++ *area += sizeof *sd; ++ return 0; ++} ++ ++/* symlink stat data extension */ ++ ++/* allocate memory for symlink target and attach it to inode->i_private */ ++static int ++symlink_target_to_inode(struct inode *inode, const char *target, int len) ++{ ++ assert("vs-845", inode->i_private == NULL); ++ assert("vs-846", !reiser4_inode_get_flag(inode, ++ REISER4_GENERIC_PTR_USED)); ++ /* FIXME-VS: this is prone to deadlock. Not more than other similar ++ places, though */ ++ inode->i_private = kmalloc((size_t) len + 1, ++ reiser4_ctx_gfp_mask_get()); ++ if (!inode->i_private) ++ return RETERR(-ENOMEM); ++ ++ memcpy((char *)(inode->i_private), target, (size_t) len); ++ ((char *)(inode->i_private))[len] = 0; ++ reiser4_inode_set_flag(inode, REISER4_GENERIC_PTR_USED); ++ return 0; ++} ++ ++/* this is called on read_inode. There is nothing to do actually, but some ++ sanity checks */ ++static int present_symlink_sd(struct inode *inode, char **area, int *len) ++{ ++ int result; ++ int length; ++ reiser4_symlink_stat *sd; ++ ++ length = (int)inode->i_size; ++ /* ++ * *len is number of bytes in stat data item from *area to the end of ++ * item. It must be not less than size of symlink + 1 for ending 0 ++ */ ++ if (length > *len) ++ return not_enough_space(inode, "symlink"); ++ ++ if (*(*area + length) != 0) { ++ warning("vs-840", "Symlink is not zero terminated"); ++ return RETERR(-EIO); ++ } ++ ++ sd = (reiser4_symlink_stat *) * area; ++ result = symlink_target_to_inode(inode, sd->body, length); ++ ++ move_on(len, area, length + 1); ++ return result; ++} ++ ++static int save_len_symlink_sd(struct inode *inode) ++{ ++ return inode->i_size + 1; ++} ++ ++/* this is called on create and update stat data. Do nothing on update but ++ update @area */ ++static int save_symlink_sd(struct inode *inode, char **area) ++{ ++ int result; ++ int length; ++ reiser4_symlink_stat *sd; ++ ++ length = (int)inode->i_size; ++ /* inode->i_size must be set already */ ++ assert("vs-841", length); ++ ++ result = 0; ++ sd = (reiser4_symlink_stat *) * area; ++ if (!reiser4_inode_get_flag(inode, REISER4_GENERIC_PTR_USED)) { ++ const char *target; ++ ++ target = (const char *)(inode->i_private); ++ inode->i_private = NULL; ++ ++ result = symlink_target_to_inode(inode, target, length); ++ ++ /* copy symlink to stat data */ ++ memcpy(sd->body, target, (size_t) length); ++ (*area)[length] = 0; ++ } else { ++ /* there is nothing to do in update but move area */ ++ assert("vs-844", ++ !memcmp(inode->i_private, sd->body, ++ (size_t) length + 1)); ++ } ++ ++ *area += (length + 1); ++ return result; ++} ++ ++static int present_flags_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ , ++ int *len /* remaining length */ ) ++{ ++ assert("nikita-645", inode != NULL); ++ assert("nikita-646", area != NULL); ++ assert("nikita-647", *area != NULL); ++ assert("nikita-648", len != NULL); ++ assert("nikita-649", *len > 0); ++ ++ if (*len >= (int)sizeof(reiser4_flags_stat)) { ++ reiser4_flags_stat *sd; ++ ++ sd = (reiser4_flags_stat *) * area; ++ inode->i_flags = le32_to_cpu(get_unaligned(&sd->flags)); ++ move_on(len, area, sizeof *sd); ++ return 0; ++ } else ++ return not_enough_space(inode, "generation and attrs"); ++} ++ ++/* Audited by: green(2002.06.14) */ ++static int save_len_flags_sd(struct inode *inode UNUSED_ARG /* object being ++ * processed */ ) ++{ ++ return sizeof(reiser4_flags_stat); ++} ++ ++static int save_flags_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ ) ++{ ++ reiser4_flags_stat *sd; ++ ++ assert("nikita-650", inode != NULL); ++ assert("nikita-651", area != NULL); ++ assert("nikita-652", *area != NULL); ++ ++ sd = (reiser4_flags_stat *) * area; ++ put_unaligned(cpu_to_le32(inode->i_flags), &sd->flags); ++ *area += sizeof *sd; ++ return 0; ++} ++ ++static int absent_plugin_sd(struct inode *inode); ++static int present_plugin_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */ , ++ int *len /* remaining length */, ++ int is_pset /* 1 if plugin set, 0 if heir set. */) ++{ ++ reiser4_plugin_stat *sd; ++ reiser4_plugin *plugin; ++ reiser4_inode *info; ++ int i; ++ __u16 mask; ++ int result; ++ int num_of_plugins; ++ ++ assert("nikita-653", inode != NULL); ++ assert("nikita-654", area != NULL); ++ assert("nikita-655", *area != NULL); ++ assert("nikita-656", len != NULL); ++ assert("nikita-657", *len > 0); ++ ++ if (*len < (int)sizeof(reiser4_plugin_stat)) ++ return not_enough_space(inode, "plugin"); ++ ++ sd = (reiser4_plugin_stat *) * area; ++ info = reiser4_inode_data(inode); ++ ++ mask = 0; ++ num_of_plugins = le16_to_cpu(get_unaligned(&sd->plugins_no)); ++ move_on(len, area, sizeof *sd); ++ result = 0; ++ for (i = 0; i < num_of_plugins; ++i) { ++ reiser4_plugin_slot *slot; ++ reiser4_plugin_type type; ++ pset_member memb; ++ ++ slot = (reiser4_plugin_slot *) * area; ++ if (*len < (int)sizeof *slot) ++ return not_enough_space(inode, "additional plugin"); ++ ++ memb = le16_to_cpu(get_unaligned(&slot->pset_memb)); ++ type = aset_member_to_type_unsafe(memb); ++ ++ if (type == REISER4_PLUGIN_TYPES) { ++ warning("nikita-3502", ++ "wrong %s member (%i) for %llu", is_pset ? ++ "pset" : "hset", memb, ++ (unsigned long long)get_inode_oid(inode)); ++ return RETERR(-EINVAL); ++ } ++ plugin = plugin_by_disk_id(type, &slot->id); ++ if (plugin == NULL) ++ return unknown_plugin(le16_to_cpu(get_unaligned(&slot->id)), inode); ++ ++ /* plugin is loaded into inode, mark this into inode's ++ bitmask of loaded non-standard plugins */ ++ if (!(mask & (1 << memb))) { ++ mask |= (1 << memb); ++ } else { ++ warning("nikita-658", "duplicate plugin for %llu", ++ (unsigned long long)get_inode_oid(inode)); ++ return RETERR(-EINVAL); ++ } ++ move_on(len, area, sizeof *slot); ++ /* load plugin data, if any */ ++ if (plugin->h.pops != NULL && plugin->h.pops->load) ++ result = plugin->h.pops->load(inode, plugin, area, len); ++ else ++ result = aset_set_unsafe(is_pset ? &info->pset : ++ &info->hset, memb, plugin); ++ if (result) ++ return result; ++ } ++ if (is_pset) { ++ /* if object plugin wasn't loaded from stat-data, guess it by ++ mode bits */ ++ plugin = file_plugin_to_plugin(inode_file_plugin(inode)); ++ if (plugin == NULL) ++ result = absent_plugin_sd(inode); ++ info->plugin_mask = mask; ++ } else ++ info->heir_mask = mask; ++ ++ return result; ++} ++ ++static int present_pset_sd(struct inode *inode, char **area, int *len) { ++ return present_plugin_sd(inode, area, len, 1 /* pset */); ++} ++ ++/* Determine object plugin for @inode based on i_mode. ++ ++ Many objects in reiser4 file system are controlled by standard object ++ plugins that emulate traditional unix objects: unix file, directory, symlink, fifo, and so on. ++ ++ For such files we don't explicitly store plugin id in object stat ++ data. Rather required plugin is guessed from mode bits, where file "type" ++ is encoded (see stat(2)). ++*/ ++static int ++guess_plugin_by_mode(struct inode *inode /* object to guess plugins for */ ) ++{ ++ int fplug_id; ++ int dplug_id; ++ reiser4_inode *info; ++ ++ assert("nikita-736", inode != NULL); ++ ++ dplug_id = fplug_id = -1; ++ ++ switch (inode->i_mode & S_IFMT) { ++ case S_IFSOCK: ++ case S_IFBLK: ++ case S_IFCHR: ++ case S_IFIFO: ++ fplug_id = SPECIAL_FILE_PLUGIN_ID; ++ break; ++ case S_IFLNK: ++ fplug_id = SYMLINK_FILE_PLUGIN_ID; ++ break; ++ case S_IFDIR: ++ fplug_id = DIRECTORY_FILE_PLUGIN_ID; ++ dplug_id = HASHED_DIR_PLUGIN_ID; ++ break; ++ default: ++ warning("nikita-737", "wrong file mode: %o", inode->i_mode); ++ return RETERR(-EIO); ++ case S_IFREG: ++ fplug_id = UNIX_FILE_PLUGIN_ID; ++ break; ++ } ++ info = reiser4_inode_data(inode); ++ set_plugin(&info->pset, PSET_FILE, (fplug_id >= 0) ? ++ plugin_by_id(REISER4_FILE_PLUGIN_TYPE, fplug_id) : NULL); ++ set_plugin(&info->pset, PSET_DIR, (dplug_id >= 0) ? ++ plugin_by_id(REISER4_DIR_PLUGIN_TYPE, dplug_id) : NULL); ++ return 0; ++} ++ ++/* Audited by: green(2002.06.14) */ ++static int absent_plugin_sd(struct inode *inode /* object being processed */ ) ++{ ++ int result; ++ ++ assert("nikita-659", inode != NULL); ++ ++ result = guess_plugin_by_mode(inode); ++ /* if mode was wrong, guess_plugin_by_mode() returns "regular file", ++ but setup_inode_ops() will call make_bad_inode(). ++ Another, more logical but bit more complex solution is to add ++ "bad-file plugin". */ ++ /* FIXME-VS: activate was called here */ ++ return result; ++} ++ ++/* helper function for plugin_sd_save_len(): calculate how much space ++ required to save state of given plugin */ ++/* Audited by: green(2002.06.14) */ ++static int len_for(reiser4_plugin * plugin /* plugin to save */ , ++ struct inode *inode /* object being processed */ , ++ pset_member memb, ++ int len, int is_pset) ++{ ++ reiser4_inode *info; ++ assert("nikita-661", inode != NULL); ++ ++ if (plugin == NULL) ++ return len; ++ ++ info = reiser4_inode_data(inode); ++ if (is_pset ? ++ info->plugin_mask & (1 << memb) : ++ info->heir_mask & (1 << memb)) { ++ len += sizeof(reiser4_plugin_slot); ++ if (plugin->h.pops && plugin->h.pops->save_len != NULL) { ++ /* ++ * non-standard plugin, call method ++ * commented as it is incompatible with alignment ++ * policy in save_plug() -edward ++ * ++ * len = reiser4_round_up(len, ++ * plugin->h.pops->alignment); ++ */ ++ len += plugin->h.pops->save_len(inode, plugin); ++ } ++ } ++ return len; ++} ++ ++/* calculate how much space is required to save state of all plugins, ++ associated with inode */ ++static int save_len_plugin_sd(struct inode *inode /* object being processed */, ++ int is_pset) ++{ ++ int len; ++ int last; ++ reiser4_inode *state; ++ pset_member memb; ++ ++ assert("nikita-663", inode != NULL); ++ ++ state = reiser4_inode_data(inode); ++ ++ /* common case: no non-standard plugins */ ++ if (is_pset ? state->plugin_mask == 0 : state->heir_mask == 0) ++ return 0; ++ len = sizeof(reiser4_plugin_stat); ++ last = PSET_LAST; ++ ++ for (memb = 0; memb < last; ++memb) { ++ len = len_for(aset_get(is_pset ? state->pset : state->hset, memb), ++ inode, memb, len, is_pset); ++ } ++ assert("nikita-664", len > (int)sizeof(reiser4_plugin_stat)); ++ return len; ++} ++ ++static int save_len_pset_sd(struct inode *inode) { ++ return save_len_plugin_sd(inode, 1 /* pset */); ++} ++ ++/* helper function for plugin_sd_save(): save plugin, associated with ++ inode. */ ++static int save_plug(reiser4_plugin * plugin /* plugin to save */ , ++ struct inode *inode /* object being processed */ , ++ int memb /* what element of pset is saved */ , ++ char **area /* position in stat-data */ , ++ int *count /* incremented if plugin were actually saved. */, ++ int is_pset /* 1 for plugin set, 0 for heir set */) ++{ ++ reiser4_plugin_slot *slot; ++ int fake_len; ++ int result; ++ ++ assert("nikita-665", inode != NULL); ++ assert("nikita-666", area != NULL); ++ assert("nikita-667", *area != NULL); ++ ++ if (plugin == NULL) ++ return 0; ++ ++ if (is_pset ? ++ !(reiser4_inode_data(inode)->plugin_mask & (1 << memb)) : ++ !(reiser4_inode_data(inode)->heir_mask & (1 << memb))) ++ return 0; ++ slot = (reiser4_plugin_slot *) * area; ++ put_unaligned(cpu_to_le16(memb), &slot->pset_memb); ++ put_unaligned(cpu_to_le16(plugin->h.id), &slot->id); ++ fake_len = (int)0xffff; ++ move_on(&fake_len, area, sizeof *slot); ++ ++*count; ++ result = 0; ++ if (plugin->h.pops != NULL) { ++ if (plugin->h.pops->save != NULL) ++ result = plugin->h.pops->save(inode, plugin, area); ++ } ++ return result; ++} ++ ++/* save state of all non-standard plugins associated with inode */ ++static int save_plugin_sd(struct inode *inode /* object being processed */ , ++ char **area /* position in stat-data */, ++ int is_pset /* 1 for pset, 0 for hset */) ++{ ++ int fake_len; ++ int result = 0; ++ int num_of_plugins; ++ reiser4_plugin_stat *sd; ++ reiser4_inode *state; ++ pset_member memb; ++ ++ assert("nikita-669", inode != NULL); ++ assert("nikita-670", area != NULL); ++ assert("nikita-671", *area != NULL); ++ ++ state = reiser4_inode_data(inode); ++ if (is_pset ? state->plugin_mask == 0 : state->heir_mask == 0) ++ return 0; ++ sd = (reiser4_plugin_stat *) * area; ++ fake_len = (int)0xffff; ++ move_on(&fake_len, area, sizeof *sd); ++ ++ num_of_plugins = 0; ++ for (memb = 0; memb < PSET_LAST; ++memb) { ++ result = save_plug(aset_get(is_pset ? state->pset : state->hset, ++ memb), ++ inode, memb, area, &num_of_plugins, is_pset); ++ if (result != 0) ++ break; ++ } ++ ++ put_unaligned(cpu_to_le16((__u16)num_of_plugins), &sd->plugins_no); ++ return result; ++} ++ ++static int save_pset_sd(struct inode *inode, char **area) { ++ return save_plugin_sd(inode, area, 1 /* pset */); ++} ++ ++static int present_hset_sd(struct inode *inode, char **area, int *len) { ++ return present_plugin_sd(inode, area, len, 0 /* hset */); ++} ++ ++static int save_len_hset_sd(struct inode *inode) { ++ return save_len_plugin_sd(inode, 0 /* pset */); ++} ++ ++static int save_hset_sd(struct inode *inode, char **area) { ++ return save_plugin_sd(inode, area, 0 /* hset */); ++} ++ ++/* helper function for crypto_sd_present(), crypto_sd_save. ++ Extract crypto info from stat-data and attach it to inode */ ++static int extract_crypto_info (struct inode * inode, ++ reiser4_crypto_stat * sd) ++{ ++ struct reiser4_crypto_info * info; ++ assert("edward-11", !inode_crypto_info(inode)); ++ assert("edward-1413", ++ !reiser4_inode_get_flag(inode, REISER4_CRYPTO_STAT_LOADED)); ++ /* create and attach a crypto-stat without secret key loaded */ ++ info = reiser4_alloc_crypto_info(inode); ++ if (IS_ERR(info)) ++ return PTR_ERR(info); ++ info->keysize = le16_to_cpu(get_unaligned(&sd->keysize)); ++ memcpy(info->keyid, sd->keyid, inode_digest_plugin(inode)->fipsize); ++ reiser4_attach_crypto_info(inode, info); ++ reiser4_inode_set_flag(inode, REISER4_CRYPTO_STAT_LOADED); ++ return 0; ++} ++ ++/* crypto stat-data extension */ ++ ++static int present_crypto_sd(struct inode *inode, char **area, int *len) ++{ ++ int result; ++ reiser4_crypto_stat *sd; ++ digest_plugin *dplug = inode_digest_plugin(inode); ++ ++ assert("edward-06", dplug != NULL); ++ assert("edward-684", dplug->fipsize); ++ assert("edward-07", area != NULL); ++ assert("edward-08", *area != NULL); ++ assert("edward-09", len != NULL); ++ assert("edward-10", *len > 0); ++ ++ if (*len < (int)sizeof(reiser4_crypto_stat)) { ++ return not_enough_space(inode, "crypto-sd"); ++ } ++ /* *len is number of bytes in stat data item from *area to the end of ++ item. It must be not less than size of this extension */ ++ assert("edward-75", sizeof(*sd) + dplug->fipsize <= *len); ++ ++ sd = (reiser4_crypto_stat *) * area; ++ result = extract_crypto_info(inode, sd); ++ move_on(len, area, sizeof(*sd) + dplug->fipsize); ++ ++ return result; ++} ++ ++static int save_len_crypto_sd(struct inode *inode) ++{ ++ return sizeof(reiser4_crypto_stat) + ++ inode_digest_plugin(inode)->fipsize; ++} ++ ++static int save_crypto_sd(struct inode *inode, char **area) ++{ ++ int result = 0; ++ reiser4_crypto_stat *sd; ++ struct reiser4_crypto_info * info = inode_crypto_info(inode); ++ digest_plugin *dplug = inode_digest_plugin(inode); ++ ++ assert("edward-12", dplug != NULL); ++ assert("edward-13", area != NULL); ++ assert("edward-14", *area != NULL); ++ assert("edward-15", info != NULL); ++ assert("edward-1414", info->keyid != NULL); ++ assert("edward-1415", info->keysize != 0); ++ assert("edward-76", reiser4_inode_data(inode) != NULL); ++ ++ if (!reiser4_inode_get_flag(inode, REISER4_CRYPTO_STAT_LOADED)) { ++ /* file is just created */ ++ sd = (reiser4_crypto_stat *) *area; ++ /* copy everything but private key to the disk stat-data */ ++ put_unaligned(cpu_to_le16(info->keysize), &sd->keysize); ++ memcpy(sd->keyid, info->keyid, (size_t) dplug->fipsize); ++ reiser4_inode_set_flag(inode, REISER4_CRYPTO_STAT_LOADED); ++ } ++ *area += (sizeof(*sd) + dplug->fipsize); ++ return result; ++} ++ ++static int eio(struct inode *inode, char **area, int *len) ++{ ++ return RETERR(-EIO); ++} ++ ++sd_ext_plugin sd_ext_plugins[LAST_SD_EXTENSION] = { ++ [LIGHT_WEIGHT_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = LIGHT_WEIGHT_STAT, ++ .pops = NULL, ++ .label = "light-weight sd", ++ .desc = "sd for light-weight files", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_lw_sd, ++ .absent = NULL, ++ .save_len = save_len_lw_sd, ++ .save = save_lw_sd, ++ .alignment = 8 ++ }, ++ [UNIX_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = UNIX_STAT, ++ .pops = NULL, ++ .label = "unix-sd", ++ .desc = "unix stat-data fields", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_unix_sd, ++ .absent = absent_unix_sd, ++ .save_len = save_len_unix_sd, ++ .save = save_unix_sd, ++ .alignment = 8 ++ }, ++ [LARGE_TIMES_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = LARGE_TIMES_STAT, ++ .pops = NULL, ++ .label = "64time-sd", ++ .desc = "nanosecond resolution for times", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_large_times_sd, ++ .absent = NULL, ++ .save_len = save_len_large_times_sd, ++ .save = save_large_times_sd, ++ .alignment = 8 ++ }, ++ [SYMLINK_STAT] = { ++ /* stat data of symlink has this extension */ ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = SYMLINK_STAT, ++ .pops = NULL, ++ .label = "symlink-sd", ++ .desc = ++ "stat data is appended with symlink name", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_symlink_sd, ++ .absent = NULL, ++ .save_len = save_len_symlink_sd, ++ .save = save_symlink_sd, ++ .alignment = 8 ++ }, ++ [PLUGIN_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = PLUGIN_STAT, ++ .pops = NULL, ++ .label = "plugin-sd", ++ .desc = "plugin stat-data fields", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_pset_sd, ++ .absent = absent_plugin_sd, ++ .save_len = save_len_pset_sd, ++ .save = save_pset_sd, ++ .alignment = 8 ++ }, ++ [HEIR_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = HEIR_STAT, ++ .pops = NULL, ++ .label = "heir-plugin-sd", ++ .desc = "heir plugin stat-data fields", ++ .linkage = {NULL,NULL} ++ }, ++ .present = present_hset_sd, ++ .absent = NULL, ++ .save_len = save_len_hset_sd, ++ .save = save_hset_sd, ++ .alignment = 8 ++ }, ++ [FLAGS_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = FLAGS_STAT, ++ .pops = NULL, ++ .label = "flags-sd", ++ .desc = "inode bit flags", ++ .linkage = {NULL, NULL} ++ }, ++ .present = present_flags_sd, ++ .absent = NULL, ++ .save_len = save_len_flags_sd, ++ .save = save_flags_sd, ++ .alignment = 8 ++ }, ++ [CAPABILITIES_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = CAPABILITIES_STAT, ++ .pops = NULL, ++ .label = "capabilities-sd", ++ .desc = "capabilities", ++ .linkage = {NULL, NULL} ++ }, ++ .present = eio, ++ .absent = NULL, ++ .save_len = save_len_flags_sd, ++ .save = save_flags_sd, ++ .alignment = 8 ++ }, ++ [CRYPTO_STAT] = { ++ .h = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .id = CRYPTO_STAT, ++ .pops = NULL, ++ .label = "crypto-sd", ++ .desc = "secret key size and id", ++ .linkage = {NULL, NULL} ++ }, ++ .present = present_crypto_sd, ++ .absent = NULL, ++ .save_len = save_len_crypto_sd, ++ .save = save_crypto_sd, ++ .alignment = 8 ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/static_stat.h linux-5.10.2/fs/reiser4/plugin/item/static_stat.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/static_stat.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/static_stat.h 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,224 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* This describes the static_stat item, used to hold all information needed by the stat() syscall. ++ ++In the case where each file has not less than the fields needed by the ++stat() syscall, it is more compact to store those fields in this ++struct. ++ ++If this item does not exist, then all stats are dynamically resolved. ++At the moment, we either resolve all stats dynamically or all of them ++statically. If you think this is not fully optimal, and the rest of ++reiser4 is working, then fix it...:-) ++ ++*/ ++ ++#if !defined( __FS_REISER4_PLUGIN_ITEM_STATIC_STAT_H__ ) ++#define __FS_REISER4_PLUGIN_ITEM_STATIC_STAT_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++ ++#include /* for struct inode */ ++ ++/* Stat data layout: goals and implementation. ++ ++ We want to be able to have lightweight files which have complete flexibility in what semantic metadata is attached to ++ them, including not having semantic metadata attached to them. ++ ++ There is one problem with doing that, which is that if in fact you have exactly the same metadata for most files you ++ want to store, then it takes more space to store that metadata in a dynamically sized structure than in a statically ++ sized structure because the statically sized structure knows without recording it what the names and lengths of the ++ attributes are. ++ ++ This leads to a natural compromise, which is to special case those files which have simply the standard unix file ++ attributes, and only employ the full dynamic stat data mechanism for those files that differ from the standard unix ++ file in their use of file attributes. ++ ++ Yet this compromise deserves to be compromised a little. ++ ++ We accommodate the case where you have no more than the standard unix file attributes by using an "extension ++ bitmask": each bit in it indicates presence or absence of or particular stat data extension (see sd_ext_bits enum). ++ ++ If the first bit of the extension bitmask bit is 0, we have light-weight file whose attributes are either inherited ++ from parent directory (as uid, gid) or initialised to some sane values. ++ ++ To capitalize on existing code infrastructure, extensions are ++ implemented as plugins of type REISER4_SD_EXT_PLUGIN_TYPE. ++ Each stat-data extension plugin implements four methods: ++ ++ ->present() called by sd_load() when this extension is found in stat-data ++ ->absent() called by sd_load() when this extension is not found in stat-data ++ ->save_len() called by sd_len() to calculate total length of stat-data ++ ->save() called by sd_save() to store extension data into stat-data ++ ++ Implementation is in fs/reiser4/plugin/item/static_stat.c ++*/ ++ ++/* stat-data extension. Please order this by presumed frequency of use */ ++typedef enum { ++ /* support for light-weight files */ ++ LIGHT_WEIGHT_STAT, ++ /* data required to implement unix stat(2) call. Layout is in ++ reiser4_unix_stat. If this is not present, file is light-weight */ ++ UNIX_STAT, ++ /* this contains additional set of 32bit [anc]time fields to implement ++ nanosecond resolution. Layout is in reiser4_large_times_stat. Usage ++ if this extension is governed by 32bittimes mount option. */ ++ LARGE_TIMES_STAT, ++ /* stat data has link name included */ ++ SYMLINK_STAT, ++ /* on-disk slots of non-standard plugins for main plugin table ++ (@reiser4_inode->pset), that is, plugins that cannot be deduced ++ from file mode bits), for example, aggregation, interpolation etc. */ ++ PLUGIN_STAT, ++ /* this extension contains persistent inode flags. These flags are ++ single bits: immutable, append, only, etc. Layout is in ++ reiser4_flags_stat. */ ++ FLAGS_STAT, ++ /* this extension contains capabilities sets, associated with this ++ file. Layout is in reiser4_capabilities_stat */ ++ CAPABILITIES_STAT, ++ /* this extension contains size and public id of the secret key. ++ Layout is in reiser4_crypto_stat */ ++ CRYPTO_STAT, ++ /* on-disk slots of non-default plugins for inheritance, which ++ are extracted to special plugin table (@reiser4_inode->hset). ++ By default, children of the object will inherit plugins from ++ its main plugin table (pset). */ ++ HEIR_STAT, ++ LAST_SD_EXTENSION, ++ /* ++ * init_inode_static_sd() iterates over extension mask until all ++ * non-zero bits are processed. This means, that neither ->present(), ++ * nor ->absent() methods will be called for stat-data extensions that ++ * go after last present extension. But some basic extensions, we want ++ * either ->absent() or ->present() method to be called, because these ++ * extensions set up something in inode even when they are not ++ * present. This is what LAST_IMPORTANT_SD_EXTENSION is for: for all ++ * extensions before and including LAST_IMPORTANT_SD_EXTENSION either ++ * ->present(), or ->absent() method will be called, independently of ++ * what other extensions are present. ++ */ ++ LAST_IMPORTANT_SD_EXTENSION = PLUGIN_STAT ++} sd_ext_bits; ++ ++/* minimal stat-data. This allows to support light-weight files. */ ++typedef struct reiser4_stat_data_base { ++ /* 0 */ __le16 extmask; ++ /* 2 */ ++} PACKED reiser4_stat_data_base; ++ ++typedef struct reiser4_light_weight_stat { ++ /* 0 */ __le16 mode; ++ /* 2 */ __le32 nlink; ++ /* 6 */ __le64 size; ++ /* size in bytes */ ++ /* 14 */ ++} PACKED reiser4_light_weight_stat; ++ ++typedef struct reiser4_unix_stat { ++ /* owner id */ ++ /* 0 */ __le32 uid; ++ /* group id */ ++ /* 4 */ __le32 gid; ++ /* access time */ ++ /* 8 */ __le32 atime; ++ /* modification time */ ++ /* 12 */ __le32 mtime; ++ /* change time */ ++ /* 16 */ __le32 ctime; ++ union { ++ /* minor:major for device files */ ++ /* 20 */ __le64 rdev; ++ /* bytes used by file */ ++ /* 20 */ __le64 bytes; ++ } u; ++ /* 28 */ ++} PACKED reiser4_unix_stat; ++ ++/* symlink stored as part of inode */ ++typedef struct reiser4_symlink_stat { ++ char body[0]; ++} PACKED reiser4_symlink_stat; ++ ++typedef struct reiser4_plugin_slot { ++ /* 0 */ __le16 pset_memb; ++ /* 2 */ __le16 id; ++ /* 4 *//* here plugin stores its persistent state */ ++} PACKED reiser4_plugin_slot; ++ ++/* stat-data extension for files with non-standard plugin. */ ++typedef struct reiser4_plugin_stat { ++ /* number of additional plugins, associated with this object */ ++ /* 0 */ __le16 plugins_no; ++ /* 2 */ reiser4_plugin_slot slot[0]; ++ /* 2 */ ++} PACKED reiser4_plugin_stat; ++ ++/* stat-data extension for inode flags. Currently it is just fixed-width 32 ++ * bit mask. If need arise, this can be replaced with variable width ++ * bitmask. */ ++typedef struct reiser4_flags_stat { ++ /* 0 */ __le32 flags; ++ /* 4 */ ++} PACKED reiser4_flags_stat; ++ ++typedef struct reiser4_capabilities_stat { ++ /* 0 */ __le32 effective; ++ /* 8 */ __le32 permitted; ++ /* 16 */ ++} PACKED reiser4_capabilities_stat; ++ ++typedef struct reiser4_cluster_stat { ++/* this defines cluster size (an attribute of cryptcompress objects) as PAGE_SIZE << cluster shift */ ++ /* 0 */ d8 cluster_shift; ++ /* 1 */ ++} PACKED reiser4_cluster_stat; ++ ++typedef struct reiser4_crypto_stat { ++ /* secret key size, bits */ ++ /* 0 */ d16 keysize; ++ /* secret key id */ ++ /* 2 */ d8 keyid[0]; ++ /* 2 */ ++} PACKED reiser4_crypto_stat; ++ ++typedef struct reiser4_large_times_stat { ++ /* access time */ ++ /* 0 */ d32 atime; ++ /* modification time */ ++ /* 4 */ d32 mtime; ++ /* change time */ ++ /* 8 */ d32 ctime; ++ /* 12 */ ++} PACKED reiser4_large_times_stat; ++ ++/* this structure is filled by sd_item_stat */ ++typedef struct sd_stat { ++ int dirs; ++ int files; ++ int others; ++} sd_stat; ++ ++/* plugin->item.common.* */ ++extern void print_sd(const char *prefix, coord_t * coord); ++extern void item_stat_static_sd(const coord_t * coord, void *vp); ++ ++/* plugin->item.s.sd.* */ ++extern int init_inode_static_sd(struct inode *inode, char *sd, int len); ++extern int save_len_static_sd(struct inode *inode); ++extern int save_static_sd(struct inode *inode, char **area); ++ ++/* __FS_REISER4_PLUGIN_ITEM_STATIC_STAT_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/tail.c linux-5.10.2/fs/reiser4/plugin/item/tail.c +--- linux-5.10.2.orig/fs/reiser4/plugin/item/tail.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/tail.c 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,797 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "item.h" ++#include "../../inode.h" ++#include "../../page_cache.h" ++#include "../../carry.h" ++#include "../../vfs_ops.h" ++ ++#include ++#include ++#include ++ ++/* plugin->u.item.b.max_key_inside */ ++reiser4_key *max_key_inside_tail(const coord_t *coord, reiser4_key *key) ++{ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, get_key_offset(reiser4_max_key())); ++ return key; ++} ++ ++/* plugin->u.item.b.can_contain_key */ ++int can_contain_key_tail(const coord_t *coord, const reiser4_key *key, ++ const reiser4_item_data *data) ++{ ++ reiser4_key item_key; ++ ++ if (item_plugin_by_coord(coord) != data->iplug) ++ return 0; ++ ++ item_key_by_coord(coord, &item_key); ++ if (get_key_locality(key) != get_key_locality(&item_key) || ++ get_key_objectid(key) != get_key_objectid(&item_key)) ++ return 0; ++ ++ return 1; ++} ++ ++/* plugin->u.item.b.mergeable ++ first item is of tail type */ ++/* Audited by: green(2002.06.14) */ ++int mergeable_tail(const coord_t *p1, const coord_t *p2) ++{ ++ reiser4_key key1, key2; ++ ++ assert("vs-535", plugin_of_group(item_plugin_by_coord(p1), ++ FILE_BODY_ITEM_TYPE)); ++ assert("vs-365", item_id_by_coord(p1) == FORMATTING_ID); ++ ++ if (item_id_by_coord(p2) != FORMATTING_ID) { ++ /* second item is of another type */ ++ return 0; ++ } ++ ++ item_key_by_coord(p1, &key1); ++ item_key_by_coord(p2, &key2); ++ if (get_key_locality(&key1) != get_key_locality(&key2) || ++ get_key_objectid(&key1) != get_key_objectid(&key2) ++ || get_key_type(&key1) != get_key_type(&key2)) { ++ /* items of different objects */ ++ return 0; ++ } ++ if (get_key_offset(&key1) + nr_units_tail(p1) != get_key_offset(&key2)) { ++ /* not adjacent items */ ++ return 0; ++ } ++ return 1; ++} ++ ++/* plugin->u.item.b.print ++ plugin->u.item.b.check */ ++ ++/* plugin->u.item.b.nr_units */ ++pos_in_node_t nr_units_tail(const coord_t * coord) ++{ ++ return item_length_by_coord(coord); ++} ++ ++/* plugin->u.item.b.lookup */ ++lookup_result ++lookup_tail(const reiser4_key * key, lookup_bias bias, coord_t * coord) ++{ ++ reiser4_key item_key; ++ __u64 lookuped, offset; ++ unsigned nr_units; ++ ++ item_key_by_coord(coord, &item_key); ++ offset = get_key_offset(item_key_by_coord(coord, &item_key)); ++ nr_units = nr_units_tail(coord); ++ ++ /* key we are looking for must be greater than key of item @coord */ ++ assert("vs-416", keygt(key, &item_key)); ++ ++ /* offset we are looking for */ ++ lookuped = get_key_offset(key); ++ ++ if (lookuped >= offset && lookuped < offset + nr_units) { ++ /* byte we are looking for is in this item */ ++ coord->unit_pos = lookuped - offset; ++ coord->between = AT_UNIT; ++ return CBK_COORD_FOUND; ++ } ++ ++ /* set coord after last unit */ ++ coord->unit_pos = nr_units - 1; ++ coord->between = AFTER_UNIT; ++ return bias == ++ FIND_MAX_NOT_MORE_THAN ? CBK_COORD_FOUND : CBK_COORD_NOTFOUND; ++} ++ ++/* plugin->u.item.b.paste */ ++int ++paste_tail(coord_t *coord, reiser4_item_data *data, ++ carry_plugin_info *info UNUSED_ARG) ++{ ++ unsigned old_item_length; ++ char *item; ++ ++ /* length the item had before resizing has been performed */ ++ old_item_length = item_length_by_coord(coord) - data->length; ++ ++ /* tail items never get pasted in the middle */ ++ assert("vs-363", ++ (coord->unit_pos == 0 && coord->between == BEFORE_UNIT) || ++ (coord->unit_pos == old_item_length - 1 && ++ coord->between == AFTER_UNIT) || ++ (coord->unit_pos == 0 && old_item_length == 0 ++ && coord->between == AT_UNIT)); ++ ++ item = item_body_by_coord(coord); ++ if (coord->unit_pos == 0) ++ /* make space for pasted data when pasting at the beginning of ++ the item */ ++ memmove(item + data->length, item, old_item_length); ++ ++ if (coord->between == AFTER_UNIT) ++ coord->unit_pos++; ++ ++ if (data->data) { ++ assert("vs-554", data->user == 0 || data->user == 1); ++ if (data->user) { ++ assert("nikita-3035", reiser4_schedulable()); ++ /* copy from user space */ ++ if (__copy_from_user(item + coord->unit_pos, ++ (const char __user *)data->data, ++ (unsigned)data->length)) ++ return RETERR(-EFAULT); ++ } else ++ /* copy from kernel space */ ++ memcpy(item + coord->unit_pos, data->data, ++ (unsigned)data->length); ++ } else { ++ memset(item + coord->unit_pos, 0, (unsigned)data->length); ++ } ++ return 0; ++} ++ ++/* plugin->u.item.b.fast_paste */ ++ ++/* plugin->u.item.b.can_shift ++ number of units is returned via return value, number of bytes via @size. For ++ tail items they coincide */ ++int ++can_shift_tail(unsigned free_space, coord_t * source UNUSED_ARG, ++ znode * target UNUSED_ARG, shift_direction direction UNUSED_ARG, ++ unsigned *size, unsigned want) ++{ ++ /* make sure that that we do not want to shift more than we have */ ++ assert("vs-364", want > 0 ++ && want <= (unsigned)item_length_by_coord(source)); ++ ++ *size = min(want, free_space); ++ return *size; ++} ++ ++/* plugin->u.item.b.copy_units */ ++void ++copy_units_tail(coord_t * target, coord_t * source, ++ unsigned from, unsigned count, ++ shift_direction where_is_free_space, ++ unsigned free_space UNUSED_ARG) ++{ ++ /* make sure that item @target is expanded already */ ++ assert("vs-366", (unsigned)item_length_by_coord(target) >= count); ++ assert("vs-370", free_space >= count); ++ ++ if (where_is_free_space == SHIFT_LEFT) { ++ /* append item @target with @count first bytes of @source */ ++ assert("vs-365", from == 0); ++ ++ memcpy((char *)item_body_by_coord(target) + ++ item_length_by_coord(target) - count, ++ (char *)item_body_by_coord(source), count); ++ } else { ++ /* target item is moved to right already */ ++ reiser4_key key; ++ ++ assert("vs-367", ++ (unsigned)item_length_by_coord(source) == from + count); ++ ++ memcpy((char *)item_body_by_coord(target), ++ (char *)item_body_by_coord(source) + from, count); ++ ++ /* new units are inserted before first unit in an item, ++ therefore, we have to update item key */ ++ item_key_by_coord(source, &key); ++ set_key_offset(&key, get_key_offset(&key) + from); ++ ++ node_plugin_by_node(target->node)->update_item_key(target, &key, ++ NULL /*info */); ++ } ++} ++ ++/* plugin->u.item.b.create_hook */ ++ ++/* item_plugin->b.kill_hook ++ this is called when @count units starting from @from-th one are going to be removed ++ */ ++int ++kill_hook_tail(const coord_t * coord, pos_in_node_t from, ++ pos_in_node_t count, struct carry_kill_data *kdata) ++{ ++ reiser4_key key; ++ loff_t start, end; ++ ++ assert("vs-1577", kdata); ++ assert("vs-1579", kdata->inode); ++ ++ item_key_by_coord(coord, &key); ++ start = get_key_offset(&key) + from; ++ end = start + count; ++ fake_kill_hook_tail(kdata->inode, start, end, kdata->params.truncate); ++ return 0; ++} ++ ++/* plugin->u.item.b.shift_hook */ ++ ++/* helper for kill_units_tail and cut_units_tail */ ++static int ++do_cut_or_kill(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ reiser4_key * smallest_removed, reiser4_key * new_first) ++{ ++ pos_in_node_t count; ++ ++ /* this method is only called to remove part of item */ ++ assert("vs-374", (to - from + 1) < item_length_by_coord(coord)); ++ /* tails items are never cut from the middle of an item */ ++ assert("vs-396", ergo(from != 0, to == coord_last_unit_pos(coord))); ++ assert("vs-1558", ergo(from == 0, to < coord_last_unit_pos(coord))); ++ ++ count = to - from + 1; ++ ++ if (smallest_removed) { ++ /* store smallest key removed */ ++ item_key_by_coord(coord, smallest_removed); ++ set_key_offset(smallest_removed, ++ get_key_offset(smallest_removed) + from); ++ } ++ if (new_first) { ++ /* head of item is cut */ ++ assert("vs-1529", from == 0); ++ ++ item_key_by_coord(coord, new_first); ++ set_key_offset(new_first, ++ get_key_offset(new_first) + from + count); ++ } ++ ++ if (REISER4_DEBUG) ++ memset((char *)item_body_by_coord(coord) + from, 0, count); ++ return count; ++} ++ ++/* plugin->u.item.b.cut_units */ ++int ++cut_units_tail(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *cdata UNUSED_ARG, ++ reiser4_key * smallest_removed, reiser4_key * new_first) ++{ ++ return do_cut_or_kill(coord, from, to, smallest_removed, new_first); ++} ++ ++/* plugin->u.item.b.kill_units */ ++int ++kill_units_tail(coord_t * coord, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *kdata, reiser4_key * smallest_removed, ++ reiser4_key * new_first) ++{ ++ kill_hook_tail(coord, from, to - from + 1, kdata); ++ return do_cut_or_kill(coord, from, to, smallest_removed, new_first); ++} ++ ++/* plugin->u.item.b.unit_key */ ++reiser4_key *unit_key_tail(const coord_t * coord, reiser4_key * key) ++{ ++ assert("vs-375", coord_is_existing_unit(coord)); ++ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, (get_key_offset(key) + coord->unit_pos)); ++ ++ return key; ++} ++ ++/* plugin->u.item.b.estimate ++ plugin->u.item.b.item_data_by_flow */ ++ ++/* tail redpage function. It is called from readpage_tail(). */ ++static int do_readpage_tail(uf_coord_t *uf_coord, struct page *page) ++{ ++ tap_t tap; ++ int result; ++ coord_t coord; ++ lock_handle lh; ++ int count, mapped; ++ struct inode *inode; ++ char *pagedata; ++ ++ /* saving passed coord in order to do not move it by tap. */ ++ init_lh(&lh); ++ copy_lh(&lh, uf_coord->lh); ++ inode = page->mapping->host; ++ coord_dup(&coord, &uf_coord->coord); ++ ++ reiser4_tap_init(&tap, &coord, &lh, ZNODE_READ_LOCK); ++ ++ if ((result = reiser4_tap_load(&tap))) ++ goto out_tap_done; ++ ++ /* lookup until page is filled up. */ ++ for (mapped = 0; mapped < PAGE_SIZE; ) { ++ /* number of bytes to be copied to page */ ++ count = item_length_by_coord(&coord) - coord.unit_pos; ++ if (count > PAGE_SIZE - mapped) ++ count = PAGE_SIZE - mapped; ++ ++ /* attach @page to address space and get data address */ ++ pagedata = kmap_atomic(page); ++ ++ /* copy tail item to page */ ++ memcpy(pagedata + mapped, ++ ((char *)item_body_by_coord(&coord) + coord.unit_pos), ++ count); ++ mapped += count; ++ ++ flush_dcache_page(page); ++ ++ /* dettach page from address space */ ++ kunmap_atomic(pagedata); ++ ++ /* Getting next tail item. */ ++ if (mapped < PAGE_SIZE) { ++ /* ++ * unlock page in order to avoid keep it locked ++ * during tree lookup, which takes long term locks ++ */ ++ unlock_page(page); ++ ++ /* getting right neighbour. */ ++ result = go_dir_el(&tap, RIGHT_SIDE, 0); ++ ++ /* lock page back */ ++ lock_page(page); ++ if (PageUptodate(page)) { ++ /* ++ * another thread read the page, we have ++ * nothing to do ++ */ ++ result = 0; ++ goto out_unlock_page; ++ } ++ ++ if (result) { ++ if (result == -E_NO_NEIGHBOR) { ++ /* ++ * rigth neighbor is not a formatted ++ * node ++ */ ++ result = 0; ++ goto done; ++ } else { ++ goto out_tap_relse; ++ } ++ } else { ++ if (!inode_file_plugin(inode)-> ++ owns_item(inode, &coord)) { ++ /* item of another file is found */ ++ result = 0; ++ goto done; ++ } ++ } ++ } ++ } ++ ++ done: ++ if (mapped != PAGE_SIZE) ++ zero_user_segment(page, mapped, PAGE_SIZE); ++ SetPageUptodate(page); ++ out_unlock_page: ++ unlock_page(page); ++ out_tap_relse: ++ reiser4_tap_relse(&tap); ++ out_tap_done: ++ reiser4_tap_done(&tap); ++ return result; ++} ++ ++/** ++ * reiser4_read_dispatch->read_unix_file->page_cache_readahead-> ++ * ->reiser4_readpage_dispatch->readpage_unix_file->readpage_tail_unix_file ++ * or ++ * filemap_fault->reiser4_readpage_dispatch->readpage_unix_file-> ++ * ->readpage_tail_unix_file ++ * ++ * At the beginning: coord->node is read locked, zloaded, page is locked, ++ * coord is set to existing unit inside of tail item. ++ */ ++int readpage_tail_unix_file(void *vp, struct page *page) ++{ ++ uf_coord_t *uf_coord = vp; ++ ON_DEBUG(coord_t * coord = &uf_coord->coord); ++ ON_DEBUG(reiser4_key key); ++ ++ assert("umka-2515", PageLocked(page)); ++ assert("umka-2516", !PageUptodate(page)); ++ assert("umka-2517", !jprivate(page) && !PagePrivate(page)); ++ assert("umka-2518", page->mapping && page->mapping->host); ++ ++ assert("umka-2519", znode_is_loaded(coord->node)); ++ assert("umka-2520", item_is_tail(coord)); ++ assert("umka-2521", coord_is_existing_unit(coord)); ++ assert("umka-2522", znode_is_rlocked(coord->node)); ++ assert("umka-2523", ++ page->mapping->host->i_ino == ++ get_key_objectid(item_key_by_coord(coord, &key))); ++ ++ return do_readpage_tail(uf_coord, page); ++} ++ ++/** ++ * overwrite_tail ++ * @flow: ++ * @coord: ++ * ++ * Overwrites tail item or its part by user data. Returns number of bytes ++ * written or error code. ++ */ ++static int overwrite_tail(flow_t *flow, coord_t *coord) ++{ ++ unsigned count; ++ ++ assert("vs-570", flow->user == 1); ++ assert("vs-946", flow->data); ++ assert("vs-947", coord_is_existing_unit(coord)); ++ assert("vs-948", znode_is_write_locked(coord->node)); ++ assert("nikita-3036", reiser4_schedulable()); ++ ++ count = item_length_by_coord(coord) - coord->unit_pos; ++ if (count > flow->length) ++ count = flow->length; ++ ++ if (__copy_from_user((char *)item_body_by_coord(coord) + coord->unit_pos, ++ (const char __user *)flow->data, count)) ++ return RETERR(-EFAULT); ++ ++ znode_make_dirty(coord->node); ++ return count; ++} ++ ++/** ++ * insert_first_tail ++ * @inode: ++ * @flow: ++ * @coord: ++ * @lh: ++ * ++ * Returns number of bytes written or error code. ++ */ ++static ssize_t insert_first_tail(struct inode *inode, flow_t *flow, ++ coord_t *coord, lock_handle *lh) ++{ ++ int result; ++ loff_t to_write; ++ struct unix_file_info *uf_info; ++ ++ if (get_key_offset(&flow->key) != 0) { ++ /* ++ * file is empty and we have to write not to the beginning of ++ * file. Create a hole at the beginning of file. On success ++ * insert_flow returns 0 as number of written bytes which is ++ * what we have to return on padding a file with holes ++ */ ++ flow->data = NULL; ++ flow->length = get_key_offset(&flow->key); ++ set_key_offset(&flow->key, 0); ++ /* ++ * holes in files built of tails are stored just like if there ++ * were real data which are all zeros. ++ */ ++ inode_add_bytes(inode, flow->length); ++ result = reiser4_insert_flow(coord, lh, flow); ++ if (flow->length) ++ inode_sub_bytes(inode, flow->length); ++ ++ uf_info = unix_file_inode_data(inode); ++ ++ /* ++ * first item insertion is only possible when writing to empty ++ * file or performing tail conversion ++ */ ++ assert("", (uf_info->container == UF_CONTAINER_EMPTY || ++ (reiser4_inode_get_flag(inode, ++ REISER4_PART_MIXED) && ++ reiser4_inode_get_flag(inode, ++ REISER4_PART_IN_CONV)))); ++ /* if file was empty - update its state */ ++ if (result == 0 && uf_info->container == UF_CONTAINER_EMPTY) ++ uf_info->container = UF_CONTAINER_TAILS; ++ return result; ++ } ++ ++ inode_add_bytes(inode, flow->length); ++ ++ to_write = flow->length; ++ result = reiser4_insert_flow(coord, lh, flow); ++ if (flow->length) ++ inode_sub_bytes(inode, flow->length); ++ return (to_write - flow->length) ? (to_write - flow->length) : result; ++} ++ ++/** ++ * append_tail ++ * @inode: ++ * @flow: ++ * @coord: ++ * @lh: ++ * ++ * Returns number of bytes written or error code. ++ */ ++static ssize_t append_tail(struct inode *inode, ++ flow_t *flow, coord_t *coord, lock_handle *lh) ++{ ++ int result; ++ reiser4_key akey; ++ loff_t to_write; ++ ++ if (!keyeq(&flow->key, append_key_tail(coord, &akey))) { ++ flow->data = NULL; ++ flow->length = get_key_offset(&flow->key) - get_key_offset(&akey); ++ set_key_offset(&flow->key, get_key_offset(&akey)); ++ /* ++ * holes in files built of tails are stored just like if there ++ * were real data which are all zeros. ++ */ ++ inode_add_bytes(inode, flow->length); ++ result = reiser4_insert_flow(coord, lh, flow); ++ if (flow->length) ++ inode_sub_bytes(inode, flow->length); ++ return result; ++ } ++ ++ inode_add_bytes(inode, flow->length); ++ ++ to_write = flow->length; ++ result = reiser4_insert_flow(coord, lh, flow); ++ if (flow->length) ++ inode_sub_bytes(inode, flow->length); ++ return (to_write - flow->length) ? (to_write - flow->length) : result; ++} ++ ++/** ++ * write_tail_reserve_space - reserve space for tail write operation ++ * @inode: ++ * ++ * Estimates and reserves space which may be required for writing one flow to a ++ * file ++ */ ++static int write_tail_reserve_space(struct inode *inode) ++{ ++ __u64 count; ++ reiser4_tree *tree; ++ ++ /* ++ * to write one flow to a file by tails we have to reserve disk space for: ++ ++ * 1. find_file_item may have to insert empty node to the tree (empty ++ * leaf node between two extent items). This requires 1 block and ++ * number of blocks which are necessary to perform insertion of an ++ * internal item into twig level. ++ * ++ * 2. flow insertion ++ * ++ * 3. stat data update ++ */ ++ tree = meta_subvol_tree(); ++ count = estimate_one_insert_item(tree) + ++ estimate_insert_flow(tree->height) + ++ estimate_one_insert_item(tree); ++ grab_space_enable(); ++ return reiser4_grab_space(count, 0 , get_meta_subvol()); ++} ++ ++#define PAGE_PER_FLOW 4 ++ ++static loff_t faultin_user_pages(const char __user *buf, size_t count) ++{ ++ loff_t faulted; ++ int to_fault; ++ ++ if (count > PAGE_PER_FLOW * PAGE_SIZE) ++ count = PAGE_PER_FLOW * PAGE_SIZE; ++ faulted = 0; ++ while (count > 0) { ++ to_fault = PAGE_SIZE; ++ if (count < to_fault) ++ to_fault = count; ++ fault_in_pages_readable(buf + faulted, to_fault); ++ count -= to_fault; ++ faulted += to_fault; ++ } ++ return faulted; ++} ++ ++ssize_t write_tail_noreserve(struct file *file, ++ struct inode * inode, ++ const char __user *buf, ++ size_t count, loff_t *pos) ++{ ++ struct hint hint; ++ int result; ++ flow_t flow; ++ coord_t *coord; ++ lock_handle *lh; ++ znode *loaded; ++ ++ assert("edward-1548", inode != NULL); ++ ++ result = load_file_hint(file, &hint); ++ BUG_ON(result != 0); ++ ++ flow.length = faultin_user_pages(buf, count); ++ flow.user = 1; ++ memcpy(&flow.data, &buf, sizeof(buf)); ++ flow.op = WRITE_OP; ++ inode_file_plugin(inode)->build_body_key(inode, *pos, &flow.key); ++ result = find_file_item(&hint, &flow.key, ZNODE_WRITE_LOCK, inode); ++ if (IS_CBKERR(result)) ++ return result; ++ ++ coord = &hint.ext_coord.coord; ++ lh = hint.ext_coord.lh; ++ ++ result = zload(coord->node); ++ BUG_ON(result != 0); ++ loaded = coord->node; ++ ++ if (coord->between == AFTER_UNIT) { ++ /* append with data or hole */ ++ result = append_tail(inode, &flow, coord, lh); ++ } else if (coord->between == AT_UNIT) { ++ /* overwrite */ ++ result = overwrite_tail(&flow, coord); ++ } else { ++ /* no items of this file yet. insert data or hole */ ++ result = insert_first_tail(inode, &flow, coord, lh); ++ } ++ zrelse(loaded); ++ if (result < 0) { ++ done_lh(lh); ++ return result; ++ } ++ ++ /* seal and unlock znode */ ++ hint.ext_coord.valid = 0; ++ if (hint.ext_coord.valid) ++ reiser4_set_hint(&hint, &flow.key, ZNODE_WRITE_LOCK); ++ else ++ reiser4_unset_hint(&hint); ++ ++ save_file_hint(file, &hint); ++ return result; ++} ++ ++/** ++ * @file: file to write to ++ * @buf: address of user-space buffer ++ * @count: number of bytes to write ++ * @pos: position in file to write to ++ * ++ * Returns number of written bytes or error code. ++ */ ++ssize_t write_tail_unix_file(struct file *file, struct inode * inode, ++ const char __user *buf, size_t count, loff_t *pos) ++{ ++ if (write_tail_reserve_space(inode)) ++ return RETERR(-ENOSPC); ++ return write_tail_noreserve(file, inode, buf, count, pos); ++} ++ ++#if REISER4_DEBUG ++static int coord_matches_key_tail(struct inode *inode, ++ const coord_t *coord, const reiser4_key *key) ++{ ++ reiser4_key item_key; ++ ++ assert("vs-1356", coord_is_existing_unit(coord)); ++ assert("vs-1354", keylt(key, append_key_tail(coord, &item_key))); ++ assert("vs-1355", keyge(key, item_key_by_coord(coord, &item_key))); ++ return get_key_offset(key) == ++ get_key_offset(&item_key) + coord->unit_pos; ++} ++#endif ++ ++int read_tail_unix_file(struct file *file, flow_t *f, hint_t *hint) ++{ ++ unsigned count; ++ int item_length; ++ coord_t *coord; ++ uf_coord_t *uf_coord; ++ ++ uf_coord = &hint->ext_coord; ++ coord = &uf_coord->coord; ++ ++ assert("vs-571", f->user == 1); ++ assert("vs-571", f->data); ++ assert("vs-967", coord && coord->node); ++ assert("vs-1117", znode_is_rlocked(coord->node)); ++ assert("vs-1118", znode_is_loaded(coord->node)); ++ ++ assert("nikita-3037", reiser4_schedulable()); ++ assert("vs-1357", coord_matches_key_tail(file_inode(file), ++ coord, &f->key)); ++ /* calculate number of bytes to read off the item */ ++ item_length = item_length_by_coord(coord); ++ count = item_length_by_coord(coord) - coord->unit_pos; ++ if (count > f->length) ++ count = f->length; ++ ++ /* user page has to be brought in so that major page fault does not ++ * occur here when longtem lock is held */ ++ if (__copy_to_user((char __user *)f->data, ++ ((char *)item_body_by_coord(coord) + coord->unit_pos), ++ count)) ++ return RETERR(-EFAULT); ++ ++ /* probably mark_page_accessed() should only be called if ++ * coord->unit_pos is zero. */ ++ mark_page_accessed(znode_page(coord->node)); ++ move_flow_forward(f, count); ++ ++ coord->unit_pos += count; ++ if (item_length == coord->unit_pos) { ++ coord->unit_pos--; ++ coord->between = AFTER_UNIT; ++ } ++ reiser4_set_hint(hint, &f->key, ZNODE_READ_LOCK); ++ return 0; ++} ++ ++reiser4_key *append_key_tail(const coord_t *coord, reiser4_key *key) ++{ ++ item_key_by_coord(coord, key); ++ set_key_offset(key, get_key_offset(key) + item_length_by_coord(coord)); ++ return key; ++} ++ ++/* plugin->u.item.s.file.init_coord_extension */ ++void init_coord_extension_tail(uf_coord_t * uf_coord, loff_t lookuped) ++{ ++ uf_coord->valid = 1; ++} ++ ++/* ++ plugin->u.item.s.file.get_block ++*/ ++int ++get_block_address_tail(const coord_t * coord, sector_t lblock, sector_t * block) ++{ ++ assert("nikita-3252", znode_get_level(coord->node) == LEAF_LEVEL); ++ ++ if (reiser4_blocknr_is_fake(znode_get_block(coord->node))) ++ /* if node has'nt obtainet its block number yet, return 0. ++ * Lets avoid upsetting users with some cosmic numbers beyond ++ * the device capacity.*/ ++ *block = 0; ++ else ++ *block = *znode_get_block(coord->node); ++ return 0; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/item/tail.h linux-5.10.2/fs/reiser4/plugin/item/tail.h +--- linux-5.10.2.orig/fs/reiser4/plugin/item/tail.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/item/tail.h 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,59 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined( __REISER4_TAIL_H__ ) ++#define __REISER4_TAIL_H__ ++ ++struct tail_coord_extension { ++ int not_used; ++}; ++ ++struct cut_list; ++ ++/* plugin->u.item.b.* */ ++reiser4_key *max_key_inside_tail(const coord_t *, reiser4_key *); ++int can_contain_key_tail(const coord_t * coord, const reiser4_key * key, ++ const reiser4_item_data *); ++int mergeable_tail(const coord_t * p1, const coord_t * p2); ++pos_in_node_t nr_units_tail(const coord_t *); ++lookup_result lookup_tail(const reiser4_key *, lookup_bias, coord_t *); ++int paste_tail(coord_t *, reiser4_item_data *, carry_plugin_info *); ++int can_shift_tail(unsigned free_space, coord_t * source, ++ znode * target, shift_direction, unsigned *size, ++ unsigned want); ++void copy_units_tail(coord_t * target, coord_t * source, unsigned from, ++ unsigned count, shift_direction, unsigned free_space); ++int kill_hook_tail(const coord_t *, pos_in_node_t from, pos_in_node_t count, ++ struct carry_kill_data *); ++int cut_units_tail(coord_t *, pos_in_node_t from, pos_in_node_t to, ++ struct carry_cut_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++int kill_units_tail(coord_t *, pos_in_node_t from, pos_in_node_t to, ++ struct carry_kill_data *, reiser4_key * smallest_removed, ++ reiser4_key * new_first); ++reiser4_key *unit_key_tail(const coord_t *, reiser4_key *); ++ ++/* plugin->u.item.s.* */ ++ssize_t write_tail_noreserve(struct file *file, struct inode * inode, ++ const char __user *buf, size_t count, ++ loff_t *pos); ++ssize_t write_tail_unix_file(struct file *file, struct inode * inode, ++ const char __user *buf, size_t count, loff_t *pos); ++int read_tail_unix_file(struct file *, flow_t *, hint_t *); ++int readpage_tail_unix_file(void *vp, struct page *page); ++reiser4_key *append_key_tail(const coord_t *, reiser4_key *); ++void init_coord_extension_tail(uf_coord_t *, loff_t offset); ++int get_block_address_tail(const coord_t *, sector_t, sector_t *); ++ ++/* __REISER4_TAIL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/Makefile linux-5.10.2/fs/reiser4/plugin/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/Makefile 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,28 @@ ++obj-$(CONFIG_REISER4_FS) += plugins.o ++ ++plugins-objs := \ ++ plugin.o \ ++ plugin_set.o \ ++ object.o \ ++ inode_ops.o \ ++ inode_ops_rename.o \ ++ file_ops.o \ ++ file_ops_readdir.o \ ++ file_plugin_common.o \ ++ dir_plugin_common.o \ ++ digest.o \ ++ hash.o \ ++ fibration.o \ ++ tail_policy.o \ ++ regular.o ++ ++obj-$(CONFIG_REISER4_FS) += item/ ++obj-$(CONFIG_REISER4_FS) += file/ ++obj-$(CONFIG_REISER4_FS) += dir/ ++obj-$(CONFIG_REISER4_FS) += node/ ++obj-$(CONFIG_REISER4_FS) += compress/ ++obj-$(CONFIG_REISER4_FS) += space/ ++obj-$(CONFIG_REISER4_FS) += disk_format/ ++obj-$(CONFIG_REISER4_FS) += security/ ++obj-$(CONFIG_REISER4_FS) += volume/ ++obj-$(CONFIG_REISER4_FS) += dst/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/Makefile linux-5.10.2/fs/reiser4/plugin/node/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/node/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/Makefile 2020-12-23 16:07:46.129813290 +0100 +@@ -0,0 +1,6 @@ ++obj-$(CONFIG_REISER4_FS) += node_plugins.o ++ ++node_plugins-objs := \ ++ node.o \ ++ node40.o \ ++ node41.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node40.c linux-5.10.2/fs/reiser4/plugin/node/node40.c +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node40.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node40.c 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,3142 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../debug.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "../plugin_header.h" ++#include "../item/item.h" ++#include "node.h" ++#include "node40.h" ++#include "../plugin.h" ++#include "../../jnode.h" ++#include "../../znode.h" ++#include "../../pool.h" ++#include "../../carry.h" ++#include "../../tap.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../../reiser4.h" ++ ++#include ++#include ++#include ++ ++/* leaf 40 format: ++ ++ [node header | item 0, item 1, .., item N-1 | free space | item_head N-1, .. item_head 1, item head 0 ] ++ plugin_id (16) key ++ free_space (16) pluginid (16) ++ free_space_start (16) offset (16) ++ level (8) ++ num_items (16) ++ magic (32) ++ flush_time (32) ++*/ ++/* NIKITA-FIXME-HANS: I told you guys not less than 10 times to not call it r4fs. Change to "ReIs". */ ++/* magic number that is stored in ->magic field of node header */ ++static const __u32 REISER4_NODE40_MAGIC = 0x52344653; /* (*(__u32 *)"R4FS"); */ ++ ++static int prepare_for_update(znode * left, znode * right, ++ carry_plugin_info * info); ++ ++/* header of node of reiser40 format is at the beginning of node */ ++static inline node40_header *node40_node_header(const znode * node /* node to ++ * query */ ) ++{ ++ assert("nikita-567", node != NULL); ++ assert("nikita-568", znode_page(node) != NULL); ++ assert("nikita-569", zdata(node) != NULL); ++ return (node40_header *) zdata(node); ++} ++ ++/* functions to get/set fields of node40_header */ ++#define nh40_get_magic(nh) le32_to_cpu(get_unaligned(&(nh)->magic)) ++#define nh40_get_free_space(nh) le16_to_cpu(get_unaligned(&(nh)->free_space)) ++#define nh40_get_free_space_start(nh) le16_to_cpu(get_unaligned(&(nh)->free_space_start)) ++#define nh40_get_level(nh) get_unaligned(&(nh)->level) ++#define nh40_get_num_items(nh) le16_to_cpu(get_unaligned(&(nh)->nr_items)) ++#define nh40_get_flush_id(nh) le64_to_cpu(get_unaligned(&(nh)->flush_id)) ++ ++#define nh40_set_magic(nh, value) put_unaligned(cpu_to_le32(value), &(nh)->magic) ++#define nh40_set_free_space(nh, value) put_unaligned(cpu_to_le16(value), &(nh)->free_space) ++#define nh40_set_free_space_start(nh, value) put_unaligned(cpu_to_le16(value), &(nh)->free_space_start) ++#define nh40_set_level(nh, value) put_unaligned(value, &(nh)->level) ++#define nh40_set_num_items(nh, value) put_unaligned(cpu_to_le16(value), &(nh)->nr_items) ++#define nh40_set_mkfs_id(nh, value) put_unaligned(cpu_to_le32(value), &(nh)->mkfs_id) ++ ++/* plugin field of node header should be read/set by ++ plugin_by_disk_id/save_disk_plugin */ ++ ++/* array of item headers is at the end of node */ ++static inline item_header40 *node40_ih_at(const znode * node, unsigned pos) ++{ ++ return (item_header40 *) (zdata(node) + znode_size(node)) - pos - 1; ++} ++ ++/* ( page_address( node -> pg ) + PAGE_CACHE_SIZE ) - pos - 1 ++ */ ++static inline item_header40 *node40_ih_at_coord(const coord_t * coord) ++{ ++ return (item_header40 *) (zdata(coord->node) + ++ znode_size(coord->node)) - (coord->item_pos) - ++ 1; ++} ++ ++/* functions to get/set fields of item_header40 */ ++#define ih40_get_offset(ih) le16_to_cpu(get_unaligned(&(ih)->offset)) ++ ++#define ih40_set_offset(ih, value) put_unaligned(cpu_to_le16(value), &(ih)->offset) ++ ++/* plugin field of item header should be read/set by ++ plugin_by_disk_id/save_disk_plugin */ ++ ++/* plugin methods */ ++ ++/* plugin->u.node.item_overhead ++ look for description of this method in plugin/node/node.h */ ++size_t ++item_overhead_node40(const znode * node UNUSED_ARG, flow_t * f UNUSED_ARG) ++{ ++ return sizeof(item_header40); ++} ++ ++/* plugin->u.node.free_space ++ look for description of this method in plugin/node/node.h */ ++size_t free_space_node40(znode * node) ++{ ++ assert("nikita-577", node != NULL); ++ assert("nikita-578", znode_is_loaded(node)); ++ assert("nikita-579", zdata(node) != NULL); ++ ++ return nh40_get_free_space(node40_node_header(node)); ++} ++ ++/* private inline version of node40_num_of_items() for use in this file. This ++ is necessary, because address of node40_num_of_items() is taken and it is ++ never inlined as a result. */ ++static inline short node40_num_of_items_internal(const znode * node) ++{ ++ return nh40_get_num_items(node40_node_header(node)); ++} ++ ++#if REISER4_DEBUG ++static inline void check_num_items(const znode * node) ++{ ++ assert("nikita-2749", ++ node40_num_of_items_internal(node) == node->nr_items); ++ assert("nikita-2746", znode_is_write_locked(node)); ++} ++#else ++#define check_num_items(node) noop ++#endif ++ ++/* plugin->u.node.num_of_items ++ look for description of this method in plugin/node/node.h */ ++int num_of_items_node40(const znode * node) ++{ ++ return node40_num_of_items_internal(node); ++} ++ ++static void ++node40_set_num_items(znode * node, node40_header * nh, unsigned value) ++{ ++ assert("nikita-2751", node != NULL); ++ assert("nikita-2750", nh == node40_node_header(node)); ++ ++ check_num_items(node); ++ nh40_set_num_items(nh, value); ++ node->nr_items = value; ++ check_num_items(node); ++} ++ ++/* plugin->u.node.item_by_coord ++ look for description of this method in plugin/node/node.h */ ++char *item_by_coord_node40(const coord_t * coord) ++{ ++ item_header40 *ih; ++ char *p; ++ ++ /* @coord is set to existing item */ ++ assert("nikita-596", coord != NULL); ++ assert("vs-255", coord_is_existing_item(coord)); ++ ++ ih = node40_ih_at_coord(coord); ++ p = zdata(coord->node) + ih40_get_offset(ih); ++ return p; ++} ++ ++/* plugin->u.node.length_by_coord ++ look for description of this method in plugin/node/node.h */ ++int length_by_coord_node40(const coord_t * coord) ++{ ++ item_header40 *ih; ++ int result; ++ ++ /* @coord is set to existing item */ ++ assert("vs-256", coord != NULL); ++ assert("vs-257", coord_is_existing_item(coord)); ++ ++ ih = node40_ih_at_coord(coord); ++ if ((int)coord->item_pos == ++ node40_num_of_items_internal(coord->node) - 1) ++ result = ++ nh40_get_free_space_start(node40_node_header(coord->node)) - ++ ih40_get_offset(ih); ++ else ++ result = ih40_get_offset(ih - 1) - ih40_get_offset(ih); ++ ++ return result; ++} ++ ++static pos_in_node_t ++node40_item_length(const znode * node, pos_in_node_t item_pos) ++{ ++ item_header40 *ih; ++ pos_in_node_t result; ++ ++ /* @coord is set to existing item */ ++ assert("vs-256", node != NULL); ++ assert("vs-257", node40_num_of_items_internal(node) > item_pos); ++ ++ ih = node40_ih_at(node, item_pos); ++ if (item_pos == node40_num_of_items_internal(node) - 1) ++ result = ++ nh40_get_free_space_start(node40_node_header(node)) - ++ ih40_get_offset(ih); ++ else ++ result = ih40_get_offset(ih - 1) - ih40_get_offset(ih); ++ ++ return result; ++} ++ ++/* plugin->u.node.plugin_by_coord ++ look for description of this method in plugin/node/node.h */ ++item_plugin *plugin_by_coord_node40(const coord_t * coord) ++{ ++ item_header40 *ih; ++ item_plugin *result; ++ ++ /* @coord is set to existing item */ ++ assert("vs-258", coord != NULL); ++ assert("vs-259", coord_is_existing_item(coord)); ++ ++ ih = node40_ih_at_coord(coord); ++ /* pass NULL in stead of current tree. This is time critical call. */ ++ result = item_plugin_by_disk_id(&ih->plugin_id); ++ return result; ++} ++ ++/* plugin->u.node.key_at ++ look for description of this method in plugin/node/node.h */ ++reiser4_key *key_at_node40(const coord_t * coord, reiser4_key * key) ++{ ++ item_header40 *ih; ++ ++ assert("nikita-1765", coord_is_existing_item(coord)); ++ ++ /* @coord is set to existing item */ ++ ih = node40_ih_at_coord(coord); ++ memcpy(key, &ih->key, sizeof(reiser4_key)); ++ return key; ++} ++ ++/* VS-FIXME-HANS: please review whether the below are properly disabled when debugging is disabled */ ++ ++#define NODE_INCSTAT(n, counter) \ ++ reiser4_stat_inc_at_level(znode_get_level(n), node.lookup.counter) ++ ++#define NODE_ADDSTAT(n, counter, val) \ ++ reiser4_stat_add_at_level(znode_get_level(n), node.lookup.counter, val) ++ ++/* plugin->u.node.lookup ++ look for description of this method in plugin/node/node.h */ ++node_search_result lookup_node40(znode * node /* node to query */ , ++ const reiser4_key * key /* key to look for */ , ++ lookup_bias bias /* search bias */ , ++ coord_t * coord /* resulting coord */ ) ++{ ++ int left; ++ int right; ++ int found; ++ int items; ++ ++ item_header40 *lefth; ++ item_header40 *righth; ++ ++ item_plugin *iplug; ++ item_header40 *bstop; ++ item_header40 *ih; ++ cmp_t order; ++ ++ assert("nikita-583", node != NULL); ++ assert("nikita-584", key != NULL); ++ assert("nikita-585", coord != NULL); ++ assert("nikita-2693", znode_is_any_locked(node)); ++ ++ items = node_num_items(node); ++ ++ if (unlikely(items == 0)) { ++ coord_init_first_unit(coord, node); ++ return NS_NOT_FOUND; ++ } ++ ++ /* binary search for item that can contain given key */ ++ left = 0; ++ right = items - 1; ++ coord->node = node; ++ coord_clear_iplug(coord); ++ found = 0; ++ ++ lefth = node40_ih_at(node, left); ++ righth = node40_ih_at(node, right); ++ ++ /* It is known that for small arrays sequential search is on average ++ more efficient than binary. This is because sequential search is ++ coded as tight loop that can be better optimized by compilers and ++ for small array size gain from this optimization makes sequential ++ search the winner. Another, maybe more important, reason for this, ++ is that sequential array is more CPU cache friendly, whereas binary ++ search effectively destroys CPU caching. ++ ++ Critical here is the notion of "smallness". Reasonable value of ++ REISER4_SEQ_SEARCH_BREAK can be found by playing with code in ++ fs/reiser4/ulevel/ulevel.c:test_search(). ++ ++ Don't try to further optimize sequential search by scanning from ++ right to left in attempt to use more efficient loop termination ++ condition (comparison with 0). This doesn't work. ++ ++ */ ++ ++ while (right - left >= REISER4_SEQ_SEARCH_BREAK) { ++ int median; ++ item_header40 *medianh; ++ ++ median = (left + right) / 2; ++ medianh = node40_ih_at(node, median); ++ ++ assert("nikita-1084", median >= 0); ++ assert("nikita-1085", median < items); ++ switch (keycmp(key, &medianh->key)) { ++ case LESS_THAN: ++ right = median; ++ righth = medianh; ++ break; ++ default: ++ wrong_return_value("nikita-586", "keycmp"); ++ case GREATER_THAN: ++ left = median; ++ lefth = medianh; ++ break; ++ case EQUAL_TO: ++ do { ++ --median; ++ /* headers are ordered from right to left */ ++ ++medianh; ++ } while (median >= 0 && keyeq(key, &medianh->key)); ++ right = left = median + 1; ++ ih = lefth = righth = medianh - 1; ++ found = 1; ++ break; ++ } ++ } ++ /* sequential scan. Item headers, and, therefore, keys are stored at ++ the rightmost part of a node from right to left. We are trying to ++ access memory from left to right, and hence, scan in _descending_ ++ order of item numbers. ++ */ ++ if (!found) { ++ for (left = right, ih = righth; left >= 0; ++ih, --left) { ++ cmp_t comparison; ++ ++ prefetchkey(&(ih + 1)->key); ++ comparison = keycmp(&ih->key, key); ++ if (comparison == GREATER_THAN) ++ continue; ++ if (comparison == EQUAL_TO) { ++ found = 1; ++ do { ++ --left; ++ ++ih; ++ } while (left >= 0 && keyeq(&ih->key, key)); ++ ++left; ++ --ih; ++ } else { ++ assert("nikita-1256", comparison == LESS_THAN); ++ } ++ break; ++ } ++ if (unlikely(left < 0)) ++ left = 0; ++ } ++ ++ assert("nikita-3212", right >= left); ++ assert("nikita-3214", ++ equi(found, keyeq(&node40_ih_at(node, left)->key, key))); ++ ++ coord_set_item_pos(coord, left); ++ coord->unit_pos = 0; ++ coord->between = AT_UNIT; ++ ++ /* key < leftmost key in a mode or node is corrupted and keys ++ are not sorted */ ++ bstop = node40_ih_at(node, (unsigned)left); ++ order = keycmp(&bstop->key, key); ++ if (unlikely(order == GREATER_THAN)) { ++ if (unlikely(left != 0)) { ++ /* screw up */ ++ warning("nikita-587", "Key less than %i key in a node", ++ left); ++ reiser4_print_key("key", key); ++ reiser4_print_key("min", &bstop->key); ++ print_coord_content("coord", coord); ++ return RETERR(-EIO); ++ } else { ++ coord->between = BEFORE_UNIT; ++ return NS_NOT_FOUND; ++ } ++ } ++ /* left <= key, ok */ ++ iplug = item_plugin_by_disk_id(&bstop->plugin_id); ++ ++ if (unlikely(iplug == NULL)) { ++ warning("nikita-588", "Unknown plugin %i", ++ le16_to_cpu(get_unaligned(&bstop->plugin_id))); ++ reiser4_print_key("key", key); ++ print_coord_content("coord", coord); ++ return RETERR(-EIO); ++ } ++ ++ coord_set_iplug(coord, iplug); ++ ++ /* if exact key from item header was found by binary search, no ++ further checks are necessary. */ ++ if (found) { ++ assert("nikita-1259", order == EQUAL_TO); ++ return NS_FOUND; ++ } ++ if (iplug->b.max_key_inside != NULL) { ++ reiser4_key max_item_key; ++ ++ /* key > max_item_key --- outside of an item */ ++ if (keygt(key, iplug->b.max_key_inside(coord, &max_item_key))) { ++ coord->unit_pos = 0; ++ coord->between = AFTER_ITEM; ++ /* FIXME-VS: key we are looking for does not fit into ++ found item. Return NS_NOT_FOUND then. Without that ++ the following case does not work: there is extent of ++ file 10000, 10001. File 10000, 10002 has been just ++ created. When writing to position 0 in that file - ++ traverse_tree will stop here on twig level. When we ++ want it to go down to leaf level ++ */ ++ return NS_NOT_FOUND; ++ } ++ } ++ ++ if (iplug->b.lookup != NULL) { ++ return (node_search_result)iplug->b.lookup(key, bias, coord); ++ } else { ++ assert("nikita-1260", order == LESS_THAN); ++ coord->between = AFTER_UNIT; ++ return (bias == FIND_EXACT) ? NS_NOT_FOUND : NS_FOUND; ++ } ++} ++ ++#undef NODE_ADDSTAT ++#undef NODE_INCSTAT ++ ++/* plugin->u.node.estimate ++ look for description of this method in plugin/node/node.h */ ++size_t estimate_node40(znode * node) ++{ ++ size_t result; ++ ++ assert("nikita-597", node != NULL); ++ ++ result = free_space_node40(node) - sizeof(item_header40); ++ ++ return (result > 0) ? result : 0; ++} ++ ++/* plugin->u.node.check ++ look for description of this method in plugin/node/node.h */ ++int check_node40(const znode * node /* node to check */ , ++ __u32 flags /* check flags */ , ++ const char **error /* where to store error message */ ) ++{ ++ reiser4_tree *tree; ++ int nr_items; ++ int i; ++ reiser4_key prev; ++ unsigned old_offset; ++ tree_level level; ++ coord_t coord; ++ int result; ++ ++ assert("nikita-580", node != NULL); ++ assert("nikita-581", error != NULL); ++ assert("nikita-2948", znode_is_loaded(node)); ++ ++ if (ZF_ISSET(node, JNODE_HEARD_BANSHEE)) ++ return 0; ++ ++ assert("nikita-582", zdata(node) != NULL); ++ ++ tree = znode_get_tree(node); ++ ++ nr_items = node40_num_of_items_internal(node); ++ if (nr_items < 0) { ++ *error = "Negative number of items"; ++ return -1; ++ } ++ ++ if (flags & REISER4_NODE_DKEYS) ++ prev = *znode_get_ld_key((znode *) node); ++ else ++ prev = *reiser4_min_key(); ++ ++ old_offset = 0; ++ coord_init_zero(&coord); ++ coord.node = (znode *) node; ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ level = znode_get_level(node); ++ for (i = 0; i < nr_items; i++) { ++ item_header40 *ih; ++ reiser4_key unit_key; ++ unsigned j; ++ ++ ih = node40_ih_at(node, (unsigned)i); ++ coord_set_item_pos(&coord, i); ++ if ((ih40_get_offset(ih) >= ++ znode_size(node) - nr_items * sizeof(item_header40)) || ++ (ih40_get_offset(ih) < sizeof(node40_header))) { ++ *error = "Offset is out of bounds"; ++ return -1; ++ } ++ if (ih40_get_offset(ih) <= old_offset) { ++ *error = "Offsets are in wrong order"; ++ return -1; ++ } ++ if ((i == 0) && (ih40_get_offset(ih) != sizeof(node40_header))) { ++ *error = "Wrong offset of first item"; ++ return -1; ++ } ++ old_offset = ih40_get_offset(ih); ++ ++ if (keygt(&prev, &ih->key)) { ++ *error = "Keys are in wrong order"; ++ return -1; ++ } ++ if (!keyeq(&ih->key, unit_key_by_coord(&coord, &unit_key))) { ++ *error = "Wrong key of first unit"; ++ return -1; ++ } ++ prev = ih->key; ++ for (j = 0; j < coord_num_units(&coord); ++j) { ++ coord.unit_pos = j; ++ unit_key_by_coord(&coord, &unit_key); ++ if (keygt(&prev, &unit_key)) { ++ *error = "Unit keys are in wrong order"; ++ return -1; ++ } ++ prev = unit_key; ++ } ++ coord.unit_pos = 0; ++ if (level != TWIG_LEVEL && item_is_extent(&coord)) { ++ *error = "extent on the wrong level"; ++ return -1; ++ } ++ if (level == LEAF_LEVEL && item_is_internal(&coord)) { ++ *error = "internal item on the wrong level"; ++ return -1; ++ } ++ if (level != LEAF_LEVEL && ++ !item_is_internal(&coord) && !item_is_extent(&coord)) { ++ *error = "wrong item on the internal level"; ++ return -1; ++ } ++ if (level > TWIG_LEVEL && !item_is_internal(&coord)) { ++ *error = "non-internal item on the internal level"; ++ return -1; ++ } ++#if REISER4_DEBUG ++ if (item_plugin_by_coord(&coord)->b.check ++ && item_plugin_by_coord(&coord)->b.check(&coord, error)) ++ return -1; ++#endif ++ if ((flags & REISER4_NODE_CHECK_MERGEABLE) && i) { ++ coord_t prev_coord; ++ /* two neighboring items can not be mergeable */ ++ coord_dup(&prev_coord, &coord); ++ coord_prev_item(&prev_coord); ++ if (are_items_mergeable(&prev_coord, &coord)) { ++ *error = "mergeable items in one node"; ++ return -1; ++ } ++ ++ } ++ } ++ if ((flags & REISER4_NODE_DKEYS) && !node_is_empty(node)) { ++ coord_t coord; ++ reiser4_key mkey; ++ ++ coord_init_last_unit(&coord, node); ++ max_item_key_by_coord(&coord, &mkey); ++ ++ read_lock_dk(tree); ++ result = keygt(&mkey, znode_get_rd_key((znode *) node)); ++ read_unlock_dk(tree); ++ if (result) { ++ *error = "key of rightmost item is too large"; ++ return -1; ++ } ++ } ++ if (flags & REISER4_NODE_DKEYS) { ++ read_lock_tree(); ++ read_lock_dk(tree); ++ ++ flags |= REISER4_NODE_TREE_STABLE; ++ ++ if (keygt(&prev, znode_get_rd_key((znode *) node))) { ++ if (flags & REISER4_NODE_TREE_STABLE) { ++ *error = "Last key is greater than rdkey"; ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ return -1; ++ } ++ } ++ if (keygt ++ (znode_get_ld_key((znode *) node), ++ znode_get_rd_key((znode *) node))) { ++ *error = "ldkey is greater than rdkey"; ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ return -1; ++ } ++ if (ZF_ISSET(node, JNODE_LEFT_CONNECTED) && ++ (node->left != NULL) && ++ !ZF_ISSET(node->left, JNODE_HEARD_BANSHEE) && ++ ergo(flags & REISER4_NODE_TREE_STABLE, ++ !keyeq(znode_get_rd_key(node->left), ++ znode_get_ld_key((znode *) node))) ++ && ergo(!(flags & REISER4_NODE_TREE_STABLE), ++ keygt(znode_get_rd_key(node->left), ++ znode_get_ld_key((znode *) node)))) { ++ *error = "left rdkey or ldkey is wrong"; ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ return -1; ++ } ++ if (ZF_ISSET(node, JNODE_RIGHT_CONNECTED) && ++ (node->right != NULL) && ++ !ZF_ISSET(node->right, JNODE_HEARD_BANSHEE) && ++ ergo(flags & REISER4_NODE_TREE_STABLE, ++ !keyeq(znode_get_rd_key((znode *) node), ++ znode_get_ld_key(node->right))) ++ && ergo(!(flags & REISER4_NODE_TREE_STABLE), ++ keygt(znode_get_rd_key((znode *) node), ++ znode_get_ld_key(node->right)))) { ++ *error = "rdkey or right ldkey is wrong"; ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ return -1; ++ } ++ ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ } ++ ++ return 0; ++} ++ ++int parse_node40_common(znode *node, const __u32 magic) ++{ ++ node40_header *header; ++ int result; ++ d8 level; ++ ++ header = node40_node_header((znode *) node); ++ result = -EIO; ++ level = nh40_get_level(header); ++ if (unlikely(((__u8) znode_get_level(node)) != level)) ++ warning("nikita-494", "Wrong level found in node: %i != %i", ++ znode_get_level(node), level); ++ else if (unlikely(nh40_get_magic(header) != magic)) ++ warning("nikita-495", ++ "Wrong magic in tree node: want %x, got %x", ++ magic, nh40_get_magic(header)); ++ else { ++ node->nr_items = node40_num_of_items_internal(node); ++ result = 0; ++ } ++ return RETERR(result); ++} ++ ++/* ++ * plugin->u.node.parse ++ * look for description of this method in plugin/node/node.h ++ */ ++int parse_node40(znode *node /* node to parse */) ++{ ++ return parse_node40_common(node, REISER4_NODE40_MAGIC); ++} ++ ++/* ++ * common part of ->init_node() for all nodes, ++ * which contain node40_header at the beginning ++ */ ++int init_node40_common(znode *node, node_plugin *nplug, ++ size_t node_header_size, const __u32 magic) ++{ ++ node40_header *header40; ++ ++ assert("nikita-570", node != NULL); ++ assert("nikita-572", zdata(node) != NULL); ++ ++ header40 = node40_node_header(node); ++ memset(header40, 0, sizeof(node40_header)); ++ ++ nh40_set_free_space(header40, znode_size(node) - node_header_size); ++ nh40_set_free_space_start(header40, node_header_size); ++ /* ++ * sane hypothesis: 0 in CPU format is 0 in disk format ++ */ ++ save_plugin_id(node_plugin_to_plugin(nplug), ++ &header40->common_header.plugin_id); ++ nh40_set_level(header40, znode_get_level(node)); ++ nh40_set_magic(header40, magic); ++ nh40_set_mkfs_id(header40, reiser4_mkfs_id(reiser4_get_current_sb(), ++ znode_get_subvol(node)->id)); ++ /* ++ * nr_items: 0 ++ * flags: 0 ++ */ ++ return 0; ++} ++ ++/* ++ * plugin->u.node.init ++ * look for description of this method in plugin/node/node.h ++ */ ++int init_node40(znode *node /* node to initialise */) ++{ ++ return init_node40_common(node, node_plugin_by_id(NODE40_ID), ++ sizeof(node40_header), REISER4_NODE40_MAGIC); ++} ++ ++#ifdef GUESS_EXISTS ++int guess_node40_common(const znode *node, reiser4_node_id id, ++ const __u32 magic) ++{ ++ node40_header *header; ++ ++ assert("nikita-1058", node != NULL); ++ header = node40_node_header(node); ++ return (nh40_get_magic(header) == magic) && ++ (id == plugin_by_disk_id(REISER4_NODE_PLUGIN_TYPE, ++ &header->common_header.plugin_id)->h.id); ++} ++ ++int guess_node40(const znode *node /* node to guess plugin of */) ++{ ++ return guess_node40_common(node, NODE40_ID, REISER4_NODE40_MAGIC); ++} ++#endif ++ ++/* plugin->u.node.chage_item_size ++ look for description of this method in plugin/node/node.h */ ++void change_item_size_node40(coord_t * coord, int by) ++{ ++ node40_header *nh; ++ item_header40 *ih; ++ char *item_data; ++ int item_length; ++ unsigned i; ++ ++ /* make sure that @item is coord of existing item */ ++ assert("vs-210", coord_is_existing_item(coord)); ++ ++ nh = node40_node_header(coord->node); ++ ++ item_data = item_by_coord_node40(coord); ++ item_length = length_by_coord_node40(coord); ++ ++ /* move item bodies */ ++ ih = node40_ih_at_coord(coord); ++ memmove(item_data + item_length + by, item_data + item_length, ++ nh40_get_free_space_start(nh) - ++ (ih40_get_offset(ih) + item_length)); ++ ++ /* update offsets of moved items */ ++ for (i = coord->item_pos + 1; i < nh40_get_num_items(nh); i++) { ++ ih = node40_ih_at(coord->node, i); ++ ih40_set_offset(ih, ih40_get_offset(ih) + by); ++ } ++ ++ /* update node header */ ++ nh40_set_free_space(nh, nh40_get_free_space(nh) - by); ++ nh40_set_free_space_start(nh, nh40_get_free_space_start(nh) + by); ++} ++ ++static int should_notify_parent(const znode * node) ++{ ++ /* FIXME_JMACD This looks equivalent to znode_is_root(), right? -josh */ ++ return !disk_addr_eq(znode_get_block(node), ++ &znode_get_tree(node)->root_block); ++} ++ ++/* plugin->u.node.create_item ++ look for description of this method in plugin/node/node.h */ ++int ++create_item_node40(coord_t *target, const reiser4_key *key, ++ reiser4_item_data *data, carry_plugin_info *info) ++{ ++ node40_header *nh; ++ item_header40 *ih; ++ unsigned offset; ++ unsigned i; ++ ++ nh = node40_node_header(target->node); ++ ++ assert("vs-212", coord_is_between_items(target)); ++ /* node must have enough free space */ ++ assert("vs-254", ++ free_space_node40(target->node) >= ++ data->length + sizeof(item_header40)); ++ assert("vs-1410", data->length >= 0); ++ ++ if (coord_set_to_right(target)) ++ /* there are not items to the right of @target, so, new item ++ will be inserted after last one */ ++ coord_set_item_pos(target, nh40_get_num_items(nh)); ++ ++ if (target->item_pos < nh40_get_num_items(nh)) { ++ /* there are items to be moved to prepare space for new ++ item */ ++ ih = node40_ih_at_coord(target); ++ /* new item will start at this offset */ ++ offset = ih40_get_offset(ih); ++ ++ memmove(zdata(target->node) + offset + data->length, ++ zdata(target->node) + offset, ++ nh40_get_free_space_start(nh) - offset); ++ /* update headers of moved items */ ++ for (i = target->item_pos; i < nh40_get_num_items(nh); i++) { ++ ih = node40_ih_at(target->node, i); ++ ih40_set_offset(ih, ih40_get_offset(ih) + data->length); ++ } ++ ++ /* @ih is set to item header of the last item, move item headers */ ++ memmove(ih - 1, ih, ++ sizeof(item_header40) * (nh40_get_num_items(nh) - ++ target->item_pos)); ++ } else { ++ /* new item will start at this offset */ ++ offset = nh40_get_free_space_start(nh); ++ } ++ ++ /* make item header for the new item */ ++ ih = node40_ih_at_coord(target); ++ memcpy(&ih->key, key, sizeof(reiser4_key)); ++ ih40_set_offset(ih, offset); ++ save_plugin_id(item_plugin_to_plugin(data->iplug), &ih->plugin_id); ++ ++ /* update node header */ ++ nh40_set_free_space(nh, ++ nh40_get_free_space(nh) - data->length - ++ sizeof(item_header40)); ++ nh40_set_free_space_start(nh, ++ nh40_get_free_space_start(nh) + data->length); ++ node40_set_num_items(target->node, nh, nh40_get_num_items(nh) + 1); ++ ++ /* FIXME: check how does create_item work when between is set to BEFORE_UNIT */ ++ target->unit_pos = 0; ++ target->between = AT_UNIT; ++ coord_clear_iplug(target); ++ ++ /* initialize item */ ++ if (data->iplug->b.init != NULL) { ++ data->iplug->b.init(target, NULL, data); ++ } ++ /* copy item body */ ++ if (data->iplug->b.paste != NULL) { ++ data->iplug->b.paste(target, data, info); ++ } else if (data->data != NULL) { ++ if (data->user) { ++ /* AUDIT: Are we really should not check that pointer ++ from userspace was valid and data bytes were ++ available? How will we return -EFAULT of some kind ++ without this check? */ ++ assert("nikita-3038", reiser4_schedulable()); ++ /* copy data from user space */ ++ if (__copy_from_user(zdata(target->node) + offset, ++ (const char __user *)data->data, ++ (unsigned)data->length)) ++ return RETERR(-EFAULT); ++ } else ++ /* copy from kernel space */ ++ memcpy(zdata(target->node) + offset, data->data, ++ (unsigned)data->length); ++ } ++ ++ if (target->item_pos == 0) { ++ /* left delimiting key has to be updated */ ++ prepare_for_update(NULL, target->node, info); ++ } ++ ++ if (item_plugin_by_coord(target)->b.create_hook != NULL) { ++ item_plugin_by_coord(target)->b.create_hook(target, data->arg); ++ } ++ ++ return 0; ++} ++ ++/* plugin->u.node.update_item_key ++ look for description of this method in plugin/node/node.h */ ++void ++update_item_key_node40(coord_t * target, const reiser4_key * key, ++ carry_plugin_info * info) ++{ ++ item_header40 *ih; ++ ++ ih = node40_ih_at_coord(target); ++ memcpy(&ih->key, key, sizeof(reiser4_key)); ++ ++ if (target->item_pos == 0) { ++ prepare_for_update(NULL, target->node, info); ++ } ++} ++ ++/* this bits encode cut mode */ ++#define CMODE_TAIL 1 ++#define CMODE_WHOLE 2 ++#define CMODE_HEAD 4 ++ ++struct cut40_info { ++ int mode; ++ pos_in_node_t tail_removed; /* position of item which gets tail removed */ ++ pos_in_node_t first_removed; /* position of first the leftmost item among items removed completely */ ++ pos_in_node_t removed_count; /* number of items removed completely */ ++ pos_in_node_t head_removed; /* position of item which gets head removed */ ++ ++ pos_in_node_t freed_space_start; ++ pos_in_node_t freed_space_end; ++ pos_in_node_t first_moved; ++ pos_in_node_t head_removed_location; ++}; ++ ++static void init_cinfo(struct cut40_info *cinfo) ++{ ++ cinfo->mode = 0; ++ cinfo->tail_removed = MAX_POS_IN_NODE; ++ cinfo->first_removed = MAX_POS_IN_NODE; ++ cinfo->removed_count = MAX_POS_IN_NODE; ++ cinfo->head_removed = MAX_POS_IN_NODE; ++ cinfo->freed_space_start = MAX_POS_IN_NODE; ++ cinfo->freed_space_end = MAX_POS_IN_NODE; ++ cinfo->first_moved = MAX_POS_IN_NODE; ++ cinfo->head_removed_location = MAX_POS_IN_NODE; ++} ++ ++/* complete cut_node40/kill_node40 content by removing the gap created by */ ++static void compact(znode * node, struct cut40_info *cinfo) ++{ ++ node40_header *nh; ++ item_header40 *ih; ++ pos_in_node_t freed; ++ pos_in_node_t pos, nr_items; ++ ++ assert("vs-1526", (cinfo->freed_space_start != MAX_POS_IN_NODE && ++ cinfo->freed_space_end != MAX_POS_IN_NODE && ++ cinfo->first_moved != MAX_POS_IN_NODE)); ++ assert("vs-1523", cinfo->freed_space_end >= cinfo->freed_space_start); ++ ++ nh = node40_node_header(node); ++ nr_items = nh40_get_num_items(nh); ++ ++ /* remove gap made up by removal */ ++ memmove(zdata(node) + cinfo->freed_space_start, ++ zdata(node) + cinfo->freed_space_end, ++ nh40_get_free_space_start(nh) - cinfo->freed_space_end); ++ ++ /* update item headers of moved items - change their locations */ ++ pos = cinfo->first_moved; ++ ih = node40_ih_at(node, pos); ++ if (cinfo->head_removed_location != MAX_POS_IN_NODE) { ++ assert("vs-1580", pos == cinfo->head_removed); ++ ih40_set_offset(ih, cinfo->head_removed_location); ++ pos++; ++ ih--; ++ } ++ ++ freed = cinfo->freed_space_end - cinfo->freed_space_start; ++ for (; pos < nr_items; pos++, ih--) { ++ assert("vs-1581", ih == node40_ih_at(node, pos)); ++ ih40_set_offset(ih, ih40_get_offset(ih) - freed); ++ } ++ ++ /* free space start moved to right */ ++ nh40_set_free_space_start(nh, nh40_get_free_space_start(nh) - freed); ++ ++ if (cinfo->removed_count != MAX_POS_IN_NODE) { ++ /* number of items changed. Remove item headers of those items */ ++ ih = node40_ih_at(node, nr_items - 1); ++ memmove(ih + cinfo->removed_count, ih, ++ sizeof(item_header40) * (nr_items - ++ cinfo->removed_count - ++ cinfo->first_removed)); ++ freed += sizeof(item_header40) * cinfo->removed_count; ++ node40_set_num_items(node, nh, nr_items - cinfo->removed_count); ++ } ++ ++ /* total amount of free space increased */ ++ nh40_set_free_space(nh, nh40_get_free_space(nh) + freed); ++} ++ ++int shrink_item_node40(coord_t * coord, int delta) ++{ ++ node40_header *nh; ++ item_header40 *ih; ++ pos_in_node_t pos; ++ pos_in_node_t nr_items; ++ char *end; ++ znode *node; ++ int off; ++ ++ assert("nikita-3487", coord != NULL); ++ assert("nikita-3488", delta >= 0); ++ ++ node = coord->node; ++ nh = node40_node_header(node); ++ nr_items = nh40_get_num_items(nh); ++ ++ ih = node40_ih_at_coord(coord); ++ assert("nikita-3489", delta <= length_by_coord_node40(coord)); ++ off = ih40_get_offset(ih) + length_by_coord_node40(coord); ++ end = zdata(node) + off; ++ ++ /* remove gap made up by removal */ ++ memmove(end - delta, end, nh40_get_free_space_start(nh) - off); ++ ++ /* update item headers of moved items - change their locations */ ++ pos = coord->item_pos + 1; ++ ih = node40_ih_at(node, pos); ++ for (; pos < nr_items; pos++, ih--) { ++ assert("nikita-3490", ih == node40_ih_at(node, pos)); ++ ih40_set_offset(ih, ih40_get_offset(ih) - delta); ++ } ++ ++ /* free space start moved to left */ ++ nh40_set_free_space_start(nh, nh40_get_free_space_start(nh) - delta); ++ /* total amount of free space increased */ ++ nh40_set_free_space(nh, nh40_get_free_space(nh) + delta); ++ /* ++ * This method does _not_ changes number of items. Hence, it cannot ++ * make node empty. Also it doesn't remove items at all, which means ++ * that no keys have to be updated either. ++ */ ++ return 0; ++} ++ ++/* ++ * Evaluate cut mode, if key range has been specified. ++ * ++ * This is for the case when units are not minimal objects ++ * addressed by keys. ++ * ++ * This doesn't work when range contains objects with ++ * non-unique keys (e.g. directory items). ++ */ ++static int parse_cut_by_key_range(struct cut40_info *cinfo, ++ const struct cut_kill_params *params) ++{ ++ reiser4_key min_from_key, max_to_key; ++ const reiser4_key *from_key = params->from_key; ++ const reiser4_key *to_key = params->to_key; ++ /* ++ * calculate minimal key stored in first item ++ * of items to be cut (params->from) ++ */ ++ item_key_by_coord(params->from, &min_from_key); ++ /* ++ * calculate maximal key stored in last item ++ * of items to be cut (params->to) ++ */ ++ max_item_key_by_coord(params->to, &max_to_key); ++ ++ if (params->from->item_pos == params->to->item_pos) { ++ if (keylt(&min_from_key, from_key) ++ && keylt(to_key, &max_to_key)) ++ return 1; ++ ++ if (keygt(from_key, &min_from_key)) { ++ /* tail of item is to be cut cut */ ++ cinfo->tail_removed = params->from->item_pos; ++ cinfo->mode |= CMODE_TAIL; ++ } else if (keylt(to_key, &max_to_key)) { ++ /* head of item is to be cut */ ++ cinfo->head_removed = params->from->item_pos; ++ cinfo->mode |= CMODE_HEAD; ++ } else { ++ /* item is removed completely */ ++ cinfo->first_removed = params->from->item_pos; ++ cinfo->removed_count = 1; ++ cinfo->mode |= CMODE_WHOLE; ++ } ++ } else { ++ cinfo->first_removed = params->from->item_pos + 1; ++ cinfo->removed_count = ++ params->to->item_pos - params->from->item_pos - 1; ++ ++ if (keygt(from_key, &min_from_key)) { ++ /* first item is not cut completely */ ++ cinfo->tail_removed = params->from->item_pos; ++ cinfo->mode |= CMODE_TAIL; ++ } else { ++ cinfo->first_removed--; ++ cinfo->removed_count++; ++ } ++ if (keylt(to_key, &max_to_key)) { ++ /* last item is not cut completely */ ++ cinfo->head_removed = params->to->item_pos; ++ cinfo->mode |= CMODE_HEAD; ++ } else { ++ cinfo->removed_count++; ++ } ++ if (cinfo->removed_count) ++ cinfo->mode |= CMODE_WHOLE; ++ } ++ return 0; ++} ++ ++/* ++ * Evaluate cut mode, if the key range hasn't been specified. ++ * In this case the range can include objects with non-unique ++ * keys (e.g. directory entries). ++ * ++ * This doesn't work when units are not the minimal objects ++ * addressed by keys (e.g. bytes in file's body stored in ++ * unformatted nodes). ++ */ ++static int parse_cut_by_coord_range(struct cut40_info *cinfo, ++ const struct cut_kill_params *params) ++{ ++ coord_t *from = params->from; ++ coord_t *to = params->to; ++ ++ if (from->item_pos == to->item_pos) { ++ /* ++ * cut is performed on only one item ++ */ ++ if (from->unit_pos > 0 && ++ to->unit_pos < coord_last_unit_pos(to)) ++ /* ++ * cut from the middle of item ++ */ ++ return 1; ++ if (from->unit_pos > 0) { ++ /* ++ * tail of item is to be cut ++ */ ++ cinfo->tail_removed = params->from->item_pos; ++ cinfo->mode |= CMODE_TAIL; ++ } else if (to->unit_pos < coord_last_unit_pos(to)) { ++ /* ++ * head of item is to be cut ++ */ ++ cinfo->head_removed = params->from->item_pos; ++ cinfo->mode |= CMODE_HEAD; ++ } else { ++ /* ++ * item is removed completely ++ */ ++ assert("edward-1631", ++ from->unit_pos == 0 && ++ to->unit_pos == coord_last_unit_pos(to)); ++ ++ cinfo->first_removed = params->from->item_pos; ++ cinfo->removed_count = 1; ++ cinfo->mode |= CMODE_WHOLE; ++ } ++ } else { ++ cinfo->first_removed = from->item_pos + 1; ++ cinfo->removed_count = ++ to->item_pos - from->item_pos - 1; ++ ++ if (from->unit_pos > 0) { ++ /* ++ * first item is not cut completely ++ */ ++ cinfo->tail_removed = from->item_pos; ++ cinfo->mode |= CMODE_TAIL; ++ } else { ++ cinfo->first_removed--; ++ cinfo->removed_count++; ++ } ++ if (to->unit_pos < coord_last_unit_pos(to)) { ++ /* ++ * last item is not cut completely ++ */ ++ cinfo->head_removed = to->item_pos; ++ cinfo->mode |= CMODE_HEAD; ++ } else { ++ cinfo->removed_count++; ++ } ++ if (cinfo->removed_count) ++ cinfo->mode |= CMODE_WHOLE; ++ } ++ return 0; ++} ++ ++/* ++ * this is used by cut_node40 and kill_node40. It analyses input parameters ++ * and calculates cut mode. There are 2 types of cut. First is when a unit is ++ * removed from the middle of an item. In this case this function returns 1. ++ * All the rest fits into second case: 0 or 1 of items getting tail cut, 0 or ++ * more items removed completely and 0 or 1 item getting head cut. Function ++ * returns 0 in this case ++ */ ++static int parse_cut(struct cut40_info *cinfo, ++ const struct cut_kill_params *params) ++{ ++ init_cinfo(cinfo); ++ if (params->from_key == NULL) { ++ /* ++ * cut key range is not defined in input parameters ++ */ ++ assert("vs-1513", params->to_key == NULL); ++ return parse_cut_by_coord_range(cinfo, params); ++ } else ++ return parse_cut_by_key_range(cinfo, params); ++} ++ ++static void ++call_kill_hooks(znode * node, pos_in_node_t from, pos_in_node_t count, ++ carry_kill_data * kdata) ++{ ++ coord_t coord; ++ item_plugin *iplug; ++ pos_in_node_t pos; ++ ++ coord.node = node; ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ for (pos = 0; pos < count; pos++) { ++ coord_set_item_pos(&coord, from + pos); ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ iplug = item_plugin_by_coord(&coord); ++ if (iplug->b.kill_hook) { ++ iplug->b.kill_hook(&coord, 0, coord_num_units(&coord), ++ kdata); ++ } ++ } ++} ++ ++/* this is used to kill item partially */ ++static pos_in_node_t ++kill_units(coord_t * coord, pos_in_node_t from, pos_in_node_t to, void *data, ++ reiser4_key * smallest_removed, reiser4_key * new_first_key) ++{ ++ struct carry_kill_data *kdata; ++ item_plugin *iplug; ++ ++ kdata = data; ++ iplug = item_plugin_by_coord(coord); ++ ++ assert("vs-1524", iplug->b.kill_units); ++ return iplug->b.kill_units(coord, from, to, kdata, smallest_removed, ++ new_first_key); ++} ++ ++/* call item plugin to cut tail of file */ ++static pos_in_node_t ++kill_tail(coord_t * coord, void *data, reiser4_key * smallest_removed) ++{ ++ struct carry_kill_data *kdata; ++ pos_in_node_t to; ++ ++ kdata = data; ++ to = coord_last_unit_pos(coord); ++ return kill_units(coord, coord->unit_pos, to, kdata, smallest_removed, ++ NULL); ++} ++ ++/* call item plugin to cut head of item */ ++static pos_in_node_t ++kill_head(coord_t * coord, void *data, reiser4_key * smallest_removed, ++ reiser4_key * new_first_key) ++{ ++ return kill_units(coord, 0, coord->unit_pos, data, smallest_removed, ++ new_first_key); ++} ++ ++/* this is used to cut item partially */ ++static pos_in_node_t ++cut_units(coord_t * coord, pos_in_node_t from, pos_in_node_t to, void *data, ++ reiser4_key * smallest_removed, reiser4_key * new_first_key) ++{ ++ carry_cut_data *cdata; ++ item_plugin *iplug; ++ ++ cdata = data; ++ iplug = item_plugin_by_coord(coord); ++ assert("vs-302", iplug->b.cut_units); ++ return iplug->b.cut_units(coord, from, to, cdata, smallest_removed, ++ new_first_key); ++} ++ ++/* call item plugin to cut tail of file */ ++static pos_in_node_t ++cut_tail(coord_t * coord, void *data, reiser4_key * smallest_removed) ++{ ++ carry_cut_data *cdata; ++ pos_in_node_t to; ++ ++ cdata = data; ++ to = coord_last_unit_pos(cdata->params.from); ++ return cut_units(coord, coord->unit_pos, to, data, smallest_removed, NULL); ++} ++ ++/* call item plugin to cut head of item */ ++static pos_in_node_t ++cut_head(coord_t * coord, void *data, reiser4_key * smallest_removed, ++ reiser4_key * new_first_key) ++{ ++ return cut_units(coord, 0, coord->unit_pos, data, smallest_removed, ++ new_first_key); ++} ++ ++/* this returns 1 of key of first item changed, 0 - if it did not */ ++static int ++prepare_for_compact(struct cut40_info *cinfo, ++ const struct cut_kill_params *params, int is_cut, ++ void *data, carry_plugin_info * info) ++{ ++ znode *node; ++ item_header40 *ih; ++ pos_in_node_t freed; ++ pos_in_node_t item_pos; ++ coord_t coord; ++ reiser4_key new_first_key; ++ pos_in_node_t(*kill_units_f) (coord_t *, pos_in_node_t, pos_in_node_t, ++ void *, reiser4_key *, reiser4_key *); ++ pos_in_node_t(*kill_tail_f) (coord_t *, void *, reiser4_key *); ++ pos_in_node_t(*kill_head_f) (coord_t *, void *, reiser4_key *, ++ reiser4_key *); ++ int retval; ++ ++ retval = 0; ++ ++ node = params->from->node; ++ ++ assert("vs-184", node == params->to->node); ++ assert("vs-312", !node_is_empty(node)); ++ assert("vs-297", ++ coord_compare(params->from, params->to) != COORD_CMP_ON_RIGHT); ++ ++ if (is_cut) { ++ kill_units_f = cut_units; ++ kill_tail_f = cut_tail; ++ kill_head_f = cut_head; ++ } else { ++ kill_units_f = kill_units; ++ kill_tail_f = kill_tail; ++ kill_head_f = kill_head; ++ } ++ ++ if (parse_cut(cinfo, params) == 1) { ++ /* cut from the middle of item */ ++ freed = ++ kill_units_f(params->from, params->from->unit_pos, ++ params->to->unit_pos, data, ++ params->smallest_removed, NULL); ++ ++ item_pos = params->from->item_pos; ++ ih = node40_ih_at(node, item_pos); ++ cinfo->freed_space_start = ++ ih40_get_offset(ih) + node40_item_length(node, ++ item_pos) - freed; ++ cinfo->freed_space_end = cinfo->freed_space_start + freed; ++ cinfo->first_moved = item_pos + 1; ++ } else { ++ assert("vs-1521", (cinfo->tail_removed != MAX_POS_IN_NODE || ++ cinfo->first_removed != MAX_POS_IN_NODE || ++ cinfo->head_removed != MAX_POS_IN_NODE)); ++ ++ switch (cinfo->mode) { ++ case CMODE_TAIL: ++ /* one item gets cut partially from its end */ ++ assert("vs-1562", ++ cinfo->tail_removed == params->from->item_pos); ++ ++ freed = ++ kill_tail_f(params->from, data, ++ params->smallest_removed); ++ ++ item_pos = cinfo->tail_removed; ++ ih = node40_ih_at(node, item_pos); ++ cinfo->freed_space_start = ++ ih40_get_offset(ih) + node40_item_length(node, ++ item_pos) - ++ freed; ++ cinfo->freed_space_end = ++ cinfo->freed_space_start + freed; ++ cinfo->first_moved = cinfo->tail_removed + 1; ++ break; ++ ++ case CMODE_WHOLE: ++ /* one or more items get removed completely */ ++ assert("vs-1563", ++ cinfo->first_removed == params->from->item_pos); ++ assert("vs-1564", cinfo->removed_count > 0 ++ && cinfo->removed_count != MAX_POS_IN_NODE); ++ ++ /* call kill hook for all items removed completely */ ++ if (is_cut == 0) ++ call_kill_hooks(node, cinfo->first_removed, ++ cinfo->removed_count, data); ++ ++ item_pos = cinfo->first_removed; ++ ih = node40_ih_at(node, item_pos); ++ ++ if (params->smallest_removed) ++ memcpy(params->smallest_removed, &ih->key, ++ sizeof(reiser4_key)); ++ ++ cinfo->freed_space_start = ih40_get_offset(ih); ++ ++ item_pos += (cinfo->removed_count - 1); ++ ih -= (cinfo->removed_count - 1); ++ cinfo->freed_space_end = ++ ih40_get_offset(ih) + node40_item_length(node, ++ item_pos); ++ cinfo->first_moved = item_pos + 1; ++ if (cinfo->first_removed == 0) ++ /* key of first item of the node changes */ ++ retval = 1; ++ break; ++ ++ case CMODE_HEAD: ++ /* one item gets cut partially from its head */ ++ assert("vs-1565", ++ cinfo->head_removed == params->from->item_pos); ++ ++ freed = ++ kill_head_f(params->to, data, ++ params->smallest_removed, ++ &new_first_key); ++ ++ item_pos = cinfo->head_removed; ++ ih = node40_ih_at(node, item_pos); ++ cinfo->freed_space_start = ih40_get_offset(ih); ++ cinfo->freed_space_end = ih40_get_offset(ih) + freed; ++ cinfo->first_moved = cinfo->head_removed + 1; ++ ++ /* item head is removed, therefore, item key changed */ ++ coord.node = node; ++ coord_set_item_pos(&coord, item_pos); ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ update_item_key_node40(&coord, &new_first_key, NULL); ++ if (item_pos == 0) ++ /* key of first item of the node changes */ ++ retval = 1; ++ break; ++ ++ case CMODE_TAIL | CMODE_WHOLE: ++ /* one item gets cut from its end and one or more items get removed completely */ ++ assert("vs-1566", ++ cinfo->tail_removed == params->from->item_pos); ++ assert("vs-1567", ++ cinfo->first_removed == cinfo->tail_removed + 1); ++ assert("vs-1564", cinfo->removed_count > 0 ++ && cinfo->removed_count != MAX_POS_IN_NODE); ++ ++ freed = ++ kill_tail_f(params->from, data, ++ params->smallest_removed); ++ ++ item_pos = cinfo->tail_removed; ++ ih = node40_ih_at(node, item_pos); ++ cinfo->freed_space_start = ++ ih40_get_offset(ih) + node40_item_length(node, ++ item_pos) - ++ freed; ++ ++ /* call kill hook for all items removed completely */ ++ if (is_cut == 0) ++ call_kill_hooks(node, cinfo->first_removed, ++ cinfo->removed_count, data); ++ ++ item_pos += cinfo->removed_count; ++ ih -= cinfo->removed_count; ++ cinfo->freed_space_end = ++ ih40_get_offset(ih) + node40_item_length(node, ++ item_pos); ++ cinfo->first_moved = item_pos + 1; ++ break; ++ ++ case CMODE_WHOLE | CMODE_HEAD: ++ /* one or more items get removed completely and one item gets cut partially from its head */ ++ assert("vs-1568", ++ cinfo->first_removed == params->from->item_pos); ++ assert("vs-1564", cinfo->removed_count > 0 ++ && cinfo->removed_count != MAX_POS_IN_NODE); ++ assert("vs-1569", ++ cinfo->head_removed == ++ cinfo->first_removed + cinfo->removed_count); ++ ++ /* call kill hook for all items removed completely */ ++ if (is_cut == 0) ++ call_kill_hooks(node, cinfo->first_removed, ++ cinfo->removed_count, data); ++ ++ item_pos = cinfo->first_removed; ++ ih = node40_ih_at(node, item_pos); ++ ++ if (params->smallest_removed) ++ memcpy(params->smallest_removed, &ih->key, ++ sizeof(reiser4_key)); ++ ++ freed = ++ kill_head_f(params->to, data, NULL, &new_first_key); ++ ++ cinfo->freed_space_start = ih40_get_offset(ih); ++ ++ ih = node40_ih_at(node, cinfo->head_removed); ++ /* this is the most complex case. Item which got head removed and items which are to be moved ++ intact change their location differently. */ ++ cinfo->freed_space_end = ih40_get_offset(ih) + freed; ++ cinfo->first_moved = cinfo->head_removed; ++ cinfo->head_removed_location = cinfo->freed_space_start; ++ ++ /* item head is removed, therefore, item key changed */ ++ coord.node = node; ++ coord_set_item_pos(&coord, cinfo->head_removed); ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ update_item_key_node40(&coord, &new_first_key, NULL); ++ ++ assert("vs-1579", cinfo->first_removed == 0); ++ /* key of first item of the node changes */ ++ retval = 1; ++ break; ++ ++ case CMODE_TAIL | CMODE_HEAD: ++ /* one item get cut from its end and its neighbor gets cut from its tail */ ++ impossible("vs-1576", "this can not happen currently"); ++ break; ++ ++ case CMODE_TAIL | CMODE_WHOLE | CMODE_HEAD: ++ impossible("vs-1577", "this can not happen currently"); ++ break; ++ default: ++ impossible("vs-1578", "unexpected cut mode"); ++ break; ++ } ++ } ++ return retval; ++} ++ ++/* plugin->u.node.kill ++ return value is number of items removed completely */ ++int kill_node40(struct carry_kill_data *kdata, carry_plugin_info * info) ++{ ++ znode *node; ++ struct cut40_info cinfo; ++ int first_key_changed; ++ ++ node = kdata->params.from->node; ++ ++ first_key_changed = ++ prepare_for_compact(&cinfo, &kdata->params, 0 /* not cut */ , kdata, ++ info); ++ compact(node, &cinfo); ++ ++ if (info) { ++ /* it is not called by node40_shift, so we have to take care ++ of changes on upper levels */ ++ if (node_is_empty(node) ++ && !(kdata->flags & DELETE_RETAIN_EMPTY)) ++ /* all contents of node is deleted */ ++ prepare_removal_node40(node, info); ++ else if (first_key_changed) { ++ prepare_for_update(NULL, node, info); ++ } ++ } ++ ++ coord_clear_iplug(kdata->params.from); ++ coord_clear_iplug(kdata->params.to); ++ ++ znode_make_dirty(node); ++ return cinfo.removed_count == MAX_POS_IN_NODE ? 0 : cinfo.removed_count; ++} ++ ++/* plugin->u.node.cut ++ return value is number of items removed completely */ ++int cut_node40(struct carry_cut_data *cdata, carry_plugin_info * info) ++{ ++ znode *node; ++ struct cut40_info cinfo; ++ int first_key_changed; ++ ++ node = cdata->params.from->node; ++ ++ first_key_changed = ++ prepare_for_compact(&cinfo, &cdata->params, 1 /* not cut */ , cdata, ++ info); ++ compact(node, &cinfo); ++ ++ if (info) { ++ /* it is not called by node40_shift, so we have to take care ++ of changes on upper levels */ ++ if (node_is_empty(node)) ++ /* all contents of node is deleted */ ++ prepare_removal_node40(node, info); ++ else if (first_key_changed) { ++ prepare_for_update(NULL, node, info); ++ } ++ } ++ ++ coord_clear_iplug(cdata->params.from); ++ coord_clear_iplug(cdata->params.to); ++ ++ znode_make_dirty(node); ++ return cinfo.removed_count == MAX_POS_IN_NODE ? 0 : cinfo.removed_count; ++} ++ ++/* this structure is used by shift method of node40 plugin */ ++struct shift_params { ++ shift_direction pend; /* when @pend == append - we are shifting to ++ left, when @pend == prepend - to right */ ++ coord_t wish_stop; /* when shifting to left this is last unit we ++ want shifted, when shifting to right - this ++ is set to unit we want to start shifting ++ from */ ++ znode *target; ++ int everything; /* it is set to 1 if everything we have to shift is ++ shifted, 0 - otherwise */ ++ ++ /* FIXME-VS: get rid of read_stop */ ++ ++ /* these are set by estimate_shift */ ++ coord_t real_stop; /* this will be set to last unit which will be ++ really shifted */ ++ ++ /* coordinate in source node before operation of unit which becomes ++ first after shift to left of last after shift to right */ ++ union { ++ coord_t future_first; ++ coord_t future_last; ++ } u; ++ ++ unsigned merging_units; /* number of units of first item which have to ++ be merged with last item of target node */ ++ unsigned merging_bytes; /* number of bytes in those units */ ++ ++ unsigned entire; /* items shifted in their entirety */ ++ unsigned entire_bytes; /* number of bytes in those items */ ++ ++ unsigned part_units; /* number of units of partially copied item */ ++ unsigned part_bytes; /* number of bytes in those units */ ++ ++ unsigned shift_bytes; /* total number of bytes in items shifted (item ++ headers not included) */ ++ ++}; ++ ++static int item_creation_overhead(coord_t *item) ++{ ++ return node_plugin_by_coord(item)->item_overhead(item->node, NULL); ++} ++ ++/* how many units are there in @source starting from source->unit_pos ++ but not further than @stop_coord */ ++static int ++wanted_units(coord_t *source, coord_t *stop_coord, shift_direction pend) ++{ ++ if (pend == SHIFT_LEFT) { ++ assert("vs-181", source->unit_pos == 0); ++ } else { ++ assert("vs-182", ++ source->unit_pos == coord_last_unit_pos(source)); ++ } ++ ++ if (source->item_pos != stop_coord->item_pos) { ++ /* @source and @stop_coord are different items */ ++ return coord_last_unit_pos(source) + 1; ++ } ++ ++ if (pend == SHIFT_LEFT) { ++ return stop_coord->unit_pos + 1; ++ } else { ++ return source->unit_pos - stop_coord->unit_pos + 1; ++ } ++} ++ ++/* this calculates what can be copied from @shift->wish_stop.node to ++ @shift->target */ ++static void ++estimate_shift(struct shift_params *shift, const reiser4_context * ctx) ++{ ++ unsigned target_free_space, size; ++ pos_in_node_t stop_item; /* item which estimating should not consider */ ++ unsigned want; /* number of units of item we want shifted */ ++ coord_t source; /* item being estimated */ ++ item_plugin *iplug; ++ ++ /* shifting to left/right starts from first/last units of ++ @shift->wish_stop.node */ ++ if (shift->pend == SHIFT_LEFT) { ++ coord_init_first_unit(&source, shift->wish_stop.node); ++ } else { ++ coord_init_last_unit(&source, shift->wish_stop.node); ++ } ++ shift->real_stop = source; ++ ++ /* free space in target node and number of items in source */ ++ target_free_space = znode_free_space(shift->target); ++ ++ shift->everything = 0; ++ if (!node_is_empty(shift->target)) { ++ /* target node is not empty, check for boundary items ++ mergeability */ ++ coord_t to; ++ ++ /* item we try to merge @source with */ ++ if (shift->pend == SHIFT_LEFT) { ++ coord_init_last_unit(&to, shift->target); ++ } else { ++ coord_init_first_unit(&to, shift->target); ++ } ++ ++ if ((shift->pend == SHIFT_LEFT) ? are_items_mergeable(&to, ++ &source) : ++ are_items_mergeable(&source, &to)) { ++ /* how many units of @source do we want to merge to ++ item @to */ ++ want = ++ wanted_units(&source, &shift->wish_stop, ++ shift->pend); ++ ++ /* how many units of @source we can merge to item ++ @to */ ++ iplug = item_plugin_by_coord(&source); ++ if (iplug->b.can_shift != NULL) ++ shift->merging_units = ++ iplug->b.can_shift(target_free_space, ++ &source, shift->target, ++ shift->pend, &size, ++ want); ++ else { ++ shift->merging_units = 0; ++ size = 0; ++ } ++ shift->merging_bytes = size; ++ shift->shift_bytes += size; ++ /* update stop coord to be set to last unit of @source ++ we can merge to @target */ ++ if (shift->merging_units) ++ /* at least one unit can be shifted */ ++ shift->real_stop.unit_pos = ++ (shift->merging_units - source.unit_pos - ++ 1) * shift->pend; ++ else { ++ /* nothing can be shifted */ ++ if (shift->pend == SHIFT_LEFT) ++ coord_init_before_first_item(&shift-> ++ real_stop, ++ source. ++ node); ++ else ++ coord_init_after_last_item(&shift-> ++ real_stop, ++ source.node); ++ } ++ assert("nikita-2081", shift->real_stop.unit_pos + 1); ++ ++ if (shift->merging_units != want) { ++ /* we could not copy as many as we want, so, ++ there is no reason for estimating any ++ longer */ ++ return; ++ } ++ ++ target_free_space -= size; ++ coord_add_item_pos(&source, shift->pend); ++ } ++ } ++ ++ /* number of item nothing of which we want to shift */ ++ stop_item = shift->wish_stop.item_pos + shift->pend; ++ ++ /* calculate how many items can be copied into given free ++ space as whole */ ++ for (; source.item_pos != stop_item; ++ coord_add_item_pos(&source, shift->pend)) { ++ if (shift->pend == SHIFT_RIGHT) ++ source.unit_pos = coord_last_unit_pos(&source); ++ ++ /* how many units of @source do we want to copy */ ++ want = wanted_units(&source, &shift->wish_stop, shift->pend); ++ ++ if (want == coord_last_unit_pos(&source) + 1) { ++ /* we want this item to be copied entirely */ ++ size = ++ item_length_by_coord(&source) + ++ item_creation_overhead(&source); ++ if (size <= target_free_space) { ++ /* item fits into target node as whole */ ++ target_free_space -= size; ++ shift->shift_bytes += ++ size - item_creation_overhead(&source); ++ shift->entire_bytes += ++ size - item_creation_overhead(&source); ++ shift->entire++; ++ ++ /* update shift->real_stop coord to be set to ++ last unit of @source we can merge to ++ @target */ ++ shift->real_stop = source; ++ if (shift->pend == SHIFT_LEFT) ++ shift->real_stop.unit_pos = ++ coord_last_unit_pos(&shift-> ++ real_stop); ++ else ++ shift->real_stop.unit_pos = 0; ++ continue; ++ } ++ } ++ ++ /* we reach here only for an item which does not fit into ++ target node in its entirety. This item may be either ++ partially shifted, or not shifted at all. We will have to ++ create new item in target node, so decrease amout of free ++ space by an item creation overhead. We can reach here also ++ if stop coord is in this item */ ++ if (target_free_space >= ++ (unsigned)item_creation_overhead(&source)) { ++ target_free_space -= item_creation_overhead(&source); ++ iplug = item_plugin_by_coord(&source); ++ if (iplug->b.can_shift) { ++ shift->part_units = iplug->b.can_shift(target_free_space, ++ &source, ++ NULL, /* target */ ++ shift->pend, ++ &size, ++ want); ++ } else { ++ target_free_space = 0; ++ shift->part_units = 0; ++ size = 0; ++ } ++ } else { ++ target_free_space = 0; ++ shift->part_units = 0; ++ size = 0; ++ } ++ shift->part_bytes = size; ++ shift->shift_bytes += size; ++ ++ /* set @shift->real_stop to last unit of @source we can merge ++ to @shift->target */ ++ if (shift->part_units) { ++ shift->real_stop = source; ++ shift->real_stop.unit_pos = ++ (shift->part_units - source.unit_pos - ++ 1) * shift->pend; ++ assert("nikita-2082", shift->real_stop.unit_pos + 1); ++ } ++ ++ if (want != shift->part_units) ++ /* not everything wanted were shifted */ ++ return; ++ break; ++ } ++ ++ shift->everything = 1; ++} ++ ++static void ++copy_units(coord_t * target, coord_t * source, unsigned from, unsigned count, ++ shift_direction dir, unsigned free_space) ++{ ++ item_plugin *iplug; ++ ++ assert("nikita-1463", target != NULL); ++ assert("nikita-1464", source != NULL); ++ assert("nikita-1465", from + count <= coord_num_units(source)); ++ ++ iplug = item_plugin_by_coord(source); ++ assert("nikita-1468", iplug == item_plugin_by_coord(target)); ++ iplug->b.copy_units(target, source, from, count, dir, free_space); ++ ++ if (dir == SHIFT_RIGHT) { ++ /* FIXME-VS: this looks not necessary. update_item_key was ++ called already by copy_units method */ ++ reiser4_key split_key; ++ ++ assert("nikita-1469", target->unit_pos == 0); ++ ++ unit_key_by_coord(target, &split_key); ++ node_plugin_by_coord(target)->update_item_key(target, ++ &split_key, NULL); ++ } ++} ++ ++/* copy part of @shift->real_stop.node starting either from its beginning or ++ from its end and ending at @shift->real_stop to either the end or the ++ beginning of @shift->target */ ++static void copy(struct shift_params *shift, size_t node_header_size) ++{ ++ node40_header *nh; ++ coord_t from; ++ coord_t to; ++ item_header40 *from_ih, *to_ih; ++ int free_space_start; ++ int new_items; ++ unsigned old_items; ++ int old_offset; ++ unsigned i; ++ ++ nh = node40_node_header(shift->target); ++ free_space_start = nh40_get_free_space_start(nh); ++ old_items = nh40_get_num_items(nh); ++ new_items = shift->entire + (shift->part_units ? 1 : 0); ++ assert("vs-185", ++ shift->shift_bytes == ++ shift->merging_bytes + shift->entire_bytes + shift->part_bytes); ++ ++ from = shift->wish_stop; ++ ++ coord_init_first_unit(&to, shift->target); ++ ++ /* NOTE:NIKITA->VS not sure what I am doing: shift->target is empty, ++ hence to.between is set to EMPTY_NODE above. Looks like we want it ++ to be AT_UNIT. ++ ++ Oh, wonders of ->betweeness... ++ ++ */ ++ to.between = AT_UNIT; ++ ++ if (shift->pend == SHIFT_LEFT) { ++ /* copying to left */ ++ ++ coord_set_item_pos(&from, 0); ++ from_ih = node40_ih_at(from.node, 0); ++ ++ coord_set_item_pos(&to, ++ node40_num_of_items_internal(to.node) - 1); ++ if (shift->merging_units) { ++ /* expand last item, so that plugin methods will see ++ correct data */ ++ free_space_start += shift->merging_bytes; ++ nh40_set_free_space_start(nh, ++ (unsigned)free_space_start); ++ nh40_set_free_space(nh, ++ nh40_get_free_space(nh) - ++ shift->merging_bytes); ++ ++ /* appending last item of @target */ ++ copy_units(&to, &from, 0, /* starting from 0-th unit */ ++ shift->merging_units, SHIFT_LEFT, ++ shift->merging_bytes); ++ coord_inc_item_pos(&from); ++ from_ih--; ++ coord_inc_item_pos(&to); ++ } ++ ++ to_ih = node40_ih_at(shift->target, old_items); ++ if (shift->entire) { ++ /* copy @entire items entirely */ ++ ++ /* copy item headers */ ++ memcpy(to_ih - shift->entire + 1, ++ from_ih - shift->entire + 1, ++ shift->entire * sizeof(item_header40)); ++ /* update item header offset */ ++ old_offset = ih40_get_offset(from_ih); ++ /* AUDIT: Looks like if we calculate old_offset + free_space_start here instead of just old_offset, we can perform one "add" operation less per each iteration */ ++ for (i = 0; i < shift->entire; i++, to_ih--, from_ih--) ++ ih40_set_offset(to_ih, ++ ih40_get_offset(from_ih) - ++ old_offset + free_space_start); ++ ++ /* copy item bodies */ ++ memcpy(zdata(shift->target) + free_space_start, zdata(from.node) + old_offset, /*ih40_get_offset (from_ih), */ ++ shift->entire_bytes); ++ ++ coord_add_item_pos(&from, (int)shift->entire); ++ coord_add_item_pos(&to, (int)shift->entire); ++ } ++ ++ nh40_set_free_space_start(nh, ++ free_space_start + ++ shift->shift_bytes - ++ shift->merging_bytes); ++ nh40_set_free_space(nh, ++ nh40_get_free_space(nh) - ++ (shift->shift_bytes - shift->merging_bytes + ++ sizeof(item_header40) * new_items)); ++ ++ /* update node header */ ++ node40_set_num_items(shift->target, nh, old_items + new_items); ++ assert("vs-170", ++ nh40_get_free_space(nh) < znode_size(shift->target)); ++ ++ if (shift->part_units) { ++ /* copy heading part (@part units) of @source item as ++ a new item into @target->node */ ++ ++ /* copy item header of partially copied item */ ++ coord_set_item_pos(&to, ++ node40_num_of_items_internal(to.node) ++ - 1); ++ memcpy(to_ih, from_ih, sizeof(item_header40)); ++ ih40_set_offset(to_ih, ++ nh40_get_free_space_start(nh) - ++ shift->part_bytes); ++ if (item_plugin_by_coord(&to)->b.init) ++ item_plugin_by_coord(&to)->b.init(&to, &from, ++ NULL); ++ copy_units(&to, &from, 0, shift->part_units, SHIFT_LEFT, ++ shift->part_bytes); ++ } ++ ++ } else { ++ /* copying to right */ ++ ++ coord_set_item_pos(&from, ++ node40_num_of_items_internal(from.node) - 1); ++ from_ih = node40_ih_at_coord(&from); ++ ++ coord_set_item_pos(&to, 0); ++ ++ /* prepare space for new items */ ++ memmove(zdata(to.node) + node_header_size + ++ shift->shift_bytes, ++ zdata(to.node) + node_header_size, ++ free_space_start - node_header_size); ++ /* update item headers of moved items */ ++ to_ih = node40_ih_at(to.node, 0); ++ /* first item gets @merging_bytes longer. free space appears ++ at its beginning */ ++ if (!node_is_empty(to.node)) ++ ih40_set_offset(to_ih, ++ ih40_get_offset(to_ih) + ++ shift->shift_bytes - ++ shift->merging_bytes); ++ ++ for (i = 1; i < old_items; i++) ++ ih40_set_offset(to_ih - i, ++ ih40_get_offset(to_ih - i) + ++ shift->shift_bytes); ++ ++ /* move item headers to make space for new items */ ++ memmove(to_ih - old_items + 1 - new_items, ++ to_ih - old_items + 1, ++ sizeof(item_header40) * old_items); ++ to_ih -= (new_items - 1); ++ ++ nh40_set_free_space_start(nh, ++ free_space_start + ++ shift->shift_bytes); ++ nh40_set_free_space(nh, ++ nh40_get_free_space(nh) - ++ (shift->shift_bytes + ++ sizeof(item_header40) * new_items)); ++ ++ /* update node header */ ++ node40_set_num_items(shift->target, nh, old_items + new_items); ++ assert("vs-170", ++ nh40_get_free_space(nh) < znode_size(shift->target)); ++ ++ if (shift->merging_units) { ++ coord_add_item_pos(&to, new_items); ++ to.unit_pos = 0; ++ to.between = AT_UNIT; ++ /* prepend first item of @to */ ++ copy_units(&to, &from, ++ coord_last_unit_pos(&from) - ++ shift->merging_units + 1, ++ shift->merging_units, SHIFT_RIGHT, ++ shift->merging_bytes); ++ coord_dec_item_pos(&from); ++ from_ih++; ++ } ++ ++ if (shift->entire) { ++ /* copy @entire items entirely */ ++ ++ /* copy item headers */ ++ memcpy(to_ih, from_ih, ++ shift->entire * sizeof(item_header40)); ++ ++ /* update item header offset */ ++ old_offset = ++ ih40_get_offset(from_ih + shift->entire - 1); ++ /* AUDIT: old_offset + sizeof (node40_header) + shift->part_bytes calculation can be taken off the loop. */ ++ for (i = 0; i < shift->entire; i++, to_ih++, from_ih++) ++ ih40_set_offset(to_ih, ++ ih40_get_offset(from_ih) - ++ old_offset + ++ node_header_size + ++ shift->part_bytes); ++ /* copy item bodies */ ++ coord_add_item_pos(&from, -(int)(shift->entire - 1)); ++ memcpy(zdata(to.node) + node_header_size + ++ shift->part_bytes, item_by_coord_node40(&from), ++ shift->entire_bytes); ++ coord_dec_item_pos(&from); ++ } ++ ++ if (shift->part_units) { ++ coord_set_item_pos(&to, 0); ++ to.unit_pos = 0; ++ to.between = AT_UNIT; ++ /* copy heading part (@part units) of @source item as ++ a new item into @target->node */ ++ ++ /* copy item header of partially copied item */ ++ memcpy(to_ih, from_ih, sizeof(item_header40)); ++ ih40_set_offset(to_ih, node_header_size); ++ if (item_plugin_by_coord(&to)->b.init) ++ item_plugin_by_coord(&to)->b.init(&to, &from, ++ NULL); ++ copy_units(&to, &from, ++ coord_last_unit_pos(&from) - ++ shift->part_units + 1, shift->part_units, ++ SHIFT_RIGHT, shift->part_bytes); ++ } ++ } ++} ++ ++/* remove everything either before or after @fact_stop. Number of items ++ removed completely is returned */ ++static int delete_copied(struct shift_params *shift) ++{ ++ coord_t from; ++ coord_t to; ++ struct carry_cut_data cdata; ++ ++ if (shift->pend == SHIFT_LEFT) { ++ /* we were shifting to left, remove everything from the ++ beginning of @shift->wish_stop->node upto ++ @shift->wish_stop */ ++ coord_init_first_unit(&from, shift->real_stop.node); ++ to = shift->real_stop; ++ ++ /* store old coordinate of unit which will be first after ++ shift to left */ ++ shift->u.future_first = to; ++ coord_next_unit(&shift->u.future_first); ++ } else { ++ /* we were shifting to right, remove everything from ++ @shift->stop_coord upto to end of ++ @shift->stop_coord->node */ ++ from = shift->real_stop; ++ coord_init_last_unit(&to, from.node); ++ ++ /* store old coordinate of unit which will be last after ++ shift to right */ ++ shift->u.future_last = from; ++ coord_prev_unit(&shift->u.future_last); ++ } ++ ++ cdata.params.from = &from; ++ cdata.params.to = &to; ++ cdata.params.from_key = NULL; ++ cdata.params.to_key = NULL; ++ cdata.params.smallest_removed = NULL; ++ return cut_node40(&cdata, NULL); ++} ++ ++/* something was moved between @left and @right. Add carry operation to @info ++ list to have carry to update delimiting key between them */ ++static int ++prepare_for_update(znode * left, znode * right, carry_plugin_info * info) ++{ ++ carry_op *op; ++ carry_node *cn; ++ ++ if (info == NULL) ++ /* nowhere to send operation to. */ ++ return 0; ++ ++ if (!should_notify_parent(right)) ++ return 0; ++ ++ op = node_post_carry(info, COP_UPDATE, right, 1); ++ if (IS_ERR(op) || op == NULL) ++ return op ? PTR_ERR(op) : -EIO; ++ ++ if (left != NULL) { ++ carry_node *reference; ++ ++ if (info->doing) ++ reference = insert_carry_node(info->doing, ++ info->todo, left); ++ else ++ reference = op->node; ++ assert("nikita-2992", reference != NULL); ++ cn = reiser4_add_carry(info->todo, POOLO_BEFORE, reference); ++ if (IS_ERR(cn)) ++ return PTR_ERR(cn); ++ cn->parent = 1; ++ cn->node = left; ++ if (ZF_ISSET(left, JNODE_ORPHAN)) ++ cn->left_before = 1; ++ op->u.update.left = cn; ++ } else ++ op->u.update.left = NULL; ++ return 0; ++} ++ ++/* plugin->u.node.prepare_removal ++ to delete a pointer to @empty from the tree add corresponding carry ++ operation (delete) to @info list */ ++int prepare_removal_node40(znode * empty, carry_plugin_info * info) ++{ ++ carry_op *op; ++ reiser4_tree *tree; ++ ++ if (!should_notify_parent(empty)) ++ return 0; ++ /* already on a road to Styx */ ++ if (ZF_ISSET(empty, JNODE_HEARD_BANSHEE)) ++ return 0; ++ op = node_post_carry(info, COP_DELETE, empty, 1); ++ if (IS_ERR(op) || op == NULL) ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ ++ op->u.delete.child = NULL; ++ op->u.delete.flags = 0; ++ ++ /* fare thee well */ ++ tree = znode_get_tree(empty); ++ read_lock_tree(); ++ write_lock_dk(tree); ++ znode_set_ld_key(empty, znode_get_rd_key(empty)); ++ if (znode_is_left_connected(empty) && empty->left) ++ znode_set_rd_key(empty->left, znode_get_rd_key(empty)); ++ write_unlock_dk(tree); ++ read_unlock_tree(); ++ ++ ZF_SET(empty, JNODE_HEARD_BANSHEE); ++ return 0; ++} ++ ++/* something were shifted from @insert_coord->node to @shift->target, update ++ @insert_coord correspondingly */ ++static void ++adjust_coord(coord_t * insert_coord, struct shift_params *shift, int removed, ++ int including_insert_coord) ++{ ++ /* item plugin was invalidated by shifting */ ++ coord_clear_iplug(insert_coord); ++ ++ if (node_is_empty(shift->wish_stop.node)) { ++ assert("vs-242", shift->everything); ++ if (including_insert_coord) { ++ if (shift->pend == SHIFT_RIGHT) { ++ /* set @insert_coord before first unit of ++ @shift->target node */ ++ coord_init_before_first_item(insert_coord, ++ shift->target); ++ } else { ++ /* set @insert_coord after last in target node */ ++ coord_init_after_last_item(insert_coord, ++ shift->target); ++ } ++ } else { ++ /* set @insert_coord inside of empty node. There is ++ only one possible coord within an empty ++ node. init_first_unit will set that coord */ ++ coord_init_first_unit(insert_coord, ++ shift->wish_stop.node); ++ } ++ return; ++ } ++ ++ if (shift->pend == SHIFT_RIGHT) { ++ /* there was shifting to right */ ++ if (shift->everything) { ++ /* everything wanted was shifted */ ++ if (including_insert_coord) { ++ /* @insert_coord is set before first unit of ++ @to node */ ++ coord_init_before_first_item(insert_coord, ++ shift->target); ++ insert_coord->between = BEFORE_UNIT; ++ } else { ++ /* @insert_coord is set after last unit of ++ @insert->node */ ++ coord_init_last_unit(insert_coord, ++ shift->wish_stop.node); ++ insert_coord->between = AFTER_UNIT; ++ } ++ } ++ return; ++ } ++ ++ /* there was shifting to left */ ++ if (shift->everything) { ++ /* everything wanted was shifted */ ++ if (including_insert_coord) { ++ /* @insert_coord is set after last unit in @to node */ ++ coord_init_after_last_item(insert_coord, shift->target); ++ } else { ++ /* @insert_coord is set before first unit in the same ++ node */ ++ coord_init_before_first_item(insert_coord, ++ shift->wish_stop.node); ++ } ++ return; ++ } ++ ++ /* FIXME-VS: the code below is complicated because with between == ++ AFTER_ITEM unit_pos is set to 0 */ ++ ++ if (!removed) { ++ /* no items were shifted entirely */ ++ assert("vs-195", shift->merging_units == 0 ++ || shift->part_units == 0); ++ ++ if (shift->real_stop.item_pos == insert_coord->item_pos) { ++ if (shift->merging_units) { ++ if (insert_coord->between == AFTER_UNIT) { ++ assert("nikita-1441", ++ insert_coord->unit_pos >= ++ shift->merging_units); ++ insert_coord->unit_pos -= ++ shift->merging_units; ++ } else if (insert_coord->between == BEFORE_UNIT) { ++ assert("nikita-2090", ++ insert_coord->unit_pos > ++ shift->merging_units); ++ insert_coord->unit_pos -= ++ shift->merging_units; ++ } ++ ++ assert("nikita-2083", ++ insert_coord->unit_pos + 1); ++ } else { ++ if (insert_coord->between == AFTER_UNIT) { ++ assert("nikita-1442", ++ insert_coord->unit_pos >= ++ shift->part_units); ++ insert_coord->unit_pos -= ++ shift->part_units; ++ } else if (insert_coord->between == BEFORE_UNIT) { ++ assert("nikita-2089", ++ insert_coord->unit_pos > ++ shift->part_units); ++ insert_coord->unit_pos -= ++ shift->part_units; ++ } ++ ++ assert("nikita-2084", ++ insert_coord->unit_pos + 1); ++ } ++ } ++ return; ++ } ++ ++ /* we shifted to left and there was no enough space for everything */ ++ switch (insert_coord->between) { ++ case AFTER_UNIT: ++ case BEFORE_UNIT: ++ if (shift->real_stop.item_pos == insert_coord->item_pos) ++ insert_coord->unit_pos -= shift->part_units; ++ /* fall through */ ++ case AFTER_ITEM: ++ coord_add_item_pos(insert_coord, -removed); ++ break; ++ default: ++ impossible("nikita-2087", "not ready"); ++ } ++ assert("nikita-2085", insert_coord->unit_pos + 1); ++} ++ ++static int call_shift_hooks(struct shift_params *shift) ++{ ++ unsigned i, shifted; ++ coord_t coord; ++ item_plugin *iplug; ++ ++ assert("vs-275", !node_is_empty(shift->target)); ++ ++ /* number of items shift touches */ ++ shifted = ++ shift->entire + (shift->merging_units ? 1 : 0) + ++ (shift->part_units ? 1 : 0); ++ ++ if (shift->pend == SHIFT_LEFT) { ++ /* moved items are at the end */ ++ coord_init_last_unit(&coord, shift->target); ++ coord.unit_pos = 0; ++ ++ assert("vs-279", shift->pend == 1); ++ for (i = 0; i < shifted; i++) { ++ unsigned from, count; ++ ++ iplug = item_plugin_by_coord(&coord); ++ if (i == 0 && shift->part_units) { ++ assert("vs-277", ++ coord_num_units(&coord) == ++ shift->part_units); ++ count = shift->part_units; ++ from = 0; ++ } else if (i == shifted - 1 && shift->merging_units) { ++ count = shift->merging_units; ++ from = coord_num_units(&coord) - count; ++ } else { ++ count = coord_num_units(&coord); ++ from = 0; ++ } ++ ++ if (iplug->b.shift_hook) { ++ iplug->b.shift_hook(&coord, from, count, ++ shift->wish_stop.node); ++ } ++ coord_add_item_pos(&coord, -shift->pend); ++ } ++ } else { ++ /* moved items are at the beginning */ ++ coord_init_first_unit(&coord, shift->target); ++ ++ assert("vs-278", shift->pend == -1); ++ for (i = 0; i < shifted; i++) { ++ unsigned from, count; ++ ++ iplug = item_plugin_by_coord(&coord); ++ if (i == 0 && shift->part_units) { ++ assert("vs-277", ++ coord_num_units(&coord) == ++ shift->part_units); ++ count = coord_num_units(&coord); ++ from = 0; ++ } else if (i == shifted - 1 && shift->merging_units) { ++ count = shift->merging_units; ++ from = 0; ++ } else { ++ count = coord_num_units(&coord); ++ from = 0; ++ } ++ ++ if (iplug->b.shift_hook) { ++ iplug->b.shift_hook(&coord, from, count, ++ shift->wish_stop.node); ++ } ++ coord_add_item_pos(&coord, -shift->pend); ++ } ++ } ++ ++ return 0; ++} ++ ++/* shift to left is completed. Return 1 if unit @old was moved to left neighbor */ ++static int ++unit_moved_left(const struct shift_params *shift, const coord_t * old) ++{ ++ assert("vs-944", shift->real_stop.node == old->node); ++ ++ if (shift->real_stop.item_pos < old->item_pos) ++ return 0; ++ if (shift->real_stop.item_pos == old->item_pos) { ++ if (shift->real_stop.unit_pos < old->unit_pos) ++ return 0; ++ } ++ return 1; ++} ++ ++/* shift to right is completed. Return 1 if unit @old was moved to right ++ neighbor */ ++static int ++unit_moved_right(const struct shift_params *shift, const coord_t * old) ++{ ++ assert("vs-944", shift->real_stop.node == old->node); ++ ++ if (shift->real_stop.item_pos > old->item_pos) ++ return 0; ++ if (shift->real_stop.item_pos == old->item_pos) { ++ if (shift->real_stop.unit_pos > old->unit_pos) ++ return 0; ++ } ++ return 1; ++} ++ ++/* coord @old was set in node from which shift was performed. What was shifted ++ is stored in @shift. Update @old correspondingly to performed shift */ ++static coord_t *adjust_coord2(const struct shift_params *shift, ++ const coord_t * old, coord_t * new) ++{ ++ coord_clear_iplug(new); ++ new->between = old->between; ++ ++ coord_clear_iplug(new); ++ if (old->node == shift->target) { ++ if (shift->pend == SHIFT_LEFT) { ++ /* coord which is set inside of left neighbor does not ++ change during shift to left */ ++ coord_dup(new, old); ++ return new; ++ } ++ new->node = old->node; ++ coord_set_item_pos(new, ++ old->item_pos + shift->entire + ++ (shift->part_units ? 1 : 0)); ++ new->unit_pos = old->unit_pos; ++ if (old->item_pos == 0 && shift->merging_units) ++ new->unit_pos += shift->merging_units; ++ return new; ++ } ++ ++ assert("vs-977", old->node == shift->wish_stop.node); ++ if (shift->pend == SHIFT_LEFT) { ++ if (unit_moved_left(shift, old)) { ++ /* unit @old moved to left neighbor. Calculate its ++ coordinate there */ ++ new->node = shift->target; ++ coord_set_item_pos(new, ++ node_num_items(shift->target) - ++ shift->entire - ++ (shift->part_units ? 1 : 0) + ++ old->item_pos); ++ ++ new->unit_pos = old->unit_pos; ++ if (shift->merging_units) { ++ coord_dec_item_pos(new); ++ if (old->item_pos == 0) { ++ /* unit_pos only changes if item got ++ merged */ ++ new->unit_pos = ++ coord_num_units(new) - ++ (shift->merging_units - ++ old->unit_pos); ++ } ++ } ++ } else { ++ /* unit @old did not move to left neighbor. ++ ++ Use _nocheck, because @old is outside of its node. ++ */ ++ coord_dup_nocheck(new, old); ++ coord_add_item_pos(new, ++ -shift->u.future_first.item_pos); ++ if (new->item_pos == 0) ++ new->unit_pos -= shift->u.future_first.unit_pos; ++ } ++ } else { ++ if (unit_moved_right(shift, old)) { ++ /* unit @old moved to right neighbor */ ++ new->node = shift->target; ++ coord_set_item_pos(new, ++ old->item_pos - ++ shift->real_stop.item_pos); ++ if (new->item_pos == 0) { ++ /* unit @old might change unit pos */ ++ coord_set_item_pos(new, ++ old->unit_pos - ++ shift->real_stop.unit_pos); ++ } ++ } else { ++ /* unit @old did not move to right neighbor, therefore ++ it did not change */ ++ coord_dup(new, old); ++ } ++ } ++ coord_set_iplug(new, item_plugin_by_coord(new)); ++ return new; ++} ++ ++/* this is called when shift is completed (something of source node is copied ++ to target and deleted in source) to update all taps set in current ++ context */ ++static void update_taps(const struct shift_params *shift) ++{ ++ tap_t *tap; ++ coord_t new; ++ ++ for_all_taps(tap) { ++ /* update only taps set to nodes participating in shift */ ++ if (tap->coord->node == shift->wish_stop.node ++ || tap->coord->node == shift->target) ++ tap_to_coord(tap, ++ adjust_coord2(shift, tap->coord, &new)); ++ } ++} ++ ++#if REISER4_DEBUG ++ ++struct shift_check { ++ reiser4_key key; ++ __u16 plugin_id; ++ union { ++ __u64 bytes; ++ __u64 entries; ++ void *unused; ++ } u; ++}; ++ ++void *shift_check_prepare(const znode * left, const znode * right) ++{ ++ pos_in_node_t i, nr_items; ++ int mergeable; ++ struct shift_check *data; ++ item_header40 *ih; ++ ++ if (node_is_empty(left) || node_is_empty(right)) ++ mergeable = 0; ++ else { ++ coord_t l, r; ++ ++ coord_init_last_unit(&l, left); ++ coord_init_first_unit(&r, right); ++ mergeable = are_items_mergeable(&l, &r); ++ } ++ nr_items = ++ node40_num_of_items_internal(left) + ++ node40_num_of_items_internal(right) - (mergeable ? 1 : 0); ++ data = ++ kmalloc(sizeof(struct shift_check) * nr_items, ++ reiser4_ctx_gfp_mask_get()); ++ if (data != NULL) { ++ coord_t coord; ++ pos_in_node_t item_pos; ++ ++ coord_init_first_unit(&coord, left); ++ i = 0; ++ ++ for (item_pos = 0; ++ item_pos < node40_num_of_items_internal(left); ++ item_pos++) { ++ ++ coord_set_item_pos(&coord, item_pos); ++ ih = node40_ih_at_coord(&coord); ++ ++ data[i].key = ih->key; ++ data[i].plugin_id = le16_to_cpu(get_unaligned(&ih->plugin_id)); ++ switch (data[i].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ data[i].u.bytes = coord_num_units(&coord); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ data[i].u.bytes = ++ reiser4_extent_size(&coord); ++ break; ++ case COMPOUND_DIR_ID: ++ data[i].u.entries = coord_num_units(&coord); ++ break; ++ default: ++ data[i].u.unused = NULL; ++ break; ++ } ++ i++; ++ } ++ ++ coord_init_first_unit(&coord, right); ++ ++ if (mergeable) { ++ assert("vs-1609", i != 0); ++ ++ ih = node40_ih_at_coord(&coord); ++ ++ assert("vs-1589", ++ data[i - 1].plugin_id == ++ le16_to_cpu(get_unaligned(&ih->plugin_id))); ++ switch (data[i - 1].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ data[i - 1].u.bytes += coord_num_units(&coord); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ data[i - 1].u.bytes += ++ reiser4_extent_size(&coord); ++ break; ++ case COMPOUND_DIR_ID: ++ data[i - 1].u.entries += ++ coord_num_units(&coord); ++ break; ++ default: ++ impossible("vs-1605", "wrong mergeable item"); ++ break; ++ } ++ item_pos = 1; ++ } else ++ item_pos = 0; ++ for (; item_pos < node40_num_of_items_internal(right); ++ item_pos++) { ++ ++ assert("vs-1604", i < nr_items); ++ coord_set_item_pos(&coord, item_pos); ++ ih = node40_ih_at_coord(&coord); ++ ++ data[i].key = ih->key; ++ data[i].plugin_id = le16_to_cpu(get_unaligned(&ih->plugin_id)); ++ switch (data[i].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ data[i].u.bytes = coord_num_units(&coord); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ data[i].u.bytes = ++ reiser4_extent_size(&coord); ++ break; ++ case COMPOUND_DIR_ID: ++ data[i].u.entries = coord_num_units(&coord); ++ break; ++ default: ++ data[i].u.unused = NULL; ++ break; ++ } ++ i++; ++ } ++ assert("vs-1606", i == nr_items); ++ } ++ return data; ++} ++ ++void shift_check(void *vp, const znode * left, const znode * right) ++{ ++ pos_in_node_t i, nr_items; ++ coord_t coord; ++ __u64 last_bytes; ++ int mergeable; ++ item_header40 *ih; ++ pos_in_node_t item_pos; ++ struct shift_check *data; ++ ++ data = (struct shift_check *)vp; ++ ++ if (data == NULL) ++ return; ++ ++ if (node_is_empty(left) || node_is_empty(right)) ++ mergeable = 0; ++ else { ++ coord_t l, r; ++ ++ coord_init_last_unit(&l, left); ++ coord_init_first_unit(&r, right); ++ mergeable = are_items_mergeable(&l, &r); ++ } ++ ++ nr_items = ++ node40_num_of_items_internal(left) + ++ node40_num_of_items_internal(right) - (mergeable ? 1 : 0); ++ ++ i = 0; ++ last_bytes = 0; ++ ++ coord_init_first_unit(&coord, left); ++ ++ for (item_pos = 0; item_pos < node40_num_of_items_internal(left); ++ item_pos++) { ++ ++ coord_set_item_pos(&coord, item_pos); ++ ih = node40_ih_at_coord(&coord); ++ ++ assert("vs-1611", i == item_pos); ++ assert("vs-1590", keyeq(&ih->key, &data[i].key)); ++ assert("vs-1591", ++ le16_to_cpu(get_unaligned(&ih->plugin_id)) == data[i].plugin_id); ++ if ((i < (node40_num_of_items_internal(left) - 1)) ++ || !mergeable) { ++ switch (data[i].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ assert("vs-1592", ++ data[i].u.bytes == ++ coord_num_units(&coord)); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ assert("vs-1593", ++ data[i].u.bytes == ++ reiser4_extent_size(&coord)); ++ break; ++ case COMPOUND_DIR_ID: ++ assert("vs-1594", ++ data[i].u.entries == ++ coord_num_units(&coord)); ++ break; ++ default: ++ break; ++ } ++ } ++ if (item_pos == (node40_num_of_items_internal(left) - 1) ++ && mergeable) { ++ switch (data[i].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ last_bytes = coord_num_units(&coord); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ last_bytes = reiser4_extent_size(&coord); ++ break; ++ case COMPOUND_DIR_ID: ++ last_bytes = coord_num_units(&coord); ++ break; ++ default: ++ impossible("vs-1595", "wrong mergeable item"); ++ break; ++ } ++ } ++ i++; ++ } ++ ++ coord_init_first_unit(&coord, right); ++ if (mergeable) { ++ ih = node40_ih_at_coord(&coord); ++ ++ assert("vs-1589", ++ data[i - 1].plugin_id == le16_to_cpu(get_unaligned(&ih->plugin_id))); ++ assert("vs-1608", last_bytes != 0); ++ switch (data[i - 1].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ assert("vs-1596", ++ data[i - 1].u.bytes == ++ last_bytes + coord_num_units(&coord)); ++ break; ++ ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ assert("vs-1597", ++ data[i - 1].u.bytes == ++ last_bytes + reiser4_extent_size(&coord)); ++ break; ++ ++ case COMPOUND_DIR_ID: ++ assert("vs-1598", ++ data[i - 1].u.bytes == ++ last_bytes + coord_num_units(&coord)); ++ break; ++ default: ++ impossible("vs-1599", "wrong mergeable item"); ++ break; ++ } ++ item_pos = 1; ++ } else ++ item_pos = 0; ++ ++ for (; item_pos < node40_num_of_items_internal(right); item_pos++) { ++ ++ coord_set_item_pos(&coord, item_pos); ++ ih = node40_ih_at_coord(&coord); ++ ++ assert("vs-1612", keyeq(&ih->key, &data[i].key)); ++ assert("vs-1613", ++ le16_to_cpu(get_unaligned(&ih->plugin_id)) == data[i].plugin_id); ++ switch (data[i].plugin_id) { ++ case CTAIL_ID: ++ case FORMATTING_ID: ++ assert("vs-1600", ++ data[i].u.bytes == coord_num_units(&coord)); ++ break; ++ case EXTENT40_POINTER_ID: ++ case EXTENT41_POINTER_ID: ++ assert("vs-1601", ++ data[i].u.bytes == reiser4_extent_size(&coord)); ++ break; ++ case COMPOUND_DIR_ID: ++ assert("vs-1602", ++ data[i].u.entries == coord_num_units(&coord)); ++ break; ++ default: ++ break; ++ } ++ i++; ++ } ++ ++ assert("vs-1603", i == nr_items); ++ kfree(data); ++} ++ ++#endif ++ ++/* ++ * common part of ->shift() for all nodes, ++ * which contain node40_header at the beginning and ++ * the table of item headers at the end ++ */ ++int shift_node40_common(coord_t *from, znode *to, ++ shift_direction pend, ++ int delete_child, /* if @from->node becomes empty, ++ * it will be deleted from the ++ * tree if this is set to 1 */ ++ int including_stop_coord, ++ carry_plugin_info *info, ++ size_t node_header_size) ++{ ++ struct shift_params shift; ++ int result; ++ znode *left, *right; ++ znode *source; ++ int target_empty; ++ ++ assert("nikita-2161", coord_check(from)); ++ ++ memset(&shift, 0, sizeof(shift)); ++ shift.pend = pend; ++ shift.wish_stop = *from; ++ shift.target = to; ++ ++ assert("nikita-1473", znode_is_write_locked(from->node)); ++ assert("nikita-1474", znode_is_write_locked(to)); ++ ++ source = from->node; ++ ++ /* set @shift.wish_stop to rightmost/leftmost unit among units we want ++ shifted */ ++ if (pend == SHIFT_LEFT) { ++ result = coord_set_to_left(&shift.wish_stop); ++ left = to; ++ right = from->node; ++ } else { ++ result = coord_set_to_right(&shift.wish_stop); ++ left = from->node; ++ right = to; ++ } ++ ++ if (result) { ++ /* move insertion coord even if there is nothing to move */ ++ if (including_stop_coord) { ++ /* move insertion coord (@from) */ ++ if (pend == SHIFT_LEFT) { ++ /* after last item in target node */ ++ coord_init_after_last_item(from, to); ++ } else { ++ /* before first item in target node */ ++ coord_init_before_first_item(from, to); ++ } ++ } ++ ++ if (delete_child && node_is_empty(shift.wish_stop.node)) ++ result = ++ prepare_removal_node40(shift.wish_stop.node, info); ++ else ++ result = 0; ++ /* there is nothing to shift */ ++ assert("nikita-2078", coord_check(from)); ++ return result; ++ } ++ ++ target_empty = node_is_empty(to); ++ ++ /* when first node plugin with item body compression is implemented, ++ this must be changed to call node specific plugin */ ++ ++ /* shift->stop_coord is updated to last unit which really will be ++ shifted */ ++ estimate_shift(&shift, get_current_context()); ++ if (!shift.shift_bytes) { ++ /* we could not shift anything */ ++ assert("nikita-2079", coord_check(from)); ++ return 0; ++ } ++ ++ copy(&shift, node_header_size); ++ ++ /* result value of this is important. It is used by adjust_coord below */ ++ result = delete_copied(&shift); ++ ++ assert("vs-1610", result >= 0); ++ assert("vs-1471", ++ ((reiser4_context *) current->journal_info)->magic == ++ context_magic); ++ ++ /* item which has been moved from one node to another might want to do ++ something on that event. This can be done by item's shift_hook ++ method, which will be now called for every moved items */ ++ call_shift_hooks(&shift); ++ ++ assert("vs-1472", ++ ((reiser4_context *) current->journal_info)->magic == ++ context_magic); ++ ++ update_taps(&shift); ++ ++ assert("vs-1473", ++ ((reiser4_context *) current->journal_info)->magic == ++ context_magic); ++ ++ /* adjust @from pointer in accordance with @including_stop_coord flag ++ and amount of data which was really shifted */ ++ adjust_coord(from, &shift, result, including_stop_coord); ++ ++ if (target_empty) ++ /* ++ * items were shifted into empty node. Update delimiting key. ++ */ ++ result = prepare_for_update(NULL, left, info); ++ ++ /* add update operation to @info, which is the list of operations to ++ be performed on a higher level */ ++ result = prepare_for_update(left, right, info); ++ if (!result && node_is_empty(source) && delete_child) { ++ /* all contents of @from->node is moved to @to and @from->node ++ has to be removed from the tree, so, on higher level we ++ will be removing the pointer to node @from->node */ ++ result = prepare_removal_node40(source, info); ++ } ++ assert("nikita-2080", coord_check(from)); ++ return result ? result : (int)shift.shift_bytes; ++} ++ ++/* ++ * plugin->u.node.shift ++ * look for description of this method in plugin/node/node.h ++ */ ++int shift_node40(coord_t *from, znode *to, ++ shift_direction pend, ++ int delete_child, /* if @from->node becomes empty, ++ * it will be deleted from the ++ * tree if this is set to 1 */ ++ int including_stop_coord, ++ carry_plugin_info *info) ++{ ++ return shift_node40_common(from, to, pend, delete_child, ++ including_stop_coord, info, ++ sizeof(node40_header)); ++} ++ ++/* plugin->u.node.fast_insert() ++ look for description of this method in plugin/node/node.h */ ++int fast_insert_node40(const coord_t * coord UNUSED_ARG /* node to query */ ) ++{ ++ return 1; ++} ++ ++/* plugin->u.node.fast_paste() ++ look for description of this method in plugin/node/node.h */ ++int fast_paste_node40(const coord_t * coord UNUSED_ARG /* node to query */ ) ++{ ++ return 1; ++} ++ ++/* plugin->u.node.fast_cut() ++ look for description of this method in plugin/node/node.h */ ++int fast_cut_node40(const coord_t * coord UNUSED_ARG /* node to query */ ) ++{ ++ return 1; ++} ++ ++/* plugin->u.node.modify - not defined */ ++ ++/* plugin->u.node.max_item_size */ ++int max_item_size_node40(void) ++{ ++ return reiser4_get_current_sb()->s_blocksize - sizeof(node40_header) - ++ sizeof(item_header40); ++} ++ ++/* plugin->u.node.set_item_plugin */ ++int set_item_plugin_node40(coord_t *coord, item_id id) ++{ ++ item_header40 *ih; ++ ++ ih = node40_ih_at_coord(coord); ++ put_unaligned(cpu_to_le16(id), &ih->plugin_id); ++ coord->iplugid = id; ++ return 0; ++} ++ ++/* ++ * Merge neighboring items @left and @right located on the same node. ++ * In the result number of items in the node gets always decremented. ++ */ ++void merge_items_node40(coord_t *left, coord_t *right) ++{ ++ znode *node; ++ node40_header *nh; ++ item_header40 *ih; ++ size_t freed = 0; ++#if REISER4_DEBUG ++ //const char *error; ++ int units_before_merge; ++ ++ assert("edward-2077", left->node == right->node); ++ assert("edward-2078", coord_is_existing_item(left)); ++ assert("edward-2079", coord_is_existing_item(right)); ++ assert("edward-2080", right->item_pos == left->item_pos + 1); ++ assert("edward-2081", ++ plugin_by_coord_node40(left) == ++ plugin_by_coord_node40(right)); ++ assert("edward-2082", are_items_mergeable(left, right)); ++ ++ units_before_merge = coord_num_units(left) + coord_num_units(right); ++#endif ++ node = left->node; ++ nh = node40_node_header(node); ++ /* ++ * Try to merge units at the junction. It may release some space. ++ */ ++ if (plugin_by_coord_node40(left)->b.merge_units) ++ freed = plugin_by_coord_node40(left)->b.merge_units(left, ++ right); ++ if (freed && nh40_get_num_items(nh) > right->item_pos + 1) { ++ /* ++ * Move bodies of all items at the right of @right to the left ++ */ ++ int i; ++ char *tail; ++ size_t tail_size; ++ ++ ih = node40_ih_at(node, right->item_pos + 1); ++ tail = zdata(node) + ih40_get_offset(ih); ++ tail_size = nh40_get_free_space_start(nh) - ih40_get_offset(ih); ++ memmove(tail - freed, tail, tail_size); ++ /* ++ * Update offsets of moved items ++ */ ++ for (i = right->item_pos + 1; ++ i < nh40_get_num_items(nh); i++) { ++ ih = node40_ih_at(node, i); ++ ih40_set_offset(ih, ih40_get_offset(ih) - freed); ++ } ++ } ++ /* ++ * Remove all records about the @right from the node. ++ * ++ * Move all item headers at the left from @ih_right ++ * one position to the @right. ++ */ ++ ih = node40_ih_at(node, nh40_get_num_items(nh) - 1); ++ memmove(ih + 1, ih, sizeof(item_header40) * ++ (nh40_get_num_items(nh) - (right->item_pos + 1))); ++ /* ++ * update_node_header ++ */ ++ nh40_set_free_space(nh, nh40_get_free_space(nh) + freed + ++ sizeof(item_header40)); ++ nh40_set_free_space_start(nh, nh40_get_free_space_start(nh) - freed); ++ node40_set_num_items(node, nh, nh40_get_num_items(nh) - 1); ++#if 0 ++ assert("edward-2083", ++ check_node40(node, REISER4_NODE_TREE_STABLE, &error) == 0); ++#endif ++ assert("edward-2133", coord_num_units(left) == ++ freed ? units_before_merge - 1 : units_before_merge); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node40.h linux-5.10.2/fs/reiser4/plugin/node/node40.h +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node40.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node40.h 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,131 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined( __REISER4_NODE40_H__ ) ++#define __REISER4_NODE40_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "node.h" ++ ++#include ++ ++/* format of node header for 40 node layouts. Keep bloat out of this struct. */ ++typedef struct node40_header { ++ /* identifier of node plugin. Must be located at the very beginning ++ of a node. */ ++ common_node_header common_header; /* this is 16 bits */ ++ /* number of items. Should be first element in the node header, ++ because we haven't yet finally decided whether it shouldn't go into ++ common_header. ++ */ ++/* NIKITA-FIXME-HANS: Create a macro such that if there is only one ++ * node format at compile time, and it is this one, accesses do not function dereference when ++ * accessing these fields (and otherwise they do). Probably 80% of users will only have one node format at a time throughout the life of reiser4. */ ++ d16 nr_items; ++ /* free space in node measured in bytes */ ++ d16 free_space; ++ /* offset to start of free space in node */ ++ d16 free_space_start; ++ /* for reiser4_fsck. When information about what is a free ++ block is corrupted, and we try to recover everything even ++ if marked as freed, then old versions of data may ++ duplicate newer versions, and this field allows us to ++ restore the newer version. Also useful for when users ++ who don't have the new trashcan installed on their linux distro ++ delete the wrong files and send us desperate emails ++ offering $25 for them back. */ ++ ++ /* magic field we need to tell formatted nodes NIKITA-FIXME-HANS: improve this comment */ ++ d32 magic; ++ /* flushstamp is made of mk_id and write_counter. mk_id is an ++ id generated randomly at mkreiserfs time. So we can just ++ skip all nodes with different mk_id. write_counter is d64 ++ incrementing counter of writes on disk. It is used for ++ choosing the newest data at fsck time. NIKITA-FIXME-HANS: why was field name changed but not comment? */ ++ ++ d32 mkfs_id; ++ d64 flush_id; ++ /* node flags to be used by fsck (reiser4ck or reiser4fsck?) ++ and repacker NIKITA-FIXME-HANS: say more or reference elsewhere that says more */ ++ d16 flags; ++ ++ /* 1 is leaf level, 2 is twig level, root is the numerically ++ largest level */ ++ d8 level; ++ ++ d8 pad; ++} PACKED node40_header; ++ ++/* item headers are not standard across all node layouts, pass ++ pos_in_node to functions instead */ ++typedef struct item_header40 { ++ /* key of item */ ++ /* 0 */ reiser4_key key; ++ /* offset from start of a node measured in 8-byte chunks */ ++ /* 24 */ d16 offset; ++ /* 26 */ d16 flags; ++ /* 28 */ d16 plugin_id; ++} PACKED item_header40; ++ ++size_t item_overhead_node40(const znode * node, flow_t * aflow); ++size_t free_space_node40(znode * node); ++node_search_result lookup_node40(znode * node, const reiser4_key * key, ++ lookup_bias bias, coord_t * coord); ++int num_of_items_node40(const znode * node); ++char *item_by_coord_node40(const coord_t * coord); ++int length_by_coord_node40(const coord_t * coord); ++item_plugin *plugin_by_coord_node40(const coord_t * coord); ++reiser4_key *key_at_node40(const coord_t * coord, reiser4_key * key); ++size_t estimate_node40(znode * node); ++int check_node40(const znode * node, __u32 flags, const char **error); ++int parse_node40_common(znode *node, const __u32 magic); ++int parse_node40(znode * node); ++int init_node40_common(znode *node, node_plugin *nplug, ++ size_t node_header_size, const __u32 magic); ++int init_node40(znode *node); ++ ++#ifdef GUESS_EXISTS ++int guess_node40_common(const znode *node, reiser4_node_id id, ++ const __u32 magic); ++int guess_node40(const znode *node); ++#endif ++ ++void change_item_size_node40(coord_t * coord, int by); ++int create_item_node40(coord_t * target, const reiser4_key * key, ++ reiser4_item_data * data, carry_plugin_info * info); ++void update_item_key_node40(coord_t * target, const reiser4_key * key, ++ carry_plugin_info * info); ++int kill_node40(struct carry_kill_data *, carry_plugin_info *); ++int cut_node40(struct carry_cut_data *, carry_plugin_info *); ++int shift_node40_common(coord_t *from, znode *to, shift_direction pend, ++ int delete_child, int including_stop_coord, ++ carry_plugin_info *info, size_t nh_size); ++int shift_node40(coord_t *from, znode *to, shift_direction pend, ++ int delete_child, int including_stop_coord, ++ carry_plugin_info *info); ++void merge_items_node40(coord_t *left, coord_t *right); ++int fast_insert_node40(const coord_t * coord); ++int fast_paste_node40(const coord_t * coord); ++int fast_cut_node40(const coord_t * coord); ++int max_item_size_node40(void); ++int prepare_removal_node40(znode * empty, carry_plugin_info * info); ++int set_item_plugin_node40(coord_t * coord, item_id id); ++int shrink_item_node40(coord_t * coord, int delta); ++ ++#if REISER4_DEBUG ++void *shift_check_prepare(const znode *left, const znode *right); ++void shift_check(void *vp, const znode *left, const znode *right); ++#endif ++ ++/* __REISER4_NODE40_H__ */ ++#endif ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node41.c linux-5.10.2/fs/reiser4/plugin/node/node41.c +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node41.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node41.c 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,138 @@ ++/* ++ * Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README ++ */ ++ ++#include "../../debug.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "../plugin_header.h" ++#include "../item/item.h" ++#include "node.h" ++#include "node41.h" ++#include "../plugin.h" ++#include "../../jnode.h" ++#include "../../znode.h" ++#include "../../pool.h" ++#include "../../carry.h" ++#include "../../tap.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../../checksum.h" ++#include "../../reiser4.h" ++ ++#include ++#include ++#include ++ ++/* ++ * node41 layout it almost the same as node40: ++ * node41_header is at the beginning and a table of item headers ++ * is at the end. Ther difference is that node41_header contains ++ * a 32-bit checksum (see node41.h) ++ */ ++ ++static const __u32 REISER4_NODE41_MAGIC = 0x19051966; ++ ++static inline node41_header *node41_node_header(const znode *node) ++{ ++ assert("edward-1634", node != NULL); ++ assert("edward-1635", znode_page(node) != NULL); ++ assert("edward-1636", zdata(node) != NULL); ++ ++ return (node41_header *)zdata(node); ++} ++ ++int csum_node41(znode *node, int check) ++{ ++ __u32 cpu_csum; ++ ++ cpu_csum = reiser4_crc32c(get_current_super_private()->csum_tfm, ++ ~0, ++ zdata(node), ++ sizeof(struct node40_header)); ++ cpu_csum = reiser4_crc32c(get_current_super_private()->csum_tfm, ++ cpu_csum, ++ zdata(node) + sizeof(struct node41_header), ++ reiser4_get_current_sb()->s_blocksize - ++ sizeof(node41_header)); ++ if (check) ++ return cpu_csum == nh41_get_csum(node41_node_header(node)); ++ else { ++ nh41_set_csum(node41_node_header(node), cpu_csum); ++ return 1; ++ } ++} ++ ++/* ++ * plugin->u.node.parse ++ * look for description of this method in plugin/node/node.h ++ */ ++int parse_node41(znode *node /* node to parse */) ++{ ++ int ret; ++ ++ ret = csum_node41(node, 1/* check */); ++ if (!ret) { ++ warning("edward-1645", ++ "block %llu (%s): bad checksum. Please, scrub the volume.", ++ *jnode_get_block(ZJNODE(node)), ++ ZJNODE(node)->subvol->name); ++ ++ return RETERR(-EIO); ++ } ++ return parse_node40_common(node, REISER4_NODE41_MAGIC); ++} ++ ++/* ++ * plugin->u.node.init ++ * look for description of this method in plugin/node/node.h ++ */ ++int init_node41(znode *node /* node to initialise */) ++{ ++ return init_node40_common(node, node_plugin_by_id(NODE41_ID), ++ sizeof(node41_header), REISER4_NODE41_MAGIC); ++} ++ ++/* ++ * plugin->u.node.shift ++ * look for description of this method in plugin/node/node.h ++ */ ++int shift_node41(coord_t *from, znode *to, ++ shift_direction pend, ++ int delete_child, /* if @from->node becomes empty, ++ * it will be deleted from the ++ * tree if this is set to 1 */ ++ int including_stop_coord, ++ carry_plugin_info *info) ++{ ++ return shift_node40_common(from, to, pend, delete_child, ++ including_stop_coord, info, ++ sizeof(node41_header)); ++} ++ ++#ifdef GUESS_EXISTS ++int guess_node41(const znode *node /* node to guess plugin of */) ++{ ++ return guess_node40_common(node, NODE41_ID, REISER4_NODE41_MAGIC); ++} ++#endif ++ ++/* ++ * plugin->u.node.max_item_size ++ */ ++int max_item_size_node41(void) ++{ ++ return reiser4_get_current_sb()->s_blocksize - sizeof(node41_header) - ++ sizeof(item_header40); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node41.h linux-5.10.2/fs/reiser4/plugin/node/node41.h +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node41.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node41.h 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,50 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined( __REISER4_NODE41_H__ ) ++#define __REISER4_NODE41_H__ ++ ++#include "../../forward.h" ++#include "../../dformat.h" ++#include "node40.h" ++#include ++ ++/* ++ * node41 layout: the same as node40, but with 32-bit checksum ++ */ ++ ++typedef struct node41_header { ++ node40_header head; ++ d32 csum; ++} PACKED node41_header; ++ ++/* ++ * functions to get/set fields of node41_header ++ */ ++#define nh41_get_csum(nh) le32_to_cpu(get_unaligned(&(nh)->csum)) ++#define nh41_set_csum(nh, value) put_unaligned(cpu_to_le32(value), &(nh)->csum) ++ ++int init_node41(znode * node); ++int parse_node41(znode *node); ++int max_item_size_node41(void); ++int shift_node41(coord_t *from, znode *to, shift_direction pend, ++ int delete_child, int including_stop_coord, ++ carry_plugin_info *info); ++int csum_node41(znode *node, int check); ++ ++#ifdef GUESS_EXISTS ++int guess_node41(const znode * node); ++#endif ++extern void reiser4_handle_error(void); ++ ++/* __REISER4_NODE41_H__ */ ++#endif ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node.c linux-5.10.2/fs/reiser4/plugin/node/node.c +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node.c 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,172 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Node plugin interface. ++ ++ Description: The tree provides the abstraction of flows, which it ++ internally fragments into items which it stores in nodes. ++ ++ A key_atom is a piece of data bound to a single key. ++ ++ For reasonable space efficiency to be achieved it is often ++ necessary to store key_atoms in the nodes in the form of items, where ++ an item is a sequence of key_atoms of the same or similar type. It is ++ more space-efficient, because the item can implement (very) ++ efficient compression of key_atom's bodies using internal knowledge ++ about their semantics, and it can often avoid having a key for each ++ key_atom. Each type of item has specific operations implemented by its ++ item handler (see balance.c). ++ ++ Rationale: the rest of the code (specifically balancing routines) ++ accesses leaf level nodes through this interface. This way we can ++ implement various block layouts and even combine various layouts ++ within the same tree. Balancing/allocating algorithms should not ++ care about peculiarities of splitting/merging specific item types, ++ but rather should leave that to the item's item handler. ++ ++ Items, including those that provide the abstraction of flows, have ++ the property that if you move them in part or in whole to another ++ node, the balancing code invokes their is_left_mergeable() ++ item_operation to determine if they are mergeable with their new ++ neighbor in the node you have moved them to. For some items the ++ is_left_mergeable() function always returns null. ++ ++ When moving the bodies of items from one node to another: ++ ++ if a partial item is shifted to another node the balancing code invokes ++ an item handler method to handle the item splitting. ++ ++ if the balancing code needs to merge with an item in the node it ++ is shifting to, it will invoke an item handler method to handle ++ the item merging. ++ ++ if it needs to move whole item bodies unchanged, the balancing code uses xmemcpy() ++ adjusting the item headers after the move is done using the node handler. ++*/ ++ ++#include "../../forward.h" ++#include "../../debug.h" ++#include "../../key.h" ++#include "../../coord.h" ++#include "../plugin_header.h" ++#include "../item/item.h" ++#include "node.h" ++#include "../plugin.h" ++#include "../../znode.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../../reiser4.h" ++ ++/** ++ * leftmost_key_in_node - get the smallest key in node ++ * @node: ++ * @key: store result here ++ * ++ * Stores the leftmost key of @node in @key. ++ */ ++reiser4_key *leftmost_key_in_node(const znode *node, reiser4_key *key) ++{ ++ assert("nikita-1634", node != NULL); ++ assert("nikita-1635", key != NULL); ++ ++ if (!node_is_empty(node)) { ++ coord_t first_item; ++ ++ coord_init_first_unit(&first_item, (znode *) node); ++ item_key_by_coord(&first_item, key); ++ } else ++ *key = *reiser4_max_key(); ++ return key; ++} ++ ++node_plugin node_plugins[LAST_NODE_ID] = { ++ [NODE40_ID] = { ++ .h = { ++ .type_id = REISER4_NODE_PLUGIN_TYPE, ++ .id = NODE40_ID, ++ .pops = NULL, ++ .label = "unified", ++ .desc = "unified node layout", ++ .linkage = {NULL, NULL} ++ }, ++ .item_overhead = item_overhead_node40, ++ .free_space = free_space_node40, ++ .lookup = lookup_node40, ++ .num_of_items = num_of_items_node40, ++ .item_by_coord = item_by_coord_node40, ++ .length_by_coord = length_by_coord_node40, ++ .plugin_by_coord = plugin_by_coord_node40, ++ .key_at = key_at_node40, ++ .estimate = estimate_node40, ++ .check = check_node40, ++ .parse = parse_node40, ++ .init = init_node40, ++#ifdef GUESS_EXISTS ++ .guess = guess_node40, ++#endif ++ .change_item_size = change_item_size_node40, ++ .create_item = create_item_node40, ++ .merge_items = merge_items_node40, ++ .update_item_key = update_item_key_node40, ++ .cut_and_kill = kill_node40, ++ .cut = cut_node40, ++ .shift = shift_node40, ++ .shrink_item = shrink_item_node40, ++ .fast_insert = fast_insert_node40, ++ .fast_paste = fast_paste_node40, ++ .fast_cut = fast_cut_node40, ++ .max_item_size = max_item_size_node40, ++ .prepare_removal = prepare_removal_node40, ++ .set_item_plugin = set_item_plugin_node40 ++ }, ++ [NODE41_ID] = { ++ .h = { ++ .type_id = REISER4_NODE_PLUGIN_TYPE, ++ .id = NODE41_ID, ++ .pops = NULL, ++ .label = "node41", ++ .desc = "node41 layout", ++ .linkage = {NULL, NULL} ++ }, ++ .item_overhead = item_overhead_node40, ++ .free_space = free_space_node40, ++ .lookup = lookup_node40, ++ .num_of_items = num_of_items_node40, ++ .item_by_coord = item_by_coord_node40, ++ .length_by_coord = length_by_coord_node40, ++ .plugin_by_coord = plugin_by_coord_node40, ++ .key_at = key_at_node40, ++ .estimate = estimate_node40, ++ .check = NULL, ++ .parse = parse_node41, ++ .init = init_node41, ++#ifdef GUESS_EXISTS ++ .guess = guess_node41, ++#endif ++ .change_item_size = change_item_size_node40, ++ .create_item = create_item_node40, ++ .merge_items = merge_items_node40, ++ .update_item_key = update_item_key_node40, ++ .cut_and_kill = kill_node40, ++ .cut = cut_node40, ++ .shift = shift_node41, ++ .shrink_item = shrink_item_node40, ++ .fast_insert = fast_insert_node40, ++ .fast_paste = fast_paste_node40, ++ .fast_cut = fast_cut_node40, ++ .max_item_size = max_item_size_node41, ++ .prepare_removal = prepare_removal_node40, ++ .set_item_plugin = set_item_plugin_node40, ++ .csum = csum_node41 ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/node/node.h linux-5.10.2/fs/reiser4/plugin/node/node.h +--- linux-5.10.2.orig/fs/reiser4/plugin/node/node.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/node/node.h 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,282 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* We need a definition of the default node layout here. */ ++ ++/* Generally speaking, it is best to have free space in the middle of the ++ node so that two sets of things can grow towards it, and to have the ++ item bodies on the left so that the last one of them grows into free ++ space. We optimize for the case where we append new items to the end ++ of the node, or grow the last item, because it hurts nothing to so ++ optimize and it is a common special case to do massive insertions in ++ increasing key order (and one of cases more likely to have a real user ++ notice the delay time for). ++ ++ formatted leaf default layout: (leaf1) ++ ++ |node header:item bodies:free space:key + pluginid + item offset| ++ ++ We grow towards the middle, optimizing layout for the case where we ++ append new items to the end of the node. The node header is fixed ++ length. Keys, and item offsets plus pluginids for the items ++ corresponding to them are in increasing key order, and are fixed ++ length. Item offsets are relative to start of node (16 bits creating ++ a node size limit of 64k, 12 bits might be a better choice....). Item ++ bodies are in decreasing key order. Item bodies have a variable size. ++ There is a one to one to one mapping of keys to item offsets to item ++ bodies. Item offsets consist of pointers to the zeroth byte of the ++ item body. Item length equals the start of the next item minus the ++ start of this item, except the zeroth item whose length equals the end ++ of the node minus the start of that item (plus a byte). In other ++ words, the item length is not recorded anywhere, and it does not need ++ to be since it is computable. ++ ++ Leaf variable length items and keys layout : (lvar) ++ ++ |node header:key offset + item offset + pluginid triplets:free space:key bodies:item bodies| ++ ++ We grow towards the middle, optimizing layout for the case where we ++ append new items to the end of the node. The node header is fixed ++ length. Keys and item offsets for the items corresponding to them are ++ in increasing key order, and keys are variable length. Item offsets ++ are relative to start of node (16 bits). Item bodies are in ++ decreasing key order. Item bodies have a variable size. There is a ++ one to one to one mapping of keys to item offsets to item bodies. ++ Item offsets consist of pointers to the zeroth byte of the item body. ++ Item length equals the start of the next item's key minus the start of ++ this item, except the zeroth item whose length equals the end of the ++ node minus the start of that item (plus a byte). ++ ++ leaf compressed keys layout: (lcomp) ++ ++ |node header:key offset + key inherit + item offset pairs:free space:key bodies:item bodies| ++ ++ We grow towards the middle, optimizing layout for the case where we ++ append new items to the end of the node. The node header is fixed ++ length. Keys and item offsets for the items corresponding to them are ++ in increasing key order, and keys are variable length. The "key ++ inherit" field indicates how much of the key prefix is identical to ++ the previous key (stem compression as described in "Managing ++ Gigabytes" is used). key_inherit is a one byte integer. The ++ intra-node searches performed through this layout are linear searches, ++ and this is theorized to not hurt performance much due to the high ++ cost of processor stalls on modern CPUs, and the small number of keys ++ in a single node. Item offsets are relative to start of node (16 ++ bits). Item bodies are in decreasing key order. Item bodies have a ++ variable size. There is a one to one to one mapping of keys to item ++ offsets to item bodies. Item offsets consist of pointers to the ++ zeroth byte of the item body. Item length equals the start of the ++ next item minus the start of this item, except the zeroth item whose ++ length equals the end of the node minus the start of that item (plus a ++ byte). In other words, item length and key length is not recorded ++ anywhere, and it does not need to be since it is computable. ++ ++ internal node default layout: (idef1) ++ ++ just like ldef1 except that item bodies are either blocknrs of ++ children or extents, and moving them may require updating parent ++ pointers in the nodes that they point to. ++*/ ++ ++/* There is an inherent 3-way tradeoff between optimizing and ++ exchanging disks between different architectures and code ++ complexity. This is optimal and simple and inexchangeable. ++ Someone else can do the code for exchanging disks and make it ++ complex. It would not be that hard. Using other than the PAGE_SIZE ++ might be suboptimal. ++*/ ++ ++#if !defined( __REISER4_NODE_H__ ) ++#define __REISER4_NODE_H__ ++ ++#define LEAF40_NODE_SIZE PAGE_CACHE_SIZE ++ ++#include "../../dformat.h" ++#include "../plugin_header.h" ++ ++#include ++ ++typedef enum { ++ NS_FOUND = 0, ++ NS_NOT_FOUND = -ENOENT ++} node_search_result; ++ ++/* Maximal possible space overhead for creation of new item in a node */ ++#define REISER4_NODE_MAX_OVERHEAD ( sizeof( reiser4_key ) + 32 ) ++ ++typedef enum { ++ REISER4_NODE_DKEYS = (1 << 0), ++ REISER4_NODE_TREE_STABLE = (1 << 1), ++ REISER4_NODE_CHECK_MERGEABLE = (1 << 2) ++} reiser4_node_check_flag; ++ ++/* cut and cut_and_kill have too long list of parameters. This structure is just to safe some space on stack */ ++struct cut_list { ++ coord_t *from; ++ coord_t *to; ++ const reiser4_key *from_key; ++ const reiser4_key *to_key; ++ reiser4_key *smallest_removed; ++ carry_plugin_info *info; ++ __u32 flags; ++ struct inode *inode; /* this is to pass list of eflushed jnodes down to extent_kill_hook */ ++ lock_handle *left; ++ lock_handle *right; ++}; ++ ++struct carry_cut_data; ++struct carry_kill_data; ++ ++/* The responsibility of the node plugin is to store and give access ++ to the sequence of items within the node. */ ++typedef struct node_plugin { ++ /* generic plugin fields */ ++ plugin_header h; ++ ++ /* calculates the amount of space that will be required to store an ++ item which is in addition to the space consumed by the item body. ++ (the space consumed by the item body can be gotten by calling ++ item->estimate) */ ++ size_t(*item_overhead) (const znode * node, flow_t * f); ++ ++ /* returns free space by looking into node (i.e., without using ++ znode->free_space). */ ++ size_t(*free_space) (znode * node); ++ /* search within the node for the one item which might ++ contain the key, invoking item->search_within to search within ++ that item to see if it is in there */ ++ node_search_result(*lookup) (znode * node, const reiser4_key * key, ++ lookup_bias bias, coord_t * coord); ++ /* number of items in node */ ++ int (*num_of_items) (const znode * node); ++ ++ /* store information about item in @coord in @data */ ++ /* break into several node ops, don't add any more uses of this before doing so */ ++ /*int ( *item_at )( const coord_t *coord, reiser4_item_data *data ); */ ++ char *(*item_by_coord) (const coord_t * coord); ++ int (*length_by_coord) (const coord_t * coord); ++ item_plugin *(*plugin_by_coord) (const coord_t * coord); ++ ++ /* store item key in @key */ ++ reiser4_key *(*key_at) (const coord_t * coord, reiser4_key * key); ++ /* conservatively estimate whether unit of what size can fit ++ into node. This estimation should be performed without ++ actually looking into the node's content (free space is saved in ++ znode). */ ++ size_t(*estimate) (znode * node); ++ ++ /* performs every consistency check the node plugin author could ++ imagine. Optional. */ ++ int (*check) (const znode * node, __u32 flags, const char **error); ++ ++ /* Called when node is read into memory and node plugin is ++ already detected. This should read some data into znode (like free ++ space counter) and, optionally, check data consistency. ++ */ ++ int (*parse) (znode * node); ++ /* This method is called on a new node to initialise plugin specific ++ data (header, etc.) */ ++ int (*init) (znode * node); ++ /* Check whether @node content conforms to this plugin format. ++ Probably only useful after support for old V3.x formats is added. ++ Uncomment after 4.0 only. ++ */ ++ /* int ( *guess )( const znode *node ); */ ++#if REISER4_DEBUG ++ void (*print) (const char *prefix, const znode * node, __u32 flags); ++#endif ++ /* change size of @item by @by bytes. @item->node has enough free ++ space. When @by > 0 - free space is appended to end of item. When ++ @by < 0 - item is truncated - it is assumed that last @by bytes if ++ the item are freed already */ ++ void (*change_item_size) (coord_t * item, int by); ++ ++ /* create new item @length bytes long in coord @target */ ++ int (*create_item) (coord_t * target, const reiser4_key * key, ++ reiser4_item_data * data, carry_plugin_info * info); ++ ++ /* merge two neighboring mergeable items @left and @right ++ located on the same node. Such items can appear after ++ some operations like plugging a hole in a striped file. ++ This operation always increases free space in the node */ ++ void (*merge_items) (coord_t *left, coord_t *right); ++ ++ /* update key of item. */ ++ void (*update_item_key) (coord_t * target, const reiser4_key * key, ++ carry_plugin_info * info); ++ ++ int (*cut_and_kill) (struct carry_kill_data *, carry_plugin_info *); ++ int (*cut) (struct carry_cut_data *, carry_plugin_info *); ++ ++ /* ++ * shrink item pointed to by @coord by @delta bytes. ++ */ ++ int (*shrink_item) (coord_t * coord, int delta); ++ ++ /* copy as much as possible but not more than up to @stop from ++ @stop->node to @target. If (pend == append) then data from beginning of ++ @stop->node are copied to the end of @target. If (pend == prepend) then ++ data from the end of @stop->node are copied to the beginning of ++ @target. Copied data are removed from @stop->node. Information ++ about what to do on upper level is stored in @todo */ ++ int (*shift) (coord_t * stop, znode * target, shift_direction pend, ++ int delete_node, int including_insert_coord, ++ carry_plugin_info * info); ++ /* return true if this node allows skip carry() in some situations ++ (see fs/reiser4/tree.c:insert_by_coord()). Reiser3.x format ++ emulation doesn't. ++ ++ This will speedup insertions that doesn't require updates to the ++ parent, by bypassing initialisation of carry() structures. It's ++ believed that majority of insertions will fit there. ++ ++ */ ++ int (*fast_insert) (const coord_t * coord); ++ int (*fast_paste) (const coord_t * coord); ++ int (*fast_cut) (const coord_t * coord); ++ /* this limits max size of item which can be inserted into a node and ++ number of bytes item in a node may be appended with */ ++ int (*max_item_size) (void); ++ int (*prepare_removal) (znode * empty, carry_plugin_info * info); ++ /* change plugin id of items which are in a node already. Currently it is Used in tail conversion for regular ++ * files */ ++ int (*set_item_plugin) (coord_t * coord, item_id); ++ /* calculate and check/update znode's checksum ++ (if @check is true, then check, otherwise update) */ ++ int (*csum)(znode *node, int check); ++} node_plugin; ++ ++typedef enum { ++ NODE40_ID, /* standard unified node layout used for both, ++ leaf and internal nodes */ ++ NODE41_ID, /* node layout with a checksum */ ++ LAST_NODE_ID ++} reiser4_node_id; ++ ++extern reiser4_key *leftmost_key_in_node(const znode * node, reiser4_key * key); ++#if REISER4_DEBUG ++extern void print_node_content(const char *prefix, const znode * node, ++ __u32 flags); ++#endif ++ ++extern void indent_znode(const znode * node); ++ ++typedef struct common_node_header { ++ /* ++ * identifier of node plugin. Must be located at the very beginning of ++ * a node. ++ */ ++ __le16 plugin_id; ++} common_node_header; ++ ++/* __REISER4_NODE_H__ */ ++#endif ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/object.c linux-5.10.2/fs/reiser4/plugin/object.c +--- linux-5.10.2.orig/fs/reiser4/plugin/object.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/object.c 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,618 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* ++ * Examples of object plugins: file, directory, symlink, special file. ++ * ++ * Plugins associated with inode: ++ * ++ * Plugin of inode is plugin referenced by plugin-id field of on-disk ++ * stat-data. How we store this plugin in in-core inode is not ++ * important. Currently pointers are used, another variant is to store offsets ++ * and do array lookup on each access. ++ * ++ * Now, each inode has one selected plugin: object plugin that ++ * determines what type of file this object is: directory, regular etc. ++ * ++ * This main plugin can use other plugins that are thus subordinated to ++ * it. Directory instance of object plugin uses hash; regular file ++ * instance uses tail policy plugin. ++ * ++ * Object plugin is either taken from id in stat-data or guessed from ++ * i_mode bits. Once it is established we ask it to install its ++ * subordinate plugins, by looking again in stat-data or inheriting them ++ * from parent. ++ * ++ * How new inode is initialized during ->read_inode(): ++ * 1 read stat-data and initialize inode fields: i_size, i_mode, ++ * i_generation, capabilities etc. ++ * 2 read plugin id from stat data or try to guess plugin id ++ * from inode->i_mode bits if plugin id is missing. ++ * 3 Call ->init_inode() method of stat-data plugin to initialise inode fields. ++ * ++ * NIKITA-FIXME-HANS: can you say a little about 1 being done before 3? What ++ * if stat data does contain i_size, etc., due to it being an unusual plugin? ++ * ++ * 4 Call ->activate() method of object's plugin. Plugin is either read from ++ * from stat-data or guessed from mode bits ++ * 5 Call ->inherit() method of object plugin to inherit as yet un initialized ++ * plugins from parent. ++ * ++ * Easy induction proves that on last step all plugins of inode would be ++ * initialized. ++ * ++ * When creating new object: ++ * 1 obtain object plugin id (see next period) ++ * NIKITA-FIXME-HANS: period? ++ * 2 ->install() this plugin ++ * 3 ->inherit() the rest from the parent ++ * ++ * We need some examples of creating an object with default and non-default ++ * plugin ids. Nikita, please create them. ++ */ ++ ++#include "../inode.h" ++ ++int _bugop(void) ++{ ++ BUG_ON(1); ++ return 0; ++} ++ ++#define bugop ((void *)_bugop) ++ ++static int build_body_key_bugop(struct inode *inode, loff_t off, ++ reiser4_key *key) ++{ ++ BUG_ON(1); ++ return 0; ++} ++ ++static int _dummyop(void) ++{ ++ return 0; ++} ++ ++#define dummyop ((void *)_dummyop) ++ ++static int change_file(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ /* cannot change object plugin of already existing object */ ++ if (memb == PSET_FILE) ++ return RETERR(-EINVAL); ++ ++ /* Change PSET_CREATE */ ++ return aset_set_unsafe(&reiser4_inode_data(inode)->pset, memb, plugin); ++} ++ ++static reiser4_plugin_ops file_plugin_ops = { ++ .change = change_file ++}; ++ ++static struct inode_operations null_i_ops = {.create = NULL}; ++static struct file_operations null_f_ops = {.owner = NULL}; ++static struct address_space_operations null_a_ops = {.writepage = NULL}; ++ ++/* ++ * Reiser4 provides for VFS either dispatcher, or common (fop, ++ * iop, aop) method. ++ * ++ * Dispatchers (suffixed with "dispatch") pass management to ++ * proper plugin in accordance with plugin table (pset) located ++ * in the private part of inode. ++ * ++ * Common methods are NOT prefixed with "dispatch". They are ++ * the same for all plugins of FILE interface, and, hence, no ++ * dispatching is needed. ++ */ ++ ++/* ++ * VFS methods for regular files ++ */ ++static struct inode_operations regular_file_i_ops = { ++ .permission = reiser4_permission_common, ++ .setattr = reiser4_setattr_dispatch, ++ .getattr = reiser4_getattr_common ++}; ++static struct file_operations regular_file_f_ops = { ++ .llseek = generic_file_llseek, ++ .read = reiser4_read_dispatch, ++ .write = reiser4_write_dispatch, ++ .read_iter = generic_file_read_iter, ++ .unlocked_ioctl = reiser4_ioctl_dispatch, ++#ifdef CONFIG_COMPAT ++ .compat_ioctl = reiser4_ioctl_dispatch, ++#endif ++ .mmap = reiser4_mmap_dispatch, ++ .open = reiser4_open_dispatch, ++ .release = reiser4_release_dispatch, ++ .fsync = reiser4_sync_file_common, ++ .splice_read = generic_file_splice_read, ++}; ++static struct address_space_operations regular_file_a_ops = { ++ .writepage = reiser4_writepage, ++ .readpage = reiser4_readpage_dispatch, ++ //.sync_page = block_sync_page, ++ .writepages = reiser4_writepages_dispatch, ++ .set_page_dirty = reiser4_set_page_dirty, ++ .readpages = reiser4_readpages_dispatch, ++ .write_begin = reiser4_write_begin_dispatch, ++ .write_end = reiser4_write_end_dispatch, ++ .bmap = reiser4_bmap_dispatch, ++ .invalidatepage = reiser4_invalidatepage, ++ .releasepage = reiser4_releasepage, ++ .migratepage = reiser4_migratepage, ++ .batch_lock_tabu = 1 ++}; ++ ++/* VFS methods for symlink files */ ++static struct inode_operations symlink_file_i_ops = { ++ .get_link = reiser4_get_link_common, ++ .permission = reiser4_permission_common, ++ .setattr = reiser4_setattr_common, ++ .getattr = reiser4_getattr_common ++}; ++ ++/* VFS methods for special files */ ++static struct inode_operations special_file_i_ops = { ++ .permission = reiser4_permission_common, ++ .setattr = reiser4_setattr_common, ++ .getattr = reiser4_getattr_common ++}; ++ ++/* VFS methods for directories */ ++static struct inode_operations directory_i_ops = { ++ .create = reiser4_create_common, ++ .lookup = reiser4_lookup_common, ++ .link = reiser4_link_common, ++ .unlink = reiser4_unlink_common, ++ .symlink = reiser4_symlink_common, ++ .mkdir = reiser4_mkdir_common, ++ .rmdir = reiser4_unlink_common, ++ .mknod = reiser4_mknod_common, ++ .rename = reiser4_rename2_common, ++ .permission = reiser4_permission_common, ++ .setattr = reiser4_setattr_common, ++ .getattr = reiser4_getattr_common ++}; ++static struct file_operations directory_f_ops = { ++ .llseek = reiser4_llseek_dir_common, ++ .read = generic_read_dir, ++ .iterate = reiser4_iterate_common, ++ .release = reiser4_release_dir_common, ++ .fsync = reiser4_sync_common, ++#ifdef CONFIG_COMPAT ++ .compat_ioctl = reiser4_ioctl_dir_common, ++#endif ++ .unlocked_ioctl = reiser4_ioctl_dir_common ++}; ++static struct address_space_operations directory_a_ops = { ++ .writepages = dummyop, ++}; ++ ++/* ++ * Definitions of object plugins. ++ */ ++ ++file_plugin file_plugins[LAST_FILE_PLUGIN_ID] = { ++ [UNIX_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = UNIX_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_REGULAR_FILE), ++ .pops = &file_plugin_ops, ++ .label = "reg", ++ .desc = "regular file", ++ .linkage = {NULL, NULL}, ++ }, ++ /* ++ * invariant vfs ops ++ */ ++ .inode_ops = ®ular_file_i_ops, ++ .file_ops = ®ular_file_f_ops, ++ .as_ops = ®ular_file_a_ops, ++ /* ++ * private i_ops ++ */ ++ .setattr = setattr_unix_file, ++ .open = open_unix_file, ++ .read = read_unix_file, ++ .write = write_unix_file, ++ .ioctl = ioctl_unix_file, ++ .mmap = mmap_unix_file, ++ .release = release_unix_file, ++ /* ++ * private f_ops ++ */ ++ .readpage = readpage_unix_file, ++ .readpages = readpages_unix_file, ++ .writepages = writepages_unix_file, ++ .write_begin = write_begin_unix_file, ++ .write_end = write_end_unix_file, ++ /* ++ * private a_ops ++ */ ++ .bmap = bmap_unix_file, ++ /* ++ * other private methods ++ */ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .build_body_key = build_body_key_unix_file, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_common, ++ .create_object = reiser4_create_object_common, ++ .delete_object = delete_object_unix_file, ++ .add_link = reiser4_add_link_common, ++ .rem_link = reiser4_rem_link_common, ++ .owns_item = owns_item_unix_file, ++ .can_add_link = can_add_link_common, ++ .detach = dummyop, ++ .bind = dummyop, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common ++ }, ++ .init_inode_data = init_inode_data_unix_file, ++ .cut_tree_worker = cut_tree_worker_common, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ } ++ }, ++ [DIRECTORY_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = DIRECTORY_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_DIRECTORY_FILE), ++ .pops = &file_plugin_ops, ++ .label = "dir", ++ .desc = "directory", ++ .linkage = {NULL, NULL} ++ }, ++ .inode_ops = &null_i_ops, ++ .file_ops = &null_f_ops, ++ .as_ops = &null_a_ops, ++ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .build_body_key = build_body_key_bugop, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_common_dir, ++ .create_object = reiser4_create_object_common, ++ .delete_object = reiser4_delete_dir_common, ++ .add_link = reiser4_add_link_common, ++ .rem_link = rem_link_common_dir, ++ .owns_item = owns_item_common_dir, ++ .can_add_link = can_add_link_common, ++ .can_rem_link = can_rem_link_common_dir, ++ .detach = reiser4_detach_common_dir, ++ .bind = reiser4_bind_common_dir, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common_dir, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common_dir ++ }, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ }, ++ .init_inode_data = init_inode_ordering, ++ .cut_tree_worker = cut_tree_worker_common, ++ }, ++ [SYMLINK_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = SYMLINK_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_SYMLINK_FILE), ++ .pops = &file_plugin_ops, ++ .label = "symlink", ++ .desc = "symbolic link", ++ .linkage = {NULL,NULL} ++ }, ++ .inode_ops = &symlink_file_i_ops, ++ /* inode->i_fop of symlink is initialized ++ by NULL in setup_inode_ops */ ++ .file_ops = &null_f_ops, ++ .as_ops = &null_a_ops, ++ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_common, ++ .create_object = reiser4_create_symlink, ++ .delete_object = reiser4_delete_object_common, ++ .add_link = reiser4_add_link_common, ++ .rem_link = reiser4_rem_link_common, ++ .can_add_link = can_add_link_common, ++ .detach = dummyop, ++ .bind = dummyop, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common ++ }, ++ .init_inode_data = init_inode_ordering, ++ .cut_tree_worker = cut_tree_worker_common, ++ .destroy_inode = destroy_inode_symlink, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ } ++ }, ++ [SPECIAL_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = SPECIAL_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_SPECIAL_FILE), ++ .pops = &file_plugin_ops, ++ .label = "special", ++ .desc = ++ "special: fifo, device or socket", ++ .linkage = {NULL, NULL} ++ }, ++ .inode_ops = &special_file_i_ops, ++ /* file_ops of special files (sockets, block, char, fifo) are ++ initialized by init_special_inode. */ ++ .file_ops = &null_f_ops, ++ .as_ops = &null_a_ops, ++ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_common, ++ .create_object = reiser4_create_object_common, ++ .delete_object = reiser4_delete_object_common, ++ .add_link = reiser4_add_link_common, ++ .rem_link = reiser4_rem_link_common, ++ .owns_item = owns_item_common, ++ .can_add_link = can_add_link_common, ++ .detach = dummyop, ++ .bind = dummyop, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common ++ }, ++ .init_inode_data = init_inode_ordering, ++ .cut_tree_worker = cut_tree_worker_common, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ } ++ }, ++ [CRYPTCOMPRESS_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = CRYPTCOMPRESS_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_REGULAR_FILE), ++ .pops = &file_plugin_ops, ++ .label = "cryptcompress", ++ .desc = "cryptcompress file", ++ .linkage = {NULL, NULL} ++ }, ++ .inode_ops = ®ular_file_i_ops, ++ .file_ops = ®ular_file_f_ops, ++ .as_ops = ®ular_file_a_ops, ++ ++ .setattr = setattr_cryptcompress, ++ .open = open_cryptcompress, ++ .read = read_cryptcompress, ++ .write = write_cryptcompress, ++ .ioctl = ioctl_cryptcompress, ++ .mmap = mmap_cryptcompress, ++ .release = release_cryptcompress, ++ ++ .readpage = readpage_cryptcompress, ++ .readpages = readpages_cryptcompress, ++ .writepages = writepages_cryptcompress, ++ .write_begin = write_begin_cryptcompress, ++ .write_end = write_end_cryptcompress, ++ ++ .bmap = bmap_cryptcompress, ++ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .build_body_key = build_body_key_cryptcompress, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_cryptcompress, ++ .create_object = create_object_cryptcompress, ++ .delete_object = delete_object_cryptcompress, ++ .add_link = reiser4_add_link_common, ++ .rem_link = reiser4_rem_link_common, ++ .owns_item = owns_item_common, ++ .can_add_link = can_add_link_common, ++ .detach = dummyop, ++ .bind = dummyop, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common ++ }, ++ .init_inode_data = init_inode_data_cryptcompress, ++ .cut_tree_worker = cut_tree_worker_cryptcompress, ++ .destroy_inode = destroy_inode_cryptcompress, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ } ++ }, ++ [STRIPED_FILE_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .id = STRIPED_FILE_PLUGIN_ID, ++ .groups = (1 << REISER4_REGULAR_FILE), ++ .pops = &file_plugin_ops, ++ .label = "stripe", ++ .desc = "striped file", ++ .linkage = {NULL, NULL}, ++ }, ++ /* ++ * invariant vfs ops ++ */ ++ .inode_ops = ®ular_file_i_ops, ++ .file_ops = ®ular_file_f_ops, ++ .as_ops = ®ular_file_a_ops, ++ /* ++ * private i_ops ++ */ ++ .setattr = setattr_stripe, ++ .open = open_stripe, ++ .read = read_stripe, ++ .write = write_stripe, ++ .ioctl = ioctl_stripe, ++ .mmap = mmap_cryptcompress, ++ .release = release_stripe, ++ /* ++ * private f_ops ++ */ ++ .readpage = readpage_stripe, ++ .readpages = readpages_stripe, ++ .writepages = writepages_stripe, ++ .write_begin = write_begin_stripe, ++ .write_end = write_end_stripe, ++ /* ++ * private a_ops ++ */ ++ .bmap = bmap_unix_file, ++ /* ++ * other private methods ++ */ ++ .write_sd_by_inode = write_sd_by_inode_common, ++ .build_body_key = build_body_key_stripe, ++ .set_plug_in_inode = set_plug_in_inode_common, ++ .adjust_to_parent = adjust_to_parent_common, ++ .create_object = create_object_stripe, ++ .delete_object = delete_object_stripe, ++ .add_link = reiser4_add_link_common, ++ .rem_link = reiser4_rem_link_common, ++ .owns_item = owns_item_unix_file, ++ .can_add_link = can_add_link_common, ++ .detach = dummyop, ++ .bind = dummyop, ++ .safelink = safelink_common, ++ .estimate = { ++ .create = estimate_create_common, ++ .update = estimate_update_common, ++ .unlink = estimate_unlink_common ++ }, ++ .init_inode_data = init_inode_data_unix_file, ++ .cut_tree_worker = cut_tree_worker_stripe, ++ .migrate = migrate_stripe, ++ .wire = { ++ .write = wire_write_common, ++ .read = wire_read_common, ++ .get = wire_get_common, ++ .size = wire_size_common, ++ .done = wire_done_common ++ } ++ } ++}; ++ ++static int change_dir(struct inode *inode, ++ reiser4_plugin * plugin, ++ pset_member memb) ++{ ++ /* cannot change dir plugin of already existing object */ ++ return RETERR(-EINVAL); ++} ++ ++static reiser4_plugin_ops dir_plugin_ops = { ++ .change = change_dir ++}; ++ ++/* ++ * definition of directory plugins ++ */ ++ ++dir_plugin dir_plugins[LAST_DIR_ID] = { ++ /* standard hashed directory plugin */ ++ [HASHED_DIR_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_DIR_PLUGIN_TYPE, ++ .id = HASHED_DIR_PLUGIN_ID, ++ .pops = &dir_plugin_ops, ++ .label = "dir", ++ .desc = "hashed directory", ++ .linkage = {NULL, NULL} ++ }, ++ .inode_ops = &directory_i_ops, ++ .file_ops = &directory_f_ops, ++ .as_ops = &directory_a_ops, ++ ++ .get_parent = get_parent_common, ++ .is_name_acceptable = is_name_acceptable_common, ++ .build_entry_key = build_entry_key_hashed, ++ .build_readdir_key = build_readdir_key_common, ++ .add_entry = reiser4_add_entry_common, ++ .rem_entry = reiser4_rem_entry_common, ++ .init = reiser4_dir_init_common, ++ .done = reiser4_dir_done_common, ++ .attach = reiser4_attach_common, ++ .detach = reiser4_detach_common, ++ .estimate = { ++ .add_entry = estimate_add_entry_common, ++ .rem_entry = estimate_rem_entry_common, ++ .unlink = dir_estimate_unlink_common ++ } ++ }, ++ /* hashed directory for which seekdir/telldir are guaranteed to ++ * work. Brain-damage. */ ++ [SEEKABLE_HASHED_DIR_PLUGIN_ID] = { ++ .h = { ++ .type_id = REISER4_DIR_PLUGIN_TYPE, ++ .id = SEEKABLE_HASHED_DIR_PLUGIN_ID, ++ .pops = &dir_plugin_ops, ++ .label = "dir32", ++ .desc = "directory hashed with 31 bit hash", ++ .linkage = {NULL, NULL} ++ }, ++ .inode_ops = &directory_i_ops, ++ .file_ops = &directory_f_ops, ++ .as_ops = &directory_a_ops, ++ ++ .get_parent = get_parent_common, ++ .is_name_acceptable = is_name_acceptable_common, ++ .build_entry_key = build_entry_key_seekable, ++ .build_readdir_key = build_readdir_key_common, ++ .add_entry = reiser4_add_entry_common, ++ .rem_entry = reiser4_rem_entry_common, ++ .init = reiser4_dir_init_common, ++ .done = reiser4_dir_done_common, ++ .attach = reiser4_attach_common, ++ .detach = reiser4_detach_common, ++ .estimate = { ++ .add_entry = estimate_add_entry_common, ++ .rem_entry = estimate_rem_entry_common, ++ .unlink = dir_estimate_unlink_common ++ } ++ } ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/object.h linux-5.10.2/fs/reiser4/plugin/object.h +--- linux-5.10.2.orig/fs/reiser4/plugin/object.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/object.h 2020-12-23 16:07:46.130813304 +0100 +@@ -0,0 +1,119 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Declaration of object plugin functions. */ ++ ++#if !defined(__FS_REISER4_PLUGIN_OBJECT_H__) ++#define __FS_REISER4_PLUGIN_OBJECT_H__ ++ ++#include "../type_safe_hash.h" ++ ++/* common implementations of inode operations */ ++int reiser4_create_common(struct inode *parent, struct dentry *dentry, ++ umode_t mode, bool); ++struct dentry *reiser4_lookup_common(struct inode *parent, ++ struct dentry *dentry, ++ unsigned int); ++int reiser4_link_common(struct dentry *existing, struct inode *parent, ++ struct dentry *newname); ++int reiser4_unlink_common(struct inode *parent, struct dentry *victim); ++int reiser4_mkdir_common(struct inode *parent, struct dentry *dentry, umode_t mode); ++int reiser4_symlink_common(struct inode *parent, struct dentry *dentry, ++ const char *linkname); ++int reiser4_mknod_common(struct inode *parent, struct dentry *dentry, ++ umode_t mode, dev_t rdev); ++int reiser4_rename2_common(struct inode *old_dir, struct dentry *old_name, ++ struct inode *new_dir, struct dentry *new_name, ++ unsigned flags); ++const char *reiser4_get_link_common(struct dentry *, struct inode *inode, ++ struct delayed_call *done); ++int reiser4_permission_common(struct inode *, int mask); ++int reiser4_setattr_common(struct dentry *, struct iattr *); ++int reiser4_getattr_common(const struct path *path, struct kstat *stat, ++ u32 request_mask, unsigned int flags); ++ ++/* common implementations of file operations */ ++loff_t reiser4_llseek_dir_common(struct file *, loff_t off, int origin); ++int reiser4_iterate_common(struct file *, struct dir_context *context); ++int reiser4_release_dir_common(struct inode *, struct file *); ++int reiser4_sync_common(struct file *, loff_t, loff_t, int datasync); ++ ++/* file plugin operations: common implementations */ ++void build_body_key_common(struct inode *inode, reiser4_key *key); ++int write_sd_by_inode_common(struct inode *, oid_t *oid); ++int set_plug_in_inode_common(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *); ++int adjust_to_parent_common(struct inode *object, struct inode *parent, ++ struct inode *root); ++int adjust_to_parent_common_dir(struct inode *object, struct inode *parent, ++ struct inode *root); ++int adjust_to_parent_cryptcompress(struct inode *object, struct inode *parent, ++ struct inode *root); ++int reiser4_create_object_common(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *, oid_t*); ++int reiser4_delete_object_common(struct inode *); ++int reiser4_delete_dir_common(struct inode *); ++int reiser4_add_link_common(struct inode *object, struct inode *parent); ++int reiser4_rem_link_common(struct inode *object, struct inode *parent); ++int rem_link_common_dir(struct inode *object, struct inode *parent); ++int owns_item_common(const struct inode *, const coord_t *); ++int owns_item_common_dir(const struct inode *, const coord_t *); ++int can_add_link_common(const struct inode *); ++int can_rem_link_common_dir(const struct inode *); ++int reiser4_detach_common_dir(struct inode *child, struct inode *parent); ++int reiser4_bind_common_dir(struct inode *child, struct inode *parent); ++int safelink_common(struct inode *, reiser4_safe_link_t, __u64 value); ++reiser4_block_nr estimate_create_common(const struct inode *); ++reiser4_block_nr estimate_create_common_dir(const struct inode *); ++reiser4_block_nr estimate_update_common(const struct inode *); ++reiser4_block_nr estimate_unlink_common(const struct inode *, ++ const struct inode *); ++reiser4_block_nr estimate_unlink_common_dir(const struct inode *, ++ const struct inode *); ++int reserve_update_sd_common(struct inode *inode); ++ ++char *wire_write_common(struct inode *, char *start); ++char *wire_read_common(char *addr, reiser4_object_on_wire *); ++struct dentry *wire_get_common(struct super_block *, reiser4_object_on_wire *); ++int wire_size_common(struct inode *); ++void wire_done_common(reiser4_object_on_wire *); ++ ++/* dir plugin operations: common implementations */ ++struct dentry *get_parent_common(struct inode *child); ++int is_name_acceptable_common(const struct inode *, const char *name, int len); ++void build_entry_key_common(const struct inode *, ++ const struct qstr *qname, reiser4_key *); ++int build_readdir_key_common(struct file *dir, reiser4_key *); ++int reiser4_add_entry_common(struct inode *object, struct dentry *where, ++ reiser4_object_create_data * , reiser4_dir_entry_desc *); ++int reiser4_rem_entry_common(struct inode *object, struct dentry *where, ++ reiser4_dir_entry_desc *); ++int reiser4_dir_init_common(struct inode *object, struct inode *parent, ++ reiser4_object_create_data *); ++int reiser4_dir_done_common(struct inode *); ++int reiser4_attach_common(struct inode *child, struct inode *parent); ++int reiser4_detach_common(struct inode *object, struct inode *parent); ++reiser4_block_nr estimate_add_entry_common(const struct inode *); ++reiser4_block_nr estimate_rem_entry_common(const struct inode *); ++reiser4_block_nr dir_estimate_unlink_common(const struct inode *, ++ const struct inode *); ++ ++/* these are essential parts of common implementations, they are to make ++ customized implementations easier */ ++ ++/* merely useful functions */ ++int lookup_sd(struct inode *, znode_lock_mode, coord_t *, lock_handle * , ++ const reiser4_key * , lookup_bias bias, int silent); ++ ++/* __FS_REISER4_PLUGIN_OBJECT_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/plugin.c linux-5.10.2/fs/reiser4/plugin/plugin.c +--- linux-5.10.2.orig/fs/reiser4/plugin/plugin.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/plugin.c 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,587 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Basic plugin infrastructure, lookup etc. */ ++ ++/* PLUGINS: ++ ++ Plugins are internal Reiser4 "modules" or "objects" used to increase ++ extensibility and allow external users to easily adapt reiser4 to ++ their needs. ++ ++ Plugins are classified into several disjoint "types". Plugins ++ belonging to the particular plugin type are termed "instances" of ++ this type. Existing types are listed by enum reiser4_plugin_type ++ (see plugin/plugin_header.h) ++ ++NIKITA-FIXME-HANS: update this list, and review this entire comment for currency ++ ++ Object (file) plugin determines how given file-system object serves ++ standard VFS requests for read, write, seek, mmap etc. Instances of ++ file plugins are: regular file, directory, symlink. Another example ++ of file plugin is audit plugin, that optionally records accesses to ++ underlying object and forwards requests to it. ++ ++ Hash plugins compute hashes used by reiser4 to store and locate ++ files within directories. Instances of hash plugin type are: r5, ++ tea, rupasov. ++ ++ Tail plugins (or, more precisely, tail policy plugins) determine ++ when last part of the file should be stored in a formatted item. ++ ++ Scope and lookup: ++ ++ label such that pair ( type_label, plugin_label ) is unique. This ++ pair is a globally persistent and user-visible plugin ++ identifier. Internally kernel maintains plugins and plugin types in ++ arrays using an index into those arrays as plugin and plugin type ++ identifiers. File-system in turn, also maintains persistent ++ "dictionary" which is mapping from plugin label to numerical ++ identifier which is stored in file-system objects. That is, we ++ store the offset into the plugin array for that plugin type as the ++ plugin id in the stat data of the filesystem object. ++ ++ Internal kernel plugin type identifier (index in plugins[] array) is ++ of type reiser4_plugin_type. Set of available plugin types is ++ currently static, but dynamic loading doesn't seem to pose ++ insurmountable problems. ++ ++ Within each type plugins are addressed by the identifiers of type ++ reiser4_plugin_id (indices in reiser4_plugin_type_data.builtin[]). ++ Such identifiers are only required to be unique within one type, ++ not globally. ++ ++ Thus, plugin in memory is uniquely identified by the pair (type_id, ++ id). ++ ++ Usage: ++ ++ There exists only one instance of each plugin instance, but this ++ single instance can be associated with many entities (file-system ++ objects, items, nodes, transactions, file-descriptors etc.). Entity ++ to which plugin of given type is termed (due to the lack of ++ imagination) "subject" of this plugin type and, by abuse of ++ terminology, subject of particular instance of this type to which ++ it's attached currently. For example, inode is subject of object ++ plugin type. Inode representing directory is subject of directory ++ plugin, hash plugin type and some particular instance of hash plugin ++ type. Inode, representing regular file is subject of "regular file" ++ plugin, tail-policy plugin type etc. ++ ++ With each subject the plugin possibly stores some state. For example, ++ the state of a directory plugin (instance of object plugin type) is pointer ++ to hash plugin (if directories always use hashing that is). ++ ++ Interface: ++ ++ In addition to a scalar identifier, each plugin type and plugin ++ proper has a "label": short string and a "description"---longer ++ descriptive string. Labels and descriptions of plugin types are ++ hard-coded into plugins[] array, declared and defined in ++ plugin.c. Label and description of plugin are stored in .label and ++ .desc fields of reiser4_plugin_header respectively. It's possible to ++ locate plugin by the pair of labels. ++ ++ Features (not implemented): ++ ++ . user-level plugin manipulations: ++ + reiser4("filename/..file_plugin<='audit'"); ++ + write(open("filename/..file_plugin"), "audit", 8); ++ ++ . user level utilities lsplug and chplug to manipulate plugins. ++ Utilities are not of primary priority. Possibly they will be not ++ working on v4.0 ++ ++ NIKITA-FIXME-HANS: this should be a mkreiserfs option not a mount ++ option, do you agree? I don't think that specifying it at mount time, ++ and then changing it with each mount, is a good model for usage. ++ ++ . mount option "plug" to set-up plugins of root-directory. ++ "plug=foo:bar" will set "bar" as default plugin of type "foo". ++ ++ Limitations: ++ ++ . each plugin type has to provide at least one builtin ++ plugin. This is technical limitation and it can be lifted in the ++ future. ++ ++ TODO: ++ ++ New plugin types/plugings: ++ Things we should be able to separately choose to inherit: ++ ++ security plugins ++ ++ stat data ++ ++ file bodies ++ ++ file plugins ++ ++ dir plugins ++ ++ . perm:acl ++ ++ . audi---audit plugin intercepting and possibly logging all ++ accesses to object. Requires to put stub functions in file_operations ++ in stead of generic_file_*. ++ ++NIKITA-FIXME-HANS: why make overflows a plugin? ++ . over---handle hash overflows ++ ++ . sqnt---handle different access patterns and instruments read-ahead ++ ++NIKITA-FIXME-HANS: describe the line below in more detail. ++ ++ . hier---handle inheritance of plugins along file-system hierarchy ++ ++ Different kinds of inheritance: on creation vs. on access. ++ Compatible/incompatible plugins. ++ Inheritance for multi-linked files. ++ Layered plugins. ++ Notion of plugin context is abandoned. ++ ++Each file is associated ++ with one plugin and dependant plugins (hash, etc.) are stored as ++ main plugin state. Now, if we have plugins used for regular files ++ but not for directories, how such plugins would be inherited? ++ . always store them with directories also ++ ++NIKTIA-FIXME-HANS: Do the line above. It is not exclusive of doing ++the line below which is also useful. ++ ++ . use inheritance hierarchy, independent of file-system namespace ++*/ ++ ++#include "../debug.h" ++#include "../dformat.h" ++#include "plugin_header.h" ++#include "item/static_stat.h" ++#include "node/node.h" ++#include "security/perm.h" ++#include "space/space_allocator.h" ++#include "disk_format/disk_format.h" ++#include "plugin.h" ++#include "../reiser4.h" ++#include "../jnode.h" ++#include "../inode.h" ++ ++#include /* for struct super_block */ ++ ++/* ++ * init_plugins - initialize plugin sub-system. ++ * Just call this once on reiser4 startup. ++ * ++ * Initializes plugin sub-system. It is part of reiser4 module ++ * initialization. For each plugin of each type init method is called and each ++ * plugin is put into list of plugins. ++ */ ++int init_plugins(void) ++{ ++ reiser4_plugin_type type_id; ++ ++ for (type_id = 0; type_id < REISER4_PLUGIN_TYPES; ++type_id) { ++ struct reiser4_plugin_type_data *ptype; ++ int i; ++ ++ ptype = &plugins[type_id]; ++ assert("nikita-3508", ptype->label != NULL); ++ assert("nikita-3509", ptype->type_id == type_id); ++ ++ INIT_LIST_HEAD(&ptype->plugins_list); ++/* NIKITA-FIXME-HANS: change builtin_num to some other name lacking the term ++ * builtin. */ ++ for (i = 0; i < ptype->builtin_num; ++i) { ++ reiser4_plugin *plugin; ++ ++ plugin = plugin_at(ptype, i); ++ ++ if (plugin->h.label == NULL) ++ /* uninitialized slot encountered */ ++ continue; ++ assert("nikita-3445", plugin->h.type_id == type_id); ++ plugin->h.id = i; ++ if (plugin->h.pops != NULL && ++ plugin->h.pops->init != NULL) { ++ int result; ++ ++ result = plugin->h.pops->init(plugin); ++ if (result != 0) ++ return result; ++ } ++ INIT_LIST_HEAD(&plugin->h.linkage); ++ list_add_tail(&plugin->h.linkage, &ptype->plugins_list); ++ } ++ } ++ return 0; ++} ++ ++/* true if plugin type id is valid */ ++int is_plugin_type_valid(reiser4_plugin_type type) ++{ ++ /* "type" is unsigned, so no comparison with 0 is ++ necessary */ ++ return (type < REISER4_PLUGIN_TYPES); ++} ++ ++/* true if plugin id is valid */ ++int is_plugin_id_valid(reiser4_plugin_type type, reiser4_plugin_id id) ++{ ++ assert("nikita-1653", is_plugin_type_valid(type)); ++ return id < plugins[type].builtin_num; ++} ++ ++/* return plugin by its @type and @id. ++ ++ Both arguments are checked for validness: this is supposed to be called ++ from user-level. ++ ++NIKITA-FIXME-HANS: Do you instead mean that this checks ids created in ++user space, and passed to the filesystem by use of method files? Your ++comment really confused me on the first reading.... ++ ++*/ ++reiser4_plugin *plugin_by_unsafe_id(reiser4_plugin_type type /* plugin type ++ * unchecked */, ++ reiser4_plugin_id id /* plugin id, ++ * unchecked */) ++{ ++ if (is_plugin_type_valid(type)) { ++ if (is_plugin_id_valid(type, id)) ++ return plugin_at(&plugins[type], id); ++ else ++ /* id out of bounds */ ++ warning("nikita-2913", ++ "Invalid plugin id: [%i:%i]", type, id); ++ } else ++ /* type_id out of bounds */ ++ warning("nikita-2914", "Invalid type_id: %i", type); ++ return NULL; ++} ++ ++/** ++ * save_plugin_id - store plugin id in disk format ++ * @plugin: plugin to convert ++ * @area: where to store result ++ * ++ * Puts id of @plugin in little endian format to address @area. ++ */ ++int save_plugin_id(reiser4_plugin *plugin /* plugin to convert */ , ++ d16 * area/* where to store result */) ++{ ++ assert("nikita-1261", plugin != NULL); ++ assert("nikita-1262", area != NULL); ++ ++ put_unaligned(cpu_to_le16(plugin->h.id), area); ++ return 0; ++} ++ ++/* list of all plugins of given type */ ++struct list_head *get_plugin_list(reiser4_plugin_type type) ++{ ++ assert("nikita-1056", is_plugin_type_valid(type)); ++ return &plugins[type].plugins_list; ++} ++ ++static void update_pset_mask(reiser4_inode * info, pset_member memb) ++{ ++ struct dentry *rootdir; ++ reiser4_inode *root; ++ ++ assert("edward-1443", memb != PSET_FILE); ++ ++ rootdir = inode_by_reiser4_inode(info)->i_sb->s_root; ++ if (rootdir != NULL) { ++ root = reiser4_inode_data(rootdir->d_inode); ++ /* ++ * if inode is different from the default one, or we are ++ * changing plugin of root directory, update plugin_mask ++ */ ++ if (aset_get(info->pset, memb) != ++ aset_get(root->pset, memb) || ++ info == root) ++ info->plugin_mask |= (1 << memb); ++ else ++ info->plugin_mask &= ~(1 << memb); ++ } ++} ++ ++/* Get specified plugin set member from parent, ++ or from fs-defaults (if no parent is given) and ++ install the result to pset of @self */ ++int grab_plugin_pset(struct inode *self, ++ struct inode *ancestor, ++ pset_member memb) ++{ ++ reiser4_plugin *plug; ++ reiser4_inode *info; ++ int result = 0; ++ ++ /* Do not grab if initialised already. */ ++ info = reiser4_inode_data(self); ++ if (aset_get(info->pset, memb) != NULL) ++ return 0; ++ if (ancestor) { ++ reiser4_inode *parent; ++ ++ parent = reiser4_inode_data(ancestor); ++ plug = aset_get(parent->hset, memb) ? : ++ aset_get(parent->pset, memb); ++ } else ++ plug = get_default_plugin(memb); ++ ++ result = set_plugin(&info->pset, memb, plug); ++ if (result == 0) { ++ if (!ancestor || self->i_sb->s_root->d_inode != self) ++ update_pset_mask(info, memb); ++ } ++ return result; ++} ++ ++/* Take missing pset members from root inode */ ++int finish_pset(struct inode *inode) ++{ ++ reiser4_plugin *plug; ++ reiser4_inode *root; ++ reiser4_inode *info; ++ pset_member memb; ++ int result = 0; ++ ++ root = reiser4_inode_data(inode->i_sb->s_root->d_inode); ++ info = reiser4_inode_data(inode); ++ ++ assert("edward-1455", root != NULL); ++ assert("edward-1456", info != NULL); ++ ++ /* file and directory plugins are already initialized. */ ++ for (memb = PSET_DIR + 1; memb < PSET_LAST; ++memb) { ++ ++ /* Do not grab if initialised already. */ ++ if (aset_get(info->pset, memb) != NULL) ++ continue; ++ ++ plug = aset_get(root->pset, memb); ++ result = set_plugin(&info->pset, memb, plug); ++ if (result != 0) ++ break; ++ } ++ if (result != 0) { ++ warning("nikita-3447", ++ "Cannot set up plugins for %lli", ++ (unsigned long long) ++ get_inode_oid(inode)); ++ } ++ return result; ++} ++ ++int force_plugin_pset(struct inode *self, pset_member memb, ++ reiser4_plugin * plug) ++{ ++ reiser4_inode *info; ++ int result = 0; ++ ++ if (!self->i_sb->s_root || self->i_sb->s_root->d_inode == self) { ++ /* Changing pset in the root object. */ ++ return RETERR(-EINVAL); ++ } ++ ++ info = reiser4_inode_data(self); ++ if (plug->h.pops != NULL && plug->h.pops->change != NULL) ++ result = plug->h.pops->change(self, plug, memb); ++ else ++ result = aset_set_unsafe(&info->pset, memb, plug); ++ if (result == 0) { ++ __u16 oldmask = info->plugin_mask; ++ ++ update_pset_mask(info, memb); ++ if (oldmask != info->plugin_mask) ++ reiser4_inode_clr_flag(self, REISER4_SDLEN_KNOWN); ++ } ++ return result; ++} ++ ++struct reiser4_plugin_type_data plugins[REISER4_PLUGIN_TYPES] = { ++ /* C90 initializers */ ++ [REISER4_FILE_PLUGIN_TYPE] = { ++ .type_id = REISER4_FILE_PLUGIN_TYPE, ++ .label = "file", ++ .desc = "Object plugins", ++ .builtin_num = sizeof_array(file_plugins), ++ .builtin = file_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(file_plugin) ++ }, ++ [REISER4_DIR_PLUGIN_TYPE] = { ++ .type_id = REISER4_DIR_PLUGIN_TYPE, ++ .label = "dir", ++ .desc = "Directory plugins", ++ .builtin_num = sizeof_array(dir_plugins), ++ .builtin = dir_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(dir_plugin) ++ }, ++ [REISER4_HASH_PLUGIN_TYPE] = { ++ .type_id = REISER4_HASH_PLUGIN_TYPE, ++ .label = "hash", ++ .desc = "Directory hashes", ++ .builtin_num = sizeof_array(hash_plugins), ++ .builtin = hash_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(hash_plugin) ++ }, ++ [REISER4_FIBRATION_PLUGIN_TYPE] = { ++ .type_id = ++ REISER4_FIBRATION_PLUGIN_TYPE, ++ .label = "fibration", ++ .desc = "Directory fibrations", ++ .builtin_num = sizeof_array(fibration_plugins), ++ .builtin = fibration_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(fibration_plugin) ++ }, ++ [REISER4_CIPHER_PLUGIN_TYPE] = { ++ .type_id = REISER4_CIPHER_PLUGIN_TYPE, ++ .label = "cipher", ++ .desc = "Cipher plugins", ++ .builtin_num = sizeof_array(cipher_plugins), ++ .builtin = cipher_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(cipher_plugin) ++ }, ++ [REISER4_DIGEST_PLUGIN_TYPE] = { ++ .type_id = REISER4_DIGEST_PLUGIN_TYPE, ++ .label = "digest", ++ .desc = "Digest plugins", ++ .builtin_num = sizeof_array(digest_plugins), ++ .builtin = digest_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(digest_plugin) ++ }, ++ [REISER4_COMPRESSION_PLUGIN_TYPE] = { ++ .type_id = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .label = "compression", ++ .desc = "Compression plugins", ++ .builtin_num = sizeof_array(compression_plugins), ++ .builtin = compression_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(compression_plugin) ++ }, ++ [REISER4_FORMATTING_PLUGIN_TYPE] = { ++ .type_id = REISER4_FORMATTING_PLUGIN_TYPE, ++ .label = "formatting", ++ .desc = "Tail inlining policies", ++ .builtin_num = sizeof_array(formatting_plugins), ++ .builtin = formatting_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(formatting_plugin) ++ }, ++ [REISER4_PERM_PLUGIN_TYPE] = { ++ .type_id = REISER4_PERM_PLUGIN_TYPE, ++ .label = "perm", ++ .desc = "Permission checks", ++ .builtin_num = sizeof_array(perm_plugins), ++ .builtin = perm_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(perm_plugin) ++ }, ++ [REISER4_ITEM_PLUGIN_TYPE] = { ++ .type_id = REISER4_ITEM_PLUGIN_TYPE, ++ .label = "item", ++ .desc = "Item handlers", ++ .builtin_num = sizeof_array(item_plugins), ++ .builtin = item_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(item_plugin) ++ }, ++ [REISER4_NODE_PLUGIN_TYPE] = { ++ .type_id = REISER4_NODE_PLUGIN_TYPE, ++ .label = "node", ++ .desc = "node layout handlers", ++ .builtin_num = sizeof_array(node_plugins), ++ .builtin = node_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(node_plugin) ++ }, ++ [REISER4_SD_EXT_PLUGIN_TYPE] = { ++ .type_id = REISER4_SD_EXT_PLUGIN_TYPE, ++ .label = "sd_ext", ++ .desc = "Parts of stat-data", ++ .builtin_num = sizeof_array(sd_ext_plugins), ++ .builtin = sd_ext_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(sd_ext_plugin) ++ }, ++ [REISER4_FORMAT_PLUGIN_TYPE] = { ++ .type_id = REISER4_FORMAT_PLUGIN_TYPE, ++ .label = "disk_layout", ++ .desc = "defines filesystem on disk layout", ++ .builtin_num = sizeof_array(format_plugins), ++ .builtin = format_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(disk_format_plugin) ++ }, ++ [REISER4_JNODE_PLUGIN_TYPE] = { ++ .type_id = REISER4_JNODE_PLUGIN_TYPE, ++ .label = "jnode", ++ .desc = "defines kind of jnode", ++ .builtin_num = sizeof_array(jnode_plugins), ++ .builtin = jnode_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(jnode_plugin) ++ }, ++ [REISER4_COMPRESSION_MODE_PLUGIN_TYPE] = { ++ .type_id = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .label = "compression_mode", ++ .desc = "Defines compression mode", ++ .builtin_num = sizeof_array(compression_mode_plugins), ++ .builtin = compression_mode_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(compression_mode_plugin) ++ }, ++ [REISER4_CLUSTER_PLUGIN_TYPE] = { ++ .type_id = REISER4_CLUSTER_PLUGIN_TYPE, ++ .label = "cluster", ++ .desc = "Defines cluster size", ++ .builtin_num = sizeof_array(cluster_plugins), ++ .builtin = cluster_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(cluster_plugin) ++ }, ++ [REISER4_TXMOD_PLUGIN_TYPE] = { ++ .type_id = REISER4_TXMOD_PLUGIN_TYPE, ++ .label = "txmod", ++ .desc = "Defines transaction model", ++ .builtin_num = sizeof_array(txmod_plugins), ++ .builtin = txmod_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(txmod_plugin) ++ }, ++ [REISER4_DISTRIBUTION_PLUGIN_TYPE] = { ++ .type_id = REISER4_DISTRIBUTION_PLUGIN_TYPE, ++ .label = "distrib", ++ .desc = "Defines distribution of named objects", ++ .builtin_num = sizeof_array(distribution_plugins), ++ .builtin = distribution_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(distribution_plugin) ++ }, ++ [REISER4_VOLUME_PLUGIN_TYPE] = { ++ .type_id = REISER4_VOLUME_PLUGIN_TYPE, ++ .label = "volume", ++ .desc = "Manages logical volumes", ++ .builtin_num = sizeof_array(volume_plugins), ++ .builtin = volume_plugins, ++ .plugins_list = {NULL, NULL}, ++ .size = sizeof(volume_plugin) ++ } ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/plugin.h linux-5.10.2/fs/reiser4/plugin/plugin.h +--- linux-5.10.2.orig/fs/reiser4/plugin/plugin.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/plugin.h 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,1194 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Basic plugin data-types. ++ see fs/reiser4/plugin/plugin.c for details */ ++ ++#if !defined(__FS_REISER4_PLUGIN_TYPES_H__) ++#define __FS_REISER4_PLUGIN_TYPES_H__ ++ ++#include "../forward.h" ++#include "../debug.h" ++#include "../dformat.h" ++#include "../key.h" ++#include "../ioctl.h" ++#include "compress/compress.h" ++#include "crypto/cipher.h" ++#include "plugin_header.h" ++#include "item/static_stat.h" ++#include "item/internal.h" ++#include "item/sde.h" ++#include "item/cde.h" ++#include "item/item.h" ++#include "node/node.h" ++#include "node/node41.h" ++#include "security/perm.h" ++#include "fibration.h" ++ ++#include "space/bitmap.h" ++#include "space/space_allocator.h" ++ ++#include "disk_format/disk_format40.h" ++#include "disk_format/disk_format.h" ++ ++#include /* for struct super_block, address_space */ ++#include /* for struct page */ ++#include /* for struct buffer_head */ ++#include /* for struct dentry */ ++#include ++#include ++ ++typedef struct reiser4_object_on_wire reiser4_object_on_wire; ++ ++/* ++ * File plugin. Defines the set of methods that file plugins implement, some ++ * of which are optional. ++ * ++ * A file plugin offers to the caller an interface for IO ( writing to and/or ++ * reading from) to what the caller sees as one sequence of bytes. An IO to it ++ * may affect more than one physical sequence of bytes, or no physical sequence ++ * of bytes, it may affect sequences of bytes offered by other file plugins to ++ * the semantic layer, and the file plugin may invoke other plugins and ++ * delegate work to them, but its interface is structured for offering the ++ * caller the ability to read and/or write what the caller sees as being a ++ * single sequence of bytes. ++ * ++ * The file plugin must present a sequence of bytes to the caller, but it does ++ * not necessarily have to store a sequence of bytes, it does not necessarily ++ * have to support efficient tree traversal to any offset in the sequence of ++ * bytes (tail and extent items, whose keys contain offsets, do however provide ++ * efficient non-sequential lookup of any offset in the sequence of bytes). ++ * ++ * Directory plugins provide methods for selecting file plugins by resolving a ++ * name for them. ++ * ++ * The functionality other filesystems call an attribute, and rigidly tie ++ * together, we decompose into orthogonal selectable features of files. Using ++ * the terminology we will define next, an attribute is a perhaps constrained, ++ * perhaps static length, file whose parent has a uni-count-intra-link to it, ++ * which might be grandparent-major-packed, and whose parent has a deletion ++ * method that deletes it. ++ * ++ * File plugins can implement constraints. ++ * ++ * Files can be of variable length (e.g. regular unix files), or of static ++ * length (e.g. static sized attributes). ++ * ++ * An object may have many sequences of bytes, and many file plugins, but, it ++ * has exactly one objectid. It is usually desirable that an object has a ++ * deletion method which deletes every item with that objectid. Items cannot ++ * in general be found by just their objectids. This means that an object must ++ * have either a method built into its deletion plugin method for knowing what ++ * items need to be deleted, or links stored with the object that provide the ++ * plugin with a method for finding those items. Deleting a file within an ++ * object may or may not have the effect of deleting the entire object, ++ * depending on the file plugin's deletion method. ++ * ++ * LINK TAXONOMY: ++ * ++ * Many objects have a reference count, and when the reference count reaches 0 ++ * the object's deletion method is invoked. Some links embody a reference ++ * count increase ("countlinks"), and others do not ("nocountlinks"). ++ * ++ * Some links are bi-directional links ("bilinks"), and some are ++ * uni-directional("unilinks"). ++ * ++ * Some links are between parts of the same object ("intralinks"), and some are ++ * between different objects ("interlinks"). ++ * ++ * PACKING TAXONOMY: ++ * ++ * Some items of an object are stored with a major packing locality based on ++ * their object's objectid (e.g. unix directory items in plan A), and these are ++ * called "self-major-packed". ++ * ++ * Some items of an object are stored with a major packing locality based on ++ * their semantic parent object's objectid (e.g. unix file bodies in plan A), ++ * and these are called "parent-major-packed". ++ * ++ * Some items of an object are stored with a major packing locality based on ++ * their semantic grandparent, and these are called "grandparent-major-packed". ++ * Now carefully notice that we run into trouble with key length if we have to ++ * store a 8 byte major+minor grandparent based packing locality, an 8 byte ++ * parent objectid, an 8 byte attribute objectid, and an 8 byte offset, all in ++ * a 24 byte key. One of these fields must be sacrificed if an item is to be ++ * grandparent-major-packed, and which to sacrifice is left to the item author ++ * choosing to make the item grandparent-major-packed. You cannot make tail ++ * items and extent items grandparent-major-packed, though you could make them ++ * self-major-packed (usually they are parent-major-packed). ++ * ++ * In the case of ACLs (which are composed of fixed length ACEs which consist ++ * of {subject-type, subject, and permission bitmask} triples), it makes sense ++ * to not have an offset field in the ACE item key, and to allow duplicate keys ++ * for ACEs. Thus, the set of ACES for a given file is found by looking for a ++ * key consisting of the objectid of the grandparent (thus grouping all ACLs in ++ * a directory together), the minor packing locality of ACE, the objectid of ++ * the file, and 0. ++ * ++ * IO involves moving data from one location to another, which means that two ++ * locations must be specified, source and destination. ++ * ++ * This source and destination can be in the filesystem, or they can be a ++ * pointer in the user process address space plus a byte count. ++ * ++ * If both source and destination are in the filesystem, then at least one of ++ * them must be representable as a pure stream of bytes (which we call a flow, ++ * and define as a struct containing a key, a data pointer, and a length). ++ * This may mean converting one of them into a flow. We provide a generic ++ * cast_into_flow() method, which will work for any plugin supporting ++ * read_flow(), though it is inefficiently implemented in that it temporarily ++ * stores the flow in a buffer (Question: what to do with huge flows that ++ * cannot fit into memory? Answer: we must not convert them all at once. ) ++ * ++ * Performing a write requires resolving the write request into a flow defining ++ * the source, and a method that performs the write, and a key that defines ++ * where in the tree the write is to go. ++ * ++ * Performing a read requires resolving the read request into a flow defining ++ * the target, and a method that performs the read, and a key that defines ++ * where in the tree the read is to come from. ++ * ++ * There will exist file plugins which have no pluginid stored on the disk for ++ * them, and which are only invoked by other plugins. ++ */ ++ ++/* ++ * This should be incremented in every release which adds one ++ * or more new plugins. ++ * NOTE: Make sure that respective marco is also incremented in ++ * the new release of reiser4progs. ++ */ ++#define PLUGIN_LIBRARY_VERSION 3 ++ ++ /* enumeration of fields within plugin_set */ ++typedef enum { ++ PSET_FILE, ++ PSET_DIR, /* PSET_FILE and PSET_DIR should be first ++ * elements: inode.c:read_inode() depends on ++ * this. */ ++ PSET_PERM, ++ PSET_FORMATTING, ++ PSET_HASH, ++ PSET_FIBRATION, ++ PSET_SD, ++ PSET_DIR_ITEM, ++ PSET_CIPHER, ++ PSET_DIGEST, ++ PSET_COMPRESSION, ++ PSET_COMPRESSION_MODE, ++ PSET_CLUSTER, ++ PSET_CREATE, ++ PSET_LAST ++} pset_member; ++ ++/* builtin file-plugins */ ++typedef enum { ++ /* regular file */ ++ UNIX_FILE_PLUGIN_ID, ++ /* directory */ ++ DIRECTORY_FILE_PLUGIN_ID, ++ /* symlink */ ++ SYMLINK_FILE_PLUGIN_ID, ++ /* for objects completely handled by the VFS: fifos, devices, ++ sockets */ ++ SPECIAL_FILE_PLUGIN_ID, ++ /* regular cryptcompress file */ ++ CRYPTCOMPRESS_FILE_PLUGIN_ID, ++ /* regular striped file */ ++ STRIPED_FILE_PLUGIN_ID, ++ /* number of file plugins. Used as size of arrays to hold ++ file plugins. */ ++ LAST_FILE_PLUGIN_ID ++} reiser4_file_id; ++ ++typedef struct file_plugin { ++ ++ /* generic fields */ ++ plugin_header h; ++ ++ /* VFS methods */ ++ struct inode_operations * inode_ops; ++ struct file_operations * file_ops; ++ struct address_space_operations * as_ops; ++ /** ++ * Private methods. These are optional. If used they will allow you ++ * to minimize the amount of code needed to implement a deviation ++ * from some other method that also uses them. ++ */ ++ /* ++ * private inode_ops ++ */ ++ int (*setattr)(struct dentry *, struct iattr *); ++ /* ++ * private file_ops ++ */ ++ /* do whatever is necessary to do when object is opened */ ++ int (*open) (struct inode *inode, struct file *file); ++ ssize_t (*read) (struct file *, char __user *buf, size_t read_amount, ++ loff_t *off); ++ /* write as much as possible bytes from nominated @write_amount ++ * before plugin scheduling is occurred. Save scheduling state ++ * in @cont */ ++ ssize_t (*write) (struct file *, const char __user *buf, ++ size_t write_amount, loff_t * off, ++ struct dispatch_context * cont); ++ int (*ioctl) (struct file *filp, unsigned int cmd, unsigned long arg); ++ int (*mmap) (struct file *, struct vm_area_struct *); ++ int (*release) (struct inode *, struct file *); ++ /* ++ * private a_ops ++ */ ++ int (*readpage) (struct file *file, struct page *page); ++ int (*readpages)(struct file *file, struct address_space *mapping, ++ struct list_head *pages, unsigned nr_pages); ++ int (*writepages)(struct address_space *mapping, ++ struct writeback_control *wbc); ++ int (*write_begin)(struct file *file, struct page *page, ++ loff_t pos, unsigned len, void **fsdata); ++ int (*write_end)(struct file *file, struct page *page, ++ loff_t pos, unsigned copied, void *fsdata); ++ sector_t (*bmap) (struct address_space * mapping, sector_t lblock); ++ /* other private methods */ ++ /* save inode cached stat-data onto disk. It was called ++ reiserfs_update_sd() in 3.x */ ++ int (*write_sd_by_inode) (struct inode *, oid_t *oid); ++ ++ /* Build file body key by inode and offset */ ++ int (*build_body_key) (struct inode *, loff_t off, reiser4_key *); ++ ++ /* NIKITA-FIXME-HANS: this comment is not as clear to others as you ++ * think.... */ ++ /* ++ * set the plugin for a file. Called during file creation in creat() ++ * but not reiser4() unless an inode already exists for the file. ++ */ ++ int (*set_plug_in_inode) (struct inode *inode, struct inode *parent, ++ reiser4_object_create_data *); ++ ++ /* NIKITA-FIXME-HANS: comment and name seem to say different things, ++ * are you setting up the object itself also or just adjusting the ++ * parent?.... */ ++ /* set up plugins for new @object created in @parent. @root is root ++ directory. */ ++ int (*adjust_to_parent) (struct inode *object, struct inode *parent, ++ struct inode *root); ++ /* ++ * this does whatever is necessary to do when object is created. For ++ * instance, for unix files stat data is inserted. It is supposed to be ++ * called by create of struct inode_operations. ++ */ ++ int (*create_object) (struct inode *object, struct inode *parent, ++ reiser4_object_create_data *, oid_t *oid); ++ /* ++ * this method should check REISER4_NO_SD and set REISER4_NO_SD on ++ * success. Deletion of an object usually includes removal of items ++ * building file body (for directories this is removal of "." and "..") ++ * and removal of stat-data item. ++ */ ++ int (*delete_object) (struct inode *); ++ ++ /* add link from @parent to @object */ ++ int (*add_link) (struct inode *object, struct inode *parent); ++ ++ /* remove link from @parent to @object */ ++ int (*rem_link) (struct inode *object, struct inode *parent); ++ ++ /* ++ * return true if item addressed by @coord belongs to @inode. This is ++ * used by read/write to properly slice flow into items in presence of ++ * multiple key assignment policies, because items of a file are not ++ * necessarily contiguous in a key space, for example, in a plan-b. ++ */ ++ int (*owns_item) (const struct inode *, const coord_t *); ++ ++ /* checks whether yet another hard links to this object can be ++ added */ ++ int (*can_add_link) (const struct inode *); ++ ++ /* checks whether hard links to this object can be removed */ ++ int (*can_rem_link) (const struct inode *); ++ ++ /* not empty for DIRECTORY_FILE_PLUGIN_ID only currently. It calls ++ detach of directory plugin to remove ".." */ ++ int (*detach) (struct inode *child, struct inode *parent); ++ ++ /* called when @child was just looked up in the @parent. It is not ++ empty for DIRECTORY_FILE_PLUGIN_ID only where it calls attach of ++ directory plugin */ ++ int (*bind) (struct inode *child, struct inode *parent); ++ ++ /* process safe-link during mount */ ++ int (*safelink) (struct inode *object, reiser4_safe_link_t link, ++ __u64 value); ++ ++ /* The couple of estimate methods for all file operations */ ++ struct { ++ reiser4_block_nr(*create) (const struct inode *); ++ reiser4_block_nr(*update) (const struct inode *); ++ reiser4_block_nr(*unlink) (const struct inode *, ++ const struct inode *); ++ } estimate; ++ ++ /* ++ * reiser4 specific part of inode has a union of structures which are ++ * specific to a plugin. This method is called when inode is read ++ * (read_inode) and when file is created (common_create_child) so that ++ * file plugin could initialize its inode data ++ */ ++ void (*init_inode_data) (struct inode *, reiser4_object_create_data *, ++ const reiser4_key *, int); ++ ++ /* ++ * This method performs progressive deletion of items and whole nodes ++ * from right to left. ++ * ++ * @tap: the point deletion process begins from, ++ * @from_key: the beginning of the deleted key range, ++ * @to_key: the end of the deleted key range, ++ * @smallest_removed: the smallest removed key, ++ * ++ * @return: 0 if success, error code otherwise, -E_REPEAT means that ++ * long cut_tree operation was interrupted for allowing atom commit . ++ */ ++ int (*cut_tree_worker) (tap_t *, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed, struct inode *, ++ int, int *); ++ ++ /* called from ->destroy_inode() */ ++ void (*destroy_inode) (struct inode *); ++ /* ++ * Migrate data blocks of a regular file specified by @inode. ++ * If @dst_id is not NULL, then migrate all the blocks to brick with ++ * @dst_id. Otherwise, migrate in accordance with current distribution ++ * table. ++ */ ++ int (*migrate)(struct inode *object, u64 *dst_id); ++ /* ++ * methods to serialize object identify. This is used, for example, by ++ * reiser4_{en,de}code_fh(). ++ */ ++ struct { ++ /* store object's identity at @area */ ++ char *(*write) (struct inode *inode, char *area); ++ /* parse object from wire to the @obj */ ++ char *(*read) (char *area, reiser4_object_on_wire * obj); ++ /* given object identity in @obj, find or create its dentry */ ++ struct dentry *(*get) (struct super_block *s, ++ reiser4_object_on_wire * obj); ++ /* how many bytes ->wire.write() consumes */ ++ int (*size) (struct inode *inode); ++ /* finish with object identify */ ++ void (*done) (reiser4_object_on_wire * obj); ++ } wire; ++} file_plugin; ++ ++extern file_plugin file_plugins[LAST_FILE_PLUGIN_ID]; ++ ++struct reiser4_object_on_wire { ++ file_plugin *plugin; ++ union { ++ struct { ++ obj_key_id key_id; ++ } std; ++ void *generic; ++ } u; ++}; ++ ++/* builtin dir-plugins */ ++typedef enum { ++ HASHED_DIR_PLUGIN_ID, ++ SEEKABLE_HASHED_DIR_PLUGIN_ID, ++ LAST_DIR_ID ++} reiser4_dir_id; ++ ++typedef struct dir_plugin { ++ /* generic fields */ ++ plugin_header h; ++ ++ struct inode_operations * inode_ops; ++ struct file_operations * file_ops; ++ struct address_space_operations * as_ops; ++ ++ /* ++ * private methods: These are optional. If used they will allow you to ++ * minimize the amount of code needed to implement a deviation from ++ * some other method that uses them. You could logically argue that ++ * they should be a separate type of plugin. ++ */ ++ ++ struct dentry *(*get_parent) (struct inode *childdir); ++ ++ /* ++ * check whether "name" is acceptable name to be inserted into this ++ * object. Optionally implemented by directory-like objects. Can check ++ * for maximal length, reserved symbols etc ++ */ ++ int (*is_name_acceptable) (const struct inode *inode, const char *name, ++ int len); ++ ++ void (*build_entry_key) (const struct inode *dir /* directory where ++ * entry is (or will ++ * be) in.*/ , ++ const struct qstr *name /* name of file ++ * referenced by this ++ * entry */ , ++ reiser4_key * result /* resulting key of ++ * directory entry */ ); ++ int (*build_readdir_key) (struct file *dir, reiser4_key * result); ++ int (*add_entry) (struct inode *object, struct dentry *where, ++ reiser4_object_create_data * data, ++ reiser4_dir_entry_desc * entry); ++ int (*rem_entry) (struct inode *object, struct dentry *where, ++ reiser4_dir_entry_desc * entry); ++ ++ /* ++ * initialize directory structure for newly created object. For normal ++ * unix directories, insert dot and dotdot. ++ */ ++ int (*init) (struct inode *object, struct inode *parent, ++ reiser4_object_create_data * data); ++ ++ /* destroy directory */ ++ int (*done) (struct inode *child); ++ ++ /* called when @subdir was just looked up in the @dir */ ++ int (*attach) (struct inode *subdir, struct inode *dir); ++ int (*detach) (struct inode *subdir, struct inode *dir); ++ ++ struct { ++ reiser4_block_nr(*add_entry) (const struct inode *); ++ reiser4_block_nr(*rem_entry) (const struct inode *); ++ reiser4_block_nr(*unlink) (const struct inode *, ++ const struct inode *); ++ } estimate; ++} dir_plugin; ++ ++extern dir_plugin dir_plugins[LAST_DIR_ID]; ++ ++typedef struct formatting_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* returns non-zero iff file's tail has to be stored ++ in a direct item. */ ++ int (*have_tail) (const struct inode *inode, loff_t size); ++} formatting_plugin; ++ ++/** ++ * Plugins of this interface implement different transaction models. ++ * Transaction model is a high-level block allocator, which assigns block ++ * numbers to dirty nodes, and, thereby, decides, how individual dirty ++ * nodes of an atom will be committed. ++ */ ++typedef struct txmod_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /** ++ * Allocate a formatted node in the FORWARD PARENT-FIRST context. ++ * It can check and re-allocate locality of the formatted node in ++ * the tree. ++ * Was allocate_znode_loaded(). ++ */ ++ int (*forward_alloc_formatted)(znode *node, const coord_t *parent_coord, ++ flush_pos_t *pos); ++ /** ++ * Check if a formatted node should be re-allocated in the ++ * REVERSE PARENT-FIRST context. ++ * If it should be re-allocated, then return 1. Otherwise, return 0. ++ * Was reverse_relocate_test(). ++ */ ++ int (*reverse_should_realloc_formatted)(jnode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos); ++ /** ++ * allocate blocks in the FORWARD PARENT-FIRST context ++ * for unformatted nodes. ++ * ++ * This is called by handle_pos_on_twig to proceed extent unit ++ * flush_pos->coord is set to. It is to prepare for flushing ++ * sequence of not flushprepped nodes (slum). It supposes that ++ * slum starts at flush_pos->pos_in_unit position within the extent ++ */ ++ int (*forward_alloc_unformatted)(flush_pos_t *flush_pos); //was reiser4_alloc_extent ++ /** ++ * allocale blocks for unformatted nodes in squeeze_right_twig(). ++ * @coord is set to extent unit ++ */ ++ squeeze_result (*squeeze_alloc_unformatted)(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *stop_key); // was_squalloc_extent ++} txmod_plugin; ++ ++/* ++ * operations on an array of abstract buckets ++ */ ++struct bucket_ops { ++ /* Get capacity of a bucket with serial number @idx ++ in the array @buckets */ ++ u64 (*cap_at)(bucket_t *buckets, u64 idx); ++ /* Get apx of specified @bucket */ ++ void *(*apx_of)(bucket_t bucket); ++ /* Get apx of a bucket with serial number @idx ++ in the array @buckets */ ++ void *(*apx_at)(bucket_t *buckets, u64 idx); ++ /* Set apx @apx of a bucket with serial number @idx ++ in the array @buckets*/ ++ void (*apx_set_at)(bucket_t *buckets, u64 idx, void *apx); ++ /* Get a pointer to apx length of a bucket with ++ serial number @idx in the array @buckets */ ++ u64 *(*apx_lenp_at)(bucket_t *buckets, u64 idx); ++ /* translate bucket index in the array of abstract buckets ++ to bucket internal ID */ ++ u64 (*idx2id)(u32 idx); ++ /* translate bucket internal ID to bucket index in the array ++ of abstract buckets */ ++ u32 (*id2idx)(u64 id); ++ /* create array of abstract buckets */ ++ bucket_t *(*create_buckets)(void); ++ /* release array of abstract buckets */ ++ void (*free_buckets)(bucket_t *vec); ++ /* insert a bucket @new into array of abstract buckets @vec ++ at position pos */ ++ bucket_t *(*insert_bucket)(bucket_t *vec, bucket_t new, u32 numb, u32 pos); ++ /* remove a bucket located at position @pos in the array of ++ abstract buckets @vec */ ++ bucket_t *(*remove_bucket)(bucket_t *vec, u32 numb, u32 pos); ++ /* return space currently occupied in the abstract array of buckets */ ++ u64 (*space_occupied)(void); ++}; ++ ++struct dist_regular_ops { ++ /* initialize distribution context */ ++ int (*init)(reiser4_dcx *rdcx, void **tab, int nums_bits); ++ ++ /* release distribution context */ ++ void (*done)(void **tab); ++ ++ /* Mapping. For each word @str of length @len it calculates and ++ returns internal ID of a bucket from a set of buckets, which ++ possess abstract capacities. The set of buckets is defined by ++ a configuration pounted out by @rdcx. While calculating that ++ configuration should be protected by some means (e.g. by rcu) ++ from being destroyed by some operation like adding/removing a ++ bucket, atc */ ++ u64 (*lookup)(reiser4_dcx *rdcx, const struct inode *inode, ++ const char *str, int len, u32 seed, void *tab); ++ ++ void (*replace)(reiser4_dcx *rdcx, void **target); ++ void (*free)(void *tab); ++}; ++ ++struct dist_volume_ops { ++ /* Initialize operation context */ ++ int (*init)(void **tab, u64 num_buckets, ++ int num_sgs_bits, reiser4_dcx *rdcx); ++ /* Release operation context */ ++ void (*done)(reiser4_dcx *rdcx); ++ /* Increase array capacity. ++ If @new is not NULL, then insert bucket @new at the position ++ @target_pos in the array. Otherwise, increase capacity of the ++ bucket located at that position */ ++ int (*inc)(reiser4_dcx *rdcx, const void *tab, ++ u64 target_pos, bucket_t new); ++ /* Decrease array capacity. ++ If @old is not NULL, then remove bucket @old. ++ Otherwise, decrease capacity of the bucket located at position ++ @target_pos */ ++ int (*dec)(reiser4_dcx *rdcx, const void *tab, ++ u64 target_pos, bucket_t old); ++ /* Increase current limit for number of buckets in array */ ++ int (*spl)(reiser4_dcx *rdcx, const void *tab, u32 fact_bits); ++ /* Pack configuration for its storing on disk */ ++ void (*pack)(reiser4_dcx *rdcx, char *to, u64 src_off, u64 count); ++ /* Extract configuration from disk */ ++ void (*unpack)(reiser4_dcx *rdcx, void *tab, ++ char *from, u64 dst_off, u64 count); ++ /* Print configuration */ ++ void (*dump)(reiser4_dcx *rdcx, void *tab, ++ char *to, u64 offset, u32 size); ++}; ++ ++typedef struct distribution_plugin { ++ /* generic fields */ ++ plugin_header h; ++ u32 seg_bits; /* logarithm of segment size */ ++ struct dist_regular_ops r; ++ struct dist_volume_ops v; ++} distribution_plugin; ++ ++typedef struct volume_plugin { ++ /* generic fields */ ++ plugin_header h; ++ ++ /* Return meta-data brick internal ID */ ++ u64 (*meta_subvol_id)(void); ++ ++ /* Assign a target brick, where a chunk of data, defined by @inode ++ and @offset, should be stored on. Returns internal ID of the ++ target brick in the volume. Defines regular data distrubution ++ policy on the logical volume with configuration @conf */ ++ u64 (*calc_brick)(lv_conf *conf, const struct inode *inode, ++ loff_t offset); ++ /* Find out, on which brick an extent of data blocks, defined by ++ @coord, is stored. Return internal ID of the found brick in the ++ volume */ ++ u64 (*find_brick)(const coord_t *coord); ++ /* Load a portion of volume configuration contained ++ in its brick @subv. Normally is called at mount time */ ++ int (*load_volume)(reiser4_subvol *subv); ++ /* Release resources associated with logical volume @vol. ++ Normally, is called at unmount time */ ++ void (*done_volume)(reiser4_volume *vol); ++ /* Init logical volume @vol after loading its system info ++ from all its bricks */ ++ int (*init_volume)(struct super_block *sb, reiser4_volume *vol); ++ /* Change data capacity of @brick to new @value */ ++ int (*resize_brick)(reiser4_volume *vol, reiser4_subvol *brick, ++ long long value, int *need_balance); ++ /* Add @new brick to logical volume @vol */ ++ int (*add_brick)(reiser4_volume *vol, reiser4_subvol *new); ++ ++ /* Start brick removal. Build a new volume configuration, which ++ doesn't include @victim and move all data from the @victim to ++ other bricks of the volume @vol */ ++ int (*remove_brick)(reiser4_volume *vol, reiser4_subvol *victim); ++ ++ /* End brick removal. Release resources associated with the brick ++ @victim scheduled for removal. Should be called after successful ++ volume rebalancing, which moves out all data from @victim to ++ other bricks of the volume @vol */ ++ int (*remove_brick_tail)(reiser4_volume *vol, reiser4_subvol *victim); ++ ++ /* Print brick info */ ++ int (*print_brick)(struct super_block *sb, ++ struct reiser4_vol_op_args *args); ++ /* Print volume info */ ++ int (*print_volume)(struct super_block *sb, ++ struct reiser4_vol_op_args *args); ++ /* Increase current limit for number of bricks in a volume */ ++ int (*scale_volume)(struct super_block *sb, unsigned factor_bits); ++ /* ++ * Migrate all data blocks of a regular file to a brick with ++ * serial number @dst_idx (as it is visible by user) */ ++ int (*migrate_file)(struct inode *inode, u64 dst_idx); ++ /* ++ * Migrate data blocks of a logical volume in accordance with ++ * a distribution policy defined by volume configuration and ++ * control @flags ++ */ ++ int (*balance_volume)(struct super_block *super, u32 flags); ++ struct bucket_ops bucket_ops; ++} volume_plugin; ++ ++typedef struct hash_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* computes hash of the given name */ ++ __u64(*hash) (const unsigned char *name, int len); ++} hash_plugin; ++ ++typedef struct cipher_plugin { ++ /* generic fields */ ++ plugin_header h; ++ struct crypto_blkcipher * (*alloc) (void); ++ void (*free) (struct crypto_blkcipher *tfm); ++ /* Offset translator. For each offset this returns (k * offset), where ++ k (k >= 1) is an expansion factor of the cipher algorithm. ++ For all symmetric algorithms k == 1. For asymmetric algorithms (which ++ inflate data) offset translation guarantees that all disk cluster's ++ units will have keys smaller then next cluster's one. ++ */ ++ loff_t(*scale) (struct inode *inode, size_t blocksize, loff_t src); ++ /* Cipher algorithms can accept data only by chunks of cipher block ++ size. This method is to align any flow up to cipher block size when ++ we pass it to cipher algorithm. To align means to append padding of ++ special format specific to the cipher algorithm */ ++ int (*align_stream) (__u8 *tail, int clust_size, int blocksize); ++ /* low-level key manager (check, install, etc..) */ ++ int (*setkey) (struct crypto_tfm *tfm, const __u8 *key, ++ unsigned int keylen); ++ /* main text processing procedures */ ++ void (*encrypt) (__u32 *expkey, __u8 *dst, const __u8 *src); ++ void (*decrypt) (__u32 *expkey, __u8 *dst, const __u8 *src); ++} cipher_plugin; ++ ++typedef struct digest_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* fingerprint size in bytes */ ++ int fipsize; ++ struct crypto_hash * (*alloc) (void); ++ void (*free) (struct crypto_hash *tfm); ++} digest_plugin; ++ ++typedef struct compression_plugin { ++ /* generic fields */ ++ plugin_header h; ++ int (*init) (void); ++ /* the maximum number of bytes the size of the "compressed" data can ++ * exceed the uncompressed data. */ ++ int (*overrun) (unsigned src_len); ++ coa_t(*alloc) (tfm_action act); ++ void (*free) (coa_t coa, tfm_action act); ++ /* minimal size of the flow we still try to compress */ ++ int (*min_size_deflate) (void); ++ __u32(*checksum) (char *data, __u32 length); ++ /* main transform procedures */ ++ void (*compress) (coa_t coa, __u8 *src_first, size_t src_len, ++ __u8 *dst_first, size_t *dst_len); ++ void (*decompress) (coa_t coa, __u8 *src_first, size_t src_len, ++ __u8 *dst_first, size_t *dst_len); ++} compression_plugin; ++ ++typedef struct compression_mode_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* this is called when estimating compressibility ++ of a logical cluster by its content */ ++ int (*should_deflate) (struct inode *inode, cloff_t index); ++ /* this is called when results of compression should be saved */ ++ int (*accept_hook) (struct inode *inode, cloff_t index); ++ /* this is called when results of compression should be discarded */ ++ int (*discard_hook) (struct inode *inode, cloff_t index); ++} compression_mode_plugin; ++ ++typedef struct cluster_plugin { ++ /* generic fields */ ++ plugin_header h; ++ int shift; ++} cluster_plugin; ++ ++typedef struct sd_ext_plugin { ++ /* generic fields */ ++ plugin_header h; ++ int (*present) (struct inode *inode, char **area, int *len); ++ int (*absent) (struct inode *inode); ++ int (*save_len) (struct inode *inode); ++ int (*save) (struct inode *inode, char **area); ++ /* alignment requirement for this stat-data part */ ++ int alignment; ++} sd_ext_plugin; ++ ++/* this plugin contains methods to allocate objectid for newly created files, ++ to deallocate objectid when file gets removed, to report number of used and ++ free objectids */ ++typedef struct oid_allocator_plugin { ++ /* generic fields */ ++ plugin_header h; ++ int (*init_oid_allocator) (reiser4_oid_allocator * map, __u64 nr_files, ++ __u64 oids); ++ /* used to report statfs->f_files */ ++ __u64(*oids_used) (reiser4_oid_allocator * map); ++ /* get next oid to use */ ++ __u64(*next_oid) (reiser4_oid_allocator * map); ++ /* used to report statfs->f_ffree */ ++ __u64(*oids_free) (reiser4_oid_allocator * map); ++ /* allocate new objectid */ ++ int (*allocate_oid) (reiser4_oid_allocator * map, oid_t *); ++ /* release objectid */ ++ int (*release_oid) (reiser4_oid_allocator * map, oid_t); ++ /* how many pages to reserve in transaction for allocation of new ++ objectid */ ++ int (*oid_reserve_allocate) (reiser4_oid_allocator * map); ++ /* how many pages to reserve in transaction for freeing of an ++ objectid */ ++ int (*oid_reserve_release) (reiser4_oid_allocator * map); ++ void (*print_info) (const char *, reiser4_oid_allocator *); ++} oid_allocator_plugin; ++ ++/* disk layout plugin: this specifies super block, journal, bitmap (if there ++ are any) locations, etc */ ++typedef struct disk_format_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* Read format super-block from disk, find internal subvolume ID ++ and store it in @subv_id */ ++ int (*extract_subvol_id)(struct block_device *bdev, u64 *subv_id); ++ /* replay journal, initialize super_info_data, etc */ ++ int (*init_format) (struct super_block *, reiser4_subvol *); ++ /* key of root directory stat data */ ++ const reiser4_key * (*root_dir_key) (const struct super_block *); ++ int (*release_format) (struct super_block *, reiser4_subvol *); ++ jnode * (*log_super) (struct super_block *, reiser4_subvol *); ++ int (*check_open) (const struct inode *object); ++ /* ++ * Decide, if minor disk format version number in format ++ * super-block should be upgraded. ++ * If no, then return 0. If yes, then put format super-block into ++ * a transaction and return 1. In this case the caller should put ++ * additional efforts to commit that transaction (if needed). ++ * In the case of errors return <0. ++ */ ++ int (*version_update) (struct super_block *, reiser4_subvol *); ++} disk_format_plugin; ++ ++struct jnode_plugin { ++ /* generic fields */ ++ plugin_header h; ++ int (*init) (jnode *node); ++ /* verify validness of node's content */ ++ int (*parse) (jnode *node); ++ struct address_space *(*mapping) (const jnode *node); ++ unsigned long (*index) (const jnode *node); ++}; ++ ++/* plugin instance. */ ++/* */ ++/* This is "wrapper" union for all types of plugins. Most of the code uses */ ++/* plugins of particular type (file_plugin, dir_plugin, etc.) rather than */ ++/* operates with pointers to reiser4_plugin. This union is only used in */ ++/* some generic code in plugin/plugin.c that operates on all */ ++/* plugins. Technically speaking purpose of this union is to add type */ ++/* safety to said generic code: each plugin type (file_plugin, for */ ++/* example), contains plugin_header as its first memeber. This first member */ ++/* is located at the same place in memory as .h member of */ ++/* reiser4_plugin. Generic code, obtains pointer to reiser4_plugin and */ ++/* looks in the .h which is header of plugin type located in union. This */ ++/* allows to avoid type-casts. */ ++union reiser4_plugin { ++ /* generic fields */ ++ plugin_header h; ++ /* file plugin */ ++ file_plugin file; ++ /* directory plugin */ ++ dir_plugin dir; ++ /* hash plugin, used by directory plugin */ ++ hash_plugin hash; ++ /* fibration plugin used by directory plugin */ ++ fibration_plugin fibration; ++ /* cipher transform plugin, used by file plugin */ ++ cipher_plugin cipher; ++ /* digest transform plugin, used by file plugin */ ++ digest_plugin digest; ++ /* compression transform plugin, used by file plugin */ ++ compression_plugin compression; ++ /* tail plugin, used by file plugin */ ++ formatting_plugin formatting; ++ /* permission plugin */ ++ perm_plugin perm; ++ /* node plugin */ ++ node_plugin node; ++ /* item plugin */ ++ item_plugin item; ++ /* stat-data extension plugin */ ++ sd_ext_plugin sd_ext; ++ /* disk layout plugin */ ++ disk_format_plugin format; ++ /* object id allocator plugin */ ++ oid_allocator_plugin oid_allocator; ++ /* plugin for different jnode types */ ++ jnode_plugin jnode; ++ /* compression mode plugin, used by object plugin */ ++ compression_mode_plugin compression_mode; ++ /* cluster plugin, used by object plugin */ ++ cluster_plugin clust; ++ /* transaction mode plugin */ ++ txmod_plugin txmod; ++ /* distribution plugin */ ++ distribution_plugin distribution; ++ /* volume plugin */ ++ volume_plugin volume; ++ /* place-holder for new plugin types that can be registered ++ dynamically, and used by other dynamically loaded plugins. */ ++ void *generic; ++}; ++ ++struct reiser4_plugin_ops { ++ /* called when plugin is initialized */ ++ int (*init) (reiser4_plugin * plugin); ++ /* called when plugin is unloaded */ ++ int (*done) (reiser4_plugin * plugin); ++ /* load given plugin from disk */ ++ int (*load) (struct inode *inode, ++ reiser4_plugin * plugin, char **area, int *len); ++ /* how many space is required to store this plugin's state ++ in stat-data */ ++ int (*save_len) (struct inode *inode, reiser4_plugin * plugin); ++ /* save persistent plugin-data to disk */ ++ int (*save) (struct inode *inode, reiser4_plugin * plugin, ++ char **area); ++ /* alignment requirement for on-disk state of this plugin ++ in number of bytes */ ++ int alignment; ++ /* install itself into given inode. This can return error ++ (e.g., you cannot change hash of non-empty directory). */ ++ int (*change) (struct inode *inode, reiser4_plugin * plugin, ++ pset_member memb); ++ /* install itself into given inode. This can return error ++ (e.g., you cannot change hash of non-empty directory). */ ++ int (*inherit) (struct inode *inode, struct inode *parent, ++ reiser4_plugin * plugin); ++}; ++ ++/* functions implemented in fs/reiser4/plugin/plugin.c */ ++ ++/* stores plugin reference in reiser4-specific part of inode */ ++extern int set_object_plugin(struct inode *inode, reiser4_plugin_id id); ++extern int init_plugins(void); ++ ++/* builtin plugins */ ++ ++/* builtin hash-plugins */ ++ ++typedef enum { ++ RUPASOV_HASH_ID, ++ R5_HASH_ID, ++ TEA_HASH_ID, ++ FNV1_HASH_ID, ++ DEGENERATE_HASH_ID, ++ LAST_HASH_ID ++} reiser4_hash_id; ++ ++/* builtin cipher plugins */ ++ ++typedef enum { ++ NONE_CIPHER_ID, ++ LAST_CIPHER_ID ++} reiser4_cipher_id; ++ ++/* builtin digest plugins */ ++ ++typedef enum { ++ SHA256_32_DIGEST_ID, ++ LAST_DIGEST_ID ++} reiser4_digest_id; ++ ++/* builtin compression mode plugins */ ++typedef enum { ++ NONE_COMPRESSION_MODE_ID, ++ LATTD_COMPRESSION_MODE_ID, ++ ULTIM_COMPRESSION_MODE_ID, ++ FORCE_COMPRESSION_MODE_ID, ++ CONVX_COMPRESSION_MODE_ID, ++ LAST_COMPRESSION_MODE_ID ++} reiser4_compression_mode_id; ++ ++/* builtin cluster plugins */ ++typedef enum { ++ CLUSTER_64K_ID, ++ CLUSTER_32K_ID, ++ CLUSTER_16K_ID, ++ CLUSTER_8K_ID, ++ CLUSTER_4K_ID, ++ LAST_CLUSTER_ID ++} reiser4_cluster_id; ++ ++/* builtin tail packing policies */ ++typedef enum { ++ NEVER_TAILS_FORMATTING_ID, ++ ALWAYS_TAILS_FORMATTING_ID, ++ SMALL_FILE_FORMATTING_ID, ++ LAST_TAIL_FORMATTING_ID ++} reiser4_formatting_id; ++ ++/* builtin transaction models */ ++typedef enum { ++ HYBRID_TXMOD_ID, ++ JOURNAL_TXMOD_ID, ++ WA_TXMOD_ID, ++ LAST_TXMOD_ID ++} reiser4_txmod_id; ++ ++/* builtin distribution plugins */ ++typedef enum { ++ TRIV_DISTRIB_ID, /* for simple volumes */ ++ FSX32M_DISTRIB_ID, /* builtin distribution of Eduard Shishkin */ ++ LAST_DISTRIB_ID ++} reiser4_distribution_id; ++ ++/* builtin volume plugins */ ++typedef enum { ++ SIMPLE_VOLUME_ID, /* for volumes 4.X.Y and simple volumes 5.X.Y */ ++ ASYM_VOLUME_ID, /* for logical volumes 5.X.Y */ ++ LAST_VOLUME_ID ++} reiser4_volume_id; ++ ++/* data type used to pack parameters that we pass to vfs object creation ++ function create_object() */ ++struct reiser4_object_create_data { ++ /* plugin to control created object */ ++ reiser4_file_id id; ++ /* mode of regular file, directory or special file */ ++/* what happens if some other sort of perm plugin is in use? */ ++ umode_t mode; ++ /* rdev of special file */ ++ dev_t rdev; ++ /* symlink target */ ++ const char *name; ++ /* add here something for non-standard objects you invent, like ++ query for interpolation file etc. */ ++ ++ struct reiser4_crypto_info *crypto; ++ ++ struct inode *parent; ++ struct dentry *dentry; ++}; ++ ++/* description of directory entry being created/destroyed/sought for ++ ++ It is passed down to the directory plugin and farther to the ++ directory item plugin methods. Creation of new directory is done in ++ several stages: first we search for an entry with the same name, then ++ create new one. reiser4_dir_entry_desc is used to store some information ++ collected at some stage of this process and required later: key of ++ item that we want to insert/delete and pointer to an object that will ++ be bound by the new directory entry. Probably some more fields will ++ be added there. ++ ++*/ ++struct reiser4_dir_entry_desc { ++ /* key of directory entry */ ++ reiser4_key key; ++ /* object bound by this entry. */ ++ struct inode *obj; ++}; ++ ++#define MAX_PLUGIN_TYPE_LABEL_LEN 32 ++#define MAX_PLUGIN_PLUG_LABEL_LEN 32 ++ ++#define PLUGIN_BY_ID(TYPE, ID, FIELD) \ ++static inline TYPE *TYPE ## _by_id(reiser4_plugin_id id) \ ++{ \ ++ reiser4_plugin *plugin = plugin_by_id(ID, id); \ ++ return plugin ? &plugin->FIELD : NULL; \ ++} \ ++static inline TYPE *TYPE ## _by_disk_id(d16 *id) \ ++{ \ ++ reiser4_plugin *plugin = plugin_by_disk_id(ID, id); \ ++ return plugin ? &plugin->FIELD : NULL; \ ++} \ ++static inline TYPE *TYPE ## _by_unsafe_id(reiser4_plugin_id id) \ ++{ \ ++ reiser4_plugin *plugin = plugin_by_unsafe_id(ID, id); \ ++ return plugin ? &plugin->FIELD : NULL; \ ++} \ ++static inline reiser4_plugin* TYPE ## _to_plugin(TYPE* plugin) \ ++{ \ ++ return (reiser4_plugin *) plugin; \ ++} \ ++static inline reiser4_plugin_id TYPE ## _id(TYPE* plugin) \ ++{ \ ++ return TYPE ## _to_plugin(plugin)->h.id; \ ++} \ ++typedef struct { int foo; } TYPE ## _plugin_dummy ++ ++ ++static inline unsigned get_release_number_principal(void) ++{ ++ return REISER4_VERSION_PRINCIPAL; ++} ++ ++/** ++ * Guess principal format number by major release number ++ */ ++static inline int get_format_number_principal(int major) ++{ ++ switch (major) { ++ case 0: ++ case 1: ++ return 4 + major; ++ default: ++ impossible("edward-2429", "Unsupported major release number"); ++ } ++ return 0; ++} ++ ++static inline int get_release_number_major(void) ++{ ++ return LAST_FORMAT_ID - 1; ++} ++ ++static inline int get_release_number_minor(void) ++{ ++ return PLUGIN_LIBRARY_VERSION; ++} ++ ++PLUGIN_BY_ID(item_plugin, REISER4_ITEM_PLUGIN_TYPE, item); ++PLUGIN_BY_ID(file_plugin, REISER4_FILE_PLUGIN_TYPE, file); ++PLUGIN_BY_ID(dir_plugin, REISER4_DIR_PLUGIN_TYPE, dir); ++PLUGIN_BY_ID(node_plugin, REISER4_NODE_PLUGIN_TYPE, node); ++PLUGIN_BY_ID(sd_ext_plugin, REISER4_SD_EXT_PLUGIN_TYPE, sd_ext); ++PLUGIN_BY_ID(perm_plugin, REISER4_PERM_PLUGIN_TYPE, perm); ++PLUGIN_BY_ID(hash_plugin, REISER4_HASH_PLUGIN_TYPE, hash); ++PLUGIN_BY_ID(fibration_plugin, REISER4_FIBRATION_PLUGIN_TYPE, fibration); ++PLUGIN_BY_ID(cipher_plugin, REISER4_CIPHER_PLUGIN_TYPE, cipher); ++PLUGIN_BY_ID(digest_plugin, REISER4_DIGEST_PLUGIN_TYPE, digest); ++PLUGIN_BY_ID(compression_plugin, REISER4_COMPRESSION_PLUGIN_TYPE, compression); ++PLUGIN_BY_ID(formatting_plugin, REISER4_FORMATTING_PLUGIN_TYPE, formatting); ++PLUGIN_BY_ID(disk_format_plugin, REISER4_FORMAT_PLUGIN_TYPE, format); ++PLUGIN_BY_ID(jnode_plugin, REISER4_JNODE_PLUGIN_TYPE, jnode); ++PLUGIN_BY_ID(compression_mode_plugin, REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ compression_mode); ++PLUGIN_BY_ID(cluster_plugin, REISER4_CLUSTER_PLUGIN_TYPE, clust); ++PLUGIN_BY_ID(txmod_plugin, REISER4_TXMOD_PLUGIN_TYPE, txmod); ++PLUGIN_BY_ID(distribution_plugin, REISER4_DISTRIBUTION_PLUGIN_TYPE, ++ distribution); ++PLUGIN_BY_ID(volume_plugin, REISER4_VOLUME_PLUGIN_TYPE, volume); ++ ++extern int save_plugin_id(reiser4_plugin * plugin, d16 * area); ++ ++extern struct list_head *get_plugin_list(reiser4_plugin_type type_id); ++ ++#define for_all_plugins(ptype, plugin) \ ++for (plugin = list_entry(get_plugin_list(ptype)->next, reiser4_plugin, h.linkage); \ ++ get_plugin_list(ptype) != &plugin->h.linkage; \ ++ plugin = list_entry(plugin->h.linkage.next, reiser4_plugin, h.linkage)) ++ ++ ++extern int grab_plugin_pset(struct inode *self, struct inode *ancestor, ++ pset_member memb); ++extern int force_plugin_pset(struct inode *self, pset_member memb, ++ reiser4_plugin *plug); ++extern int finish_pset(struct inode *inode); ++ ++/* defined in fs/reiser4/plugin/object.c */ ++extern file_plugin file_plugins[LAST_FILE_PLUGIN_ID]; ++/* defined in fs/reiser4/plugin/object.c */ ++extern dir_plugin dir_plugins[LAST_DIR_ID]; ++/* defined in fs/reiser4/plugin/item/static_stat.c */ ++extern sd_ext_plugin sd_ext_plugins[LAST_SD_EXTENSION]; ++/* defined in fs/reiser4/plugin/hash.c */ ++extern hash_plugin hash_plugins[LAST_HASH_ID]; ++/* defined in fs/reiser4/plugin/fibration.c */ ++extern fibration_plugin fibration_plugins[LAST_FIBRATION_ID]; ++/* defined in fs/reiser4/plugin/txmod.c */ ++extern txmod_plugin txmod_plugins[LAST_TXMOD_ID]; ++/* defined in fs/reiser4/plugin/distribution.c */ ++extern distribution_plugin distribution_plugins[LAST_DISTRIB_ID]; ++/* defined in fs/reiser4/plugin/volume.c */ ++extern volume_plugin volume_plugins[LAST_VOLUME_ID]; ++/* defined in fs/reiser4/plugin/crypt.c */ ++extern cipher_plugin cipher_plugins[LAST_CIPHER_ID]; ++/* defined in fs/reiser4/plugin/digest.c */ ++extern digest_plugin digest_plugins[LAST_DIGEST_ID]; ++/* defined in fs/reiser4/plugin/compress/compress.c */ ++extern compression_plugin compression_plugins[LAST_COMPRESSION_ID]; ++/* defined in fs/reiser4/plugin/compress/compression_mode.c */ ++extern compression_mode_plugin ++compression_mode_plugins[LAST_COMPRESSION_MODE_ID]; ++/* defined in fs/reiser4/plugin/cluster.c */ ++extern cluster_plugin cluster_plugins[LAST_CLUSTER_ID]; ++/* defined in fs/reiser4/plugin/tail.c */ ++extern formatting_plugin formatting_plugins[LAST_TAIL_FORMATTING_ID]; ++/* defined in fs/reiser4/plugin/security/security.c */ ++extern perm_plugin perm_plugins[LAST_PERM_ID]; ++/* defined in fs/reiser4/plugin/item/item.c */ ++extern item_plugin item_plugins[LAST_ITEM_ID]; ++/* defined in fs/reiser4/plugin/node/node.c */ ++extern node_plugin node_plugins[LAST_NODE_ID]; ++/* defined in fs/reiser4/plugin/disk_format/disk_format.c */ ++extern disk_format_plugin format_plugins[LAST_FORMAT_ID]; ++ ++/* __FS_REISER4_PLUGIN_TYPES_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/plugin_header.h linux-5.10.2/fs/reiser4/plugin/plugin_header.h +--- linux-5.10.2.orig/fs/reiser4/plugin/plugin_header.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/plugin_header.h 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,151 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* plugin header. Data structures required by all plugin types. */ ++ ++#if !defined(__PLUGIN_HEADER_H__) ++#define __PLUGIN_HEADER_H__ ++ ++/* plugin data-types and constants */ ++ ++#include "../debug.h" ++#include "../dformat.h" ++ ++/* The list of Reiser4 interfaces */ ++typedef enum { ++ REISER4_FILE_PLUGIN_TYPE, /* manage VFS objects */ ++ REISER4_DIR_PLUGIN_TYPE, /* manage directories */ ++ REISER4_ITEM_PLUGIN_TYPE, /* manage items */ ++ REISER4_NODE_PLUGIN_TYPE, /* manage formatted nodes */ ++ REISER4_HASH_PLUGIN_TYPE, /* hash methods */ ++ REISER4_FIBRATION_PLUGIN_TYPE, /* directory fibrations */ ++ REISER4_FORMATTING_PLUGIN_TYPE, /* dispatching policy */ ++ REISER4_PERM_PLUGIN_TYPE, /* stub (vacancy) */ ++ REISER4_SD_EXT_PLUGIN_TYPE, /* manage stat-data extensions */ ++ REISER4_FORMAT_PLUGIN_TYPE, /* disk format specifications */ ++ REISER4_JNODE_PLUGIN_TYPE, /* manage in-memory headers */ ++ REISER4_CIPHER_PLUGIN_TYPE, /* cipher transform methods */ ++ REISER4_DIGEST_PLUGIN_TYPE, /* digest transform methods */ ++ REISER4_COMPRESSION_PLUGIN_TYPE, /* compression methods */ ++ REISER4_COMPRESSION_MODE_PLUGIN_TYPE, /* dispatching policies */ ++ REISER4_CLUSTER_PLUGIN_TYPE, /* manage logical clusters */ ++ REISER4_TXMOD_PLUGIN_TYPE, /* transaction models */ ++ REISER4_DISTRIBUTION_PLUGIN_TYPE, /* distribution algorithm */ ++ REISER4_VOLUME_PLUGIN_TYPE, /* volume types */ ++ REISER4_PLUGIN_TYPES ++} reiser4_plugin_type; ++ ++/* Supported plugin groups */ ++typedef enum { ++ REISER4_DIRECTORY_FILE, ++ REISER4_REGULAR_FILE, ++ REISER4_SYMLINK_FILE, ++ REISER4_SPECIAL_FILE, ++} file_plugin_group; ++ ++struct reiser4_plugin_ops; ++/* generic plugin operations, supported by each ++ plugin type. */ ++typedef struct reiser4_plugin_ops reiser4_plugin_ops; ++ ++/* the common part of all plugin instances. */ ++typedef struct plugin_header { ++ /* plugin type */ ++ reiser4_plugin_type type_id; ++ /* id of this plugin */ ++ reiser4_plugin_id id; ++ /* bitmask of groups the plugin belongs to. */ ++ reiser4_plugin_groups groups; ++ /* plugin operations */ ++ reiser4_plugin_ops *pops; ++/* NIKITA-FIXME-HANS: usage of and access to label and desc is not commented and ++ * defined. */ ++ /* short label of this plugin */ ++ const char *label; ++ /* descriptive string.. */ ++ const char *desc; ++ /* list linkage */ ++ struct list_head linkage; ++} plugin_header; ++ ++#define plugin_of_group(plug, group) (plug->h.groups & (1 << group)) ++ ++/* PRIVATE INTERFACES */ ++/* NIKITA-FIXME-HANS: what is this for and why does it duplicate what is in ++ * plugin_header? */ ++/* plugin type representation. */ ++struct reiser4_plugin_type_data { ++ /* internal plugin type identifier. Should coincide with ++ index of this item in plugins[] array. */ ++ reiser4_plugin_type type_id; ++ /* short symbolic label of this plugin type. Should be no longer ++ than MAX_PLUGIN_TYPE_LABEL_LEN characters including '\0'. */ ++ const char *label; ++ /* plugin type description longer than .label */ ++ const char *desc; ++ ++/* NIKITA-FIXME-HANS: define built-in */ ++ /* number of built-in plugin instances of this type */ ++ int builtin_num; ++ /* array of built-in plugins */ ++ void *builtin; ++ struct list_head plugins_list; ++ size_t size; ++}; ++ ++extern struct reiser4_plugin_type_data plugins[REISER4_PLUGIN_TYPES]; ++ ++int is_plugin_type_valid(reiser4_plugin_type type); ++int is_plugin_id_valid(reiser4_plugin_type type, reiser4_plugin_id id); ++ ++static inline reiser4_plugin *plugin_at(struct reiser4_plugin_type_data *ptype, ++ int i) ++{ ++ char *builtin; ++ ++ builtin = ptype->builtin; ++ return (reiser4_plugin *) (builtin + i * ptype->size); ++} ++ ++/* return plugin by its @type_id and @id */ ++static inline reiser4_plugin *plugin_by_id(reiser4_plugin_type type, ++ reiser4_plugin_id id) ++{ ++ assert("nikita-1651", is_plugin_type_valid(type)); ++ assert("nikita-1652", is_plugin_id_valid(type, id)); ++ return plugin_at(&plugins[type], id); ++} ++ ++extern reiser4_plugin *plugin_by_unsafe_id(reiser4_plugin_type type_id, ++ reiser4_plugin_id id); ++ ++/** ++ * plugin_by_disk_id - get reiser4_plugin ++ * @type_id: plugin type id ++ * @did: plugin id in disk format ++ * ++ * Returns reiser4_plugin by plugin type id an dplugin_id. ++ */ ++static inline reiser4_plugin *plugin_by_disk_id(reiser4_plugin_type type_id, ++ __le16 *plugin_id) ++{ ++ /* ++ * what we should do properly is to maintain within each file-system a ++ * dictionary that maps on-disk plugin ids to "universal" ids. This ++ * dictionary will be resolved on mount time, so that this function ++ * will perform just one additional array lookup. ++ */ ++ return plugin_by_unsafe_id(type_id, le16_to_cpu(*plugin_id)); ++} ++ ++/* __PLUGIN_HEADER_H__ */ ++#endif ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/plugin_set.c linux-5.10.2/fs/reiser4/plugin/plugin_set.c +--- linux-5.10.2.orig/fs/reiser4/plugin/plugin_set.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/plugin_set.c 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,387 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++/* This file contains Reiser4 plugin set operations */ ++ ++/* plugin sets ++ * ++ * Each file in reiser4 is controlled by a whole set of plugins (file plugin, ++ * directory plugin, hash plugin, tail policy plugin, security plugin, etc.) ++ * assigned (inherited, deduced from mode bits, etc.) at creation time. This ++ * set of plugins (so called pset) is described by structure plugin_set (see ++ * plugin/plugin_set.h), which contains pointers to all required plugins. ++ * ++ * Children can inherit some pset members from their parent, however sometimes ++ * it is useful to specify members different from parent ones. Since object's ++ * pset can not be easily changed without fatal consequences, we use for this ++ * purpose another special plugin table (so called hset, or heir set) described ++ * by the same structure. ++ * ++ * Inode only stores a pointers to pset and hset. Different inodes with the ++ * same set of pset (hset) members point to the same pset (hset). This is ++ * archived by storing psets and hsets in global hash table. Races are avoided ++ * by simple (and efficient so far) solution of never recycling psets, even ++ * when last inode pointing to it is destroyed. ++ */ ++ ++#include "../debug.h" ++#include "../super.h" ++#include "plugin_set.h" ++ ++#include ++#include ++ ++/* slab for plugin sets */ ++static struct kmem_cache *plugin_set_slab; ++ ++static spinlock_t plugin_set_lock[8] __cacheline_aligned_in_smp = { ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[0]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[1]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[2]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[3]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[4]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[5]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[6]), ++ __SPIN_LOCK_UNLOCKED(plugin_set_lock[7]) ++}; ++ ++/* hash table support */ ++ ++#define PS_TABLE_SIZE (32) ++ ++static inline plugin_set *cast_to(const unsigned long *a) ++{ ++ return container_of(a, plugin_set, hashval); ++} ++ ++static inline int pseq(const unsigned long *a1, const unsigned long *a2) ++{ ++ plugin_set *set1; ++ plugin_set *set2; ++ ++ /* make sure fields are not missed in the code below */ ++ static_assert(sizeof *set1 == ++ sizeof set1->hashval + ++ sizeof set1->link + ++ sizeof set1->file + ++ sizeof set1->dir + ++ sizeof set1->perm + ++ sizeof set1->formatting + ++ sizeof set1->hash + ++ sizeof set1->fibration + ++ sizeof set1->sd + ++ sizeof set1->dir_item + ++ sizeof set1->cipher + ++ sizeof set1->digest + ++ sizeof set1->compression + ++ sizeof set1->compression_mode + ++ sizeof set1->cluster + ++ sizeof set1->create); ++ ++ set1 = cast_to(a1); ++ set2 = cast_to(a2); ++ return ++ set1->hashval == set2->hashval && ++ set1->file == set2->file && ++ set1->dir == set2->dir && ++ set1->perm == set2->perm && ++ set1->formatting == set2->formatting && ++ set1->hash == set2->hash && ++ set1->fibration == set2->fibration && ++ set1->sd == set2->sd && ++ set1->dir_item == set2->dir_item && ++ set1->cipher == set2->cipher && ++ set1->digest == set2->digest && ++ set1->compression == set2->compression && ++ set1->compression_mode == set2->compression_mode && ++ set1->cluster == set2->cluster && ++ set1->create == set2->create; ++} ++ ++#define HASH_FIELD(hash, set, field) \ ++({ \ ++ (hash) += (unsigned long)(set)->field >> 2; \ ++}) ++ ++static inline unsigned long calculate_hash(const plugin_set * set) ++{ ++ unsigned long result; ++ ++ result = 0; ++ HASH_FIELD(result, set, file); ++ HASH_FIELD(result, set, dir); ++ HASH_FIELD(result, set, perm); ++ HASH_FIELD(result, set, formatting); ++ HASH_FIELD(result, set, hash); ++ HASH_FIELD(result, set, fibration); ++ HASH_FIELD(result, set, sd); ++ HASH_FIELD(result, set, dir_item); ++ HASH_FIELD(result, set, cipher); ++ HASH_FIELD(result, set, digest); ++ HASH_FIELD(result, set, compression); ++ HASH_FIELD(result, set, compression_mode); ++ HASH_FIELD(result, set, cluster); ++ HASH_FIELD(result, set, create); ++ return result & (PS_TABLE_SIZE - 1); ++} ++ ++static inline unsigned long ++pshash(ps_hash_table * table, const unsigned long *a) ++{ ++ return *a; ++} ++ ++/* The hash table definition */ ++#define KMALLOC(size) kmalloc((size), reiser4_ctx_gfp_mask_get()) ++#define KFREE(ptr, size) kfree(ptr) ++TYPE_SAFE_HASH_DEFINE(ps, plugin_set, unsigned long, hashval, link, pshash, ++ pseq); ++#undef KFREE ++#undef KMALLOC ++ ++static ps_hash_table ps_table; ++static plugin_set empty_set = { ++ .hashval = 0, ++ .file = NULL, ++ .dir = NULL, ++ .perm = NULL, ++ .formatting = NULL, ++ .hash = NULL, ++ .fibration = NULL, ++ .sd = NULL, ++ .dir_item = NULL, ++ .cipher = NULL, ++ .digest = NULL, ++ .compression = NULL, ++ .compression_mode = NULL, ++ .cluster = NULL, ++ .create = NULL, ++ .link = {NULL} ++}; ++ ++plugin_set *plugin_set_get_empty(void) ++{ ++ return &empty_set; ++} ++ ++void plugin_set_put(plugin_set * set) ++{ ++} ++ ++static inline unsigned long *pset_field(plugin_set * set, int offset) ++{ ++ return (unsigned long *)(((char *)set) + offset); ++} ++ ++static int plugin_set_field(plugin_set ** set, const unsigned long val, ++ const int offset) ++{ ++ unsigned long *spot; ++ spinlock_t *lock; ++ plugin_set replica; ++ plugin_set *twin; ++ plugin_set *psal; ++ plugin_set *orig; ++ ++ assert("nikita-2902", set != NULL); ++ assert("nikita-2904", *set != NULL); ++ ++ spot = pset_field(*set, offset); ++ if (unlikely(*spot == val)) ++ return 0; ++ ++ replica = *(orig = *set); ++ *pset_field(&replica, offset) = val; ++ replica.hashval = calculate_hash(&replica); ++ rcu_read_lock(); ++ twin = ps_hash_find(&ps_table, &replica.hashval); ++ if (unlikely(twin == NULL)) { ++ rcu_read_unlock(); ++ psal = kmem_cache_alloc(plugin_set_slab, ++ reiser4_ctx_gfp_mask_get()); ++ if (psal == NULL) ++ return RETERR(-ENOMEM); ++ *psal = replica; ++ lock = &plugin_set_lock[replica.hashval & 7]; ++ spin_lock(lock); ++ twin = ps_hash_find(&ps_table, &replica.hashval); ++ if (likely(twin == NULL)) { ++ *set = psal; ++ ps_hash_insert_rcu(&ps_table, psal); ++ } else { ++ *set = twin; ++ kmem_cache_free(plugin_set_slab, psal); ++ } ++ spin_unlock(lock); ++ } else { ++ rcu_read_unlock(); ++ *set = twin; ++ } ++ return 0; ++} ++ ++static struct { ++ int offset; ++ reiser4_plugin_groups groups; ++ reiser4_plugin_type type; ++} pset_descr[PSET_LAST] = { ++ [PSET_FILE] = { ++ .offset = offsetof(plugin_set, file), ++ .type = REISER4_FILE_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_DIR] = { ++ .offset = offsetof(plugin_set, dir), ++ .type = REISER4_DIR_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_PERM] = { ++ .offset = offsetof(plugin_set, perm), ++ .type = REISER4_PERM_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_FORMATTING] = { ++ .offset = offsetof(plugin_set, formatting), ++ .type = REISER4_FORMATTING_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_HASH] = { ++ .offset = offsetof(plugin_set, hash), ++ .type = REISER4_HASH_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_FIBRATION] = { ++ .offset = offsetof(plugin_set, fibration), ++ .type = REISER4_FIBRATION_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_SD] = { ++ .offset = offsetof(plugin_set, sd), ++ .type = REISER4_ITEM_PLUGIN_TYPE, ++ .groups = (1 << STAT_DATA_ITEM_TYPE) ++ }, ++ [PSET_DIR_ITEM] = { ++ .offset = offsetof(plugin_set, dir_item), ++ .type = REISER4_ITEM_PLUGIN_TYPE, ++ .groups = (1 << DIR_ENTRY_ITEM_TYPE) ++ }, ++ [PSET_CIPHER] = { ++ .offset = offsetof(plugin_set, cipher), ++ .type = REISER4_CIPHER_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_DIGEST] = { ++ .offset = offsetof(plugin_set, digest), ++ .type = REISER4_DIGEST_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_COMPRESSION] = { ++ .offset = offsetof(plugin_set, compression), ++ .type = REISER4_COMPRESSION_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_COMPRESSION_MODE] = { ++ .offset = offsetof(plugin_set, compression_mode), ++ .type = REISER4_COMPRESSION_MODE_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_CLUSTER] = { ++ .offset = offsetof(plugin_set, cluster), ++ .type = REISER4_CLUSTER_PLUGIN_TYPE, ++ .groups = 0 ++ }, ++ [PSET_CREATE] = { ++ .offset = offsetof(plugin_set, create), ++ .type = REISER4_FILE_PLUGIN_TYPE, ++ .groups = (1 << REISER4_REGULAR_FILE) ++ } ++}; ++ ++#define DEFINE_PSET_OPS(PREFIX) \ ++ reiser4_plugin_type PREFIX##_member_to_type_unsafe(pset_member memb) \ ++{ \ ++ if (memb > PSET_LAST) \ ++ return REISER4_PLUGIN_TYPES; \ ++ return pset_descr[memb].type; \ ++} \ ++ \ ++int PREFIX##_set_unsafe(plugin_set ** set, pset_member memb, \ ++ reiser4_plugin * plugin) \ ++{ \ ++ assert("nikita-3492", set != NULL); \ ++ assert("nikita-3493", *set != NULL); \ ++ assert("nikita-3494", plugin != NULL); \ ++ assert("nikita-3495", 0 <= memb && memb < PSET_LAST); \ ++ assert("nikita-3496", plugin->h.type_id == pset_descr[memb].type); \ ++ \ ++ if (pset_descr[memb].groups) \ ++ if (!(pset_descr[memb].groups & plugin->h.groups)) \ ++ return -EINVAL; \ ++ \ ++ return plugin_set_field(set, \ ++ (unsigned long)plugin, pset_descr[memb].offset); \ ++} \ ++ \ ++reiser4_plugin *PREFIX##_get(plugin_set * set, pset_member memb) \ ++{ \ ++ assert("nikita-3497", set != NULL); \ ++ assert("nikita-3498", 0 <= memb && memb < PSET_LAST); \ ++ \ ++ return *(reiser4_plugin **) (((char *)set) + pset_descr[memb].offset); \ ++} ++ ++DEFINE_PSET_OPS(aset); ++ ++int set_plugin(plugin_set ** set, pset_member memb, reiser4_plugin * plugin) ++{ ++ return plugin_set_field(set, ++ (unsigned long)plugin, pset_descr[memb].offset); ++} ++ ++/** ++ * init_plugin_set - create plugin set cache and hash table ++ * ++ * Initializes slab cache of plugin_set-s and their hash table. It is part of ++ * reiser4 module initialization. ++ */ ++int init_plugin_set(void) ++{ ++ int result; ++ ++ result = ps_hash_init(&ps_table, PS_TABLE_SIZE); ++ if (result == 0) { ++ plugin_set_slab = kmem_cache_create("plugin_set", ++ sizeof(plugin_set), 0, ++ SLAB_HWCACHE_ALIGN, ++ NULL); ++ if (plugin_set_slab == NULL) ++ result = RETERR(-ENOMEM); ++ } ++ return result; ++} ++ ++/** ++ * done_plugin_set - delete plugin_set cache and plugin_set hash table ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void done_plugin_set(void) ++{ ++ plugin_set *cur, *next; ++ ++ for_all_in_htable(&ps_table, ps, cur, next) { ++ ps_hash_remove(&ps_table, cur); ++ kmem_cache_free(plugin_set_slab, cur); ++ } ++ destroy_reiser4_cache(&plugin_set_slab); ++ ps_hash_done(&ps_table); ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/plugin_set.h linux-5.10.2/fs/reiser4/plugin/plugin_set.h +--- linux-5.10.2.orig/fs/reiser4/plugin/plugin_set.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/plugin_set.h 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,78 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Reiser4 plugin set definition. ++ See fs/reiser4/plugin/plugin_set.c for details */ ++ ++#if !defined(__PLUGIN_SET_H__) ++#define __PLUGIN_SET_H__ ++ ++#include "../type_safe_hash.h" ++#include "plugin.h" ++ ++#include ++ ++struct plugin_set; ++typedef struct plugin_set plugin_set; ++ ++TYPE_SAFE_HASH_DECLARE(ps, plugin_set); ++ ++struct plugin_set { ++ unsigned long hashval; ++ /* plugin of file */ ++ file_plugin *file; ++ /* plugin of dir */ ++ dir_plugin *dir; ++ /* perm plugin for this file */ ++ perm_plugin *perm; ++ /* tail policy plugin. Only meaningful for regular files */ ++ formatting_plugin *formatting; ++ /* hash plugin. Only meaningful for directories. */ ++ hash_plugin *hash; ++ /* fibration plugin. Only meaningful for directories. */ ++ fibration_plugin *fibration; ++ /* plugin of stat-data */ ++ item_plugin *sd; ++ /* plugin of items a directory is built of */ ++ item_plugin *dir_item; ++ /* cipher plugin */ ++ cipher_plugin *cipher; ++ /* digest plugin */ ++ digest_plugin *digest; ++ /* compression plugin */ ++ compression_plugin *compression; ++ /* compression mode plugin */ ++ compression_mode_plugin *compression_mode; ++ /* cluster plugin */ ++ cluster_plugin *cluster; ++ /* this specifies file plugin of regular children. ++ only meaningful for directories */ ++ file_plugin *create; ++ ps_hash_link link; ++}; ++ ++extern plugin_set *plugin_set_get_empty(void); ++extern void plugin_set_put(plugin_set * set); ++ ++extern int init_plugin_set(void); ++extern void done_plugin_set(void); ++ ++extern reiser4_plugin *aset_get(plugin_set * set, pset_member memb); ++extern int set_plugin(plugin_set ** set, pset_member memb, ++ reiser4_plugin * plugin); ++extern int aset_set_unsafe(plugin_set ** set, pset_member memb, ++ reiser4_plugin * plugin); ++extern reiser4_plugin_type aset_member_to_type_unsafe(pset_member memb); ++ ++/* __PLUGIN_SET_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/regular.c linux-5.10.2/fs/reiser4/plugin/regular.c +--- linux-5.10.2.orig/fs/reiser4/plugin/regular.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/regular.c 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,55 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Contains Reiser4 regular plugins which: ++ . specify a set of reiser4 regular object plugins, ++ . used by directory plugin to create entries powered by specified ++ regular plugins */ ++ ++#include "plugin.h" ++ ++regular_plugin regular_plugins[LAST_REGULAR_ID] = { ++ [UF_REGULAR_ID] = { ++ .h = { ++ .type_id = REISER4_REGULAR_PLUGIN_TYPE, ++ .id = UF_REGULAR_ID, ++ .pops = NULL, ++ .label = "unixfile", ++ .desc = "Unix file regular plugin", ++ .linkage = {NULL, NULL} ++ }, ++ .id = UNIX_FILE_PLUGIN_ID ++ }, ++ [CRC_REGULAR_ID] = { ++ .h = { ++ .type_id = REISER4_REGULAR_PLUGIN_TYPE, ++ .id = CRC_REGULAR_ID, ++ .pops = NULL, ++ .label = "cryptcompress", ++ .desc = "Cryptcompress regular plugin", ++ .linkage = {NULL, NULL} ++ }, ++ .id = CRC_FILE_PLUGIN_ID ++ }, ++ [SF_REGULAR_ID] = { ++ .h = { ++ .type_id = REISER4_REGULAR_PLUGIN_TYPE, ++ .id = SF_REGULAR_ID, ++ .pops = NULL, ++ .label = "striped-file", ++ .desc = "Striped regular plugin", ++ .linkage = {NULL, NULL} ++ }, ++ .id = SF_FILE_PLUGIN_ID ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/security/Makefile linux-5.10.2/fs/reiser4/plugin/security/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/security/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/security/Makefile 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,4 @@ ++obj-$(CONFIG_REISER4_FS) += security_plugins.o ++ ++security_plugins-objs := \ ++ perm.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/security/perm.c linux-5.10.2/fs/reiser4/plugin/security/perm.c +--- linux-5.10.2.orig/fs/reiser4/plugin/security/perm.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/security/perm.c 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,33 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* ++ * This file contains implementation of permission plugins. ++ * See the comments in perm.h ++ */ ++ ++#include "../plugin.h" ++#include "../plugin_header.h" ++#include "../../debug.h" ++ ++perm_plugin perm_plugins[LAST_PERM_ID] = { ++ [NULL_PERM_ID] = { ++ .h = { ++ .type_id = REISER4_PERM_PLUGIN_TYPE, ++ .id = NULL_PERM_ID, ++ .pops = NULL, ++ .label = "null", ++ .desc = "stub permission plugin", ++ .linkage = {NULL, NULL} ++ } ++ } ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/security/perm.h linux-5.10.2/fs/reiser4/plugin/security/perm.h +--- linux-5.10.2.orig/fs/reiser4/plugin/security/perm.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/security/perm.h 2020-12-23 16:07:46.131813319 +0100 +@@ -0,0 +1,38 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Perm (short for "permissions") plugins common stuff. */ ++ ++#if !defined( __REISER4_PERM_H__ ) ++#define __REISER4_PERM_H__ ++ ++#include "../../forward.h" ++#include "../plugin_header.h" ++ ++#include ++ ++/* Definition of permission plugin */ ++/* NIKITA-FIXME-HANS: define what this is targeted for. ++ It does not seem to be intended for use with sys_reiser4. Explain. */ ++ ++/* NOTE-EDWARD: This seems to be intended for deprecated sys_reiser4. ++ Consider it like a temporary "seam" and reserved pset member. ++ If you have something usefull to add, then rename this plugin and add here */ ++typedef struct perm_plugin { ++ /* generic plugin fields */ ++ plugin_header h; ++} perm_plugin; ++ ++typedef enum { NULL_PERM_ID, LAST_PERM_ID } reiser4_perm_id; ++ ++/* __REISER4_PERM_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/space/bitmap.c linux-5.10.2/fs/reiser4/plugin/space/bitmap.c +--- linux-5.10.2.orig/fs/reiser4/plugin/space/bitmap.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/space/bitmap.c 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,1649 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#include "../../debug.h" ++#include "../../dformat.h" ++#include "../../txnmgr.h" ++#include "../../jnode.h" ++#include "../../block_alloc.h" ++#include "../../tree.h" ++#include "../../super.h" ++#include "../plugin.h" ++#include "space_allocator.h" ++#include "bitmap.h" ++ ++#include ++#include /* for struct super_block */ ++#include ++#include ++ ++/* Proposed (but discarded) optimization: dynamic loading/unloading of bitmap ++ * blocks ++ ++ A useful optimization of reiser4 bitmap handling would be dynamic bitmap ++ blocks loading/unloading which is different from v3.x where all bitmap ++ blocks are loaded at mount time. ++ ++ To implement bitmap blocks unloading we need to count bitmap block usage ++ and detect currently unused blocks allowing them to be unloaded. It is not ++ a simple task since we allow several threads to modify one bitmap block ++ simultaneously. ++ ++ Briefly speaking, the following schema is proposed: we count in special ++ variable associated with each bitmap block. That is for counting of block ++ alloc/dealloc operations on that bitmap block. With a deferred block ++ deallocation feature of reiser4 all those operation will be represented in ++ atom dirty/deleted lists as jnodes for freshly allocated or deleted ++ nodes. ++ ++ So, we increment usage counter for each new node allocated or deleted, and ++ decrement it at atom commit one time for each node from the dirty/deleted ++ atom's list. Of course, freshly allocated node deletion and node reusing ++ from atom deleted (if we do so) list should decrement bitmap usage counter ++ also. ++ ++ This schema seems to be working but that reference counting is ++ not easy to debug. I think we should agree with Hans and do not implement ++ it in v4.0. Current code implements "on-demand" bitmap blocks loading only. ++ ++ For simplicity all bitmap nodes (both commit and working bitmap blocks) are ++ loaded into memory on fs mount time or each bitmap nodes are loaded at the ++ first access to it, the "dont_load_bitmap" mount option controls whether ++ bimtap nodes should be loaded at mount time. Dynamic unloading of bitmap ++ nodes currently is not supported. */ ++ ++#define CHECKSUM_SIZE 4 ++ ++#define BYTES_PER_LONG (sizeof(long)) ++ ++#if BITS_PER_LONG == 64 ++# define LONG_INT_SHIFT (6) ++#else ++# define LONG_INT_SHIFT (5) ++#endif ++ ++#define LONG_INT_MASK (BITS_PER_LONG - 1UL) ++ ++typedef unsigned long ulong_t; ++ ++#define bmap_size(blocksize) ((blocksize) - CHECKSUM_SIZE) ++#define bmap_bit_count(blocksize) (bmap_size(blocksize) << 3) ++ ++/* Block allocation/deallocation are done through special bitmap objects which ++ are allocated in an array at fs mount. */ ++struct bitmap_node { ++ struct mutex mutex; /* long term lock object */ ++ ++ jnode *wjnode; /* j-nodes for WORKING ... */ ++ jnode *cjnode; /* ... and COMMIT bitmap blocks */ ++ ++ bmap_off_t first_zero_bit; /* for skip_busy option implementation */ ++ ++ atomic_t loaded; /* a flag which shows that bnode is loaded ++ * already */ ++}; ++ ++static inline char *bnode_working_data(struct bitmap_node *bnode) ++{ ++ char *data; ++ ++ data = jdata(bnode->wjnode); ++ assert("zam-429", data != NULL); ++ ++ return data + CHECKSUM_SIZE; ++} ++ ++static inline char *bnode_commit_data(const struct bitmap_node *bnode) ++{ ++ char *data; ++ ++ data = jdata(bnode->cjnode); ++ assert("zam-430", data != NULL); ++ ++ return data + CHECKSUM_SIZE; ++} ++ ++static inline __u32 bnode_commit_crc(const struct bitmap_node *bnode) ++{ ++ char *data; ++ ++ data = jdata(bnode->cjnode); ++ assert("vpf-261", data != NULL); ++ ++ return le32_to_cpu(get_unaligned((d32 *)data)); ++} ++ ++static inline void bnode_set_commit_crc(struct bitmap_node *bnode, __u32 crc) ++{ ++ char *data; ++ ++ data = jdata(bnode->cjnode); ++ assert("vpf-261", data != NULL); ++ ++ put_unaligned(cpu_to_le32(crc), (d32 *)data); ++} ++ ++/* ZAM-FIXME-HANS: is the idea that this might be a union someday? having ++ * written the code, does this added abstraction still have */ ++/* ANSWER(Zam): No, the abstractions is in the level above (exact place is the ++ * reiser4_space_allocator structure) */ ++/* ZAM-FIXME-HANS: I don't understand your english in comment above. */ ++/* FIXME-HANS(Zam): I don't understand the questions like "might be a union ++ * someday?". What they about? If there is a reason to have a union, it should ++ * be a union, if not, it should not be a union. "..might be someday" means no ++ * reason. */ ++struct bitmap_allocator_data { ++ /* an array for bitmap blocks direct access */ ++ struct bitmap_node *bitmap; ++}; ++ ++#define get_barray(subvol) \ ++(((struct bitmap_allocator_data *)(subvol->space_allocator.u.generic))->bitmap) ++ ++#define get_bnode(subvol, i) (get_barray(subvol) + i) ++ ++/* allocate and initialize jnode with JNODE_BITMAP type */ ++static jnode *bnew(reiser4_subvol *subvol) ++{ ++ jnode *jal = jalloc(); ++ ++ if (jal) ++ jnode_init(jal, subvol, JNODE_BITMAP); ++ return jal; ++} ++ ++/* this file contains: ++ - bitmap based implementation of space allocation plugin ++ - all the helper functions like set bit, find_first_zero_bit, etc */ ++ ++/* Audited by: green(2002.06.12) */ ++static int find_next_zero_bit_in_word(ulong_t word, int start_bit) ++{ ++ ulong_t mask = 1UL << start_bit; ++ int i = start_bit; ++ ++ while ((word & mask) != 0) { ++ mask <<= 1; ++ if (++i >= BITS_PER_LONG) ++ break; ++ } ++ ++ return i; ++} ++ ++#include ++ ++#if BITS_PER_LONG == 64 ++ ++#define OFF(addr) (((ulong_t)(addr) & (BYTES_PER_LONG - 1)) << 3) ++#define BASE(addr) ((ulong_t*) ((ulong_t)(addr) & ~(BYTES_PER_LONG - 1))) ++ ++static inline void reiser4_set_bit(int nr, void *addr) ++{ ++ __test_and_set_bit_le(nr + OFF(addr), BASE(addr)); ++} ++ ++static inline void reiser4_clear_bit(int nr, void *addr) ++{ ++ __test_and_clear_bit_le(nr + OFF(addr), BASE(addr)); ++} ++ ++static inline int reiser4_test_bit(int nr, void *addr) ++{ ++ return test_bit_le(nr + OFF(addr), BASE(addr)); ++} ++static inline int reiser4_find_next_zero_bit(void *addr, int maxoffset, ++ int offset) ++{ ++ int off = OFF(addr); ++ ++ return find_next_zero_bit_le(BASE(addr), maxoffset + off, ++ offset + off) - off; ++} ++ ++#else ++ ++#define reiser4_set_bit(nr, addr) __test_and_set_bit_le(nr, addr) ++#define reiser4_clear_bit(nr, addr) __test_and_clear_bit_le(nr, addr) ++#define reiser4_test_bit(nr, addr) test_bit_le(nr, addr) ++ ++#define reiser4_find_next_zero_bit(addr, maxoffset, offset) \ ++find_next_zero_bit_le(addr, maxoffset, offset) ++#endif ++ ++/* Search for a set bit in the bit array [@start_offset, @max_offset[, offsets ++ * are counted from @addr, return the offset of the first bit if it is found, ++ * @maxoffset otherwise. */ ++static bmap_off_t __reiser4_find_next_set_bit(void *addr, bmap_off_t max_offset, ++ bmap_off_t start_offset) ++{ ++ ulong_t *base = addr; ++ /* start_offset is in bits, convert it to byte offset within bitmap. */ ++ int word_nr = start_offset >> LONG_INT_SHIFT; ++ /* bit number within the byte. */ ++ int bit_nr = start_offset & LONG_INT_MASK; ++ int max_word_nr = (max_offset - 1) >> LONG_INT_SHIFT; ++ ++ assert("zam-387", max_offset != 0); ++ ++ /* Unaligned @start_offset case. */ ++ if (bit_nr != 0) { ++ bmap_nr_t nr; ++ ++ nr = find_next_zero_bit_in_word(~(base[word_nr]), bit_nr); ++ ++ if (nr < BITS_PER_LONG) ++ return (word_nr << LONG_INT_SHIFT) + nr; ++ ++ ++word_nr; ++ } ++ ++ /* Fast scan trough aligned words. */ ++ while (word_nr <= max_word_nr) { ++ if (base[word_nr] != 0) { ++ return (word_nr << LONG_INT_SHIFT) ++ + find_next_zero_bit_in_word(~(base[word_nr]), 0); ++ } ++ ++ ++word_nr; ++ } ++ ++ return max_offset; ++} ++ ++#if BITS_PER_LONG == 64 ++ ++static bmap_off_t reiser4_find_next_set_bit(void *addr, bmap_off_t max_offset, ++ bmap_off_t start_offset) ++{ ++ bmap_off_t off = OFF(addr); ++ ++ return __reiser4_find_next_set_bit(BASE(addr), max_offset + off, ++ start_offset + off) - off; ++} ++ ++#else ++#define reiser4_find_next_set_bit(addr, max_offset, start_offset) \ ++ __reiser4_find_next_set_bit(addr, max_offset, start_offset) ++#endif ++ ++/* search for the first set bit in single word. */ ++static int find_last_set_bit_in_word(ulong_t word, int start_bit) ++{ ++ ulong_t bit_mask; ++ int nr = start_bit; ++ ++ assert("zam-965", start_bit < BITS_PER_LONG); ++ assert("zam-966", start_bit >= 0); ++ ++ bit_mask = (1UL << nr); ++ ++ while (bit_mask != 0) { ++ if (bit_mask & word) ++ return nr; ++ bit_mask >>= 1; ++ nr--; ++ } ++ return BITS_PER_LONG; ++} ++ ++/* Search bitmap for a set bit in backward direction from the end to the ++ * beginning of given region ++ * ++ * @result: result offset of the last set bit ++ * @addr: base memory address, ++ * @low_off: low end of the search region, edge bit included into the region, ++ * @high_off: high end of the search region, edge bit included into the region, ++ * ++ * @return: 0 - set bit was found, -1 otherwise. ++ */ ++static int ++reiser4_find_last_set_bit(bmap_off_t * result, void *addr, bmap_off_t low_off, ++ bmap_off_t high_off) ++{ ++ ulong_t *base = addr; ++ int last_word; ++ int first_word; ++ int last_bit; ++ int nr; ++ ++ assert("zam-962", high_off >= low_off); ++ ++ last_word = high_off >> LONG_INT_SHIFT; ++ last_bit = high_off & LONG_INT_MASK; ++ first_word = low_off >> LONG_INT_SHIFT; ++ ++ if (last_bit < BITS_PER_LONG) { ++ nr = find_last_set_bit_in_word(base[last_word], last_bit); ++ if (nr < BITS_PER_LONG) { ++ *result = (last_word << LONG_INT_SHIFT) + nr; ++ return 0; ++ } ++ --last_word; ++ } ++ while (last_word >= first_word) { ++ if (base[last_word] != 0x0) { ++ last_bit = ++ find_last_set_bit_in_word(base[last_word], ++ BITS_PER_LONG - 1); ++ assert("zam-972", last_bit < BITS_PER_LONG); ++ *result = (last_word << LONG_INT_SHIFT) + last_bit; ++ return 0; ++ } ++ --last_word; ++ } ++ ++ return -1; /* set bit not found */ ++} ++ ++/* Search bitmap for a clear bit in backward direction from the end to the ++ * beginning of given region */ ++static int ++reiser4_find_last_zero_bit(bmap_off_t * result, void *addr, bmap_off_t low_off, ++ bmap_off_t high_off) ++{ ++ ulong_t *base = addr; ++ int last_word; ++ int first_word; ++ int last_bit; ++ int nr; ++ ++ last_word = high_off >> LONG_INT_SHIFT; ++ last_bit = high_off & LONG_INT_MASK; ++ first_word = low_off >> LONG_INT_SHIFT; ++ ++ if (last_bit < BITS_PER_LONG) { ++ nr = find_last_set_bit_in_word(~base[last_word], last_bit); ++ if (nr < BITS_PER_LONG) { ++ *result = (last_word << LONG_INT_SHIFT) + nr; ++ return 0; ++ } ++ --last_word; ++ } ++ while (last_word >= first_word) { ++ if (base[last_word] != (ulong_t) (-1)) { ++ *result = (last_word << LONG_INT_SHIFT) + ++ find_last_set_bit_in_word(~base[last_word], ++ BITS_PER_LONG - 1); ++ return 0; ++ } ++ --last_word; ++ } ++ ++ return -1; /* zero bit not found */ ++} ++ ++/* Audited by: green(2002.06.12) */ ++static void reiser4_clear_bits(char *addr, bmap_off_t start, bmap_off_t end) ++{ ++ int first_byte; ++ int last_byte; ++ ++ unsigned char first_byte_mask = 0xFF; ++ unsigned char last_byte_mask = 0xFF; ++ ++ assert("zam-410", start < end); ++ ++ first_byte = start >> 3; ++ last_byte = (end - 1) >> 3; ++ ++ if (last_byte > first_byte + 1) ++ memset(addr + first_byte + 1, 0, ++ (size_t) (last_byte - first_byte - 1)); ++ ++ first_byte_mask >>= 8 - (start & 0x7); ++ last_byte_mask <<= ((end - 1) & 0x7) + 1; ++ ++ if (first_byte == last_byte) { ++ addr[first_byte] &= (first_byte_mask | last_byte_mask); ++ } else { ++ addr[first_byte] &= first_byte_mask; ++ addr[last_byte] &= last_byte_mask; ++ } ++} ++ ++/* Audited by: green(2002.06.12) */ ++/* ZAM-FIXME-HANS: comment this */ ++static void reiser4_set_bits(char *addr, bmap_off_t start, bmap_off_t end) ++{ ++ int first_byte; ++ int last_byte; ++ ++ unsigned char first_byte_mask = 0xFF; ++ unsigned char last_byte_mask = 0xFF; ++ ++ assert("zam-386", start < end); ++ ++ first_byte = start >> 3; ++ last_byte = (end - 1) >> 3; ++ ++ if (last_byte > first_byte + 1) ++ memset(addr + first_byte + 1, 0xFF, ++ (size_t) (last_byte - first_byte - 1)); ++ ++ first_byte_mask <<= start & 0x7; ++ last_byte_mask >>= 7 - ((end - 1) & 0x7); ++ ++ if (first_byte == last_byte) { ++ addr[first_byte] |= (first_byte_mask & last_byte_mask); ++ } else { ++ addr[first_byte] |= first_byte_mask; ++ addr[last_byte] |= last_byte_mask; ++ } ++} ++ ++#define ADLER_BASE 65521 ++#define ADLER_NMAX 5552 ++ ++/* Calculates the adler32 checksum for the data pointed by `data` of the ++ length `len`. This function was originally taken from zlib, version 1.1.3, ++ July 9th, 1998. ++ ++ Copyright (C) 1995-1998 Jean-loup Gailly and Mark Adler ++ ++ This software is provided 'as-is', without any express or implied ++ warranty. In no event will the authors be held liable for any damages ++ arising from the use of this software. ++ ++ Permission is granted to anyone to use this software for any purpose, ++ including commercial applications, and to alter it and redistribute it ++ freely, subject to the following restrictions: ++ ++ 1. The origin of this software must not be misrepresented; you must not ++ claim that you wrote the original software. If you use this software ++ in a product, an acknowledgment in the product documentation would be ++ appreciated but is not required. ++ 2. Altered source versions must be plainly marked as such, and must not be ++ misrepresented as being the original software. ++ 3. This notice may not be removed or altered from any source distribution. ++ ++ Jean-loup Gailly Mark Adler ++ jloup@gzip.org madler@alumni.caltech.edu ++ ++ The above comment applies only to the reiser4_adler32 function. ++*/ ++ ++__u32 reiser4_adler32(char *data, __u32 len) ++{ ++ unsigned char *t = data; ++ __u32 s1 = 1; ++ __u32 s2 = 0; ++ int k; ++ ++ while (len > 0) { ++ k = len < ADLER_NMAX ? len : ADLER_NMAX; ++ len -= k; ++ ++ while (k--) { ++ s1 += *t++; ++ s2 += s1; ++ } ++ ++ s1 %= ADLER_BASE; ++ s2 %= ADLER_BASE; ++ } ++ return (s2 << 16) | s1; ++} ++ ++#define subvol_by_bnode(bnode) (jnode_get_subvol(bnode->wjnode)) ++ ++static __u32 bnode_calc_crc(const struct bitmap_node *bnode, unsigned long size) ++{ ++ return reiser4_adler32(bnode_commit_data(bnode), bmap_size(size)); ++} ++ ++static int ++bnode_check_adler32(const struct bitmap_node *bnode, unsigned long size) ++{ ++ if (bnode_calc_crc(bnode, size) != bnode_commit_crc(bnode)) { ++ bmap_nr_t bmap; ++ ++ bmap = bnode - get_bnode(subvol_by_bnode(bnode), 0); ++ ++ warning("vpf-263", ++ "Checksum for the bitmap block %llu is incorrect", ++ bmap); ++ ++ return RETERR(-EIO); ++ } ++ ++ return 0; ++} ++ ++#define REISER4_CHECK_BMAP_CRC (0) ++ ++#if REISER4_CHECK_BMAP_CRC ++static int bnode_check_crc(const struct bitmap_node *bnode) ++{ ++ return bnode_check_adler32(bnode, ++ bmap_size(subvol_by_bnode(bnode)->s_blocksize)); ++} ++ ++/* REISER4_CHECK_BMAP_CRC */ ++#else ++ ++#define bnode_check_crc(bnode) (0) ++ ++/* REISER4_CHECK_BMAP_CRC */ ++#endif ++ ++/* Recalculates the adler32 checksum for only 1 byte change. ++ adler - previous adler checksum ++ old_data, data - old, new byte values. ++ tail == (chunk - offset) : length, checksum was calculated for, - offset of ++ the changed byte within this chunk. ++ This function can be used for checksum calculation optimisation. ++*/ ++ ++static __u32 ++adler32_recalc(__u32 adler, unsigned char old_data, unsigned char data, ++ __u32 tail) ++{ ++ __u32 delta = data - old_data + 2 * ADLER_BASE; ++ __u32 s1 = adler & 0xffff; ++ __u32 s2 = (adler >> 16) & 0xffff; ++ ++ s1 = (delta + s1) % ADLER_BASE; ++ s2 = (delta * tail + s2) % ADLER_BASE; ++ ++ return (s2 << 16) | s1; ++} ++ ++#define LIMIT(val, boundary) ((val) > (boundary) ? (boundary) : (val)) ++ ++/** ++ * get_nr_bmap - calculate number of bitmap blocks ++ * @super: super block with initialized blocksize and block count ++ * ++ * Calculates number of bitmap blocks of a filesystem which uses bitmaps to ++ * maintain free disk space. It assumes that each bitmap addresses the same ++ * number of blocks which is calculated by bmap_block_count macro defined in ++ * above. Number of blocks in the subvolume has to be initialized in struct ++ * reiser4_subvol already so that it can be obtained via ++ * reiser4_subvol_block_count(). Unfortunately, number of blocks addressed ++ * by a bitmap is not power of 2 because 4 bytes are used for checksum. ++ * Therefore, we have to use special function to divide and modulo 64bits ++ * filesystem block counters. ++ * ++ * Example: suppose filesystem have 32768 blocks. Blocksize is 4096. Each bitmap ++ * block addresses (4096 - 4) * 8 = 32736 blocks. Number of bitmaps to address ++ * all 32768 blocks is calculated as (32768 - 1) / 32736 + 1 = 2. ++ */ ++static bmap_nr_t get_nr_bmap(const struct super_block *super, ++ reiser4_subvol *subv) ++{ ++ u64 quotient; ++ ++ assert("zam-393", reiser4_subvol_block_count(subv) != 0); ++ ++ quotient = reiser4_subvol_block_count(subv) - 1; ++ do_div(quotient, bmap_bit_count(super->s_blocksize)); ++ return quotient + 1; ++} ++ ++/** ++ * parse_blocknr - calculate bitmap number and offset in it by block number ++ * @block: pointer to block number to calculate location in bitmap of ++ * @bmap: pointer where to store bitmap block number ++ * @offset: pointer where to store offset within bitmap block ++ * @subv: subvolume where the block is located in ++ * ++ * Calculates location of bit which is responsible for allocation/freeing of ++ * block @*block. That location is represented by bitmap block number and offset ++ * within that bitmap block. ++ */ ++static void parse_blocknr(const reiser4_block_nr *block, bmap_nr_t *bmap, ++ bmap_off_t *offset, reiser4_subvol *subv) ++{ ++ struct super_block *super = get_current_context()->super; ++ u64 quotient = *block; ++ ++ *offset = do_div(quotient, bmap_bit_count(super->s_blocksize)); ++ *bmap = quotient; ++ ++ assert("zam-433", *bmap < get_nr_bmap(super, subv)); ++ assert("", *offset < bmap_bit_count(super->s_blocksize)); ++} ++ ++#if REISER4_DEBUG ++static void check_block_range(const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ reiser4_subvol *subv) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ ++ assert("zam-436", sb != NULL); ++ assert("zam-455", start != NULL); ++ assert("zam-437", *start != 0); ++ assert("zam-541", !reiser4_blocknr_is_fake(start)); ++ assert("zam-441", *start < reiser4_subvol_block_count(subv)); ++ ++ if (len != NULL) { ++ assert("zam-438", *len != 0); ++ assert("zam-442", ++ *start + *len <= reiser4_subvol_block_count(subv)); ++ } ++} ++ ++static void check_bnode_loaded(const struct bitmap_node *bnode) ++{ ++ assert("zam-485", bnode != NULL); ++ assert("zam-483", jnode_page(bnode->wjnode) != NULL); ++ assert("zam-484", jnode_page(bnode->cjnode) != NULL); ++ assert("nikita-2820", jnode_is_loaded(bnode->wjnode)); ++ assert("nikita-2821", jnode_is_loaded(bnode->cjnode)); ++} ++#else ++ ++#define check_block_range(start, len, subv) do { /* nothing */} while(0) ++#define check_bnode_loaded(bnode) do { /* nothing */} while(0) ++ ++#endif ++ ++/* modify bnode->first_zero_bit (if we free bits before); bnode should be ++ spin-locked */ ++static inline void ++adjust_first_zero_bit(struct bitmap_node *bnode, bmap_off_t offset) ++{ ++ if (offset < bnode->first_zero_bit) ++ bnode->first_zero_bit = offset; ++} ++ ++/* return a physical disk address for logical bitmap number @bmap */ ++/* FIXME-VS: this is somehow related to disk layout? */ ++/* ZAM-FIXME-HANS: your answer is? Use not more than one function dereference ++ * per block allocation so that performance is not affected. Probably this ++ * whole file should be considered part of the disk layout plugin, and other ++ * disk layouts can use other defines and efficiency will not be significantly ++ * affected. */ ++ ++#define REISER4_FIRST_BITMAP_BLOCK \ ++ ((REISER4_MASTER_OFFSET / PAGE_SIZE) + 2) ++ ++/* Audited by: green(2002.06.12) */ ++static void ++get_bitmap_blocknr(reiser4_subvol *subv, bmap_nr_t bmap, ++ reiser4_block_nr * bnr) ++{ ++ struct super_block *super = subv->super; ++ ++ assert("zam-390", bmap < get_nr_bmap(super, subv)); ++ ++#ifdef CONFIG_REISER4_BADBLOCKS ++#define BITMAP_PLUGIN_DISKMAP_ID ((0xc0e1<<16) | (0xe0ff)) ++ /* Check if the diskmap have this already, first. */ ++ if (reiser4_get_diskmap_value(BITMAP_PLUGIN_DISKMAP_ID, bmap, bnr) == 0) ++ return; /* Found it in diskmap */ ++#endif ++ /* FIXME_ZAM: before discussing of disk layouts and disk format ++ plugins I implement bitmap location scheme which is close to scheme ++ used in reiser 3.6 */ ++ if (bmap == 0) { ++ *bnr = REISER4_FIRST_BITMAP_BLOCK; ++ } else { ++ *bnr = bmap * bmap_bit_count(super->s_blocksize); ++ } ++} ++ ++/* construct a fake block number for shadow bitmap (WORKING BITMAP) block */ ++/* Audited by: green(2002.06.12) */ ++static void get_working_bitmap_blocknr(bmap_nr_t bmap, reiser4_block_nr * bnr) ++{ ++ *bnr = ++ (reiser4_block_nr) ((bmap & ~REISER4_BLOCKNR_STATUS_BIT_MASK) | ++ REISER4_BITMAP_BLOCKS_STATUS_VALUE); ++} ++ ++/* bnode structure initialization */ ++static void init_bnode(struct bitmap_node *bnode, bmap_nr_t bmap UNUSED_ARG) ++{ ++ memset(bnode, 0, sizeof(struct bitmap_node)); ++ ++ mutex_init(&bnode->mutex); ++ atomic_set(&bnode->loaded, 0); ++} ++ ++static void release(jnode * node) ++{ ++ jrelse(node); ++ JF_SET(node, JNODE_HEARD_BANSHEE); ++ jput(node); ++} ++ ++/* This function is for internal bitmap.c use because it assumes that jnode is ++ in under full control of this thread */ ++static void done_bnode(struct bitmap_node *bnode) ++{ ++ if (bnode) { ++ atomic_set(&bnode->loaded, 0); ++ if (bnode->wjnode != NULL) ++ release(bnode->wjnode); ++ if (bnode->cjnode != NULL) ++ release(bnode->cjnode); ++ bnode->wjnode = bnode->cjnode = NULL; ++ } ++} ++ ++/* ++ * ZAM-FIXME-HANS: comment this. Called only by load_and_lock_bnode() ++ */ ++static int prepare_bnode(struct bitmap_node *bnode, jnode **cjnode_ret, ++ jnode **wjnode_ret, reiser4_subvol *subv) ++{ ++ struct super_block *super; ++ jnode *cjnode; ++ jnode *wjnode; ++ bmap_nr_t bmap; ++ int ret; ++ ++ super = reiser4_get_current_sb(); ++ ++ *wjnode_ret = wjnode = bnew(subv); ++ if (wjnode == NULL) { ++ *cjnode_ret = NULL; ++ return RETERR(-ENOMEM); ++ } ++ ++ *cjnode_ret = cjnode = bnew(subv); ++ if (cjnode == NULL) ++ return RETERR(-ENOMEM); ++ ++ bmap = bnode - get_bnode(subv, 0); ++ ++ get_working_bitmap_blocknr(bmap, &wjnode->blocknr); ++ get_bitmap_blocknr(subv, bmap, &cjnode->blocknr); ++ ++ jref(cjnode); ++ jref(wjnode); ++ ++ /* load commit bitmap */ ++ ret = jload_gfp(cjnode, GFP_NOFS, 1); ++ ++ if (ret) ++ goto error; ++ ++ /* allocate memory for working bitmap block. Note that for ++ * bitmaps jinit_new() doesn't actually modifies node content, ++ * so parallel calls to this are ok. */ ++ ret = jinit_new(wjnode, GFP_NOFS); ++ ++ if (ret != 0) { ++ jrelse(cjnode); ++ goto error; ++ } ++ ++ return 0; ++ ++ error: ++ jput(cjnode); ++ jput(wjnode); ++ *wjnode_ret = *cjnode_ret = NULL; ++ return ret; ++ ++} ++ ++/* Check the bnode data on read. */ ++static int check_struct_bnode(struct bitmap_node *bnode, __u32 blksize) ++{ ++ void *data; ++ int ret; ++ ++ /* Check CRC */ ++ ret = bnode_check_adler32(bnode, blksize); ++ ++ if (ret) { ++ return ret; ++ } ++ ++ data = jdata(bnode->cjnode) + CHECKSUM_SIZE; ++ ++ /* Check the very first bit -- it must be busy. */ ++ if (!reiser4_test_bit(0, data)) { ++ warning("vpf-1362", "The allocator block %llu is not marked " ++ "as used.", (unsigned long long)bnode->cjnode->blocknr); ++ ++ return -EINVAL; ++ } ++ ++ return 0; ++} ++ ++/* load bitmap blocks "on-demand" */ ++static int load_and_lock_bnode(struct bitmap_node *bnode, ++ reiser4_subvol *subvol) ++{ ++ int ret; ++ ++ jnode *cjnode; ++ jnode *wjnode; ++ ++ assert("nikita-3040", reiser4_schedulable()); ++ ++/* ZAM-FIXME-HANS: since bitmaps are never unloaded, this does not ++ * need to be atomic, right? Just leave a comment that if bitmaps were ++ * unloadable, this would need to be atomic. */ ++ if (atomic_read(&bnode->loaded)) { ++ /* bitmap is already loaded, nothing to do */ ++ check_bnode_loaded(bnode); ++ mutex_lock(&bnode->mutex); ++ assert("nikita-2827", atomic_read(&bnode->loaded)); ++ return 0; ++ } ++ ret = prepare_bnode(bnode, &cjnode, &wjnode, subvol); ++ if (ret) ++ return ret; ++ ++ mutex_lock(&bnode->mutex); ++ ++ if (!atomic_read(&bnode->loaded)) { ++ assert("nikita-2822", cjnode != NULL); ++ assert("nikita-2823", wjnode != NULL); ++ assert("nikita-2824", jnode_is_loaded(cjnode)); ++ assert("nikita-2825", jnode_is_loaded(wjnode)); ++ ++ bnode->wjnode = wjnode; ++ bnode->cjnode = cjnode; ++ ++ ret = check_struct_bnode(bnode, current_blocksize); ++ if (unlikely(ret != 0)) ++ goto error; ++ ++ atomic_set(&bnode->loaded, 1); ++ /* working bitmap is initialized by on-disk ++ * commit bitmap. This should be performed ++ * under mutex. */ ++ memcpy(bnode_working_data(bnode), ++ bnode_commit_data(bnode), ++ bmap_size(current_blocksize)); ++ } else ++ /* race: someone already loaded bitmap ++ * while we were busy initializing data. */ ++ check_bnode_loaded(bnode); ++ return 0; ++ ++ error: ++ release(wjnode); ++ release(cjnode); ++ bnode->wjnode = NULL; ++ bnode->cjnode = NULL; ++ mutex_unlock(&bnode->mutex); ++ return ret; ++} ++ ++static void release_and_unlock_bnode(struct bitmap_node *bnode) ++{ ++ check_bnode_loaded(bnode); ++ mutex_unlock(&bnode->mutex); ++} ++ ++/* This function does all block allocation work but only for one bitmap ++ block.*/ ++/* FIXME_ZAM: It does not allow us to allocate block ranges across bitmap ++ block responsibility zone boundaries. This had no sense in v3.6 but may ++ have it in v4.x */ ++/* ZAM-FIXME-HANS: do you mean search one bitmap block forward? */ ++ ++static int search_one_bitmap_forward(bmap_nr_t bmap, bmap_off_t *offset, ++ bmap_off_t max_offset, int min_len, ++ int max_len, reiser4_subvol *subv) ++{ ++ struct bitmap_node *bnode = get_bnode(subv, bmap); ++ ++ char *data; ++ ++ bmap_off_t search_end; ++ bmap_off_t start; ++ bmap_off_t end; ++ ++ int set_first_zero_bit = 0; ++ ++ int ret; ++ ++ assert("zam-364", min_len > 0); ++ assert("zam-365", max_len >= min_len); ++ assert("zam-366", *offset <= max_offset); ++ ++ ret = load_and_lock_bnode(bnode, subv); ++ ++ if (ret) ++ return ret; ++ ++ data = bnode_working_data(bnode); ++ ++ start = *offset; ++ ++ if (bnode->first_zero_bit >= start) { ++ start = bnode->first_zero_bit; ++ set_first_zero_bit = 1; ++ } ++ ++ while (start + min_len < max_offset) { ++ ++ start = ++ reiser4_find_next_zero_bit((long *)data, max_offset, start); ++ if (set_first_zero_bit) { ++ bnode->first_zero_bit = start; ++ set_first_zero_bit = 0; ++ } ++ if (start >= max_offset) ++ break; ++ ++ search_end = LIMIT(start + max_len, max_offset); ++ end = ++ reiser4_find_next_set_bit((long *)data, search_end, start); ++ if (end >= start + min_len) { ++ /* we can't trust find_next_set_bit result if set bit ++ was not fount, result may be bigger than ++ max_offset */ ++ if (end > search_end) ++ end = search_end; ++ ++ ret = end - start; ++ *offset = start; ++ ++ reiser4_set_bits(data, start, end); ++ ++ /* FIXME: we may advance first_zero_bit if [start, ++ end] region overlaps the first_zero_bit point */ ++ ++ break; ++ } ++ ++ start = end + 1; ++ } ++ ++ release_and_unlock_bnode(bnode); ++ ++ return ret; ++} ++ ++static int search_one_bitmap_backward(bmap_nr_t bmap, bmap_off_t *start_offset, ++ bmap_off_t end_offset, int min_len, ++ int max_len, reiser4_subvol *subv) ++{ ++ struct bitmap_node *bnode = get_bnode(subv, bmap); ++ char *data; ++ bmap_off_t start; ++ int ret; ++ ++ assert("zam-958", min_len > 0); ++ assert("zam-959", max_len >= min_len); ++ assert("zam-960", *start_offset >= end_offset); ++ ++ ret = load_and_lock_bnode(bnode, subv); ++ if (ret) ++ return ret; ++ ++ data = bnode_working_data(bnode); ++ start = *start_offset; ++ ++ while (1) { ++ bmap_off_t end, search_end; ++ ++ /* Find the beginning of the zero filled region */ ++ if (reiser4_find_last_zero_bit(&start, data, end_offset, start)) ++ break; ++ /* Is there more than `min_len' bits from `start' to ++ * `end_offset'? */ ++ if (start < end_offset + min_len - 1) ++ break; ++ ++ /* Do not search to `end_offset' if we need to find less than ++ * `max_len' zero bits. */ ++ if (end_offset + max_len - 1 < start) ++ search_end = start - max_len + 1; ++ else ++ search_end = end_offset; ++ ++ if (reiser4_find_last_set_bit(&end, data, search_end, start)) ++ end = search_end; ++ else ++ end++; ++ ++ if (end + min_len <= start + 1) { ++ if (end < search_end) ++ end = search_end; ++ ret = start - end + 1; ++ *start_offset = end; /* `end' is lowest offset */ ++ assert("zam-987", ++ reiser4_find_next_set_bit(data, start + 1, ++ end) >= start + 1); ++ reiser4_set_bits(data, end, start + 1); ++ break; ++ } ++ ++ if (end <= end_offset) ++ /* left search boundary reached. */ ++ break; ++ start = end - 1; ++ } ++ ++ release_and_unlock_bnode(bnode); ++ return ret; ++} ++ ++/* allocate contiguous range of blocks in bitmap */ ++static int bitmap_alloc_forward(reiser4_block_nr *start, ++ const reiser4_block_nr *end, ++ int min_len, int max_len, ++ reiser4_subvol *subv) ++{ ++ bmap_nr_t bmap, end_bmap; ++ bmap_off_t offset, end_offset; ++ int len; ++ ++ reiser4_block_nr tmp; ++ ++ struct super_block *super = get_current_context()->super; ++ const bmap_off_t max_offset = bmap_bit_count(super->s_blocksize); ++ ++ parse_blocknr(start, &bmap, &offset, subv); ++ ++ tmp = *end - 1; ++ parse_blocknr(&tmp, &end_bmap, &end_offset, subv); ++ ++end_offset; ++ ++ assert("zam-358", end_bmap >= bmap); ++ assert("zam-359", ergo(end_bmap == bmap, end_offset >= offset)); ++ ++ for (; bmap < end_bmap; bmap++, offset = 0) { ++ len = search_one_bitmap_forward(bmap, &offset, max_offset, ++ min_len, max_len, subv); ++ if (len != 0) ++ goto out; ++ } ++ ++ len = search_one_bitmap_forward(bmap, &offset, end_offset, min_len, ++ max_len, subv); ++ out: ++ *start = bmap * max_offset + offset; ++ return len; ++} ++ ++/* ++ * allocate contiguous range of blocks in bitmap (from @start to @end in ++ * backward direction) ++ */ ++static int bitmap_alloc_backward(reiser4_block_nr *start, ++ const reiser4_block_nr *end, int min_len, ++ int max_len, reiser4_subvol *subv) ++{ ++ bmap_nr_t bmap, end_bmap; ++ bmap_off_t offset, end_offset; ++ int len; ++ struct super_block *super = get_current_context()->super; ++ const bmap_off_t max_offset = bmap_bit_count(super->s_blocksize); ++ ++ parse_blocknr(start, &bmap, &offset, subv); ++ parse_blocknr(end, &end_bmap, &end_offset, subv); ++ ++ assert("zam-961", end_bmap <= bmap); ++ assert("zam-962", ergo(end_bmap == bmap, end_offset <= offset)); ++ ++ for (; bmap > end_bmap; bmap--, offset = max_offset - 1) { ++ len = search_one_bitmap_backward(bmap, &offset, 0, min_len, ++ max_len, subv); ++ if (len != 0) ++ goto out; ++ } ++ len = search_one_bitmap_backward(bmap, &offset, end_offset, min_len, ++ max_len, subv); ++ out: ++ *start = bmap * max_offset + offset; ++ return len; ++} ++ ++/* ++ * plugin->u.space_allocator.alloc_blocks() ++ */ ++static int alloc_blocks_forward(reiser4_blocknr_hint *hint, int needed, ++ reiser4_block_nr *start, reiser4_block_nr *len, ++ reiser4_subvol *subv) ++{ ++ int actual_len; ++ ++ reiser4_block_nr search_start; ++ reiser4_block_nr search_end; ++ ++ assert("zam-398", subv != NULL); ++ assert("zam-412", hint != NULL); ++ assert("zam-397", hint->blk <= reiser4_subvol_block_count(subv)); ++ ++ if (hint->max_dist == 0) ++ search_end = reiser4_subvol_block_count(subv); ++ else ++ search_end = LIMIT(hint->blk + hint->max_dist, ++ reiser4_subvol_block_count(subv)); ++ ++ /* We use @hint -> blk as a search start and search from it to the end ++ of the disk or in given region if @hint -> max_dist is not zero */ ++ search_start = hint->blk; ++ ++ actual_len = bitmap_alloc_forward(&search_start, &search_end, 1, ++ needed, subv); ++ ++ /* There is only one bitmap search if max_dist was specified or first ++ pass was from the beginning of the bitmap. We also do one pass for ++ scanning bitmap in backward direction. */ ++ if (!(actual_len != 0 || hint->max_dist != 0 || search_start == 0)) { ++ /* next step is a scanning from 0 to search_start */ ++ search_end = search_start; ++ search_start = 0; ++ actual_len = ++ bitmap_alloc_forward(&search_start, &search_end, 1, ++ needed, subv); ++ } ++ if (actual_len == 0) ++ return RETERR(-ENOSPC); ++ if (actual_len < 0) ++ return RETERR(actual_len); ++ *len = actual_len; ++ *start = search_start; ++ return 0; ++} ++ ++static int alloc_blocks_backward(reiser4_blocknr_hint *hint, int needed, ++ reiser4_block_nr *start, reiser4_block_nr *len, ++ reiser4_subvol *subv) ++{ ++ reiser4_block_nr search_start; ++ reiser4_block_nr search_end; ++ int actual_len; ++ ++ ON_DEBUG(struct super_block *super = reiser4_get_current_sb()); ++ ++ assert("zam-969", super != NULL); ++ assert("zam-970", hint != NULL); ++ assert("zam-971", hint->blk <= reiser4_subvol_block_count(subv)); ++ ++ search_start = hint->blk; ++ if (hint->max_dist == 0 || search_start <= hint->max_dist) ++ search_end = 0; ++ else ++ search_end = search_start - hint->max_dist; ++ ++ actual_len = bitmap_alloc_backward(&search_start, &search_end, 1, ++ needed, subv); ++ if (actual_len == 0) ++ return RETERR(-ENOSPC); ++ if (actual_len < 0) ++ return RETERR(actual_len); ++ *len = actual_len; ++ *start = search_start; ++ return 0; ++} ++ ++/* ++ * plugin->u.space_allocator.alloc_blocks() ++ */ ++int reiser4_alloc_blocks_bitmap(reiser4_space_allocator *allocator, ++ reiser4_blocknr_hint *hint, int needed, ++ reiser4_block_nr *start, reiser4_block_nr *len, ++ reiser4_subvol *subv) ++{ ++ if (hint->backward) ++ return alloc_blocks_backward(hint, needed, start, len, subv); ++ return alloc_blocks_forward(hint, needed, start, len, subv); ++} ++ ++/* plugin->u.space_allocator.dealloc_blocks(). */ ++/* ++ * It just frees blocks in WORKING BITMAP. Usually formatted an unformatted ++ * nodes deletion is deferred until transaction commit. However, deallocation ++ * of temporary objects like wandered blocks and transaction commit records ++ * requires immediate node deletion from WORKING BITMAP ++ */ ++void reiser4_dealloc_blocks_bitmap(reiser4_space_allocator * allocator, ++ reiser4_block_nr start, reiser4_block_nr len, ++ reiser4_subvol *subv) ++{ ++ bmap_nr_t bmap; ++ bmap_off_t offset; ++ ++ struct bitmap_node *bnode; ++ int ret; ++ ++ assert("zam-468", len != 0); ++ check_block_range(&start, &len, subv); ++ parse_blocknr(&start, &bmap, &offset, subv); ++ ++ assert("zam-469", ++ offset + len <= bmap_bit_count(subv->super->s_blocksize)); ++ ++ bnode = get_bnode(subv, bmap); ++ ++ assert("zam-470", bnode != NULL); ++ ++ ret = load_and_lock_bnode(bnode, subv); ++ assert("zam-481", ret == 0); ++ ++ reiser4_clear_bits(bnode_working_data(bnode), offset, ++ (bmap_off_t) (offset + len)); ++ ++ adjust_first_zero_bit(bnode, offset); ++ ++ release_and_unlock_bnode(bnode); ++} ++ ++static int check_blocks_one_bitmap(bmap_nr_t bmap, bmap_off_t start_offset, ++ bmap_off_t end_offset, int desired, ++ reiser4_subvol *subv) ++{ ++ struct bitmap_node *bnode = get_bnode(subv, bmap); ++ int ret; ++ ++ assert("nikita-2215", bnode != NULL); ++ ++ ret = load_and_lock_bnode(bnode, subv); ++ assert("zam-626", ret == 0); ++ ++ assert("nikita-2216", jnode_is_loaded(bnode->wjnode)); ++ ++ if (desired) { ++ ret = reiser4_find_next_zero_bit(bnode_working_data(bnode), ++ end_offset, start_offset) ++ >= end_offset; ++ } else { ++ ret = reiser4_find_next_set_bit(bnode_working_data(bnode), ++ end_offset, start_offset) ++ >= end_offset; ++ } ++ ++ release_and_unlock_bnode(bnode); ++ ++ return ret; ++} ++ ++/* plugin->u.space_allocator.check_blocks(). */ ++int reiser4_check_blocks_bitmap(const reiser4_block_nr *start, ++ const reiser4_block_nr *len, int desired, ++ reiser4_subvol *subv) ++{ ++ struct super_block *super = reiser4_get_current_sb(); ++ ++ reiser4_block_nr end; ++ bmap_nr_t bmap, end_bmap; ++ bmap_off_t offset, end_offset; ++ const bmap_off_t max_offset = bmap_bit_count(super->s_blocksize); ++ ++ assert("intelfx-9", start != NULL); ++ assert("intelfx-10", ergo(len != NULL, *len > 0)); ++ ++ if (len != NULL) { ++ check_block_range(start, len, subv); ++ end = *start + *len - 1; ++ } else { ++ /* ++ * on next line, end is used as temporary len ++ * for check_block_range() ++ */ ++ end = 1; check_block_range(start, &end, subv); ++ end = *start; ++ } ++ ++ parse_blocknr(start, &bmap, &offset, subv); ++ ++ if (end == *start) { ++ end_bmap = bmap; ++ end_offset = offset; ++ } else { ++ parse_blocknr(&end, &end_bmap, &end_offset, subv); ++ } ++ ++end_offset; ++ ++ assert("intelfx-4", end_bmap >= bmap); ++ assert("intelfx-5", ergo(end_bmap == bmap, end_offset >= offset)); ++ ++ for (; bmap < end_bmap; bmap++, offset = 0) { ++ if (!check_blocks_one_bitmap(bmap, offset, max_offset, desired, ++ subv)) { ++ return 0; ++ } ++ } ++ return check_blocks_one_bitmap(bmap, offset, end_offset, desired, ++ subv); ++} ++ ++/* conditional insertion of @node into atom's overwrite set if it was not there */ ++static void cond_add_to_overwrite_set(txn_atom *atom, jnode *node) ++{ ++ assert("zam-546", atom != NULL); ++ assert("zam-547", atom->stage == ASTAGE_PRE_COMMIT); ++ assert("zam-548", node != NULL); ++ assert("edward-1782", node->subvol != NULL); ++ ++ spin_lock_atom(atom); ++ spin_lock_jnode(node); ++ ++ if (node->atom == NULL) { ++ JF_SET(node, JNODE_OVRWR); ++ insert_into_atom_ovrwr_list(atom, node); ++ } else { ++ assert("zam-549", node->atom == atom); ++ } ++ ++ spin_unlock_jnode(node); ++ spin_unlock_atom(atom); ++} ++ ++/* ++ * an actor which applies a single delete set entry to COMMIT bitmap ++ */ ++static int apply_dset_to_commit_bmap(txn_atom *atom, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr * len, ++ __u32 subv_id, void *data) ++{ ++ int ret; ++ bmap_nr_t bmap; ++ bmap_off_t offset; ++ struct bitmap_node *bnode; ++ struct super_block *sb = reiser4_get_current_sb(); ++ reiser4_subvol *subv = current_origin(subv_id); ++ ++ check_block_range(start, len, subv); ++ ++ parse_blocknr(start, &bmap, &offset, subv); ++ ++ /* FIXME-ZAM: we assume that all block ranges are allocated by this ++ bitmap-based allocator and each block range can't go over a zone of ++ responsibility of one bitmap block; same assumption is used in ++ other journal hooks in bitmap code. */ ++ bnode = get_bnode(subv, bmap); ++ assert("zam-448", bnode != NULL); ++ ++ /* it is safe to unlock atom with is in ASTAGE_PRE_COMMIT */ ++ assert("zam-767", atom->stage == ASTAGE_PRE_COMMIT); ++ ret = load_and_lock_bnode(bnode, subv); ++ if (ret) ++ return ret; ++ ++ /* put bnode into atom's overwrite set */ ++ cond_add_to_overwrite_set(atom, bnode->cjnode); ++ ++ data = bnode_commit_data(bnode); ++ ++ ret = bnode_check_crc(bnode); ++ if (ret != 0) ++ return ret; ++ ++ if (len != NULL) { ++ /* FIXME-ZAM: a check that all bits are set should be there */ ++ assert("zam-443", ++ offset + *len <= bmap_bit_count(sb->s_blocksize)); ++ reiser4_clear_bits(data, offset, (bmap_off_t) (offset + *len)); ++ ++ subv->blocks_freed += *len; ++ } else { ++ reiser4_clear_bit(offset, data); ++ subv->blocks_freed ++; ++ } ++ bnode_set_commit_crc(bnode, bnode_calc_crc(bnode, sb->s_blocksize)); ++ ++ release_and_unlock_bnode(bnode); ++ ++ return 0; ++} ++ ++/* plugin->u.space_allocator.pre_commit_hook(). */ ++/* It just applies transaction changes to fs-wide COMMIT BITMAP, hoping the ++ rest is done by transaction manager (allocate wandered locations for COMMIT ++ BITMAP blocks, copy COMMIT BITMAP blocks data). */ ++/* Only one instance of this function can be running at one given time, because ++ only one transaction can be committed a time, therefore it is safe to access ++ some global variables without any locking */ ++ ++int reiser4_pre_commit_hook_bitmap(void) ++{ ++ txn_atom *atom; ++ struct rb_node *node; ++ struct super_block *super = reiser4_get_current_sb(); ++ reiser4_super_info_data *sbinfo = get_super_private(super); ++ ++ atom = get_current_atom_locked(); ++ assert("zam-876", atom->stage == ASTAGE_PRE_COMMIT); ++ spin_unlock_atom(atom); ++ ++ { ++ /* ++ * scan atom's captured list and find all freshly allocated ++ * nodes, mark corresponded bits in COMMIT BITMAP as used ++ */ ++ struct list_head *head = ATOM_CLEAN_LIST(atom); ++ jnode *node = list_entry(head->next, jnode, capture_link); ++ ++ while (head != &node->capture_link) { ++ /* we detect freshly allocated jnodes */ ++ if (JF_ISSET(node, JNODE_RELOC)) { ++ int ret; ++ bmap_nr_t bmap; ++ ++ bmap_off_t offset; ++ bmap_off_t index; ++ struct bitmap_node *bn; ++ __u32 size = bmap_size(super->s_blocksize); ++ __u32 crc; ++ char byte; ++ ++ assert("zam-559", !JF_ISSET(node, JNODE_OVRWR)); ++ assert("zam-460", ++ !reiser4_blocknr_is_fake(&node->blocknr)); ++ ++ parse_blocknr(&node->blocknr, ++ &bmap, &offset, node->subvol); ++ bn = get_bnode(node->subvol, bmap); ++ ++ index = offset >> 3; ++ assert("vpf-276", index < size); ++ ++ ret = bnode_check_crc(bnode); ++ if (ret != 0) ++ return ret; ++ ++ check_bnode_loaded(bn); ++ load_and_lock_bnode(bn, node->subvol); ++ ++ byte = *(bnode_commit_data(bn) + index); ++ reiser4_set_bit(offset, bnode_commit_data(bn)); ++ ++ crc = adler32_recalc(bnode_commit_crc(bn), byte, ++ *(bnode_commit_data(bn) + ++ index), ++ size - index), ++ bnode_set_commit_crc(bn, crc); ++ ++ release_and_unlock_bnode(bn); ++ ++ ret = bnode_check_crc(bn); ++ if (ret != 0) ++ return ret; ++ /* ++ * working of this depends on how it inserts ++ * new j-node into clean list, because we are ++ * scanning the same list now. It is OK, if ++ * insertion is done to the list front ++ */ ++ cond_add_to_overwrite_set(atom, bn->cjnode); ++ } ++ node = list_entry(node->capture_link.next, ++ jnode, capture_link); ++ } ++ } ++#if 1 ++ /* ++ * make sure that ->blocks_feed of all items are properly initialized ++ */ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ reiser4_subvol *subv; ++ struct atom_brick_info *abi; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ subv = current_origin(abi->brick_id); ++ subv->blocks_freed = 0; ++ } ++#endif ++ /* ++ * This will update ->blocks_freed of every abi ++ */ ++ atom_dset_deferred_apply(atom, apply_dset_to_commit_bmap, NULL, 0); ++ /* ++ * Finally, update "committed" version of free blocks counters ++ * for all bricks, which participate in the transaction ++ */ ++ spin_lock_reiser4_super(sbinfo); /* FIXME-EDWARD: lock respective ++ subvolume instead of super-block */ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ reiser4_subvol *subv; ++ struct atom_brick_info *abi; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ subv = current_origin(abi->brick_id); ++ ++ subv->blocks_free_committed += ++ (subv->blocks_freed - abi->nr_blocks_allocated); ++ } ++ spin_unlock_reiser4_super(sbinfo); ++ return 0; ++} ++ ++/* ++ * plugin->u.space_allocator.init_allocator constructor ++ * of reiser4_space_allocator object. It is called on fs mount ++ */ ++int reiser4_init_allocator_bitmap(reiser4_space_allocator *allocator, ++ const struct super_block *super, ++ reiser4_subvol *subv, void *arg) ++{ ++ struct bitmap_allocator_data *data = NULL; ++ bmap_nr_t bitmap_blocks_nr; ++ bmap_nr_t i; ++ ++ assert("nikita-3039", reiser4_schedulable()); ++ /* ++ * getting memory for bitmap allocator private data holder ++ */ ++ data = kmalloc(sizeof(struct bitmap_allocator_data), ++ reiser4_ctx_gfp_mask_get()); ++ if (data == NULL) ++ return RETERR(-ENOMEM); ++ /* ++ * allocate and initialize array of bnodes ++ */ ++ bitmap_blocks_nr = get_nr_bmap(super, subv); ++ /* ++ FIXME-ZAM: it is not clear what to do with huge number of bitmaps ++ which is bigger than 2^32 (= 8 * 4096 * 4096 * 2^32 bytes = 5.76e+17, ++ may I never meet someone who still uses the ia32 architecture when ++ storage devices of that size enter the market, and wants to use ia32 ++ with that storage device, much less reiser4. ;-) -Hans). ++ Kmalloc is not possible and, probably, another dynamic data structure ++ should replace a static array of bnodes ++ ++ data->bitmap = reiser4_kmalloc((size_t) ++ (sizeof (struct bitmap_node) * bitmap_blocks_nr), GFP_KERNEL); ++ */ ++ data->bitmap = ++ reiser4_vmalloc(sizeof(struct bitmap_node) * bitmap_blocks_nr); ++ if (data->bitmap == NULL) { ++ kfree(data); ++ return RETERR(-ENOMEM); ++ } ++ for (i = 0; i < bitmap_blocks_nr; i++) ++ init_bnode(data->bitmap + i, i); ++ ++ allocator->u.generic = data; ++ ++ if (!test_bit(REISER4_DONT_LOAD_BITMAP, ++ &get_super_private(super)->fs_flags)) { ++ /* ++ * Load all bitmap blocks at mount time ++ */ ++ __u64 start_time, elapsed_time; ++ struct bitmap_node *bnode; ++ int ret; ++ ++ if (REISER4_DEBUG) ++ printk(KERN_INFO "loading reiser4 bitmap..."); ++ start_time = jiffies; ++ ++ for (i = 0; i < bitmap_blocks_nr; i++) { ++ bnode = data->bitmap + i; ++ ret = load_and_lock_bnode(bnode, subv); ++ if (ret) { ++ reiser4_destroy_allocator_bitmap(allocator, ++ super, subv); ++ return ret; ++ } ++ release_and_unlock_bnode(bnode); ++ } ++ elapsed_time = jiffies - start_time; ++ if (REISER4_DEBUG) ++ printk("...done (%llu jiffies)\n", ++ (unsigned long long)elapsed_time); ++ } ++ return 0; ++} ++ ++/** ++ * plugin->u.space_allocator.destroy_allocator ++ * destructor. It is called on fs unmount ++ */ ++int reiser4_destroy_allocator_bitmap(reiser4_space_allocator *allocator, ++ const struct super_block *super, ++ reiser4_subvol *subv) ++{ ++ bmap_nr_t bitmap_blocks_nr; ++ bmap_nr_t i; ++ ++ struct bitmap_allocator_data *data = allocator->u.generic; ++ ++ assert("zam-414", data != NULL); ++ assert("zam-376", data->bitmap != NULL); ++ ++ bitmap_blocks_nr = get_nr_bmap(super, subv); ++ ++ for (i = 0; i < bitmap_blocks_nr; i++) { ++ struct bitmap_node *bnode = data->bitmap + i; ++ ++ mutex_lock(&bnode->mutex); ++ ++#if REISER4_DEBUG ++ if (atomic_read(&bnode->loaded)) { ++ jnode *wj = bnode->wjnode; ++ jnode *cj = bnode->cjnode; ++ ++ assert("zam-480", jnode_page(cj) != NULL); ++ assert("zam-633", jnode_page(wj) != NULL); ++ ++ assert("zam-634", ++ memcmp(jdata(wj), jdata(wj), ++ bmap_size(super->s_blocksize)) == 0); ++ ++ } ++#endif ++ done_bnode(bnode); ++ mutex_unlock(&bnode->mutex); ++ } ++ ++ vfree(data->bitmap); ++ kfree(data); ++ ++ allocator->u.generic = NULL; ++ ++ return 0; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/space/bitmap.h linux-5.10.2/fs/reiser4/plugin/space/bitmap.h +--- linux-5.10.2.orig/fs/reiser4/plugin/space/bitmap.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/space/bitmap.h 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,49 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined (__REISER4_PLUGIN_SPACE_BITMAP_H__) ++#define __REISER4_PLUGIN_SPACE_BITMAP_H__ ++ ++#include "../../dformat.h" ++#include "../../block_alloc.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block */ ++/* EDWARD-FIXME-HANS: write something as informative as the below for every .h file lacking it. */ ++/* declarations of functions implementing methods of space allocator plugin for ++ bitmap based allocator. The functions themselves are in bitmap.c */ ++extern int reiser4_init_allocator_bitmap(reiser4_space_allocator *, ++ const struct super_block *, ++ reiser4_subvol *, void *); ++extern int reiser4_destroy_allocator_bitmap(reiser4_space_allocator *, ++ const struct super_block *, ++ reiser4_subvol *); ++extern int reiser4_alloc_blocks_bitmap(reiser4_space_allocator *, ++ reiser4_blocknr_hint *, int needed, ++ reiser4_block_nr *start, ++ reiser4_block_nr *len, reiser4_subvol *); ++extern int reiser4_check_blocks_bitmap(const reiser4_block_nr *, ++ const reiser4_block_nr *, int, reiser4_subvol *); ++extern void reiser4_dealloc_blocks_bitmap(reiser4_space_allocator *, ++ reiser4_block_nr, ++ reiser4_block_nr, reiser4_subvol *); ++extern int reiser4_pre_commit_hook_bitmap(void); ++ ++#define reiser4_post_commit_hook_bitmap() do{}while(0) ++#define reiser4_post_write_back_hook_bitmap() do{}while(0) ++#define reiser4_print_info_bitmap(pref, al) do{}while(0) ++ ++typedef __u64 bmap_nr_t; ++typedef __u32 bmap_off_t; ++ ++#endif /* __REISER4_PLUGIN_SPACE_BITMAP_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/space/Makefile linux-5.10.2/fs/reiser4/plugin/space/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/space/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/space/Makefile 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,4 @@ ++obj-$(CONFIG_REISER4_FS) += space_plugins.o ++ ++space_plugins-objs := \ ++ bitmap.o +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/space/space_allocator.h linux-5.10.2/fs/reiser4/plugin/space/space_allocator.h +--- linux-5.10.2.orig/fs/reiser4/plugin/space/space_allocator.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/space/space_allocator.h 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,85 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#ifndef __SPACE_ALLOCATOR_H__ ++#define __SPACE_ALLOCATOR_H__ ++ ++#include "../../forward.h" ++#include "bitmap.h" ++/* NIKITA-FIXME-HANS: surely this could use a comment. Something about how bitmap is the only space allocator for now, ++ * but... */ ++#define DEF_SPACE_ALLOCATOR(allocator) \ ++ \ ++static inline int sa_init_allocator (reiser4_space_allocator * al, const struct super_block *s, \ ++ reiser4_subvol *subv, void * opaque) \ ++{ \ ++ return reiser4_init_allocator_##allocator (al, s, subv, opaque); \ ++} \ ++ \ ++static inline void sa_destroy_allocator (reiser4_space_allocator *al, const struct super_block *s, \ ++ reiser4_subvol *subv) \ ++{ \ ++ reiser4_destroy_allocator_##allocator (al, s, subv); \ ++} \ ++ \ ++static inline int sa_alloc_blocks (reiser4_space_allocator *al, reiser4_blocknr_hint * hint, \ ++ int needed, reiser4_block_nr * start, reiser4_block_nr * len, \ ++ reiser4_subvol *subv) \ ++{ \ ++ return reiser4_alloc_blocks_##allocator (al, hint, needed, start, len, subv); \ ++} \ ++static inline void sa_dealloc_blocks (reiser4_space_allocator * al, reiser4_block_nr start, reiser4_block_nr len, \ ++ reiser4_subvol *subv) \ ++{ \ ++ reiser4_dealloc_blocks_##allocator (al, start, len, subv); \ ++} \ ++ \ ++static inline int sa_check_blocks (const reiser4_block_nr * start, const reiser4_block_nr * end, int desired, \ ++ reiser4_subvol *subv) \ ++{ \ ++ return reiser4_check_blocks_##allocator (start, end, desired, subv); \ ++} \ ++ \ ++static inline void sa_pre_commit_hook (void) \ ++{ \ ++ reiser4_pre_commit_hook_##allocator (); \ ++} \ ++ \ ++static inline void sa_post_commit_hook (void) \ ++{ \ ++ reiser4_post_commit_hook_##allocator (); \ ++} \ ++ \ ++static inline void sa_post_write_back_hook (void) \ ++{ \ ++ reiser4_post_write_back_hook_##allocator(); \ ++} \ ++ \ ++static inline void sa_print_info(const char * prefix, reiser4_space_allocator * al) \ ++{ \ ++ reiser4_print_info_##allocator (prefix, al); \ ++} ++ ++DEF_SPACE_ALLOCATOR(bitmap) ++ ++/* this object is part of reiser4 private in-core super block */ ++struct reiser4_space_allocator { ++ union { ++ /* space allocators might use this pointer to reference their ++ * data. */ ++ void *generic; ++ } u; ++}; ++ ++/* __SPACE_ALLOCATOR_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/tail_policy.c linux-5.10.2/fs/reiser4/plugin/tail_policy.c +--- linux-5.10.2.orig/fs/reiser4/plugin/tail_policy.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/tail_policy.c 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,113 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Formatting policy plugins */ ++ ++/* ++ * Formatting policy plugin is used by object plugin (of regular file) to ++ * convert file between two representations. ++ * ++ * Currently following policies are implemented: ++ * never store file in formatted nodes ++ * always store file in formatted nodes ++ * store file in formatted nodes if file is smaller than 4 blocks (default) ++ */ ++ ++#include "../tree.h" ++#include "../inode.h" ++#include "../super.h" ++#include "object.h" ++#include "plugin.h" ++#include "node/node.h" ++#include "plugin_header.h" ++ ++#include ++#include /* For struct inode */ ++ ++/** ++ * have_formatting_never - ++ * @inode: ++ * @size: ++ * ++ * ++ */ ++/* Never store file's tail as direct item */ ++/* Audited by: green(2002.06.12) */ ++static int have_formatting_never(const struct inode *inode UNUSED_ARG ++ /* inode to operate on */ , ++ loff_t size UNUSED_ARG/* new object size */) ++{ ++ return 0; ++} ++ ++/* Always store file's tail as direct item */ ++/* Audited by: green(2002.06.12) */ ++static int ++have_formatting_always(const struct inode *inode UNUSED_ARG ++ /* inode to operate on */ , ++ loff_t size UNUSED_ARG/* new object size */) ++{ ++ return 1; ++} ++ ++/* This function makes test if we should store file denoted @inode as tails only ++ or as extents only. */ ++static int ++have_formatting_default(const struct inode *inode UNUSED_ARG ++ /* inode to operate on */ , ++ loff_t size/* new object size */) ++{ ++ assert("umka-1253", inode != NULL); ++ ++ if (size > inode->i_sb->s_blocksize * 4) ++ return 0; ++ ++ return 1; ++} ++ ++/* tail plugins */ ++formatting_plugin formatting_plugins[LAST_TAIL_FORMATTING_ID] = { ++ [NEVER_TAILS_FORMATTING_ID] = { ++ .h = { ++ .type_id = REISER4_FORMATTING_PLUGIN_TYPE, ++ .id = NEVER_TAILS_FORMATTING_ID, ++ .pops = NULL, ++ .label = "never", ++ .desc = "Never store file's tail", ++ .linkage = {NULL, NULL} ++ }, ++ .have_tail = have_formatting_never ++ }, ++ [ALWAYS_TAILS_FORMATTING_ID] = { ++ .h = { ++ .type_id = REISER4_FORMATTING_PLUGIN_TYPE, ++ .id = ALWAYS_TAILS_FORMATTING_ID, ++ .pops = NULL, ++ .label = "always", ++ .desc = "Always store file's tail", ++ .linkage = {NULL, NULL} ++ }, ++ .have_tail = have_formatting_always ++ }, ++ [SMALL_FILE_FORMATTING_ID] = { ++ .h = { ++ .type_id = REISER4_FORMATTING_PLUGIN_TYPE, ++ .id = SMALL_FILE_FORMATTING_ID, ++ .pops = NULL, ++ .label = "4blocks", ++ .desc = "store files shorter than 4 blocks in tail items", ++ .linkage = {NULL, NULL} ++ }, ++ .have_tail = have_formatting_default ++ } ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/txmod.c linux-5.10.2/fs/reiser4/plugin/txmod.c +--- linux-5.10.2.orig/fs/reiser4/plugin/txmod.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/txmod.c 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,1264 @@ ++#include "../forward.h" ++#include "../debug.h" ++#include "../coord.h" ++#include "../plugin/plugin.h" ++#include "../jnode.h" ++#include "../znode.h" ++#include "../block_alloc.h" ++#include "../reiser4.h" ++#include "../flush.h" ++ ++/* ++ * This file contains implementation of different transaction models. ++ * ++ * Transaction model is a high-level block allocator, which assigns block ++ * numbers to dirty nodes, and, thereby, decides, how those nodes will be ++ * committed. ++ * ++ * Every dirty node of reiser4 atom can be committed by either of the ++ * following two ways: ++ * 1) via journal; ++ * 2) using "write-anywhere" technique. ++ * ++ * If the allocator doesn't change on-disk location of a node, then ++ * this node will be committed using journalling technique (overwrite). ++ * Otherwise, it will be comitted via write-anywhere technique (relocate): ++ * ++ * relocate <---- allocate --- > overwrite ++ * ++ * So, in our interpretation the 2 traditional "classic" strategies in ++ * committing transactions (journalling and "write-anywhere") are just two ++ * boundary cases: 1) when all nodes are overwritten, and 2) when all nodes ++ * are relocated. ++ * ++ * Besides those 2 boundary cases we can implement in reiser4 the infinite ++ * set of their various combinations, so that user can choose what is really ++ * suitable for his needs. ++ */ ++ ++/* jnode_make_wander_nolock <- find_flush_start_jnode (special case for znode-above-root) ++ <- jnode_make_wander */ ++void jnode_make_wander_nolock(jnode * node); ++ ++/* jnode_make_wander <- txmod.forward_alloc_formatted */ ++void jnode_make_wander(jnode * node); ++ ++/* jnode_make_reloc_nolock <- znode_make_reloc ++ <- unformatted_make_reloc */ ++static void jnode_make_reloc_nolock(flush_queue_t * fq, jnode * node); ++ ++ ++ ++ /* Handle formatted nodes in forward context */ ++ ++ ++/** ++ * txmod.forward_alloc_formatted <- allocate_znode <- alloc_pos_and_ancestors <- jnode_flush ++ * <- alloc_one_ancestor <- alloc_pos_and_ancestors <- jnode_flush ++ * <- alloc_one_ancestor (recursive) ++ * <- lock_parent_and_allocate_znode <- squalloc_upper_levels <- check_parents_and_squalloc_upper_levels <- squalloc_upper_levels (recursive) ++ * <- handle_pos_on_formatted ++ * <- handle_pos_on_formatted ++ * <- handle_pos_end_of_twig ++ * <- handle_pos_to_leaf ++ */ ++void znode_make_reloc(znode * z, flush_queue_t * fq); ++ ++ ++ /* Handle unformatted nodes */ ++ ++ ++/* unformatted_make_reloc <- assign_real_blocknrs <- txmod.forward_alloc_unformatted ++ <- txmod.squeeze_alloc_unformatted ++*/ ++void unformatted_make_reloc(jnode *node, flush_queue_t *fq); ++ ++static void forward_overwrite_unformatted(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, reiser4_block_nr width); ++ ++/* mark_jnode_overwrite <- forward_overwrite_unformatted <- txmod.forward_alloc_unformatted ++ squeeze_overwrite_unformatted <- txmod.squeeze_alloc_unformatted ++*/ ++static void mark_jnode_overwrite(struct list_head *jnodes, jnode *node); ++ ++int split_extent_unit(coord_t *coord, reiser4_block_nr pos_in_unit, ++ int return_inserted_pos); ++int allocated_extent_slum_size(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, unsigned long count); ++void assign_real_blocknrs(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, reiser4_block_nr count, ++ reiser4_block_nr first, reiser4_subvol *subv); ++int convert_extent_unit(coord_t *coord, reiser4_extent *replace); ++int shift_extent_left_begin(znode *dst, const coord_t *coord, ++ const reiser4_key *key, reiser4_extent *ext); ++ ++/* ++ * txmod.forward_alloc_unformatted <- handle_pos_on_twig ++ * txmod.squeeze_alloc_unformatted <- squeeze_right_twig ++ */ ++ ++/* Common functions */ ++ ++/** ++ * Mark node JNODE_OVRWR and put it on atom->overwrite_nodes list. ++ * Atom lock and jnode lock should be taken before calling this ++ * function. ++ */ ++void jnode_make_wander_nolock(jnode * node) ++{ ++ txn_atom *atom; ++ ++ assert("nikita-2432", !JF_ISSET(node, JNODE_RELOC)); ++ assert("nikita-3153", JF_ISSET(node, JNODE_DIRTY)); ++ assert("zam-897", !JF_ISSET(node, JNODE_FLUSH_QUEUED)); ++ assert("nikita-3367", !reiser4_blocknr_is_fake(jnode_get_block(node))); ++ ++ atom = node->atom; ++ ++ assert("zam-895", atom != NULL); ++ assert("zam-894", atom_is_protected(atom)); ++ ++ JF_SET(node, JNODE_OVRWR); ++ /* move node to atom's overwrite list */ ++ list_move_tail(&node->capture_link, ATOM_OVRWR_LIST(atom)); ++ ON_DEBUG(count_jnode(atom, node, DIRTY_LIST, OVRWR_LIST, 1)); ++} ++ ++/* ++ * Same as jnode_make_wander_nolock, but all necessary locks ++ * are taken inside this function. ++ */ ++void jnode_make_wander(jnode * node) ++{ ++ txn_atom *atom; ++ ++ spin_lock_jnode(node); ++ atom = jnode_get_atom(node); ++ assert("zam-913", atom != NULL); ++ assert("zam-914", !JF_ISSET(node, JNODE_RELOC)); ++ ++ jnode_make_wander_nolock(node); ++ spin_unlock_atom(atom); ++ spin_unlock_jnode(node); ++} ++ ++/* this just sets RELOC bit */ ++static void jnode_make_reloc_nolock(flush_queue_t * fq, jnode * node) ++{ ++ assert_spin_locked(&(node->guard)); ++ assert("zam-916", JF_ISSET(node, JNODE_DIRTY)); ++ assert("zam-917", !JF_ISSET(node, JNODE_RELOC)); ++ assert("zam-918", !JF_ISSET(node, JNODE_OVRWR)); ++ assert("zam-920", !JF_ISSET(node, JNODE_FLUSH_QUEUED)); ++ assert("nikita-3367", !reiser4_blocknr_is_fake(jnode_get_block(node))); ++ jnode_set_reloc(node); ++} ++ ++/* ++ * Mark znode RELOC and put it on flush queue ++ */ ++void znode_make_reloc(znode * z, flush_queue_t * fq) ++{ ++ jnode *node; ++ txn_atom *atom; ++ ++ node = ZJNODE(z); ++ spin_lock_jnode(node); ++ ++ atom = jnode_get_atom(node); ++ assert("zam-919", atom != NULL); ++ ++ jnode_make_reloc_nolock(fq, node); ++ queue_jnode(fq, node); ++ ++ spin_unlock_atom(atom); ++ spin_unlock_jnode(node); ++} ++ ++/* Mark unformatted node RELOC and put it on flush queue */ ++void unformatted_make_reloc(jnode *node, flush_queue_t *fq) ++{ ++ assert("vs-1479", jnode_is_unformatted(node)); ++ ++ jnode_make_reloc_nolock(fq, node); ++ queue_jnode(fq, node); ++} ++ ++/** ++ * mark_jnode_overwrite - assign node to overwrite set ++ * @jnodes: overwrite set list head ++ * @node: jnode to belong to overwrite set ++ * ++ * Sets OVRWR jnode state bit and puts @node to the end of list head @jnodes ++ * which is an accumulator for nodes before they get to overwrite set list of ++ * atom. ++ */ ++static void mark_jnode_overwrite(struct list_head *jnodes, jnode *node) ++{ ++ spin_lock_jnode(node); ++ ++ assert("zam-917", !JF_ISSET(node, JNODE_RELOC)); ++ assert("zam-918", !JF_ISSET(node, JNODE_OVRWR)); ++ ++ JF_SET(node, JNODE_OVRWR); ++ list_move_tail(&node->capture_link, jnodes); ++ ON_DEBUG(count_jnode(node->atom, node, DIRTY_LIST, OVRWR_LIST, 0)); ++ ++ spin_unlock_jnode(node); ++} ++ ++static int forward_relocate_unformatted(flush_pos_t *flush_pos, ++ reiser4_extent *ext, ++ extent_state state, ++ oid_t oid, __u64 index, ++ __u64 width, int *exit) ++{ ++ int result; ++ coord_t *coord; ++ reiser4_extent replace_ext; ++ reiser4_block_nr protected; ++ reiser4_block_nr start; ++ reiser4_block_nr first_allocated; ++ __u64 allocated; ++ block_stage_t block_stage; ++ reiser4_subvol *subv; ++ reiser4_blocknr_hint nohint; ++ ++ *exit = 0; ++ coord = &flush_pos->coord; ++ start = extent_get_start(ext); ++ subv = find_data_subvol(coord); ++ ++ assert("edward-1852", item_is_extent(coord)); ++ ++ if (flush_pos->pos_in_unit) { ++ assert("edward-2118", state == ALLOCATED_EXTENT); ++ /* ++ * split extent unit into two ones. The left one will ++ * be skipped - see the loop in handle_pos_on_twig() ++ */ ++ result = split_extent_unit(coord, flush_pos->pos_in_unit, ++ 0 /* leave @coord set ++ to overwritten ++ extent */); ++ flush_pos->pos_in_unit = 0; ++ *exit = 1; ++ return result; ++ } ++ /* ++ * limit number of nodes to allocate ++ */ ++ if (flush_pos->nr_to_write < width) ++ width = flush_pos->nr_to_write; ++ ++ if (state == ALLOCATED_EXTENT) { ++ /* ++ * all protected nodes are not flushprepped, therefore ++ * they are counted as flush_reserved ++ */ ++ block_stage = BLOCK_FLUSH_RESERVED; ++ protected = allocated_extent_slum_size(flush_pos, oid, ++ index, width); ++ if (protected == 0) { ++ flush_pos->state = POS_INVALID; ++ flush_pos->pos_in_unit = 0; ++ *exit = 1; ++ return 0; ++ } ++ } else { ++ block_stage = BLOCK_UNALLOCATED; ++ protected = width; ++ } ++ /* ++ * look at previous unit if possible. If it is allocated, make ++ * preceder more precise ++ */ ++ if (coord->unit_pos && (state_of_extent(ext - 1) == ALLOCATED_EXTENT)) ++ flush_pos_update_preceder(flush_pos, subv->id, ++ extent_get_start(ext - 1) + ++ extent_get_width(ext - 1)); ++ /* ++ * allocate new block numbers for protected nodes ++ */ ++ allocate_blocks_unformatted(flush_pos_get_hint(flush_pos, ++ subv->id, &nohint), ++ protected, ++ &first_allocated, &allocated, ++ block_stage, subv); ++ if (state == ALLOCATED_EXTENT) ++ /* ++ * on relocating - free nodes which are going to be ++ * relocated ++ */ ++ reiser4_dealloc_blocks(&start, &allocated, 0, BA_DEFER, subv); ++ /* ++ * assign new block numbers to protected nodes ++ */ ++ assign_real_blocknrs(flush_pos, oid, index, ++ allocated, first_allocated, subv); ++ ++ /* prepare extent which will replace current one */ ++ reiser4_set_extent(subv, &replace_ext, first_allocated, allocated); ++ ++ /* adjust extent item */ ++ result = convert_extent_unit(coord, &replace_ext); ++ if (result != 0 && result != -ENOMEM) { ++ warning("vs-1461", ++ "Failed to allocate extent. Should not happen\n"); ++ *exit = 1; ++ return result; ++ } ++ /* ++ * break flush: we prepared for flushing as many blocks as we ++ * were asked for ++ */ ++ if (flush_pos->nr_to_write == allocated) ++ flush_pos->state = POS_INVALID; ++ return 0; ++} ++ ++static squeeze_result squeeze_relocate_unformatted(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *key, ++ reiser4_key *stop_key) ++{ ++ int result; ++ reiser4_extent *ext; ++ __u64 index; ++ __u64 width; ++ reiser4_block_nr start; ++ extent_state state; ++ oid_t oid; ++ reiser4_block_nr first_allocated; ++ __u64 allocated; ++ __u64 protected; ++ reiser4_extent copy_extent; ++ block_stage_t block_stage; ++ reiser4_subvol *subv; ++ reiser4_blocknr_hint nohint; ++ ++ assert("edward-1610", flush_pos->pos_in_unit == 0); ++ assert("edward-1611", coord_is_leftmost_unit(coord)); ++ assert("edward-1612", item_is_extent(coord)); ++ ++ subv = find_data_subvol(coord); ++ ext = extent_by_coord(coord); ++ index = extent_unit_index(coord); ++ start = extent_get_start(ext); ++ width = extent_get_width(ext); ++ state = state_of_extent(ext); ++ unit_key_by_coord(coord, key); ++ oid = get_key_objectid(key); ++ ++ assert("edward-1613", state != HOLE_EXTENT); ++ ++ if (state == ALLOCATED_EXTENT) { ++ /* ++ * all protected nodes are not flushprepped, ++ * therefore they are counted as flush_reserved ++ */ ++ block_stage = BLOCK_FLUSH_RESERVED; ++ protected = allocated_extent_slum_size(flush_pos, oid, ++ index, width); ++ if (protected == 0) { ++ flush_pos->state = POS_INVALID; ++ flush_pos->pos_in_unit = 0; ++ return 0; ++ } ++ } else { ++ block_stage = BLOCK_UNALLOCATED; ++ protected = width; ++ } ++ /* ++ * look at previous unit if possible. If it is allocated, make ++ * preceder more precise ++ */ ++ if (coord->unit_pos && (state_of_extent(ext - 1) == ALLOCATED_EXTENT)) ++ flush_pos_update_preceder(flush_pos, subv->id, ++ extent_get_start(ext - 1) + ++ extent_get_width(ext - 1)); ++ /* ++ * allocate new block numbers for protected nodes ++ */ ++ allocate_blocks_unformatted(flush_pos_get_hint(flush_pos, ++ subv->id, &nohint), ++ protected, ++ &first_allocated, &allocated, ++ block_stage, subv); ++ /* ++ * prepare extent which will be copied to left ++ */ ++ reiser4_set_extent(subv, ©_extent, first_allocated, allocated); ++ result = shift_extent_left_begin(left, coord, key, ©_extent); ++ ++ if (result == -E_NODE_FULL) { ++ /* ++ * free blocks which were just allocated ++ */ ++ reiser4_dealloc_blocks(&first_allocated, &allocated, ++ (state == ALLOCATED_EXTENT) ? ++ BLOCK_FLUSH_RESERVED : BLOCK_UNALLOCATED, ++ BA_PERMANENT, subv); ++ /* ++ * rewind the preceder ++ */ ++ flush_pos_update_preceder(flush_pos, subv->id, first_allocated); ++ return SQUEEZE_TARGET_FULL; ++ } ++ if (state == ALLOCATED_EXTENT) { ++ /* ++ * free nodes which were relocated ++ */ ++ reiser4_dealloc_blocks(&start, &allocated, 0, BA_DEFER, subv); ++ } ++ /* ++ * assign new block numbers to protected nodes ++ */ ++ assign_real_blocknrs(flush_pos, oid, index, allocated, ++ first_allocated, subv); ++ set_key_offset(key, ++ get_key_offset(key) + ++ (allocated << current_blocksize_bits)); ++ return SQUEEZE_CONTINUE; ++} ++ ++/** ++ * forward_overwrite_unformatted - put bunch of jnodes to overwrite set ++ * @flush_pos: flush position ++ * @oid: objectid of file jnodes belong to ++ * @index: starting index ++ * @width: extent width ++ * ++ * Puts nodes of one extent (file objectid @oid, extent width @width) to atom's ++ * overwrite set. Starting from the one with index @index. If end of slum is ++ * detected (node is not found or flushprepped) - stop iterating and set flush ++ * position's state to POS_INVALID. ++ */ ++static void forward_overwrite_unformatted(flush_pos_t *flush_pos, oid_t oid, ++ unsigned long index, ++ reiser4_block_nr width) ++{ ++ unsigned long i; ++ jnode *node; ++ txn_atom *atom; ++ LIST_HEAD(jnodes); ++ ++ atom = atom_locked_by_fq(reiser4_pos_fq(flush_pos)); ++ assert("vs-1478", atom); ++ ++ for (i = flush_pos->pos_in_unit; i < width; i++, index++) { ++ node = jlookup(oid, index); ++ if (!node) { ++ flush_pos->state = POS_INVALID; ++ break; ++ } ++ if (jnode_check_flushprepped(node)) { ++ flush_pos->state = POS_INVALID; ++ atomic_dec(&node->x_count); ++ break; ++ } ++ if (node->atom != atom) { ++ flush_pos->state = POS_INVALID; ++ atomic_dec(&node->x_count); ++ break; ++ } ++ mark_jnode_overwrite(&jnodes, node); ++ atomic_dec(&node->x_count); ++ } ++ ++ list_splice_init(&jnodes, ATOM_OVRWR_LIST(atom)->prev); ++ spin_unlock_atom(atom); ++} ++ ++static squeeze_result squeeze_overwrite_unformatted(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *key, ++ reiser4_key *stop_key) ++{ ++ int result; ++ reiser4_extent *ext; ++ __u64 index; ++ __u64 width; ++ reiser4_block_nr start; ++ extent_state state; ++ oid_t oid; ++ reiser4_extent copy_extent; ++ reiser4_subvol *subv; ++ ++ assert("vs-1457", flush_pos->pos_in_unit == 0); ++ assert("vs-1467", coord_is_leftmost_unit(coord)); ++ assert("vs-1467", item_is_extent(coord)); ++ ++ subv = find_data_subvol(coord); ++ ext = extent_by_coord(coord); ++ index = extent_unit_index(coord); ++ start = extent_get_start(ext); ++ width = extent_get_width(ext); ++ state = state_of_extent(ext); ++ unit_key_by_coord(coord, key); ++ oid = get_key_objectid(key); ++ ++ /* ++ * try to copy unit as it is to left neighbor ++ * and make all first not flushprepped nodes ++ * overwrite nodes ++ */ ++ reiser4_set_extent(subv, ©_extent, start, width); ++ ++ result = shift_extent_left_begin(left, coord, key, ©_extent); ++ if (result == -E_NODE_FULL) ++ return SQUEEZE_TARGET_FULL; ++ ++ if (state != HOLE_EXTENT) ++ forward_overwrite_unformatted(flush_pos, oid, index, width); ++ ++ set_key_offset(key, ++ get_key_offset(key) + (width << current_blocksize_bits)); ++ return SQUEEZE_CONTINUE; ++} ++ ++/************************ HYBRID TRANSACTION MODEL ****************************/ ++ ++/** ++ * This is the default transaction model suggested by Josh MacDonald and ++ * Hans Reiser. This was the single hardcoded transaction mode till Feb 2014 ++ * when Edward introduced pure Journalling and pure Write-Anywhere. ++ * ++ * In this mode all relocate-overwrite decisions are result of attempts to ++ * defragment atom's locality. ++ */ ++ ++/* REVERSE PARENT-FIRST RELOCATION POLICIES */ ++ ++/* This implements the is-it-close-enough-to-its-preceder? test for relocation ++ in the reverse parent-first relocate context. Here all we know is the ++ preceder and the block number. Since we are going in reverse, the preceder ++ may still be relocated as well, so we can't ask the block allocator "is there ++ a closer block available to relocate?" here. In the _forward_ parent-first ++ relocate context (not here) we actually call the block allocator to try and ++ find a closer location. ++*/ ++static int reverse_try_defragment_if_close(flush_pos_t *pos, ++ const reiser4_block_nr * pblk, ++ const reiser4_block_nr * nblk, ++ reiser4_subvol *subv) ++{ ++ reiser4_block_nr dist; ++ ++ assert("jmacd-7710", *pblk != 0 && *nblk != 0); ++ assert("jmacd-7711", !reiser4_blocknr_is_fake(pblk)); ++ assert("jmacd-7712", !reiser4_blocknr_is_fake(nblk)); ++ ++ /* Distance is the absolute value. */ ++ dist = (*pblk > *nblk) ? (*pblk - *nblk) : (*nblk - *pblk); ++ ++ /* If the block is less than FLUSH_RELOCATE_DISTANCE blocks away from ++ its preceder block, do not relocate. */ ++ if (dist <= subv->flush.relocate_distance) ++ return 0; ++ return 1; ++} ++ ++/** ++ * This function is a predicate that tests for relocation. Always called in the ++ * reverse-parent-first context, when we are asking whether the current node ++ * should be relocated in order to expand the flush by dirtying the parent level ++ * (and thus proceeding to flush that level). When traversing in the forward ++ * parent-first direction (not here), relocation decisions are handled in two ++ * places: allocate_znode() and extent_needs_allocation(). ++ */ ++static int reverse_should_realloc_formatted_hybrid(jnode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ reiser4_block_nr pblk = 0; ++ reiser4_block_nr nblk = 0; ++ ++ assert("jmacd-8989", !jnode_is_root(node)); ++ assert("edward-2396", jnode_get_subvol(node) == get_meta_subvol()); ++ /* ++ * This function is called only from the ++ * reverse_relocate_check_dirty_parent() and only if the parent ++ * node is clean. This implies that the parent has the real (i.e., not ++ * fake) block number, and, so does the child, because otherwise the ++ * parent would be dirty. ++ */ ++ ++ /* New nodes are treated as if they are being relocated. */ ++ if (JF_ISSET(node, JNODE_CREATED) || ++ (__leaf_should_relocate(&pos->mfbi) && ++ jnode_get_level(node) == LEAF_LEVEL)) ++ return 1; ++ ++ /* Find the preceder. FIXME(B): When the child is an unformatted, ++ previously existing node, the coord may be leftmost even though the ++ child is not the parent-first preceder of the parent. If the first ++ dirty node appears somewhere in the middle of the first extent unit, ++ this preceder calculation is wrong. ++ Needs more logic in here. */ ++ ++ if (coord_is_leftmost_unit(parent_coord)) ++ pblk = *znode_get_block(parent_coord->node); ++ else ++ pblk = pos->mfbi.preceder.blk; ++ ++ check_preceder(pblk, get_meta_subvol()); ++ if (pblk == 0) ++ /* ++ * preceder is not set, so relocate ++ */ ++ return 1; ++ ++ nblk = *jnode_get_block(node); ++ ++ if (reiser4_blocknr_is_fake(&nblk)) ++ /* child is unallocated, mark parent dirty */ ++ return 1; ++ ++ return reverse_try_defragment_if_close(pos, &pblk, ++ &nblk, get_meta_subvol()); ++} ++ ++/** ++ * A subroutine of forward_alloc_formatted_hybrid(), this is called first to see ++ * if there is a close position to relocate to. It may return ENOSPC if there is ++ * no close position. If there is no close position it may not relocate. This ++ * takes care of updating the parent node with the relocated block address. ++ * ++ * was allocate_znode_update() ++ */ ++static int forward_try_defragment_locality(znode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ int ret; ++ reiser4_block_nr blk; ++ lock_handle uber_lock; ++ int flush_reserved_used = 0; ++ int grabbed; ++ reiser4_context *ctx; ++ reiser4_super_info_data *sbinfo; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ init_lh(&uber_lock); ++ ++ ctx = get_current_context(); ++ sbinfo = get_super_private(ctx->super); ++ ++ grabbed = ctx_subvol_grabbed(ctx, subv->id); ++ ++ ret = zload(node); ++ if (ret) ++ return ret; ++ ++ if (ZF_ISSET(node, JNODE_CREATED)) { ++ assert("zam-816", ++ reiser4_blocknr_is_fake(znode_get_block(node))); ++ pos->mfbi.preceder.block_stage = BLOCK_UNALLOCATED; ++ } else { ++ pos->mfbi.preceder.block_stage = BLOCK_GRABBED; ++ ++ /* The disk space for relocating the @node is already reserved ++ * in "flush reserved" counter if @node is leaf, otherwise we ++ * grab space using BA_RESERVED (means grab space from whole ++ * disk not from only 95%). */ ++ if (znode_get_level(node) == LEAF_LEVEL) { ++ /* ++ * earlier (during do_jnode_make_dirty()) we decided ++ * that @node can possibly go into overwrite set and ++ * reserved block for its wandering location. ++ */ ++ txn_atom *atom = get_current_atom_locked(); ++ assert("nikita-3449", ++ ZF_ISSET(node, JNODE_FLUSH_RESERVED)); ++ flush_reserved2grabbed(atom_meta_brick_info(atom), ++ context_meta_brick_info(ctx), ++ (__u64) 1, subv); ++ spin_unlock_atom(atom); ++ /* ++ * we are trying to move node into relocate ++ * set. Allocation of relocated position "uses" ++ * reserved block. ++ */ ++ ZF_CLR(node, JNODE_FLUSH_RESERVED); ++ flush_reserved_used = 1; ++ } else { ++ ret = reiser4_grab_space_force((__u64) 1, ++ BA_RESERVED, subv); ++ if (ret != 0) ++ goto exit; ++ } ++ } ++ /* ++ * We may do not use 5% of reserved disk space here ++ * and flush will not pack tightly ++ */ ++ ret = reiser4_alloc_block(&pos->mfbi.preceder, &blk, ++ BA_FORMATTED | BA_PERMANENT, subv); ++ if (ret) ++ goto exit; ++ ++ if (!ZF_ISSET(node, JNODE_CREATED)) { ++ ret = reiser4_dealloc_block(znode_get_block(node), 0, ++ BA_DEFER | BA_FORMATTED, ++ subv); ++ if (ret) ++ goto exit; ++ } ++ ++ if (likely(!znode_is_root(node))) { ++ item_plugin *iplug; ++ ++ iplug = item_plugin_by_coord(parent_coord); ++ assert("nikita-2954", iplug->f.update != NULL); ++ iplug->f.update(parent_coord, &blk); ++ ++ znode_make_dirty(parent_coord->node); ++ } else { ++ reiser4_tree *tree = znode_get_tree(node); ++ znode *uber; ++ /* ++ * We take a longterm lock on the fake node in order to change ++ * the root block number. This may cause atom fusion ++ */ ++ ret = get_uber_znode(tree, ZNODE_WRITE_LOCK, ZNODE_LOCK_HIPRI, ++ &uber_lock); ++ /* ++ * The fake node cannot be deleted, and we must have priority ++ * here, and may not be confused with ENOSPC ++ */ ++ assert("jmacd-74412", ++ ret != -EINVAL && ret != -E_DEADLOCK && ret != -ENOSPC); ++ ++ if (ret) ++ goto exit; ++ ++ uber = uber_lock.node; ++ ++ write_lock_tree(); ++ tree->root_block = blk; ++ write_unlock_tree(); ++ ++ znode_make_dirty(uber); ++ } ++ ret = znode_rehash(node, &blk); ++exit: ++ if (ret) { ++ /* Get flush reserved block back if something fails, because ++ * callers assume that on error block wasn't relocated and its ++ * flush reserved block wasn't used. */ ++ if (flush_reserved_used) { ++ /* ++ * ok, we failed to move node into relocate ++ * set. Restore status quo. ++ */ ++ grabbed2flush_reserved((__u64)1, subv); ++ ZF_SET(node, JNODE_FLUSH_RESERVED); ++ } ++ } ++ zrelse(node); ++ done_lh(&uber_lock); ++ grabbed2free_mark(grabbed, subv); ++ return ret; ++} ++ ++/* ++ * Make the final relocate/wander decision during ++ * forward parent-first squalloc for a formatted node ++ */ ++static int forward_alloc_formatted_hybrid(znode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ int ret; ++ reiser4_subvol *subv = get_meta_subvol(); ++ flush_brick_info *fbi = &pos->mfbi; ++ /** ++ * FIXME(D): We have the node write-locked and should have checked for ! ++ * allocated() somewhere before reaching this point, but there can be a ++ * race, so this assertion is bogus. ++ */ ++ assert("edward-1614", znode_is_loaded(node)); ++ assert("jmacd-7987", !jnode_check_flushprepped(ZJNODE(node))); ++ assert("jmacd-7988", znode_is_write_locked(node)); ++ assert("jmacd-7989", coord_is_invalid(parent_coord) ++ || znode_is_write_locked(parent_coord->node)); ++ ++ if (ZF_ISSET(node, JNODE_REPACK) || ZF_ISSET(node, JNODE_CREATED) || ++ znode_is_root(node) || /* We have enough nodes to ++ relocate no matter what */ ++ (__leaf_should_relocate(fbi) && ++ znode_get_level(node) == LEAF_LEVEL)) { ++ /* ++ * No need to decide with new nodes, they are treated the same ++ * as relocate. If the root node is dirty, relocate. ++ */ ++ if (fbi->preceder.blk == 0) { ++ /* ++ * preceder is unknown and we have decided to relocate ++ * node -- using of default value for search start is ++ * better than search from block #0. ++ */ ++ reiser4_block_nr blk; ++ get_blocknr_hint_default(&blk, subv); ++ fbi->preceder.blk = blk; ++ check_preceder(blk, subv); ++ } ++ goto best_reloc; ++ ++ } else if (fbi->preceder.blk == 0) { ++ /* ++ * If we don't know the preceder, leave it where it is ++ */ ++ jnode_make_wander(ZJNODE(node)); ++ } else { ++ /* Make a decision based on block distance. */ ++ reiser4_block_nr dist; ++ reiser4_block_nr nblk = *znode_get_block(node); ++ ++ assert("jmacd-6172", !reiser4_blocknr_is_fake(&nblk)); ++ assert("jmacd-6173", ++ !reiser4_blocknr_is_fake(&fbi->preceder.blk)); ++ assert("jmacd-6174", fbi->preceder.blk != 0); ++ ++ if (fbi->preceder.blk == nblk - 1) { ++ /* Ideal. */ ++ jnode_make_wander(ZJNODE(node)); ++ } else { ++ ++ dist = (nblk < fbi->preceder.blk) ? ++ (fbi->preceder.blk - nblk) : ++ (nblk - fbi->preceder.blk); ++ /* ++ * See if we can find a closer block ++ * (forward direction only). ++ */ ++ fbi->preceder.max_dist = ++ min((reiser4_block_nr)subv->flush.relocate_distance, ++ dist); ++ fbi->preceder.level = znode_get_level(node); ++ ++ ret = forward_try_defragment_locality(node, ++ parent_coord, ++ pos); ++ fbi->preceder.max_dist = 0; ++ ++ if (ret && (ret != -ENOSPC)) ++ return ret; ++ ++ if (ret == 0) { ++ /* Got a better allocation. */ ++ znode_make_reloc(node, pos->fq); ++ } else if (dist < subv->flush.relocate_distance) { ++ /* The present allocation is good enough. */ ++ jnode_make_wander(ZJNODE(node)); ++ } else { ++ /* ++ * Otherwise, try to relocate to the best ++ * position. ++ */ ++ best_reloc: ++ ret = forward_try_defragment_locality(node, ++ parent_coord, ++ pos); ++ if (ret != 0) ++ return ret; ++ /* ++ * set JNODE_RELOC bit _after_ node gets ++ * allocated ++ */ ++ znode_make_reloc(node, pos->fq); ++ } ++ } ++ } ++ fbi_update_preceder(fbi, *znode_get_block(node)); ++ pos->alloc_cnt += 1; ++ ++ assert("jmacd-4277", !reiser4_blocknr_is_fake(&fbi->preceder.blk)); ++ ++ return 0; ++} ++ ++static int forward_alloc_unformatted_hybrid(flush_pos_t *flush_pos) ++{ ++ coord_t *coord; ++ reiser4_extent *ext; ++ oid_t oid; ++ __u64 index; ++ __u64 width; ++ extent_state state; ++ reiser4_key key; ++ reiser4_subvol *subv; ++ ++ assert("vs-1468", flush_pos->state == POS_ON_EPOINT); ++ assert("vs-1469", coord_is_existing_unit(&flush_pos->coord) && ++ item_is_extent(&flush_pos->coord)); ++ ++ subv = find_data_subvol(&flush_pos->coord); ++ coord = &flush_pos->coord; ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ ++ if (state == HOLE_EXTENT) { ++ flush_pos->state = POS_INVALID; ++ return 0; ++ } ++ item_key_by_coord(coord, &key); ++ oid = get_key_objectid(&key); ++ index = extent_unit_index(coord) + flush_pos->pos_in_unit; ++ width = extent_get_width(ext); ++ ++ assert("vs-1457", width > flush_pos->pos_in_unit); ++ ++ if (leaf_should_relocate(flush_pos, subv->id) || ++ state == UNALLOCATED_EXTENT) { ++ int exit; ++ int result; ++ result = forward_relocate_unformatted(flush_pos, ext, state, ++ oid, ++ index, width, &exit); ++ if (exit) ++ return result; ++ } else ++ forward_overwrite_unformatted(flush_pos, oid, index, width); ++ ++ flush_pos->pos_in_unit = 0; ++ return 0; ++} ++ ++static squeeze_result squeeze_alloc_unformatted_hybrid(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *stop_key) ++{ ++ squeeze_result ret; ++ reiser4_key key; ++ reiser4_extent *ext; ++ extent_state state; ++ reiser4_subvol *subv; ++ ++ subv = find_data_subvol(coord); ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ ++ if ((leaf_should_relocate(flush_pos, subv->id) && ++ state == ALLOCATED_EXTENT) || ++ (state == UNALLOCATED_EXTENT)) ++ /* ++ * relocate ++ */ ++ ret = squeeze_relocate_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ else ++ /* ++ * (state == ALLOCATED_EXTENT && !flush_pos->leaf_relocate) || ++ * state == HOLE_EXTENT - overwrite ++ */ ++ ret = squeeze_overwrite_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ if (ret == SQUEEZE_CONTINUE) ++ *stop_key = key; ++ return ret; ++} ++ ++/*********************** JOURNAL TRANSACTION MODEL ****************************/ ++ ++static int forward_alloc_formatted_journal(znode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ int ret; ++ ++ if (ZF_ISSET(node, JNODE_CREATED)) { ++ if (pos->mfbi.preceder.blk == 0) { ++ /* ++ * preceder is unknown and we have decided to relocate ++ * node -- using of default value for search start is ++ * better than search from block #0. ++ */ ++ reiser4_block_nr blk; ++ get_blocknr_hint_default(&blk, get_meta_subvol()); ++ pos->mfbi.preceder.blk = blk; ++ } ++ ret = forward_try_defragment_locality(node, ++ parent_coord, ++ pos); ++ if (ret != 0) { ++ warning("edward-1615", ++ "forward defrag failed (%d)", ret); ++ return ret; ++ } ++ /* ++ * set JNODE_RELOC bit _after_ node gets ++ * allocated ++ */ ++ znode_make_reloc(node, pos->fq); ++ } ++ else ++ jnode_make_wander(ZJNODE(node)); ++ ++ pos->mfbi.preceder.blk = *znode_get_block(node); ++ pos->alloc_cnt += 1; ++ ++ assert("edward-1616", ++ !reiser4_blocknr_is_fake(&pos->mfbi.preceder.blk)); ++ return 0; ++} ++ ++static int forward_alloc_unformatted_journal(flush_pos_t *flush_pos) ++{ ++ ++ coord_t *coord; ++ reiser4_extent *ext; ++ oid_t oid; ++ __u64 index; ++ __u64 width; ++ extent_state state; ++ reiser4_key key; ++ ++ coord = &flush_pos->coord; ++ ++ assert("edward-1617", flush_pos->state == POS_ON_EPOINT); ++ assert("edward-1618", coord_is_existing_unit(&flush_pos->coord) ++ && item_is_extent(&flush_pos->coord)); ++ ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ if (state == HOLE_EXTENT) { ++ flush_pos->state = POS_INVALID; ++ return 0; ++ } ++ item_key_by_coord(coord, &key); ++ oid = get_key_objectid(&key); ++ index = extent_unit_index(coord) + flush_pos->pos_in_unit; ++ width = extent_get_width(ext); ++ ++ assert("edward-1619", width > flush_pos->pos_in_unit); ++ ++ if (state == UNALLOCATED_EXTENT) { ++ int exit; ++ int result; ++ result = forward_relocate_unformatted(flush_pos, ext, state, ++ oid, ++ index, width, &exit); ++ if (exit) ++ return result; ++ } ++ else ++ /* ++ * state == ALLOCATED_EXTENT ++ * keep old allocation ++ */ ++ forward_overwrite_unformatted(flush_pos, oid, index, width); ++ ++ flush_pos->pos_in_unit = 0; ++ return 0; ++} ++ ++static squeeze_result squeeze_alloc_unformatted_journal(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *stop_key) ++{ ++ squeeze_result ret; ++ reiser4_key key; ++ reiser4_extent *ext; ++ extent_state state; ++ ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ ++ if (state == UNALLOCATED_EXTENT) ++ ret = squeeze_relocate_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ else ++ /* ++ * state == ALLOCATED_EXTENT || state == HOLE_EXTENT ++ */ ++ ret = squeeze_overwrite_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ if (ret == SQUEEZE_CONTINUE) ++ *stop_key = key; ++ return ret; ++} ++ ++/********************** WA (Write-Anywhere) TRANSACTION MODEL ***************/ ++ ++static int forward_alloc_formatted_wa(znode * node, ++ const coord_t *parent_coord, ++ flush_pos_t *pos) ++{ ++ int ret; ++ ++ assert("edward-1620", znode_is_loaded(node)); ++ assert("edward-1621", !jnode_check_flushprepped(ZJNODE(node))); ++ assert("edward-1622", znode_is_write_locked(node)); ++ assert("edward-1623", coord_is_invalid(parent_coord) ++ || znode_is_write_locked(parent_coord->node)); ++ ++ if (pos->mfbi.preceder.blk == 0) { ++ /* ++ * preceder is unknown and we have decided to relocate ++ * node -- using of default value for search start is ++ * better than search from block #0. ++ */ ++ reiser4_block_nr blk; ++ get_blocknr_hint_default(&blk, get_meta_subvol()); ++ pos->mfbi.preceder.blk = blk; ++ } ++ ret = forward_try_defragment_locality(node, parent_coord, pos); ++ if (ret && (ret != -ENOSPC)) { ++ warning("edward-1624", ++ "forward defrag failed (%d)", ret); ++ return ret; ++ } ++ if (ret == 0) ++ znode_make_reloc(node, pos->fq); ++ else { ++ ret = forward_try_defragment_locality(node, parent_coord, pos); ++ if (ret) { ++ warning("edward-1625", ++ "forward defrag failed (%d)", ret); ++ return ret; ++ } ++ /* set JNODE_RELOC bit _after_ node gets allocated */ ++ znode_make_reloc(node, pos->fq); ++ } ++ pos->mfbi.preceder.blk = *znode_get_block(node); ++ pos->alloc_cnt += 1; ++ ++ assert("edward-1626", ++ !reiser4_blocknr_is_fake(&pos->mfbi.preceder.blk)); ++ return 0; ++} ++ ++static int forward_alloc_unformatted_wa(flush_pos_t *flush_pos) ++{ ++ int exit; ++ int result; ++ ++ coord_t *coord; ++ reiser4_extent *ext; ++ oid_t oid; ++ __u64 index; ++ __u64 width; ++ extent_state state; ++ reiser4_key key; ++ ++ assert("edward-1627", flush_pos->state == POS_ON_EPOINT); ++ assert("edward-1628", coord_is_existing_unit(&flush_pos->coord) ++ && item_is_extent(&flush_pos->coord)); ++ ++ coord = &flush_pos->coord; ++ ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ if (state == HOLE_EXTENT) { ++ flush_pos->state = POS_INVALID; ++ return 0; ++ } ++ ++ item_key_by_coord(coord, &key); ++ oid = get_key_objectid(&key); ++ index = extent_unit_index(coord) + flush_pos->pos_in_unit; ++ width = extent_get_width(ext); ++ ++ assert("edward-1629", width > flush_pos->pos_in_unit); ++ assert("edward-1630", ++ state == ALLOCATED_EXTENT || state == UNALLOCATED_EXTENT); ++ /* ++ * always relocate ++ */ ++ result = forward_relocate_unformatted(flush_pos, ext, state, oid, ++ index, width, &exit); ++ if (exit) ++ return result; ++ flush_pos->pos_in_unit = 0; ++ return 0; ++} ++ ++static squeeze_result squeeze_alloc_unformatted_wa(znode *left, ++ const coord_t *coord, ++ flush_pos_t *flush_pos, ++ reiser4_key *stop_key) ++{ ++ squeeze_result ret; ++ reiser4_key key; ++ reiser4_extent *ext; ++ extent_state state; ++ ++ ext = extent_by_coord(coord); ++ state = state_of_extent(ext); ++ ++ if (state == HOLE_EXTENT) ++ /* ++ * hole extents are handled in squeeze_overwrite ++ */ ++ ret = squeeze_overwrite_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ else ++ ret = squeeze_relocate_unformatted(left, coord, ++ flush_pos, &key, stop_key); ++ if (ret == SQUEEZE_CONTINUE) ++ *stop_key = key; ++ return ret; ++} ++ ++/******************************************************************************/ ++ ++txmod_plugin txmod_plugins[LAST_TXMOD_ID] = { ++ [HYBRID_TXMOD_ID] = { ++ .h = { ++ .type_id = REISER4_TXMOD_PLUGIN_TYPE, ++ .id = HYBRID_TXMOD_ID, ++ .pops = NULL, ++ .label = "hybrid", ++ .desc = "Hybrid Transaction Model", ++ .linkage = {NULL, NULL} ++ }, ++ .forward_alloc_formatted = forward_alloc_formatted_hybrid, ++ .reverse_should_realloc_formatted = reverse_should_realloc_formatted_hybrid, ++ .forward_alloc_unformatted = forward_alloc_unformatted_hybrid, ++ .squeeze_alloc_unformatted = squeeze_alloc_unformatted_hybrid ++ }, ++ [JOURNAL_TXMOD_ID] = { ++ .h = { ++ .type_id = REISER4_TXMOD_PLUGIN_TYPE, ++ .id = JOURNAL_TXMOD_ID, ++ .pops = NULL, ++ .label = "journal", ++ .desc = "Journalling Transaction Model", ++ .linkage = {NULL, NULL} ++ }, ++ .forward_alloc_formatted = forward_alloc_formatted_journal, ++ .reverse_should_realloc_formatted = NULL, ++ .forward_alloc_unformatted = forward_alloc_unformatted_journal, ++ .squeeze_alloc_unformatted = squeeze_alloc_unformatted_journal ++ }, ++ [WA_TXMOD_ID] = { ++ .h = { ++ .type_id = REISER4_TXMOD_PLUGIN_TYPE, ++ .id = WA_TXMOD_ID, ++ .pops = NULL, ++ .label = "wa", ++ .desc = "Write-Anywhere Transaction Model", ++ .linkage = {NULL, NULL} ++ }, ++ .forward_alloc_formatted = forward_alloc_formatted_wa, ++ .reverse_should_realloc_formatted = NULL, ++ .forward_alloc_unformatted = forward_alloc_unformatted_wa, ++ .squeeze_alloc_unformatted = squeeze_alloc_unformatted_wa ++ } ++}; ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/volume/Makefile linux-5.10.2/fs/reiser4/plugin/volume/Makefile +--- linux-5.10.2.orig/fs/reiser4/plugin/volume/Makefile 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/volume/Makefile 2020-12-23 16:07:46.132813334 +0100 +@@ -0,0 +1,4 @@ ++obj-$(CONFIG_REISER4_FS) += volume_plugins.o ++ ++volume_plugins-objs := \ ++ volume.o \ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/volume/volume.c linux-5.10.2/fs/reiser4/plugin/volume/volume.c +--- linux-5.10.2.orig/fs/reiser4/plugin/volume/volume.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/volume/volume.c 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,2624 @@ ++/* ++ Copyright (c) 2016-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include "../../debug.h" ++#include "../../super.h" ++#include "../../inode.h" ++#include "../../plugin/item/brick_symbol.h" ++#include "volume.h" ++ ++/** ++ * Implementation of simple and asymmetric logical volumes. ++ * ++ * Simple Volume can consist of only one device. Operation of adding ++ * a brick to such volume will fail. All reiser4 partitions with old ++ * "format40" layout are simple volumes. ++ * ++ * Asymmetric Logical Volume can consist of any number of devices ++ * formatted with "format41" layout, called bricks (or storage ++ * subvolumes). ++ * Mounted asymmetric volume is represented by a table of pointers to ++ * bricks. Its first column represents meta-data brick with its ++ * optional replicas. Other columns represent data bricks with ++ * replicas. Data brick contains only unformatted blocks. Meta-data ++ * brick contains blocks of all types. Asymmetric Logical Volume ++ * contains at least one meta-data brick and any number of data bricks ++ */ ++ ++#define VOLMAP_MAGIC "R4VoLMaP" ++#define VOLMAP_MAGIC_SIZE (8) ++ ++struct voltab_entry { ++ reiser4_block_nr block; /* address of the unformatted voltab block */ ++ u32 csum; /* checksum of the voltab block */ ++}PACKED; ++ ++struct volmap { ++ u32 csum; /* checksum of this volmap block */ ++ char magic[8]; ++ reiser4_block_nr next; /* disk address of the next volmap block */ ++ struct voltab_entry entries [0]; ++}PACKED; ++ ++static u32 volmap_get_csum(struct volmap *vmap) ++{ ++ return le32_to_cpu(get_unaligned(&vmap->csum)); ++} ++ ++static void volmap_set_csum(struct volmap *vmap, u32 val) ++{ ++ put_unaligned(cpu_to_le32(val), &vmap->csum); ++} ++ ++static reiser4_block_nr volmap_get_entry_blk(struct volmap *vmap, int nr) ++{ ++ return le64_to_cpu(get_unaligned(&vmap->entries[nr].block)); ++} ++ ++static void volmap_set_entry_blk(struct volmap *vmap, int nr, u64 val) ++{ ++ put_unaligned(cpu_to_le64(val), &vmap->entries[nr].block); ++} ++ ++static u32 volmap_get_entry_csum(struct volmap *vmap, int nr) ++{ ++ return le32_to_cpu(get_unaligned(&vmap->entries[nr].csum)); ++} ++ ++static void volmap_set_entry_csum(struct volmap *vmap, int nr, u32 val) ++{ ++ put_unaligned(cpu_to_le32(val), &vmap->entries[nr].csum); ++} ++ ++static reiser4_block_nr get_next_volmap_addr(struct volmap *vmap) ++{ ++ return le64_to_cpu(get_unaligned(&vmap->next)); ++} ++ ++static void set_next_volmap_addr(struct volmap *vmap, reiser4_block_nr val) ++{ ++ put_unaligned(cpu_to_le64(val), &vmap->next); ++} ++ ++static int balance_volume_asym(struct super_block *sb, u32 flags); ++ ++static int voltab_nodes_per_block(void) ++{ ++ return (current_blocksize - sizeof (struct volmap)) / ++ sizeof(struct voltab_entry); ++} ++ ++static int segments_per_block(reiser4_volume *vol) ++{ ++ distribution_plugin *dist_plug = vol->dist_plug; ++ ++ return 1 << (current_blocksize_bits - dist_plug->seg_bits); ++} ++ ++/** ++ * find a meta-data brick of not yet activated volume ++ */ ++reiser4_subvol *find_meta_brick_by_id(reiser4_volume *vol) ++{ ++ struct reiser4_subvol *subv; ++ ++ list_for_each_entry(subv, &vol->subvols_list, list) ++ if (is_meta_brick_id(subv->id)) ++ return subv; ++ return NULL; ++} ++ ++/** ++ * Allocate and initialize an array of abstract buckets for an ++ * asymmetric volume. ++ * The notion of abstract bucket encapsulates an original brick ++ * (without replicas). That array should include only DSA members. ++ */ ++static bucket_t *create_buckets(void) ++{ ++ u32 i, j; ++ bucket_t *ret; ++ reiser4_volume *vol = current_volume(); ++ lv_conf *conf = vol->conf; ++ u32 nr_buckets = num_dsa_subvols(vol); ++ ++ ret = kmalloc(nr_buckets * sizeof(*ret), GFP_KERNEL); ++ if (!ret) ++ return NULL; ++ ++ for (i = 0, j = 0; i < conf->nr_mslots; i++) { ++ if (conf->mslots[i] == NULL) ++ continue; ++ if (!is_dsa_brick(conf_origin(conf, i))) ++ continue; ++ ret[j] = conf_origin(conf, i); ++ /* ++ * set index in DSA ++ */ ++ conf_origin(conf, i)->dsa_idx = j; ++ j++; ++ } ++#if REISER4_DEBUG ++ assert("edward-2194", j == nr_buckets); ++ for (i = 0; i < nr_buckets; i++) { ++ assert("edward-2181", ret[i] != NULL); ++ assert("edward-2195", ++ ((reiser4_subvol *)ret[i])->dsa_idx == i); ++ } ++#endif ++ return (bucket_t *)ret; ++} ++ ++static void free_buckets(bucket_t *vec) ++{ ++ assert("edward-2233", vec != NULL); ++ kfree(vec); ++} ++ ++/** ++ * Allocate and initialize a new array of abstract buckets, ++ * which doesn't contain a bucket @this at position @pos in ++ * the old array @vec. Return the new array. ++ */ ++static bucket_t *remove_bucket(bucket_t *vec, u32 numb, u32 pos) ++{ ++ bucket_t *new; ++ ++ assert("edward-2338", pos < numb); ++ ++ new = kmalloc((numb - 1) * sizeof(*new), GFP_KERNEL); ++ if (new) { ++ int i; ++ /* ++ * indexes of all buckets at the right to @pos ++ * get decremented ++ */ ++ for (i = pos + 1; i < numb; i++) { ++ assert("edward-2196", ++ ((reiser4_subvol *)(vec[i]))->dsa_idx == i); ++ ((reiser4_subvol *)(vec[i]))->dsa_idx --; ++ } ++ memcpy(new, vec, pos * (sizeof(*new))); ++ memcpy(new + pos, vec + pos + 1, ++ (numb - pos - 1) * sizeof(*new)); ++ } ++ return new; ++} ++ ++static bucket_t *insert_bucket(bucket_t *vec, bucket_t this, u32 numb, u32 pos) ++{ ++ bucket_t *new; ++ ++ assert("edward-2339", pos <= numb); ++ ++ new = kmalloc((numb + 1) * sizeof(*new), GFP_KERNEL); ++ if (new) { ++ u32 i; ++ /* ++ * indexes of all buckets at @pos and at the right to @pos ++ * get incremented ++ */ ++ for (i = pos; i < numb; i++) { ++ assert("edward-2340", ++ ((reiser4_subvol *)(vec[i]))->dsa_idx == i); ++ ((reiser4_subvol *)(vec[i]))->dsa_idx ++; ++ } ++ /* ++ * new bucket gets index @pos ++ */ ++ ((reiser4_subvol *)this)->dsa_idx = pos; ++ ++ memcpy(new, vec, pos * (sizeof(*new))); ++ new[pos] = this; ++ memcpy(new + pos + 1, vec + pos, (numb - pos) * sizeof(*new)); ++ } ++ return new; ++} ++ ++static u32 id2idx(u64 id) ++{ ++ return current_origin(id)->dsa_idx; ++} ++ ++static u64 idx2id(u32 idx) ++{ ++ bucket_t *vec = current_buckets(); ++ ++ return ((reiser4_subvol *)(vec[idx]))->id; ++} ++ ++static int num_voltab_nodes(reiser4_volume *vol, int nums_bits) ++{ ++ distribution_plugin *dist_plug = vol->dist_plug; ++ ++ assert("edward-1818", ++ nums_bits + dist_plug->seg_bits >= current_blocksize_bits); ++ ++ return 1 << (nums_bits + dist_plug->seg_bits - current_blocksize_bits); ++} ++ ++static int num_volmap_nodes(reiser4_volume *vol, int nums_bits) ++{ ++ int result; ++ ++ result = num_voltab_nodes(vol, nums_bits) / voltab_nodes_per_block(); ++ if (num_voltab_nodes(vol, nums_bits) % voltab_nodes_per_block()) ++ result ++; ++ return result; ++} ++ ++void release_volinfo_nodes(reiser4_volinfo *vinfo, int dealloc) ++{ ++ u64 i; ++ ++ if (vinfo->volmap_nodes == NULL) ++ return; ++ ++ for (i = 0; i < vinfo->num_volmaps + vinfo->num_voltabs; i++) { ++ struct jnode *node = vinfo->volmap_nodes[i]; ++ if (node) { ++ if (dealloc) ++ reiser4_dealloc_block(jnode_get_block(node), ++ 0, BA_FORMATTED | BA_PERMANENT, ++ get_meta_subvol()); ++ reiser4_drop_volinfo_head(node); ++ vinfo->volmap_nodes[i] = NULL; ++ } ++ } ++ kfree(vinfo->volmap_nodes); ++ vinfo->volmap_nodes = NULL; ++ vinfo->voltab_nodes = NULL; ++} ++ ++static void done_volume_asym(reiser4_volume *vol) ++{ ++ /* ++ * release set of abstract buckets ++ */ ++ if (vol->buckets) { ++ free_buckets(vol->buckets); ++ vol->buckets = NULL; ++ } ++ release_volinfo_nodes(&vol->volinfo[CUR_VOL_CONF], 0); ++ release_volinfo_nodes(&vol->volinfo[NEW_VOL_CONF], 0); ++} ++ ++/** ++ * Load system volume configutation from disk to memory. ++ */ ++static int load_volume_dconf(reiser4_subvol *subv) ++{ ++ int id = CUR_VOL_CONF; ++ int ret; ++ int i, j; ++ u64 packed_segments = 0; ++ reiser4_volume *vol = super_volume(subv->super); ++ reiser4_volinfo *vinfo = &vol->volinfo[id]; ++ distribution_plugin *dist_plug = vol->dist_plug; ++ reiser4_block_nr volmap_loc = subv->volmap_loc[id]; ++ u64 voltabs_needed; ++ ++ assert("edward-1984", subv->id == METADATA_SUBVOL_ID); ++ assert("edward-2175", subv->volmap_loc[id] != 0); ++ ++ if (dist_plug->r.init) { ++ ret = dist_plug->r.init(&vol->dcx, &vol->conf->tab, ++ vol->num_sgs_bits); ++ if (ret) ++ return ret; ++ } ++ vinfo->num_volmaps = num_volmap_nodes(vol, vol->num_sgs_bits); ++ vinfo->num_voltabs = num_voltab_nodes(vol, vol->num_sgs_bits); ++ voltabs_needed = vinfo->num_voltabs; ++ ++ vinfo->volmap_nodes = ++ kzalloc((vinfo->num_volmaps + vinfo->num_voltabs) * ++ sizeof(*vinfo->volmap_nodes), GFP_KERNEL); ++ ++ if (!vinfo->volmap_nodes) ++ return -ENOMEM; ++ ++ vinfo->voltab_nodes = vinfo->volmap_nodes + vinfo->num_volmaps; ++ ++ for (i = 0; i < vinfo->num_volmaps; i++) { ++ struct volmap *volmap; ++ ++ assert("edward-1819", volmap_loc != 0); ++ ++ vinfo->volmap_nodes[i] = ++ reiser4_alloc_volinfo_head(&volmap_loc, subv); ++ if (!vinfo->volmap_nodes[i]) { ++ ret = -ENOMEM; ++ goto unpin; ++ } ++ ret = jload(vinfo->volmap_nodes[i]); ++ if (ret) ++ goto unpin; ++ ++ volmap = (struct volmap *)jdata(vinfo->volmap_nodes[i]); ++ /* ++ * load all voltabs pointed by current volmap ++ */ ++ for (j = 0; ++ j < voltab_nodes_per_block() && voltabs_needed; ++ j++, voltabs_needed --) { ++ ++ reiser4_block_nr voltab_loc; ++ ++ voltab_loc = volmap_get_entry_blk(volmap, j); ++ assert("edward-1986", voltab_loc != 0); ++ ++ vinfo->voltab_nodes[j] = ++ reiser4_alloc_volinfo_head(&voltab_loc, ++ subv); ++ if (!vinfo->voltab_nodes[j]) { ++ ret = -ENOMEM; ++ goto unpin; ++ } ++ ret = jload(vinfo->voltab_nodes[j]); ++ if (ret) ++ goto unpin; ++ ++ dist_plug->v.unpack(&vol->dcx, vol->conf->tab, ++ jdata(vinfo->voltab_nodes[j]), ++ packed_segments, ++ segments_per_block(vol)); ++ jrelse(vinfo->voltab_nodes[j]); ++ ++ packed_segments += segments_per_block(vol); ++ } ++ volmap_loc = get_next_volmap_addr(volmap); ++ jrelse(vinfo->volmap_nodes[i]); ++ } ++ unpin: ++ release_volinfo_nodes(vinfo, 0); ++ return ret; ++} ++ ++static int alloc_volinfo_block(reiser4_block_nr *block, reiser4_subvol *subv) ++{ ++ reiser4_blocknr_hint hint; ++ ++ reiser4_blocknr_hint_init(&hint); ++ hint.block_stage = BLOCK_NOT_COUNTED; ++ ++ return reiser4_alloc_block(&hint, block, ++ BA_FORMATTED | BA_PERMANENT | ++ BA_USE_DEFAULT_SEARCH_START, subv); ++} ++ ++static int dealloc_volinfo_block(reiser4_block_nr *block, reiser4_subvol *subv) ++{ ++ return reiser4_dealloc_block(block, BLOCK_NOT_COUNTED, BA_DEFER, subv); ++} ++ ++/** ++ * Release disk addresses occupied by volume configuration ++ */ ++static int release_volume_dconf(reiser4_volume *vol, int id) ++{ ++ int ret; ++ int i, j; ++ reiser4_subvol *mtd_subv = get_meta_subvol(); ++ reiser4_block_nr volmap_loc = mtd_subv->volmap_loc[id]; ++ reiser4_volinfo *vinfo = &vol->volinfo[id]; ++ u64 voltabs_needed; ++ ++ if (volmap_loc == 0) ++ /* nothing to release */ ++ return 0; ++ /* ++ * FIXME: this is a hack to make sure that atom exists ++ */ ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ ++ voltabs_needed = vinfo->num_voltabs; ++ ++ for (i = 0; i < vinfo->num_volmaps; i++) { ++ jnode *node; ++ struct volmap *volmap; ++ ++ assert("edward-1819", volmap_loc != 0); ++ ++ node = reiser4_alloc_volinfo_head(&volmap_loc, mtd_subv); ++ if (!node) ++ return -ENOMEM; ++ ++ ret = jload(node); ++ if (ret) { ++ reiser4_drop_volinfo_head(node); ++ return ret; ++ } ++ volmap = (struct volmap *)jdata(node); ++ /* ++ * deallocate all voltab blocks pointed out by current volmap ++ */ ++ for (j = 0; ++ j < voltab_nodes_per_block() && voltabs_needed; ++ j++, voltabs_needed --) { ++ ++ reiser4_block_nr voltab_loc; ++ ++ voltab_loc = volmap_get_entry_blk(volmap, j); ++ assert("edward-1987", voltab_loc != 0); ++ dealloc_volinfo_block(&voltab_loc, get_meta_subvol()); ++ } ++ dealloc_volinfo_block(&volmap_loc, get_meta_subvol()); ++ volmap_loc = get_next_volmap_addr(volmap); ++ jrelse(node); ++ reiser4_drop_volinfo_head(node); ++ } ++ return 0; ++} ++ ++/** ++ * Release old on-disk volume configuration and make the new ++ * configuration as "current one". ++ */ ++static int update_volume_dconf(reiser4_volume *vol) ++{ ++ int ret; ++ reiser4_subvol *mtd_subv = get_meta_subvol(); ++ ++ ret = release_volume_dconf(vol, CUR_VOL_CONF); ++ if (ret) ++ return ret; ++ ++ vol->volinfo[CUR_VOL_CONF] = vol->volinfo[NEW_VOL_CONF]; ++ memset(&vol->volinfo[NEW_VOL_CONF], 0, sizeof(reiser4_volinfo)); ++ ++ mtd_subv->volmap_loc[CUR_VOL_CONF] = mtd_subv->volmap_loc[NEW_VOL_CONF]; ++ mtd_subv->volmap_loc[NEW_VOL_CONF] = 0; ++ ++ return 0; ++} ++ ++/** ++ * Create and pin volinfo nodes, allocate disk addresses for them, ++ * and pack in-memory volume system information to those nodes ++ */ ++static int create_volume_dconf(reiser4_volume *vol, int id) ++{ ++ int ret; ++ int i, j; ++ u64 packed_segments = 0; ++ reiser4_subvol *meta_subv = get_meta_subvol(); ++ reiser4_volinfo *vinfo = &vol->volinfo[id]; ++ ++ distribution_plugin *dist_plug = vol->dist_plug; ++ reiser4_block_nr volmap_loc; ++ u64 voltabs_needed; ++ ++ assert("edward-2177", meta_subv->volmap_loc[id] == 0); ++ ++ ret = reiser4_create_atom(); ++ if (ret) ++ return ret; ++ /* ++ * allocate disk address of the first volmap block ++ */ ++ ret = alloc_volinfo_block(&volmap_loc, meta_subv); ++ if (ret) ++ return ret; ++ /* ++ * set location of the first block of volume config ++ */ ++ meta_subv->volmap_loc[id] = volmap_loc; ++ ++ vinfo->num_volmaps = num_volmap_nodes(vol, vol->num_sgs_bits); ++ vinfo->num_voltabs = num_voltab_nodes(vol, vol->num_sgs_bits); ++ voltabs_needed = vinfo->num_voltabs; ++ ++ vinfo->volmap_nodes = ++ kzalloc((vinfo->num_volmaps + vinfo->num_voltabs) * ++ sizeof(void *), GFP_KERNEL); ++ ++ if (!vinfo->volmap_nodes) { ++ /* ++ * release disk address which was just allocated ++ */ ++ reiser4_dealloc_block(&volmap_loc, 0, ++ BA_FORMATTED | BA_PERMANENT, meta_subv); ++ meta_subv->volmap_loc[id] = 0; ++ return -ENOMEM; ++ } ++ vinfo->voltab_nodes = vinfo->volmap_nodes + vinfo->num_volmaps; ++ ++ for (i = 0; i < vinfo->num_volmaps; i++) { ++ struct volmap *volmap; ++ ++ vinfo->volmap_nodes[i] = ++ reiser4_alloc_volinfo_head(&volmap_loc, meta_subv); ++ if (!vinfo->volmap_nodes[i]) { ++ reiser4_dealloc_block(&volmap_loc, 0, ++ BA_FORMATTED | BA_PERMANENT, ++ meta_subv); ++ ret = -ENOMEM; ++ goto unpin; ++ } ++ ret = jinit_new(vinfo->volmap_nodes[i], GFP_KERNEL); ++ if (ret) ++ goto unpin; ++ volmap = (struct volmap *)jdata(vinfo->volmap_nodes[i]); ++ /* ++ * load all voltabs pointed by current volmap ++ */ ++ for (j = 0; ++ j < voltab_nodes_per_block() && voltabs_needed; ++ j++, voltabs_needed --) { ++ ++ reiser4_block_nr voltab_loc; ++ /* ++ * allocate disk address for voltab node ++ */ ++ ret = alloc_volinfo_block(&voltab_loc, meta_subv); ++ if (ret) ++ goto unpin; ++ assert("edward-1838", voltab_loc != 0); ++ ++ volmap_set_entry_blk(volmap, j, voltab_loc); ++ ++ vinfo->voltab_nodes[j] = ++ reiser4_alloc_volinfo_head(&voltab_loc, ++ meta_subv); ++ if (!vinfo->voltab_nodes[j]) { ++ reiser4_dealloc_block(&voltab_loc, 0, ++ BA_FORMATTED | BA_PERMANENT, ++ meta_subv); ++ ret = -ENOMEM; ++ goto unpin; ++ } ++ ret = jinit_new(vinfo->voltab_nodes[j], ++ GFP_KERNEL); ++ if (ret) ++ goto unpin; ++ dist_plug->v.pack(&vol->dcx, ++ jdata(vinfo->voltab_nodes[j]), ++ packed_segments, ++ segments_per_block(vol)); ++ jrelse(vinfo->voltab_nodes[j]); ++ ++ packed_segments += segments_per_block(vol); ++ } ++ if (i == vinfo->num_volmaps - 1) ++ /* ++ * current volmap node is the last one ++ */ ++ set_next_volmap_addr(volmap, 0); ++ else { ++ /* ++ * allocate disk address of the next volmap block ++ * and store it in the current volmap block ++ */ ++ ret = alloc_volinfo_block(&volmap_loc, meta_subv); ++ if (ret) ++ goto unpin; ++ set_next_volmap_addr(volmap, volmap_loc); ++ } ++ /* ++ * update volmap csum ++ */ ++ jrelse(vinfo->volmap_nodes[i]); ++ } ++ return 0; ++ unpin: ++ release_volinfo_nodes(vinfo, 1 /* release disk addresses */); ++ meta_subv->volmap_loc[id] = 0; ++ return ret; ++} ++ ++/* ++ * Capture an array of jnodes, make them dirty and mark as relocate ++ */ ++static int capture_array_nodes(jnode **start, u64 count) ++{ ++ u64 i; ++ int ret; ++ ++ for (i = 0; i < count; i++) { ++ jnode *node; ++ node = start[i]; ++ set_page_dirty_notag(jnode_page(node)); ++ ++ spin_lock_jnode(node); ++ /* ++ * volinfo nodes are always written to new location ++ */ ++ jnode_set_reloc(node); ++ ret = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ BUG_ON(ret != 0); ++ jnode_make_dirty_locked(node); ++ spin_unlock_jnode(node); ++ } ++ return 0; ++} ++ ++static int capture_volume_dconf(reiser4_volume *vol, int id) ++{ ++ int ret; ++ reiser4_volinfo *vinfo = &vol->volinfo[id]; ++ /* ++ * Capture format superblock of meta-data brick with ++ * updated location of the first volmap block. ++ */ ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ return capture_array_nodes(vinfo->volmap_nodes, ++ vinfo->num_volmaps + vinfo->num_voltabs); ++} ++ ++/** ++ * Create volume configuration, put it into transaction ++ * and commit the last one. ++ */ ++static int make_volume_dconf(reiser4_volume *vol) ++{ ++ int ret; ++ ++ ret = create_volume_dconf(vol, NEW_VOL_CONF); ++ if (ret) ++ return ret; ++ ret = capture_volume_dconf(vol, NEW_VOL_CONF); ++ if (ret) ++ goto error; ++ return 0; ++ error: ++ release_volinfo_nodes(&vol->volinfo[NEW_VOL_CONF], ++ 1 /* release disk addresses */); ++ return ret; ++} ++ ++/* ++ * This is called at mount time ++ */ ++static int load_volume_asym(reiser4_subvol *subv) ++{ ++ if (subv->id != METADATA_SUBVOL_ID) ++ /* ++ * configuration of asymmetric volumes ++ * is stored only on meta-data brick ++ */ ++ return 0; ++ if (subv->volmap_loc[CUR_VOL_CONF] == 0) ++ /* ++ * volume configuration is absent on disk ++ */ ++ return 0; ++ ++ return load_volume_dconf(subv); ++} ++ ++static u64 get_pos_in_vol(reiser4_volume *vol, reiser4_subvol *subv); ++static int __remove_data_brick(reiser4_volume *vol, reiser4_subvol *victim); ++/* ++ * Init volume system info, which has been already loaded ++ * diring disk formats inialization of subvolumes (components). ++ */ ++static int init_volume_asym(struct super_block *sb, reiser4_volume *vol) ++{ ++ int ret; ++ u32 subv_id; ++ u32 nr_victims = 0; ++ lv_conf *cur_conf = vol->conf; ++ ++ if (!REISER4_PLANB_KEY_ALLOCATION) { ++ warning("edward-2161", ++ "Asymmetric LV requires Plan-B key allocation scheme"); ++ return RETERR(-EINVAL); ++ } ++ assert("edward-2341", vol->buckets == NULL); ++ /* ++ * Create an abstract set of buckets for this volume ++ */ ++ vol->buckets = create_buckets(); ++ if (!vol->buckets) ++ return -ENOMEM; ++ ++ if (reiser4_is_set(sb, REISER4_PROXY_ENABLED)) { ++ /* ++ * set proxy subvolume ++ */ ++ for_each_mslot(cur_conf, subv_id) { ++ reiser4_subvol *subv; ++ ++ if (!conf_mslot_at(cur_conf, subv_id)) ++ continue; ++ subv = conf_origin(cur_conf, subv_id); ++ if (subvol_is_set(subv, SUBVOL_IS_PROXY)) { ++ vol->proxy = subv; ++ break; ++ } ++ } ++ assert("edward-2445", vol->proxy != NULL); ++ /* ++ * start a proxy flushing kernel thread here ++ */ ++ } ++ if (!reiser4_volume_has_incomplete_removal(sb)) { ++ if (reiser4_volume_is_unbalanced(sb)) ++ warning("", "Volume (%s) is unbalanced", sb->s_id); ++ return 0; ++ } ++ assert("edward-2250", current_volume() == vol); ++ /* ++ * prepare the volume for removal completion ++ */ ++ assert("edward-2244", vol->new_conf == NULL); ++ ++ for_each_mslot(cur_conf, subv_id) { ++ reiser4_subvol *subv; ++ ++ if (!conf_mslot_at(cur_conf, subv_id)) ++ continue; ++ subv = conf_origin(cur_conf, subv_id); ++ if (subvol_is_set(subv, SUBVOL_TO_BE_REMOVED)) { ++ vol->victim = subv; ++ nr_victims ++; ++ } ++ } ++ if (nr_victims > 1) { ++ warning("edward-2246", ++ "Too many bricks (%u) scheduled for removal", ++ nr_victims); ++ return -EIO; ++ } else if (nr_victims == 0) ++ goto out; ++ ++ assert("edward-2251", vol->victim != NULL); ++ /* ++ * vol->victim is not a meta-data brick, as when removing a ++ * meta-data brick we spawn only one checkpoint (similar to ++ * case of adding a brick). It is a speciality of asymmetric ++ * volumes. ++ */ ++ assert("edward-2252", !is_meta_brick(vol->victim)); ++ /* ++ * new config will be created here ++ */ ++ ret = __remove_data_brick(vol, vol->victim); ++ if (ret) ++ return ret; ++ assert("edward-2432", vol->new_conf != NULL); ++ assert("edward-2458", vol->new_conf->tab == NULL); ++ ++ if (!subvol_is_set(vol->victim, SUBVOL_IS_PROXY)) { ++ bucket_t *new_vec; ++ new_vec = remove_bucket(vol->buckets, num_dsa_subvols(vol), ++ get_pos_in_dsa(vol->victim)); ++ if (!new_vec) { ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return -ENOMEM; ++ } ++ free_buckets(vol->buckets); ++ vol->buckets = new_vec; ++ } else ++ /* ++ * Removing proxy brick was incomplete. ++ * Disable IO requests against him. ++ */ ++ reiser4_volume_clear_proxy_io(reiser4_get_current_sb()); ++ /* ++ * borrow distribution table from the existing config (which ++ * includes the old set of slots and the new distribution table) ++ */ ++ vol->new_conf->tab = vol->conf->tab; ++ /* ++ * Now announce incomplete removal. ++ * Volume configuration will be updated by remove_brick_tail_asym() ++ * called by reiser4_finish_removal(). ++ * FIXME: don't ask user to finish removel. ++ * Call reiser4_finish_removal() right here instead. ++ */ ++ out: ++ warning("", "Please, complete brick %s removal on volume %s", ++ vol->victim ? vol->victim->name : "Null", ++ sb->s_id); ++ return 0; ++} ++ ++/** ++ * Bucket operations. ++ * The following methods translate bucket_t to mirror_t ++ */ ++static u64 cap_at_asym(bucket_t *buckets, u64 idx) ++{ ++ return ((mirror_t *)buckets)[idx]->data_capacity; ++} ++ ++static void *apx_of_asym(bucket_t bucket) ++{ ++ return ((mirror_t)bucket)->apx; ++} ++ ++static void *apx_at_asym(bucket_t *buckets, u64 index) ++{ ++ return apx_of_asym(buckets[index]); ++} ++ ++static void apx_set_at_asym(bucket_t *buckets, u64 idx, void *apx) ++{ ++ ((mirror_t *)buckets)[idx]->apx = apx; ++} ++ ++static u64 *apx_lenp_at_asym(bucket_t *buckets, u64 idx) ++{ ++ return &((mirror_t *)buckets)[idx]->apx_len; ++} ++ ++static reiser4_subvol *origin_at(slot_t slot) ++{ ++ return ((mirror_t *)slot)[0]; ++} ++ ++static u64 capacity_at(slot_t slot) ++{ ++ return origin_at(slot)->data_capacity; ++} ++ ++/** ++ * Return number of busy data blocks, which are a subject ++ * for distribution. ++ * @slot represents data brick! This function can not be ++ * applied to meta-data brick. ++ */ ++static u64 data_blocks_occupied(slot_t slot) ++{ ++ /* ++ * From the total block count on a device we need ++ * to subtract number of system blocks (from disk ++ * format specifications), which are always busy ++ * and are not a subject for distribution ++ */ ++ return origin_at(slot)->block_count - ++ origin_at(slot)->min_blocks_used - ++ origin_at(slot)->blocks_free; ++} ++ ++/** ++ * Return first non-empty data slot. ++ * If such slot not found, then return NULL ++ */ ++static slot_t find_first_nonempty_data_slot(void) ++{ ++ u32 subv_id; ++ lv_conf *conf = current_lv_conf(); ++ ++ for_each_data_mslot(conf, subv_id) ++ if (conf->mslots[subv_id]) ++ return conf->mslots[subv_id]; ++ return NULL; ++} ++ ++static u64 space_occupied_at(slot_t slot) ++{ ++ if (is_meta_brick(origin_at(slot))) { ++ slot_t neighbor; ++ /* ++ * In asymmetric LV we don't track a number of busy ++ * data blocks on the meta-data brick. However, we can ++ * calculate it approximately by the portion of busy ++ * data blocks on the neighboring data brick. The last ++ * one has to exist, because there is no need to know ++ * number of data blocks occupied in asymmetric logical ++ * volume consisting of a single meta-data brick (and, ++ * hence, to call this function). ++ */ ++ assert("edward-2069", current_nr_origins() > 1); ++ ++ neighbor = find_first_nonempty_data_slot(); ++ BUG_ON(neighbor == NULL); ++ ++ return div64_u64(capacity_at(slot) * ++ space_occupied_at(neighbor), ++ capacity_at(neighbor)); ++ } else ++ /* data brick */ ++ return data_blocks_occupied(slot); ++} ++ ++/** ++ * Return ordered number of brick @subv in the array of all original ++ * bricks of the logical volume ++ */ ++static u64 get_pos_in_vol(reiser4_volume *vol, reiser4_subvol *subv) ++{ ++ u64 i, j; ++ lv_conf *conf = vol->conf; ++ ++ for (i = 0, j = 0; i < conf->nr_mslots; i++) { ++ if (!conf->mslots[i]) ++ continue; ++ if (conf->mslots[i][0] == subv) ++ return j; ++ j++; ++ } ++ assert("edward-2197", i == conf->nr_mslots); ++ assert("edward-2198", j == vol_nr_origins(vol)); ++ return j; ++} ++ ++/** ++ * Returns true, if volume @vol includes @brick in its configuration. ++ * Pre-condition: the volume is read, or write locked ++ */ ++int brick_belongs_volume(reiser4_volume *vol, reiser4_subvol *subv) ++{ ++ return get_pos_in_vol(vol, subv) < vol_nr_origins(vol); ++} ++ ++/** ++ * Create a config, which is similar to @old except the pointer ++ * to distribution table (which is NULL for the clone). ++ */ ++static lv_conf *clone_lv_conf(lv_conf *old) ++{ ++ lv_conf *new; ++ ++ new = alloc_lv_conf(old->nr_mslots); ++ if (new) { ++ memcpy(new->mslots, old->mslots, ++ sizeof(slot_t) * old->nr_mslots); ++ } ++ return new; ++} ++ ++static int resize_brick(reiser4_volume *vol, reiser4_subvol *this, ++ long long delta, int *need_balance) ++{ ++ int ret; ++ int(*dst_resize_fn)(reiser4_dcx *, const void *, u64, bucket_t); ++ ++ assert("edward-2393", delta != 0); ++ ++ this->data_capacity += delta; ++ ++ *need_balance = 1; ++ if (num_dsa_subvols(vol) == 1 || ++ (is_meta_brick(this) && !is_dsa_brick(this))) { ++ *need_balance = 0; ++ return 0; ++ } ++ if (delta > 0) ++ dst_resize_fn = vol->dist_plug->v.inc; ++ else ++ dst_resize_fn = vol->dist_plug->v.dec; ++ ++ ret = dst_resize_fn(&vol->dcx, vol->conf->tab, ++ get_pos_in_dsa(this), NULL); ++ if (ret) ++ goto error; ++ ++ vol->new_conf = clone_lv_conf(vol->conf); ++ if (vol->new_conf == NULL) { ++ ret = -ENOMEM; ++ goto error; ++ } ++ return 0; ++ error: ++ this->data_capacity -= delta; ++ return ret; ++} ++ ++static int __add_meta_brick(reiser4_volume *vol, reiser4_subvol *new) ++{ ++ assert("edward-2433", is_meta_brick(new)); ++ /* ++ * Clone in-memory volume config ++ */ ++ vol->new_conf = clone_lv_conf(vol->conf); ++ if (vol->new_conf == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++static int add_meta_brick(reiser4_volume *vol, reiser4_subvol *new, ++ bucket_t **old_vec) ++{ ++ int ret; ++ bucket_t *new_vec; ++ ++ assert("edward-1820", is_meta_brick(new)); ++ /* ++ * We don't need to activate meta-data brick: ++ * it is always active in the mount session of the logical volume. ++ * ++ * Number of bricks and slots in the logical volume remains the same. ++ * ++ * insert @new at the first place in the set of abstract buckets ++ */ ++ new_vec = insert_bucket(vol->buckets, new, num_dsa_subvols(vol), ++ METADATA_SUBVOL_ID /* position to insert */); ++ if (!new_vec) ++ return RETERR(-ENOMEM); ++ *old_vec = vol->buckets; ++ vol->buckets = new_vec; ++ /* ++ * Create new distribution table. ++ */ ++ ret = vol->dist_plug->v.inc(&vol->dcx, vol->conf->tab, ++ METADATA_SUBVOL_ID /* pos */, new); ++ if (ret) ++ goto error; ++ /* ++ * finally, clone in-memory volume config ++ */ ++ ret =__add_meta_brick(vol, new); ++ if (ret) ++ goto error; ++ new->flags |= (1 << SUBVOL_HAS_DATA_ROOM); ++ return 0; ++ error: ++ vol->buckets = *old_vec; ++ free_buckets(new_vec); ++ return ret; ++} ++ ++/** ++ * Find first empty slot in the array of volume's slots and ++ * return its offset in that array. If all slots are busy, ++ * then return number of slots. ++ */ ++static u32 find_first_empty_slot_off(void) ++{ ++ u32 subv_id; ++ lv_conf *conf = current_lv_conf(); ++ ++ for_each_data_mslot(conf, subv_id) ++ if (conf->mslots[subv_id] == NULL) ++ return subv_id; ++ ++ assert("edward-2183", conf->nr_mslots == current_nr_origins()); ++ return conf->nr_mslots; ++} ++ ++/** ++ * Create new in-memory volume config ++ */ ++int __add_data_brick(reiser4_volume *vol, reiser4_subvol *this, u64 pos_in_vol) ++{ ++ u64 old_nr_mslots = vol->conf->nr_mslots; ++ slot_t new_slot; ++ /* ++ * Assign internal ID for the new brick ++ */ ++ this->id = pos_in_vol; ++ /* ++ * Create new in-memory volume config ++ */ ++ new_slot = alloc_mslot(1 + this->num_replicas); ++ if (!new_slot) ++ return RETERR(-ENOMEM); ++ ++ ((mirror_t *)new_slot)[this->mirror_id] = this; ++ ++ if (pos_in_vol == old_nr_mslots) ++ /* ++ * There is no free slots in the old config - ++ * create a new one with a larger number of slots ++ */ ++ vol->new_conf = alloc_lv_conf(1 + old_nr_mslots); ++ else ++ vol->new_conf = alloc_lv_conf(old_nr_mslots); ++ if (!vol->new_conf) { ++ free_mslot(new_slot); ++ return RETERR(-ENOMEM); ++ } ++ memcpy(vol->new_conf->mslots, vol->conf->mslots, ++ sizeof(slot_t) * old_nr_mslots); ++ vol->new_conf->mslots[pos_in_vol] = new_slot; ++ ++ atomic_inc(&vol->nr_origins); ++ return 0; ++} ++ ++/** ++ * Find a respective position in DSA by mslot index ++ */ ++u64 pos_in_dsa_by_mslot(u64 mslot_idx) ++{ ++ u32 i,j; ++ reiser4_volume *vol = current_volume(); ++ ++ for (i = 0, j = 0; i < mslot_idx; i++) { ++ if (!vol->conf->mslots[i]) ++ continue; ++ if (!is_dsa_brick(conf_origin(vol->conf, i))) ++ continue; ++ j++; ++ } ++ return j; ++} ++ ++int add_data_brick(reiser4_volume *vol, reiser4_subvol *this, ++ bucket_t **old_vec) ++{ ++ int ret; ++ u64 free_mslot_idx; ++ u64 pos_in_dsa; ++ bucket_t *new_vec; ++ ++ assert("edward-1929", !is_meta_brick(this)); ++ ++ free_mslot_idx = find_first_empty_slot_off(); ++ pos_in_dsa = pos_in_dsa_by_mslot(free_mslot_idx); ++ /* ++ * insert @this to the set of abstract buckets ++ */ ++ new_vec = insert_bucket(vol->buckets, this, ++ num_dsa_subvols(vol), pos_in_dsa); ++ if (!new_vec) ++ return -ENOMEM; ++ *old_vec = vol->buckets; ++ vol->buckets = new_vec; ++ ++ /* ++ * create new in-memory volume config ++ */ ++ ret = __add_data_brick(vol, this, free_mslot_idx); ++ if (ret) ++ goto error; ++ /* ++ * finally, create new distribution table ++ */ ++ return vol->dist_plug->v.inc(&vol->dcx, vol->conf->tab, ++ pos_in_dsa, this); ++ error: ++ vol->buckets = *old_vec; ++ free_buckets(new_vec); ++ return ret; ++} ++ ++static int resize_brick_asym(reiser4_volume *vol, reiser4_subvol *this, ++ long long delta, int *need_balance) ++{ ++ int ret; ++ struct super_block *sb = reiser4_get_current_sb(); ++ reiser4_dcx *rdcx = &vol->dcx; ++ distribution_plugin *dist_plug = vol->dist_plug; ++ lv_conf *old_conf = vol->conf; ++ ++ assert("edward-1824", vol != NULL); ++ assert("edward-1825", dist_plug != NULL); ++ ++ if (is_proxy_brick(this)) { ++ warning("edward-2447", ++ "Can't resize proxy brick %s", this->name); ++ return RETERR(-EINVAL); ++ } ++ ret = dist_plug->v.init(&vol->conf->tab, ++ num_dsa_subvols(vol), ++ vol->num_sgs_bits, rdcx); ++ if (ret) ++ return ret; ++ ++ ret = resize_brick(vol, this, delta, need_balance); ++ dist_plug->v.done(rdcx); ++ if (ret) ++ return ret; ++ if (!(*need_balance)) { ++ ret = capture_brick_super(this); ++ if (ret) ++ goto error; ++ printk("reiser4 (%s): Changed data capacity of brick %s.\n", ++ sb->s_id, this->name); ++ return 0; ++ } ++ assert("edward-2394", vol->new_conf != NULL); ++ ++ ret = make_volume_dconf(vol); ++ if (ret) ++ goto error; ++ ret = update_volume_dconf(vol); ++ if (ret) ++ goto error; ++ dist_plug->r.replace(&vol->dcx, &vol->new_conf->tab); ++ /* ++ * write unbalanced status and new data capacity to disk ++ */ ++ reiser4_volume_set_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ ret = capture_brick_super(this); ++ if (ret) ++ goto error; ++ ret = force_commit_current_atom(); ++ if (ret) ++ goto error; ++ /* ++ * publish the new config ++ */ ++ rcu_assign_pointer(vol->conf, vol->new_conf); ++ synchronize_rcu(); ++ free_lv_conf(old_conf); ++ vol->new_conf = NULL; ++ ++ printk("reiser4 (%s): Changed data capacity of brick %s.\n", ++ sb->s_id, this->name); ++ return 0; ++ error: ++ /* ++ * resize failed - it should be repeated in regular context ++ */ ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++static int add_proxy_asym(reiser4_volume *vol, reiser4_subvol *new) ++{ ++ int ret; ++ lv_conf *old_conf = vol->conf; ++ struct super_block *sb = reiser4_get_current_sb(); ++ ++ if (is_meta_brick(new) && (vol_nr_origins(vol) == 1)) { ++ warning("edward-2434", ++ "Single meta-data brick can not be proxy"); ++ return -EINVAL; ++ } ++ if (new == get_meta_subvol()) ++ ret = __add_meta_brick(vol, new); ++ else ++ ret = __add_data_brick(vol, new, find_first_empty_slot_off()); ++ if (ret) ++ return ret; ++ assert("edward-2436", vol->new_conf != NULL); ++ assert("edward-2459", vol->new_conf->tab == NULL); ++ ++ if (new != get_meta_subvol()) { ++ /* ++ * add a record about @new to the meta-data brick ++ */ ++ ret = reiser4_grab_space(estimate_one_insert_into_item( ++ meta_subvol_tree()), ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (ret) ++ goto error; ++ ret = brick_symbol_add(new); ++ if (ret) ++ goto error; ++ } ++ reiser4_volume_set_proxy_enabled(sb); ++ reiser4_volume_set_proxy_io(sb); ++ clear_bit(SUBVOL_HAS_DATA_ROOM, &new->flags); ++ ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ ret = capture_brick_super(new); ++ if (ret) ++ goto error; ++ /* ++ * borrow distribution table from the old config ++ */ ++ vol->new_conf->tab = old_conf->tab; ++ old_conf->tab = NULL; ++ /* ++ * publish the new config ++ */ ++ rcu_assign_pointer(vol->conf, vol->new_conf); ++ synchronize_rcu(); ++ free_lv_conf(old_conf); ++ vol->new_conf = NULL; ++ vol->proxy = new; ++ /* ++ * after publishing the new config (not before!) ++ * write superblocks of meta-data brick and the proxy brick respectively ++ */ ++ force_commit_current_atom(); ++ ++ /* FIXME: start a proxy flushing kernel thread here */ ++ ++ printk("reiser4 (%s): Proxy brick %s has been added.", ++ sb->s_id, new->name); ++ return 0; ++ error: ++ /* adding a proxy should be repeated in regular context */ ++ ++ clear_bit(SUBVOL_IS_PROXY, &new->flags); ++ if (!is_meta_brick(new)) ++ new->flags |= (1 << SUBVOL_HAS_DATA_ROOM); ++ reiser4_volume_clear_proxy_enabled(sb); ++ reiser4_volume_clear_proxy_io(sb); ++ ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++/** ++ * Add a @new brick to asymmetric logical volume @vol ++ */ ++static int add_brick_asym(reiser4_volume *vol, reiser4_subvol *new) ++{ ++ int ret; ++ distribution_plugin *dist_plug = vol->dist_plug; ++ lv_conf *old_conf = vol->conf; ++ struct super_block *sb = reiser4_get_current_sb(); ++ ++ bucket_t *old_vec; ++ bucket_t *new_vec; ++ ++ assert("edward-1931", dist_plug != NULL); ++ assert("edward-2262", vol->conf != NULL); ++ assert("edward-2239", vol->new_conf == NULL); ++ ++ if (new->data_capacity == 0) { ++ warning("edward-1962", "Can't add brick of zero capacity"); ++ return -EINVAL; ++ } ++ /* ++ * We allow to add meta-data bricks without any other conditions. ++ * In contrast, any data brick to add has to be empty. ++ */ ++ if (new != get_meta_subvol() && ++ reiser4_subvol_used_blocks(new) > ++ reiser4_subvol_min_blocks_used(new)) { ++ warning("edward-2334", "Can't add not empty data brick %s", ++ new->name); ++ return -EINVAL; ++ } ++ if (brick_belongs_volume(vol, new) && is_dsa_brick(new)) { ++ /* ++ * brick already participate in regular data distribution ++ */ ++ warning("edward-1963", "Can't add brick to DSA twice"); ++ return -EINVAL; ++ } ++ if (subvol_is_set(new, SUBVOL_IS_PROXY)) ++ return add_proxy_asym(vol, new); ++ ++ /* reserve space on meta-data subvolume for brick symbol insertion */ ++ grab_space_enable(); ++ ret = reiser4_grab_space(estimate_one_insert_into_item( ++ meta_subvol_tree()), ++ BA_CAN_COMMIT, get_meta_subvol()); ++ if (ret) ++ return ret; ++ ret = dist_plug->v.init(&vol->conf->tab, ++ num_dsa_subvols(vol), ++ vol->num_sgs_bits, ++ &vol->dcx); ++ if (ret) ++ return ret; ++ /* ++ * Create new in-memory volume config ++ */ ++ if (new == get_meta_subvol()) ++ ret = add_meta_brick(vol, new, &old_vec); ++ else ++ ret = add_data_brick(vol, new, &old_vec); ++ ++ dist_plug->v.done(&vol->dcx); ++ if (ret) ++ return ret; ++ assert("edward-2240", vol->new_conf != NULL); ++ assert("edward-2462", vol->new_conf->tab == NULL); ++ ++ ret = make_volume_dconf(vol); ++ if (ret) ++ goto error; ++ ret = update_volume_dconf(vol); ++ if (ret) ++ goto error; ++ if (new != get_meta_subvol()) { ++ /* add a record about @new to the volume */ ++ ret = brick_symbol_add(new); ++ if (ret) ++ goto error; ++ } ++ dist_plug->r.replace(&vol->dcx, &vol->new_conf->tab); ++ ++ reiser4_volume_set_unbalanced(reiser4_get_current_sb()); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ ret = capture_brick_super(new); ++ if (ret) ++ goto error; ++ /* ++ * Now publish the new config ++ */ ++ rcu_assign_pointer(vol->conf, vol->new_conf); ++ synchronize_rcu(); ++ free_lv_conf(old_conf); ++ vol->new_conf = NULL; ++ free_buckets(old_vec); ++ /* ++ * after publishing the new config (not before!) ++ * write superblocks of meta-data brick and the proxy brick respectively ++ */ ++ force_commit_current_atom(); ++ ++ printk("reiser4 (%s): Brick %s has been added.", sb->s_id, new->name); ++ return 0; ++ error: ++ /* ++ * adding a brick should be repeated in regular context ++ */ ++ if (is_meta_brick(new)) ++ clear_bit(SUBVOL_HAS_DATA_ROOM, &new->flags); ++ reiser4_volume_clear_unbalanced(reiser4_get_current_sb()); ++ ++ new_vec = vol->buckets; ++ vol->buckets = old_vec; ++ free_buckets(new_vec); ++ ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++static u64 space_occupied(void) ++{ ++ u64 ret = 0; ++ u64 subv_id; ++ lv_conf *conf = current_lv_conf(); ++ ++ txnmgr_force_commit_all(reiser4_get_current_sb(), 0); ++ ++ for_each_mslot(conf, subv_id) { ++ if (!conf->mslots[subv_id] || ++ !is_dsa_brick(conf_origin(conf, subv_id))) ++ continue; ++ ret += space_occupied_at(conf->mslots[subv_id]); ++ } ++ return ret; ++} ++ ++static int __remove_meta_brick(reiser4_volume *vol) ++{ ++ /* ++ * Clone in-memory volume config ++ */ ++ vol->new_conf = clone_lv_conf(vol->conf); ++ if (vol->new_conf == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++static int remove_meta_brick(reiser4_volume *vol, bucket_t **old_vec) ++{ ++ int ret; ++ reiser4_subvol *mtd_subv = get_meta_subvol(); ++ distribution_plugin *dist_plug = vol->dist_plug; ++ bucket_t *new_vec; ++ ++ assert("edward-1844", num_dsa_subvols(vol) > 1); ++ ++ if (!is_dsa_brick(mtd_subv)) { ++ warning("edward-2331", ++ "Metadata brick doesn't belong to DSA. Can't remove."); ++ return RETERR(-EINVAL); ++ } ++ /* ++ * remove meta-data brick from the set of abstract buckets ++ */ ++ new_vec = remove_bucket(vol->buckets, num_dsa_subvols(vol), ++ METADATA_SUBVOL_ID /* position in DSA */); ++ if (!new_vec) ++ return RETERR(-ENOMEM); ++ ++ *old_vec = vol->buckets; ++ vol->buckets = new_vec; ++ ++ ret = dist_plug->v.dec(&vol->dcx, vol->conf->tab, ++ METADATA_SUBVOL_ID, mtd_subv); ++ if (ret) ++ goto error; ++ ++ ret = __remove_meta_brick(vol); ++ if (ret) ++ goto error; ++ ++ clear_bit(SUBVOL_HAS_DATA_ROOM, &mtd_subv->flags); ++ assert("edward-1827", !is_dsa_brick(mtd_subv)); ++ return 0; ++ error: ++ vol->buckets = *old_vec; ++ free_buckets(new_vec); ++ return ret; ++} ++ ++/** ++ * Find rightmost non-empty slot different from the last one. ++ * If not found, return 0. Otherwise return slot's offset + 1. ++ */ ++static u32 get_new_nr_mslots(void) ++{ ++ u32 i; ++ lv_conf *conf = current_lv_conf(); ++ ++ assert("edward-2208", conf->nr_mslots > 1); ++ ++ for (i = conf->nr_mslots - 2;; i--) { ++ if (conf->mslots[i]) ++ return i + 1; ++ if (i == 0) ++ break; ++ } ++ return 0; ++} ++ ++static int __remove_data_brick(reiser4_volume *vol, reiser4_subvol *victim) ++{ ++ lv_conf *old = vol->conf; ++ u64 old_num_subvols = vol_nr_origins(vol); ++ u64 pos_in_vol; ++ u32 new_nr_mslots; ++ ++ assert("edward-2253", vol->new_conf == NULL); ++ ++ pos_in_vol = get_pos_in_vol(vol, victim); ++ assert("edward-2199", pos_in_vol < old_num_subvols); ++ ++ if (pos_in_vol == old_num_subvols - 1) { ++ /* ++ * removing the rightmost brick - ++ * config will be replaced with a new one ++ * with a smaller number of slots. ++ */ ++ new_nr_mslots = get_new_nr_mslots(); ++ BUG_ON(new_nr_mslots == 0); ++ } else ++ new_nr_mslots = old->nr_mslots; ++ ++ vol->new_conf = alloc_lv_conf(new_nr_mslots); ++ if (!vol->new_conf) ++ return RETERR(-ENOMEM); ++ memcpy(vol->new_conf->mslots, old->mslots, ++ new_nr_mslots * sizeof(slot_t)); ++ ++ if (pos_in_vol != old_num_subvols - 1) { ++ /* ++ * In the new config mark respective slot as empty ++ */ ++ assert("edward-2241", ++ vol->new_conf->mslots[victim->id] != NULL); ++ vol->new_conf->mslots[victim->id] = NULL; ++ } ++ return 0; ++} ++ ++static int remove_data_brick(reiser4_volume *vol, reiser4_subvol *victim, ++ bucket_t **old_vec) ++{ ++ int ret; ++ u32 pos_in_dsa; ++ bucket_t *new_vec; ++ ++ ret = __remove_data_brick(vol, victim); ++ if (ret) ++ return ret; ++ ++ pos_in_dsa = get_pos_in_dsa(victim); ++ ++ new_vec = remove_bucket(vol->buckets, num_dsa_subvols(vol), pos_in_dsa); ++ if (!new_vec) ++ return -ENOMEM; ++ ++ *old_vec = vol->buckets; ++ vol->buckets = new_vec; ++ ++ ret = vol->dist_plug->v.dec(&vol->dcx, vol->conf->tab, ++ pos_in_dsa, victim); ++ if (ret) { ++ /* ++ * release resources allocated by and ++ * roll back changes made by __remove_data_brick() ++ */ ++ bucket_t *new_vec = vol->buckets; ++ vol->buckets = *old_vec; ++ free_buckets(new_vec); ++ ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++ } ++ victim->flags |= (1 << SUBVOL_TO_BE_REMOVED); ++ return 0; ++} ++ ++static int remove_proxy_asym(reiser4_volume *vol, reiser4_subvol *victim) ++{ ++ int ret; ++ struct super_block *sb = reiser4_get_current_sb(); ++ ++ /* ++ * Prepare a new volume config with different set of bricks, ++ * not including the proxy brick, and the same distribution ++ * table ++ */ ++ if (is_meta_brick(victim)) ++ ret = __remove_meta_brick(vol); ++ else ++ ret = __remove_data_brick(vol, victim); ++ if (ret) ++ return ret; ++ assert("edward-2437", vol->new_conf != NULL); ++ assert("edward-2460", vol->new_conf->tab == NULL); ++ /* ++ * borrow distribution table from the old config ++ */ ++ vol->new_conf->tab = vol->conf->tab; ++ /* ++ * Disable IO requests against the proxy brick to be removed ++ */ ++ reiser4_volume_clear_proxy_io(sb); ++ ++ if (!is_meta_brick(victim)) ++ capture_brick_super(victim); ++ /* ++ * set unbalanced status and put format super-block ++ * of meta-data brick to the transaction ++ */ ++ reiser4_volume_set_unbalanced(sb); ++ reiser4_volume_set_incomplete_removal(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ /* ++ * write unbalanced and incomplete removal status to disk ++ */ ++ ret = force_commit_current_atom(); ++ if (ret) ++ goto error; ++ /* ++ * the volume will be balanced with the old distribution table - ++ * it will move all data from the proxy brick to other bricks ++ * of the volume ++ */ ++ return 0; ++ error: ++ /* ++ * proxy removal should be repeated in regular context ++ */ ++ reiser4_volume_clear_unbalanced(sb); ++ reiser4_volume_clear_incomplete_removal(sb); ++ ++ reiser4_volume_set_proxy_enabled(sb); ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++static int remove_brick_asym(reiser4_volume *vol, reiser4_subvol *victim) ++{ ++ int ret; ++ lv_conf *tmp_conf; ++ lv_conf *old_conf = vol->conf; ++ distribution_plugin *dist_plug = vol->dist_plug; ++ struct super_block *sb = reiser4_get_current_sb(); ++ u32 old_nr_dsa_bricks = num_dsa_subvols(vol); ++ bucket_t *old_vec; ++ bucket_t *new_vec; ++ ++ assert("edward-1830", vol != NULL); ++ assert("edward-1846", dist_plug != NULL); ++ ++ vol->victim = victim; ++ ++ if (subvol_is_set(victim, SUBVOL_IS_PROXY)) ++ return remove_proxy_asym(vol, victim); ++ ++ if (old_nr_dsa_bricks == 1) { ++ warning("edward-1941", ++ "Can't remove the single brick from DSA"); ++ return RETERR(-EINVAL); ++ } ++ ret = dist_plug->v.init(&vol->conf->tab, ++ old_nr_dsa_bricks, vol->num_sgs_bits, ++ &vol->dcx); ++ if (ret) ++ return ret; ++ ++ if (is_meta_brick(victim)) ++ ret = remove_meta_brick(vol, &old_vec); ++ else ++ ret = remove_data_brick(vol, victim, &old_vec); ++ dist_plug->v.done(&vol->dcx); ++ if (ret) ++ return ret; ++ assert("edward-2242", vol->new_conf != NULL); ++ assert("edward-2461", vol->new_conf->tab == NULL); ++ ++ ret = make_volume_dconf(vol); ++ if (ret) ++ goto error; ++ ret = update_volume_dconf(vol); ++ if (ret) ++ goto error; ++ dist_plug->r.replace(&vol->dcx, &vol->new_conf->tab); ++ /* ++ * Prepare a temporal config for balancing. This config has ++ * the same set of bricks, but updated distribution table ++ */ ++ tmp_conf = clone_lv_conf(old_conf); ++ if (!tmp_conf) { ++ ret = RETERR(-ENOMEM); ++ goto error; ++ } ++ /* borrow distribution table from the new config */ ++ tmp_conf->tab = vol->new_conf->tab; ++ ++ if (!is_meta_brick(victim)) ++ capture_brick_super(victim); ++ /* ++ * set unbalanced status and put format super-block ++ * of meta-data brick to the transaction ++ */ ++ reiser4_volume_set_unbalanced(sb); ++ reiser4_volume_set_incomplete_removal(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) { ++ tmp_conf->tab = NULL; ++ free_lv_conf(tmp_conf); ++ goto error; ++ } ++ /* ++ * write unbalanced and incomplete removal status to disk ++ */ ++ ret = force_commit_current_atom(); ++ if (ret) ++ goto error; ++ /* ++ * New configuration is written to disk. ++ * From now on the brick removal operation can not be rolled ++ * back on error paths. Instead, it should be completed in a ++ * context of a special completion operation ++ */ ++ /* ++ * Publish the temporal config ++ */ ++ rcu_assign_pointer(vol->conf, tmp_conf); ++ synchronize_rcu(); ++ free_lv_conf(old_conf); ++ free_buckets(old_vec); ++ /* ++ * From now on the file system doesn't allocate disk ++ * addresses on the brick to be removed ++ */ ++ printk("reiser4 (%s): Brick %s scheduled for removal.\n", ++ sb->s_id, victim->name); ++ return 0; ++ error: ++ /* ++ * brick removal should be repeated in regular context ++ */ ++ reiser4_volume_clear_unbalanced(sb); ++ reiser4_volume_clear_incomplete_removal(sb); ++ if (is_meta_brick(victim)) ++ victim->flags |= (1 << SUBVOL_HAS_DATA_ROOM); ++ ++ new_vec = vol->buckets; ++ vol->buckets = old_vec; ++ free_buckets(new_vec); ++ ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++static int reserve_brick_symbol_del(void) ++{ ++ reiser4_subvol *subv = get_meta_subvol(); ++ /* ++ * grab one block of meta-data brick to remove ++ * one item from a formatted node ++ */ ++ assert("edward-2303", ++ lock_stack_isclean(get_current_lock_stack())); ++ grab_space_enable(); ++ return reiser4_grab_reserved(reiser4_get_current_sb(), ++ estimate_one_item_removal(&subv->tree), ++ BA_CAN_COMMIT, subv); ++} ++ ++/** ++ * Pre-condition: all data have been moved out of the brick to be removed ++ * by the balancing procedure, and unbalanced status has been successfully ++ * cleared up on disk ++ */ ++int remove_brick_tail_asym(reiser4_volume *vol, reiser4_subvol *victim) ++{ ++ int ret; ++ int is_proxy = 0; ++ lv_conf *cur_conf = vol->conf; ++ ++ if (!is_meta_brick(victim)) ++ clear_bit(SUBVOL_TO_BE_REMOVED, &victim->flags); ++ ++ if (subvol_is_set(victim, SUBVOL_IS_PROXY)) { ++ is_proxy = 1; ++ assert("edward-2448", ++ !subvol_is_set(victim, SUBVOL_HAS_DATA_ROOM)); ++ ++ reiser4_volume_clear_proxy_enabled(reiser4_get_current_sb()); ++ clear_bit(SUBVOL_IS_PROXY, &victim->flags); ++ if (!is_meta_brick(victim)) ++ victim->flags |= (1 << SUBVOL_HAS_DATA_ROOM); ++ } ++ ret = capture_brick_super(victim); ++ if (ret) ++ goto error; ++ /* ++ * We are about to release @victim with replicas. ++ * Before this, it is absolutely necessarily to ++ * commit everything to make sure that there is ++ * no pending IOs addressed to the @victim and its ++ * replicas. ++ * ++ * During this commit @victim gets the last IO ++ * request as a member of the logical volume. ++ */ ++ txnmgr_force_commit_all(victim->super, 0); ++ all_grabbed2free(); ++ reiser4_txn_restart_current(); ++ /* ++ * Publish final config with updated set of slots ++ */ ++ if (!is_meta_brick(victim)) { ++ if (reiser4_subvol_used_blocks(victim) > ++ reiser4_subvol_min_blocks_used(victim)) { ++ warning("edward-2335", ++ "Can't remove data brick: not empty %s", ++ victim->name); ++ ret = RETERR(-EAGAIN); ++ goto error; ++ } ++ /* ++ * remove a record about @victim from the volume ++ * and decrement number of bricks in the same ++ * transaction ++ */ ++ ret = reserve_brick_symbol_del(); ++ if (ret) ++ goto error; ++ ret = brick_symbol_del(victim); ++ reiser4_release_reserved(reiser4_get_current_sb()); ++ if (ret) ++ goto error; ++ atomic_dec(&vol->nr_origins); ++ } ++ /* ++ * From now on we can not fail. Moreover, remove_brick_tail() ++ * must not be called for this brick once again. ++ */ ++ vol->victim = NULL; ++ /* ++ * Publish final config with updated set of slots, ++ * which doesn't contain @victim ++ */ ++ rcu_assign_pointer(vol->conf, vol->new_conf); ++ /* ++ * Release victim with replicas. It is safe, ++ * as at this point nobody is aware of them ++ */ ++ if (!is_meta_brick(victim)) ++ free_mslot_at(cur_conf, victim->id); ++ ++ synchronize_rcu(); ++ cur_conf->tab = NULL; ++ free_lv_conf(cur_conf); ++ vol->new_conf = NULL; ++ if (is_proxy) ++ vol->proxy = NULL; ++ ++ printk("reiser4 (%s): %s %s has been removed.\n", ++ victim->super->s_id, is_proxy ? "Proxy" : "Brick", ++ victim->name); ++ return 0; ++ error: ++ /* ++ * brick removal should be completed in the context of ++ * a special removal completion operation ++ */ ++ victim->flags |= (1 << SUBVOL_TO_BE_REMOVED); ++ if (is_proxy) { ++ set_bit(SUBVOL_IS_PROXY, &victim->flags); ++ reiser4_volume_set_proxy_enabled(reiser4_get_current_sb()); ++ if (!is_meta_brick(victim)) ++ clear_bit(SUBVOL_HAS_DATA_ROOM, &victim->flags); ++ } ++ return ret; ++} ++ ++static int init_volume_simple(struct super_block *sb, reiser4_volume *vol) ++{ ++ if (!REISER4_PLANA_KEY_ALLOCATION) { ++ warning("edward-2376", ++ "Simple volume requires Plan-A key allocation scheme"); ++ return RETERR(-EINVAL); ++ } ++ return 0; ++} ++ ++static u64 meta_subvol_id_simple(void) ++{ ++ return METADATA_SUBVOL_ID; ++} ++ ++static u64 calc_brick_simple(lv_conf *conf, const struct inode *inode, ++ loff_t offset) ++{ ++ return METADATA_SUBVOL_ID; ++} ++ ++static int remove_brick_simple(reiser4_volume *vol, reiser4_subvol *this) ++{ ++ warning("", "remove_brick operation is undefined for simple volumes"); ++ return -EINVAL; ++} ++ ++static int resize_brick_simple(reiser4_volume *vol, reiser4_subvol *this, ++ long long delta, int *need_balance) ++{ ++ warning("", "resize operation is undefined for simple volumes"); ++ return -EINVAL; ++} ++ ++static int add_brick_simple(reiser4_volume *vol, reiser4_subvol *new) ++{ ++ warning("", "add_brick operation is undefined for simple volumes"); ++ return -EINVAL; ++} ++ ++static int balance_volume_simple(struct super_block *sb, u32 flags) ++{ ++ warning("", "balance operation is undefined for simple volumes"); ++ return -EINVAL; ++} ++ ++static inline u32 get_seed(oid_t oid, reiser4_volume *vol) ++{ ++ u32 seed; ++ ++ put_unaligned(cpu_to_le64(oid), &oid); ++ ++ seed = murmur3_x86_32((const char *)&oid, sizeof(oid), ~0); ++ seed = murmur3_x86_32(vol->uuid, 16, seed); ++ return seed; ++} ++ ++static u64 calc_brick_asym(lv_conf *conf, const struct inode *inode, ++ loff_t offset) ++{ ++ assert("edward-2267", conf != NULL); ++ ++ if (!conf->tab) { ++ /* ++ * DSA includes only one brick. It is either meta-data ++ * brick, or one of the next two bricks at the right ++ */ ++ assert("edward-2474", num_dsa_subvols(current_volume()) == 1); ++ return meta_brick_belongs_dsa() ? METADATA_SUBVOL_ID : ++ is_dsa_brick(conf_origin(conf, ++ METADATA_SUBVOL_ID + 1)) ? ++ METADATA_SUBVOL_ID + 1 : METADATA_SUBVOL_ID + 2; ++ } else { ++ u64 stripe_idx; ++ reiser4_volume *vol = current_volume(); ++ distribution_plugin *dist_plug = current_dist_plug(); ++ ++ if (vol->stripe_bits) { ++ stripe_idx = offset >> vol->stripe_bits; ++ put_unaligned(cpu_to_le64(stripe_idx), &stripe_idx); ++ } else ++ stripe_idx = 0; ++ ++ return dist_plug->r.lookup(&vol->dcx, inode, ++ (const char *)&stripe_idx, ++ sizeof(stripe_idx), ++ get_seed(get_inode_oid(inode), vol), ++ conf->tab); ++ } ++} ++ ++u64 get_meta_subvol_id(void) ++{ ++ return current_vol_plug()->meta_subvol_id(); ++} ++ ++reiser4_subvol *get_meta_subvol(void) ++{ ++ return current_origin(get_meta_subvol_id()); ++} ++ ++reiser4_subvol *super_meta_subvol(struct super_block *super) ++{ ++ return super_origin(super, super_vol_plug(super)->meta_subvol_id()); ++} ++ ++u64 find_brick_simple(const coord_t *coord) ++{ ++ return METADATA_SUBVOL_ID; ++} ++ ++int print_volume_simple(struct super_block *sb, struct reiser4_vol_op_args *args) ++{ ++ reiser4_volume *vol = super_volume(sb); ++ ++ args->u.vol.nr_bricks = 1; ++ memcpy(args->u.vol.id, vol->uuid, 16); ++ args->u.vol.vpid = vol->vol_plug->h.id; ++ args->u.vol.dpid = vol->dist_plug->h.id; ++ args->u.vol.stripe_bits = vol->stripe_bits; ++ args->u.vol.fs_flags = get_super_private(sb)->fs_flags; ++ args->u.vol.nr_mslots = vol->conf->nr_mslots; ++ args->u.vol.nr_volinfo_blocks = 0; ++ return 0; ++} ++ ++int print_brick_simple(struct super_block *sb, struct reiser4_vol_op_args *args) ++{ ++ reiser4_subvol *subv; ++ reiser4_volume *vol = super_volume(sb); ++ ++ spin_lock_reiser4_super(get_super_private(sb)); ++ ++ subv = vol->conf->mslots[0][0]; ++ strncpy(args->d.name, subv->name, REISER4_PATH_NAME_MAX + 1); ++ memcpy(args->u.brick.ext_id, subv->uuid, 16); ++ args->u.brick.int_id = subv->id; ++ args->u.brick.nr_replicas = subv->num_replicas; ++ args->u.brick.subv_flags = subv->flags; ++ args->u.brick.block_count = subv->block_count; ++ args->u.brick.data_capacity = subv->data_capacity; ++ args->u.brick.blocks_used = subv->blocks_used; ++ args->u.brick.system_blocks = subv->min_blocks_used; ++ args->u.brick.volinfo_addr = 0; ++ ++ spin_unlock_reiser4_super(get_super_private(sb)); ++ return 0; ++} ++ ++u64 find_brick_asym(const coord_t *coord) ++{ ++ reiser4_key key; ++ assert("edward-1957", coord != NULL); ++ ++ switch(item_id_by_coord(coord)) { ++ case NODE_POINTER_ID: ++ case EXTENT40_POINTER_ID: ++ return METADATA_SUBVOL_ID; ++ case EXTENT41_POINTER_ID: ++ return get_key_ordering(item_key_by_coord(coord, &key)); ++ default: ++ impossible("edward-2018", "Bad item ID"); ++ return METADATA_SUBVOL_ID; ++ } ++} ++ ++/** ++ * Convert ordered number @idx of brick in the logical volume ++ * to its internal id ++ */ ++static u32 brick_idx_to_id(reiser4_volume *vol, u32 idx) ++{ ++ u32 i, j; ++ /* ++ * return idx-th non-zero slot ++ */ ++ for (i = 0, j = 0; i < vol->conf->nr_mslots; i++) { ++ if (vol->conf->mslots[i]) { ++ if (j == idx) ++ return i; ++ else ++ j ++; ++ } ++ } ++ BUG_ON(1); ++} ++ ++int print_volume_asym(struct super_block *sb, struct reiser4_vol_op_args *args) ++{ ++ reiser4_volume *vol = super_volume(sb); ++ lv_conf *conf = vol->conf; ++ reiser4_volinfo *vinfo = &vol->volinfo[CUR_VOL_CONF]; ++ ++ args->u.vol.nr_bricks = vol_nr_origins(vol); ++ args->u.vol.bricks_in_dsa = num_dsa_subvols(vol); ++ memcpy(args->u.vol.id, vol->uuid, 16); ++ args->u.vol.vpid = vol->vol_plug->h.id; ++ args->u.vol.dpid = vol->dist_plug->h.id; ++ args->u.vol.stripe_bits = vol->stripe_bits; ++ args->u.vol.nr_sgs_bits = vol->num_sgs_bits; ++ args->u.vol.fs_flags = get_super_private(sb)->fs_flags; ++ args->u.vol.nr_mslots = conf->nr_mslots; ++ args->u.vol.nr_volinfo_blocks = vinfo->num_volmaps + vinfo->num_voltabs; ++ return 0; ++} ++ ++int print_brick_asym(struct super_block *sb, struct reiser4_vol_op_args *args) ++{ ++ int ret = 0; ++ u32 id; /* internal ID */ ++ u64 brick_idx; /* ordered number of the brick in the logical volume */ ++ ++ reiser4_volume *vol = super_volume(sb); ++ lv_conf *conf = vol->conf; ++ reiser4_subvol *subv; ++ ++ spin_lock_reiser4_super(get_super_private(sb)); ++ ++ brick_idx = args->s.brick_idx; ++ if (brick_idx >= vol_nr_origins(vol)) { ++ ret = -EINVAL; ++ goto out; ++ } ++ id = brick_idx_to_id(vol, brick_idx); ++ assert("edward-2446", conf->mslots[id] != NULL); ++ ++ subv = conf->mslots[id][0]; ++ strncpy(args->d.name, subv->name, REISER4_PATH_NAME_MAX + 1); ++ memcpy(args->u.brick.ext_id, subv->uuid, 16); ++ args->u.brick.int_id = subv->id; ++ args->u.brick.nr_replicas = subv->num_replicas; ++ args->u.brick.subv_flags = subv->flags; ++ args->u.brick.block_count = subv->block_count; ++ args->u.brick.data_capacity = subv->data_capacity; ++ args->u.brick.blocks_used = subv->blocks_used; ++ args->u.brick.system_blocks = subv->min_blocks_used; ++ args->u.brick.volinfo_addr = subv->volmap_loc[CUR_VOL_CONF]; ++ out: ++ spin_unlock_reiser4_super(get_super_private(sb)); ++ return ret; ++} ++ ++static int scale_volume_asym(struct super_block *sb, unsigned factor_bits) ++{ ++ int ret; ++ reiser4_volume *vol = super_volume(sb); ++ lv_conf *old_conf = vol->conf; ++ distribution_plugin *dist_plug = vol->dist_plug; ++ ++ ret = dist_plug->v.init(&vol->conf->tab, num_dsa_subvols(vol), ++ vol->num_sgs_bits, &vol->dcx); ++ if (ret) ++ return ret; ++ ret = dist_plug->v.spl(&vol->dcx, vol->conf->tab, factor_bits); ++ dist_plug->v.done(&vol->dcx); ++ if (ret) ++ return ret; ++ vol->num_sgs_bits += factor_bits; ++ ++ vol->new_conf = clone_lv_conf(vol->conf); ++ if (vol->new_conf == NULL) { ++ ret = RETERR(-ENOMEM); ++ goto error; ++ } ++ ret = make_volume_dconf(vol); ++ if (ret) ++ goto error; ++ ret = update_volume_dconf(vol); ++ if (ret) ++ goto error; ++ ++ dist_plug->r.replace(&vol->dcx, &vol->new_conf->tab); ++ ++ reiser4_volume_set_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ /* ++ * write unbalanced status to disk ++ */ ++ ret = force_commit_current_atom(); ++ if (ret) ++ goto error; ++ /* ++ * Now publish the new config ++ */ ++ rcu_assign_pointer(vol->conf, vol->new_conf); ++ synchronize_rcu(); ++ free_lv_conf(old_conf); ++ vol->new_conf = NULL; ++ return 0; ++ error: ++ /* ++ * the scale operation should be repeated in regular context ++ */ ++ vol->num_sgs_bits -= factor_bits; ++ free_lv_conf(vol->new_conf); ++ vol->new_conf = NULL; ++ return ret; ++} ++ ++struct reiser4_iterate_context { ++ reiser4_key curr; ++ reiser4_key next; ++}; ++ ++/** ++ * Check if @coord is an extent item. ++ * If yes, then store its key as "current" in the context ++ * and return 0 to terminate iteration ++ */ ++static int iter_find_start(reiser4_tree *tree, coord_t *coord, ++ lock_handle *lh, void *arg) ++{ ++ int ret; ++ struct reiser4_iterate_context *ictx = arg; ++ ++ assert("edward-2121", ictx != NULL); ++ ++ ret = zload(coord->node); ++ if (ret) ++ return ret; ++ ++ if (!item_is_extent(coord)) { ++ assert("edward-1878", item_is_internal(coord)); ++ /* continue iteration */ ++ zrelse(coord->node); ++ return 1; ++ } ++ item_key_by_coord(coord, &ictx->curr); ++ zrelse(coord->node); ++ return 0; ++} ++ ++/** ++ * Check if @coord is an extent item of file, which doesn't ++ * own "current" key in the iteration context. If so, then ++ * store its key as "next" in the context and return 0 to ++ * terminate iteration. ++ */ ++static int iter_find_next(reiser4_tree *tree, coord_t *coord, ++ lock_handle *lh, void *arg) ++{ ++ int ret; ++ struct reiser4_iterate_context *ictx = arg; ++ ++ assert("edward-1879", ictx != NULL); ++ ++ ret = zload(coord->node); ++ if (ret) ++ return ret; ++ if (!item_is_extent(coord)) { ++ assert("edward-1880", item_is_internal(coord)); ++ /* continue iteration */ ++ zrelse(coord->node); ++ return 1; ++ } ++ item_key_by_coord(coord, &ictx->next); ++ zrelse(coord->node); ++ ++ if (get_key_objectid(&ictx->next) == ++ get_key_objectid(&ictx->curr)) ++ /* ++ * found chunk of body of same file, ++ * continue iteration ++ */ ++ return 1; ++ return 0; ++} ++ ++/** ++ * Migrate all data blocks of a regular file in asymmetric logical volume ++ */ ++static int migrate_file_asym(struct inode *inode, u64 dst_idx) ++{ ++ reiser4_volume *vol = super_volume(inode->i_sb); ++ u64 dst_id; ++ ++ if (inode_file_plugin(inode)->migrate == NULL) ++ return 0; ++ if (dst_idx >= vol_nr_origins(vol)) ++ return RETERR(-EINVAL); ++ ++ dst_id = brick_idx_to_id(vol, dst_idx); ++ return inode_file_plugin(inode)->migrate(inode, &dst_id); ++} ++ ++ ++static inline int file_is_migratable(struct inode *inode, ++ struct super_block *sb, u32 flags) ++{ ++ if (inode_file_plugin(inode)->migrate == NULL) ++ return 0; ++ if (flags & VBF_MIGRATE_ALL) ++ return 1; ++ return !reiser4_inode_get_flag(inode, REISER4_FILE_IMMOBILE); ++} ++ ++int inode_clr_immobile(struct inode *inode); ++ ++/** ++ * Balance an asymmetric logical volume. See description of the method ++ * in plugin.h ++ * ++ * @super: super-block of the volume to be balanced; ++ * ++ * Implementation details: ++ * ++ * Walk from left to right along the twig level of the storage tree ++ * and for every found regular file's inode migrate its data blocks. ++ * ++ * Stat-data (on-disk inodes) are located on leaf level, nevertheless ++ * we scan twig level, recovering stat-data from extent items. Simply ++ * because scanning twig level is ~1000 times faster (thanks to Hans, ++ * who had insisted on EOTTL at the time). ++ * ++ * When scanning twig level we obviously miss empty files (i.e. files ++ * without bodies). It doesn't lead to any problems, as there is nothing ++ * to migrate for those files. ++ * ++ * FIXME: use hint/seal to not traverse tree every time when searching ++ * for a position by "current" key of the iteration context. ++ */ ++int balance_volume_asym(struct super_block *super, u32 flags) ++{ ++ int ret; ++ coord_t coord; ++ lock_handle lh; ++ reiser4_key start_key; ++ struct reiser4_iterate_context ictx; ++ time64_t start; ++ /* ++ * Set a start key (key of the leftmost object on the ++ * TWIG level) to scan from. ++ * FIXME: This is a hack. Implement find_start_key() to ++ * find the leftmost object on the TWIG level instead. ++ */ ++ reiser4_key_init(&start_key); ++ set_key_locality(&start_key, 41 /* FORMAT40_ROOT_LOCALITY */); ++ set_key_type(&start_key, KEY_SD_MINOR); ++ set_key_objectid(&start_key, 42 /* FORMAT40_ROOT_OBJECTID */); ++ ++ memset(&ictx, 0, sizeof(ictx)); ++ ++ assert("edward-1881", super != NULL); ++ ++ printk("reiser4 (%s): Started balancing...\n", super->s_id); ++ start = ktime_get_seconds(); ++ ++ init_lh(&lh); ++ /* ++ * Prepare start position: find leftmost item on the twig level. ++ * For meta-data brick of format40 such item always exists, even ++ * in the case of empty volume ++ */ ++ ret = coord_by_key(meta_subvol_tree(), &start_key, ++ &coord, &lh, ZNODE_READ_LOCK, ++ FIND_EXACT, TWIG_LEVEL, TWIG_LEVEL, ++ CBK_UNIQUE, NULL /* read-ahead info */); ++ if (IS_CBKERR(ret)) { ++ warning("edward-2154", "cbk error when balancing (%d)", ret); ++ done_lh(&lh); ++ goto error; ++ } ++ assert("edward-2160", coord.node->level == TWIG_LEVEL); ++ ++ coord.item_pos = 0; ++ coord.unit_pos = 0; ++ coord.between = AT_UNIT; ++ /* ++ * find leftmost extent on the twig level ++ */ ++ ret = reiser4_iterate_tree(meta_subvol_tree(), &coord, &lh, ++ iter_find_start, &ictx, ZNODE_READ_LOCK, 0); ++ done_lh(&lh); ++ if (ret < 0) { ++ if (ret == -ENOENT || ret == -E_NO_NEIGHBOR) ++ /* volume doesn't contain data blocks */ ++ goto done; ++ goto error; ++ } ++ while (1) { ++ int terminate = 0; ++ reiser4_key found; ++ reiser4_key sdkey; ++ struct inode *inode; ++ /* ++ * look for an object found in previous iteration ++ */ ++ ret = coord_by_key(meta_subvol_tree(), &ictx.curr, ++ &coord, &lh, ZNODE_READ_LOCK, ++ FIND_EXACT, ++ TWIG_LEVEL, TWIG_LEVEL, ++ CBK_UNIQUE, NULL /* read-ahead info */); ++ if (IS_CBKERR(ret)) { ++ done_lh(&lh); ++ warning("edward-1886", ++ "cbk error when balancing (%d)", ret); ++ goto error; ++ } ++ ret = zload(coord.node); ++ if (ret) { ++ done_lh(&lh); ++ goto error; ++ } ++ if (!coord_is_existing_item(&coord) || ++ !keyeq(item_key_by_coord(&coord, &found), &ictx.curr)) { ++ ++ zrelse(coord.node); ++ /* ++ * object found at previous iteration is absent ++ * (truncated by concurrent process), thus current ++ * position is an item with key <= @ictx.curr, ++ * that is, we found an object, which was already ++ * processed, so we just need to find next extent, ++ * reset &ictx.curr and proceed ++ */ ++ ret = reiser4_iterate_tree(meta_subvol_tree(), ++ &coord, &lh, ++ iter_find_start, &ictx, ++ ZNODE_READ_LOCK, 0); ++ if (ret < 0) { ++ done_lh(&lh); ++ if (ret == -ENOENT || ret == -E_NO_NEIGHBOR) ++ break; ++ goto error; ++ } ++ } else ++ zrelse(coord.node); ++ /* ++ * find leftmost extent of the next file and store ++ * its key as "next" in the iteration context as a ++ * hint for next iteration ++ */ ++ assert("edward-1887", ++ WITH_DATA(coord.node, coord_is_existing_item(&coord))); ++ ++ ret = reiser4_iterate_tree(meta_subvol_tree(), &coord, ++ &lh, iter_find_next, ++ &ictx, ZNODE_READ_LOCK, 0); ++ done_lh(&lh); ++ ++ if (ret == -ENOENT || ret == -E_NO_NEIGHBOR) ++ /* ++ * next extent not found ++ */ ++ terminate = 1; ++ else if (ret < 0) ++ goto error; ++ /* ++ * construct stat-data key from the "current" key of iteration ++ * context and read the inode. ++ * We don't know actual ordering component of stat-data key, ++ * so we set a maximal one to make sure that search procedure ++ * will find it correctly. Also stat-data we are looking for ++ * can be killed by concurrent unlink(). In this case a "bad ++ * inode" is created. ++ */ ++ sdkey = ictx.curr; ++ set_key_ordering(&sdkey, KEY_ORDERING_MASK /* max ordering */); ++ set_key_type(&sdkey, KEY_SD_MINOR); ++ set_key_offset(&sdkey, 0); ++ ++ inode = reiser4_iget(super, &sdkey, FIND_MAX_NOT_MORE_THAN, 0); ++ if (IS_ERR(inode)) ++ /* ++ * file was removed ++ */ ++ goto next; ++ if (file_is_migratable(inode, super, flags)) { ++ reiser4_iget_complete(inode); ++ /* ++ * migrate data blocks of this file ++ */ ++ ret = inode_file_plugin(inode)->migrate(inode, NULL); ++ if (ret) { ++ iput(inode); ++ warning("edward-1889", ++ "Inode %lli: data migration failed (%d)", ++ (unsigned long long)get_inode_oid(inode), ++ ret); ++ goto error; ++ } ++ if (flags & VBF_CLR_IMMOBILE) { ++ ret = inode_clr_immobile(inode); ++ if (ret) ++ warning("edward-2472", ++ "Inode %lli: failed to clear immobile status(%d)", ++ (unsigned long long)get_inode_oid(inode), ++ ret); ++ } ++ } ++ iput(inode); ++ next: ++ if (terminate) ++ break; ++ ictx.curr = ictx.next; ++ } ++ done: ++ printk("reiser4 (%s): Balancing completed in %lld seconds.\n", ++ super->s_id, ktime_get_seconds() - start); ++ return 0; ++ error: ++ warning("edward-2155", "%s: Balancing aborted (%d).", super->s_id, ret); ++ return ret == -E_DEADLOCK ? -EAGAIN : ret; ++} ++ ++volume_plugin volume_plugins[LAST_VOLUME_ID] = { ++ [SIMPLE_VOLUME_ID] = { ++ .h = { ++ .type_id = REISER4_VOLUME_PLUGIN_TYPE, ++ .id = SIMPLE_VOLUME_ID, ++ .pops = NULL, ++ .label = "simple", ++ .desc = "Simple Logical Volume", ++ .linkage = {NULL, NULL} ++ }, ++ .meta_subvol_id = meta_subvol_id_simple, ++ .calc_brick = calc_brick_simple, ++ .find_brick = find_brick_simple, ++ .load_volume = NULL, ++ .done_volume = NULL, ++ .init_volume = init_volume_simple, ++ .resize_brick = resize_brick_simple, ++ .add_brick = add_brick_simple, ++ .remove_brick = remove_brick_simple, ++ .remove_brick_tail = NULL, ++ .print_brick = print_brick_simple, ++ .print_volume = print_volume_simple, ++ .balance_volume = balance_volume_simple, ++ .bucket_ops = { ++ .cap_at = NULL, ++ .apx_of = NULL, ++ .apx_at = NULL, ++ .apx_set_at = NULL, ++ .apx_lenp_at = NULL ++ } ++ }, ++ [ASYM_VOLUME_ID] = { ++ .h = { ++ .type_id = REISER4_VOLUME_PLUGIN_TYPE, ++ .id = ASYM_VOLUME_ID, ++ .pops = NULL, ++ .label = "asym", ++ .desc = "Asymmetric Heterogeneous Logical Volume", ++ .linkage = {NULL, NULL} ++ }, ++ .meta_subvol_id = meta_subvol_id_simple, ++ .calc_brick = calc_brick_asym, ++ .find_brick = find_brick_asym, ++ .load_volume = load_volume_asym, ++ .done_volume = done_volume_asym, ++ .init_volume = init_volume_asym, ++ .resize_brick = resize_brick_asym, ++ .add_brick = add_brick_asym, ++ .remove_brick = remove_brick_asym, ++ .remove_brick_tail = remove_brick_tail_asym, ++ .print_brick = print_brick_asym, ++ .print_volume = print_volume_asym, ++ .scale_volume = scale_volume_asym, ++ .migrate_file = migrate_file_asym, ++ .balance_volume = balance_volume_asym, ++ .bucket_ops = { ++ .cap_at = cap_at_asym, ++ .apx_of = apx_of_asym, ++ .apx_at = apx_at_asym, ++ .apx_set_at = apx_set_at_asym, ++ .apx_lenp_at = apx_lenp_at_asym, ++ .idx2id = idx2id, ++ .id2idx = id2idx, ++ .create_buckets = create_buckets, ++ .free_buckets = free_buckets, ++ .insert_bucket = insert_bucket, ++ .remove_bucket = remove_bucket, ++ .space_occupied = space_occupied ++ } ++ } ++}; ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/plugin/volume/volume.h linux-5.10.2/fs/reiser4/plugin/volume/volume.h +--- linux-5.10.2.orig/fs/reiser4/plugin/volume/volume.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/plugin/volume/volume.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,147 @@ ++/* ++ Copyright (c) 2014-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#ifndef VOLUME_H ++#define VOLUME_H ++ ++#define INVALID_SUBVOL_ID (0xffffffff) ++#define METADATA_SUBVOL_ID (0) ++ ++extern void deactivate_subvol(struct super_block *super, reiser4_subvol *subv); ++extern reiser4_subvol *find_meta_brick_by_id(reiser4_volume *vol); ++extern lv_conf *alloc_lv_conf(u32 nr_slots); ++extern void free_lv_conf(lv_conf *conf); ++extern void release_volinfo_nodes(reiser4_volinfo *vinfo, int dealloc); ++extern slot_t alloc_mslot(u32 nr_mirrors); ++extern void free_mslot(slot_t slot); ++extern void free_mslot_at(lv_conf *conf, u64 idx); ++extern int brick_belongs_volume(reiser4_volume *vol, reiser4_subvol *subv); ++extern int remove_brick_tail_asym(reiser4_volume *vol, reiser4_subvol *subv); ++extern reiser4_block_nr estimate_migration_iter(void); ++ ++static inline int is_meta_brick_id(u64 id) ++{ ++ return id == METADATA_SUBVOL_ID; ++} ++ ++static inline int is_meta_brick(reiser4_subvol *this) ++{ ++ assert("edward-2189", subvol_is_set(this, SUBVOL_ACTIVATED)); ++ assert("edward-2071", ergo(is_meta_brick_id(this->id), ++ this == get_meta_subvol())); ++ return is_meta_brick_id(this->id); ++} ++ ++static inline u64 get_pos_in_dsa(reiser4_subvol *subv) ++{ ++ return subv->dsa_idx; ++} ++ ++static inline int is_proxy_brick(reiser4_subvol *subv) ++{ ++ return subvol_is_set(subv, SUBVOL_IS_PROXY); ++} ++ ++/* ++ * Returns true, if @subv participates in regular data distribution ++ */ ++static inline int is_dsa_brick(reiser4_subvol *subv) ++{ ++ assert("edward-2475", ++ ergo(is_proxy_brick(subv), ++ !subvol_is_set(subv, SUBVOL_HAS_DATA_ROOM))); ++ assert("edward-2476", ++ ergo(subvol_is_set(subv, SUBVOL_HAS_DATA_ROOM), ++ !is_proxy_brick(subv))); ++ ++ return subvol_is_set(subv, SUBVOL_HAS_DATA_ROOM); ++} ++ ++/* ++ * Returns true, if meta-data subvolume participates in regular ++ * data distribution. Otherwise, returns false ++ */ ++static inline int meta_brick_belongs_dsa(void) ++{ ++ return is_dsa_brick(get_meta_subvol()); ++} ++ ++/** ++ * Without scanning all bricks i the volume, calculate and return number ++ * of bricks participating in regular data distribution ++ * ++ * Possible cases: ++ * ++ * 1 xxxxxxxxxx nr_origins ++ * ++ * 2 oxxxxxxxxx nr_origins - 1 ++ * ++ * 3 xxxxxxxxxx nr_origins - 1 ++ * ^ ++ * 4 oxxxxxxxxx nr_origins - 1 ++ * ^ ++ * 5 xxxxxxxxxx nr_origins - 1 ++ * ^ ++ * 6 oxxxxxxxxx nr_origins - 2 ++ * ^ ++ * ++ * Legend: ++ * ++ * o: meta-brick w/o data room ++ * x: data brick, or meta-brick w/ data room ++ * ^: proxy brick ++ */ ++static inline u64 num_dsa_subvols(reiser4_volume *vol) ++{ ++ if (!reiser4_is_set(reiser4_get_current_sb(), REISER4_PROXY_ENABLED)) ++ /* 1, 2 */ ++ return meta_brick_belongs_dsa() ? ++ vol_nr_origins(vol) : vol_nr_origins(vol) - 1; ++ ++ if (subvol_is_set(get_meta_subvol(), SUBVOL_IS_PROXY)) ++ /* 3, 4 */ ++ return vol_nr_origins(vol) - 1; ++ /* 5, 6 */ ++ return meta_brick_belongs_dsa() ? ++ vol_nr_origins(vol) - 1 : vol_nr_origins(vol) - 2; ++} ++ ++static inline reiser4_subvol *subvol_by_key(const reiser4_key *key) ++{ ++ return current_origin(get_key_ordering(key)); ++} ++ ++static inline int reserve_migration_iter(void) ++{ ++ grab_space_enable(); ++ return reiser4_grab_reserved(reiser4_get_current_sb(), ++ estimate_migration_iter(), ++ BA_CAN_COMMIT, ++ get_meta_subvol()); ++} ++ ++static inline reiser4_subvol *get_proxy_subvol(void) ++{ ++ assert("edward-2441", current_volume()->proxy != NULL); ++ ++ return current_volume()->proxy; ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ ++ ++#endif /* VOLUME_H */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/pool.c linux-5.10.2/fs/reiser4/pool.c +--- linux-5.10.2.orig/fs/reiser4/pool.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/pool.c 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,231 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Fast pool allocation. ++ ++ There are situations when some sub-system normally asks memory allocator ++ for only few objects, but under some circumstances could require much ++ more. Typical and actually motivating example is tree balancing. It needs ++ to keep track of nodes that were involved into it, and it is well-known ++ that in reasonable packed balanced tree most (92.938121%) percent of all ++ balancings end up after working with only few nodes (3.141592 on ++ average). But in rare cases balancing can involve much more nodes ++ (3*tree_height+1 in extremal situation). ++ ++ On the one hand, we don't want to resort to dynamic allocation (slab, ++ malloc(), etc.) to allocate data structures required to keep track of ++ nodes during balancing. On the other hand, we cannot statically allocate ++ required amount of space on the stack, because first: it is useless wastage ++ of precious resource, and second: this amount is unknown in advance (tree ++ height can change). ++ ++ Pools, implemented in this file are solution for this problem: ++ ++ - some configurable amount of objects is statically preallocated on the ++ stack ++ ++ - if this preallocated pool is exhausted and more objects is requested ++ they are allocated dynamically. ++ ++ Pools encapsulate distinction between statically and dynamically allocated ++ objects. Both allocation and recycling look exactly the same. ++ ++ To keep track of dynamically allocated objects, pool adds its own linkage ++ to each object. ++ ++ NOTE-NIKITA This linkage also contains some balancing-specific data. This ++ is not perfect. On the other hand, balancing is currently the only client ++ of pool code. ++ ++ NOTE-NIKITA Another desirable feature is to rewrite all pool manipulation ++ functions in the style of tslist/tshash, i.e., make them unreadable, but ++ type-safe. ++ ++*/ ++ ++#include "debug.h" ++#include "pool.h" ++#include "super.h" ++ ++#include ++#include ++ ++/* initialize new pool object @h */ ++static void reiser4_init_pool_obj(struct reiser4_pool_header *h) ++{ ++ INIT_LIST_HEAD(&h->usage_linkage); ++ INIT_LIST_HEAD(&h->level_linkage); ++ INIT_LIST_HEAD(&h->extra_linkage); ++} ++ ++/* initialize new pool */ ++void reiser4_init_pool(struct reiser4_pool *pool /* pool to initialize */ , ++ size_t obj_size /* size of objects in @pool */ , ++ int num_of_objs /* number of preallocated objects */ , ++ char *data/* area for preallocated objects */) ++{ ++ struct reiser4_pool_header *h; ++ int i; ++ ++ assert("nikita-955", pool != NULL); ++ assert("nikita-1044", obj_size > 0); ++ assert("nikita-956", num_of_objs >= 0); ++ assert("nikita-957", data != NULL); ++ ++ memset(pool, 0, sizeof *pool); ++ pool->obj_size = obj_size; ++ pool->data = data; ++ INIT_LIST_HEAD(&pool->free); ++ INIT_LIST_HEAD(&pool->used); ++ INIT_LIST_HEAD(&pool->extra); ++ memset(data, 0, obj_size * num_of_objs); ++ for (i = 0; i < num_of_objs; ++i) { ++ h = (struct reiser4_pool_header *) (data + i * obj_size); ++ reiser4_init_pool_obj(h); ++ /* add pool header to the end of pool's free list */ ++ list_add_tail(&h->usage_linkage, &pool->free); ++ } ++} ++ ++/* release pool resources ++ ++ Release all resources acquired by this pool, specifically, dynamically ++ allocated objects. ++ ++*/ ++void reiser4_done_pool(struct reiser4_pool *pool UNUSED_ARG) ++{ ++} ++ ++/* allocate carry object from @pool ++ ++ First, try to get preallocated object. If this fails, resort to dynamic ++ allocation. ++ ++*/ ++static void *reiser4_pool_alloc(struct reiser4_pool *pool) ++{ ++ struct reiser4_pool_header *result; ++ ++ assert("nikita-959", pool != NULL); ++ ++ if (!list_empty(&pool->free)) { ++ struct list_head *linkage; ++ ++ linkage = pool->free.next; ++ list_del(linkage); ++ INIT_LIST_HEAD(linkage); ++ result = list_entry(linkage, struct reiser4_pool_header, ++ usage_linkage); ++ BUG_ON(!list_empty(&result->level_linkage) || ++ !list_empty(&result->extra_linkage)); ++ } else { ++ /* pool is empty. Extra allocations don't deserve dedicated ++ slab to be served from, as they are expected to be rare. */ ++ result = kmalloc(pool->obj_size, reiser4_ctx_gfp_mask_get()); ++ if (result != 0) { ++ reiser4_init_pool_obj(result); ++ list_add(&result->extra_linkage, &pool->extra); ++ } else ++ return ERR_PTR(RETERR(-ENOMEM)); ++ BUG_ON(!list_empty(&result->usage_linkage) || ++ !list_empty(&result->level_linkage)); ++ } ++ ++pool->objs; ++ list_add(&result->usage_linkage, &pool->used); ++ memset(result + 1, 0, pool->obj_size - sizeof *result); ++ return result; ++} ++ ++/* return object back to the pool */ ++void reiser4_pool_free(struct reiser4_pool *pool, ++ struct reiser4_pool_header *h) ++{ ++ assert("nikita-961", h != NULL); ++ assert("nikita-962", pool != NULL); ++ ++ --pool->objs; ++ assert("nikita-963", pool->objs >= 0); ++ ++ list_del_init(&h->usage_linkage); ++ list_del_init(&h->level_linkage); ++ ++ if (list_empty(&h->extra_linkage)) ++ /* ++ * pool header is not an extra one. Push it onto free list ++ * using usage_linkage ++ */ ++ list_add(&h->usage_linkage, &pool->free); ++ else { ++ /* remove pool header from pool's extra list and kfree it */ ++ list_del(&h->extra_linkage); ++ kfree(h); ++ } ++} ++ ++/* add new object to the carry level list ++ ++ Carry level is FIFO most of the time, but not always. Complications arise ++ when make_space() function tries to go to the left neighbor and thus adds ++ carry node before existing nodes, and also, when updating delimiting keys ++ after moving data between two nodes, we want left node to be locked before ++ right node. ++ ++ Latter case is confusing at the first glance. Problem is that COP_UPDATE ++ opration that updates delimiting keys is sometimes called with two nodes ++ (when data are moved between two nodes) and sometimes with only one node ++ (when leftmost item is deleted in a node). In any case operation is ++ supplied with at least node whose left delimiting key is to be updated ++ (that is "right" node). ++ ++ @pool - from which to allocate new object; ++ @list - where to add object; ++ @reference - after (or before) which existing object to add ++*/ ++struct reiser4_pool_header *reiser4_add_obj(struct reiser4_pool *pool, ++ struct list_head *list, ++ pool_ordering order, ++ struct reiser4_pool_header *reference) ++{ ++ struct reiser4_pool_header *result; ++ ++ assert("nikita-972", pool != NULL); ++ ++ result = reiser4_pool_alloc(pool); ++ if (IS_ERR(result)) ++ return result; ++ ++ assert("nikita-973", result != NULL); ++ ++ switch (order) { ++ case POOLO_BEFORE: ++ __list_add(&result->level_linkage, ++ reference->level_linkage.prev, ++ &reference->level_linkage); ++ break; ++ case POOLO_AFTER: ++ __list_add(&result->level_linkage, ++ &reference->level_linkage, ++ reference->level_linkage.next); ++ break; ++ case POOLO_LAST: ++ list_add_tail(&result->level_linkage, list); ++ break; ++ case POOLO_FIRST: ++ list_add(&result->level_linkage, list); ++ break; ++ default: ++ wrong_return_value("nikita-927", "order"); ++ } ++ return result; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/pool.h linux-5.10.2/fs/reiser4/pool.h +--- linux-5.10.2.orig/fs/reiser4/pool.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/pool.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,57 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Fast pool allocation */ ++ ++#ifndef __REISER4_POOL_H__ ++#define __REISER4_POOL_H__ ++ ++#include ++ ++struct reiser4_pool { ++ size_t obj_size; ++ int objs; ++ char *data; ++ struct list_head free; ++ struct list_head used; ++ struct list_head extra; ++}; ++ ++struct reiser4_pool_header { ++ /* object is either on free or "used" lists */ ++ struct list_head usage_linkage; ++ struct list_head level_linkage; ++ struct list_head extra_linkage; ++}; ++ ++typedef enum { ++ POOLO_BEFORE, ++ POOLO_AFTER, ++ POOLO_LAST, ++ POOLO_FIRST ++} pool_ordering; ++ ++/* pool manipulation functions */ ++ ++extern void reiser4_init_pool(struct reiser4_pool *pool, size_t obj_size, ++ int num_of_objs, char *data); ++extern void reiser4_done_pool(struct reiser4_pool *pool); ++extern void reiser4_pool_free(struct reiser4_pool *pool, ++ struct reiser4_pool_header *h); ++struct reiser4_pool_header *reiser4_add_obj(struct reiser4_pool *pool, ++ struct list_head *list, ++ pool_ordering order, ++ struct reiser4_pool_header *reference); ++ ++/* __REISER4_POOL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/readahead.c linux-5.10.2/fs/reiser4/readahead.c +--- linux-5.10.2.orig/fs/reiser4/readahead.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/readahead.c 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,140 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "forward.h" ++#include "tree.h" ++#include "tree_walk.h" ++#include "super.h" ++#include "inode.h" ++#include "key.h" ++#include "znode.h" ++ ++#include /* for totalram_pages */ ++ ++void reiser4_init_ra_info(ra_info_t *rai) ++{ ++ rai->key_to_stop = *reiser4_min_key(); ++} ++ ++/* global formatted node readahead parameter. It can be set by mount option ++ * -o readahead:NUM:1 */ ++static inline int ra_adjacent_only(int flags) ++{ ++ return flags & RA_ADJACENT_ONLY; ++} ++ ++/* this is used by formatted_readahead to decide whether read for right neighbor ++ * of node is to be issued. It returns 1 if right neighbor's first key is less ++ * or equal to readahead's stop key */ ++static int should_readahead_neighbor(znode * node, ra_info_t *info) ++{ ++ int result; ++ ++ read_lock_dk(znode_get_tree(node)); ++ result = keyle(znode_get_rd_key(node), &info->key_to_stop); ++ read_unlock_dk(znode_get_tree(node)); ++ return result; ++} ++ ++#define LOW_MEM_PERCENTAGE (5) ++ ++static int low_on_memory(void) ++{ ++ unsigned int freepages; ++ ++ freepages = nr_free_pages(); ++ return freepages < (totalram_pages() * LOW_MEM_PERCENTAGE / 100); ++} ++ ++/* start read for @node and for a few of its right neighbors */ ++void formatted_readahead(znode * node, ra_info_t *info) ++{ ++ struct formatted_ra_params *ra_params; ++ znode *cur; ++ int i; ++ int grn_flags; ++ lock_handle next_lh; ++ ++ /* do nothing if node block number has not been assigned to node (which ++ * means it is still in cache). */ ++ if (reiser4_blocknr_is_fake(znode_get_block(node))) ++ return; ++ ++ ra_params = get_current_super_ra_params(); ++ ++ if (znode_page(node) == NULL) ++ jstartio(ZJNODE(node)); ++ ++ if (znode_get_level(node) != LEAF_LEVEL) ++ return; ++ ++ /* don't waste memory for read-ahead when low on memory */ ++ if (low_on_memory()) ++ return; ++ ++ /* We can have locked nodes on upper tree levels, in this situation lock ++ priorities do not help to resolve deadlocks, we have to use TRY_LOCK ++ here. */ ++ grn_flags = (GN_CAN_USE_UPPER_LEVELS | GN_TRY_LOCK); ++ ++ i = 0; ++ cur = zref(node); ++ init_lh(&next_lh); ++ while (i < ra_params->max) { ++ const reiser4_block_nr * nextblk; ++ ++ if (!should_readahead_neighbor(cur, info)) ++ break; ++ ++ if (reiser4_get_right_neighbor ++ (&next_lh, cur, ZNODE_READ_LOCK, grn_flags)) ++ break; ++ ++ nextblk = znode_get_block(next_lh.node); ++ if (reiser4_blocknr_is_fake(nextblk) || ++ (ra_adjacent_only(ra_params->flags) ++ && *nextblk != *znode_get_block(cur) + 1)) ++ break; ++ ++ zput(cur); ++ cur = zref(next_lh.node); ++ done_lh(&next_lh); ++ if (znode_page(cur) == NULL) ++ jstartio(ZJNODE(cur)); ++ else ++ /* Do not scan read-ahead window if pages already ++ * allocated (and i/o already started). */ ++ break; ++ ++ i++; ++ } ++ zput(cur); ++ done_lh(&next_lh); ++} ++ ++void reiser4_readdir_readahead_init(struct inode *dir, tap_t *tap) ++{ ++ reiser4_key *stop_key; ++ ++ assert("nikita-3542", dir != NULL); ++ assert("nikita-3543", tap != NULL); ++ ++ stop_key = &tap->ra_info.key_to_stop; ++ /* initialize readdir readahead information: include into readahead ++ * stat data of all files of the directory */ ++ set_key_locality(stop_key, get_inode_oid(dir)); ++ set_key_type(stop_key, KEY_SD_MINOR); ++ set_key_ordering(stop_key, get_key_ordering(reiser4_max_key())); ++ set_key_objectid(stop_key, get_key_objectid(reiser4_max_key())); ++ set_key_offset(stop_key, get_key_offset(reiser4_max_key())); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/readahead.h linux-5.10.2/fs/reiser4/readahead.h +--- linux-5.10.2.orig/fs/reiser4/readahead.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/readahead.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,42 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#ifndef __READAHEAD_H__ ++#define __READAHEAD_H__ ++ ++#include "key.h" ++ ++typedef enum { ++ RA_ADJACENT_ONLY = 1, /* only requests nodes which are adjacent. ++ Default is NO (not only adjacent) */ ++} ra_global_flags; ++ ++/* reiser4 super block has a field of this type. ++ It controls readahead during tree traversals */ ++struct formatted_ra_params { ++ unsigned long max; /* request not more than this amount of nodes. ++ Default is totalram_pages() / 4 */ ++ int flags; ++}; ++ ++typedef struct { ++ reiser4_key key_to_stop; ++} ra_info_t; ++ ++void formatted_readahead(znode * , ra_info_t *); ++void reiser4_init_ra_info(ra_info_t *rai); ++ ++extern void reiser4_readdir_readahead_init(struct inode *dir, tap_t *tap); ++ ++/* __READAHEAD_H__ */ ++#endif ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/README linux-5.10.2/fs/reiser4/README +--- linux-5.10.2.orig/fs/reiser4/README 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/README 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,128 @@ ++[LICENSING] ++ ++Reiser4 is hereby licensed under the GNU General ++Public License version 2. ++ ++Source code files that contain the phrase "licensing governed by ++reiser4/README" are "governed files" throughout this file. Governed ++files are licensed under the GPL. The portions of them owned by Hans ++Reiser, or authorized to be licensed by him, have been in the past, ++and likely will be in the future, licensed to other parties under ++other licenses. If you add your code to governed files, and don't ++want it to be owned by Hans Reiser, put your copyright label on that ++code so the poor blight and his customers can keep things straight. ++All portions of governed files not labeled otherwise are owned by Hans ++Reiser, and by adding your code to it, widely distributing it to ++others or sending us a patch, and leaving the sentence in stating that ++licensing is governed by the statement in this file, you accept this. ++It will be a kindness if you identify whether Hans Reiser is allowed ++to license code labeled as owned by you on your behalf other than ++under the GPL, because he wants to know if it is okay to do so and put ++a check in the mail to you (for non-trivial improvements) when he ++makes his next sale. He makes no guarantees as to the amount if any, ++though he feels motivated to motivate contributors, and you can surely ++discuss this with him before or after contributing. You have the ++right to decline to allow him to license your code contribution other ++than under the GPL. ++ ++Further licensing options are available for commercial and/or other ++interests directly from Hans Reiser: reiser@namesys.com. If you interpret ++the GPL as not allowing those additional licensing options, you read ++it wrongly, and Richard Stallman agrees with me, when carefully read ++you can see that those restrictions on additional terms do not apply ++to the owner of the copyright, and my interpretation of this shall ++govern for this license. ++ ++[END LICENSING] ++ ++Reiser4 is a file system based on dancing tree algorithms, and is ++described at http://www.namesys.com ++ ++mkfs.reiser4 and other utilities are on our webpage or wherever your ++Linux provider put them. You really want to be running the latest ++version off the website if you use fsck. ++ ++Yes, if you update your reiser4 kernel module you do have to ++recompile your kernel, most of the time. The errors you get will be ++quite cryptic if your forget to do so. ++ ++Hideous Commercial Pitch: Spread your development costs across other OS ++vendors. Select from the best in the world, not the best in your ++building, by buying from third party OS component suppliers. Leverage ++the software component development power of the internet. Be the most ++aggressive in taking advantage of the commercial possibilities of ++decentralized internet development, and add value through your branded ++integration that you sell as an operating system. Let your competitors ++be the ones to compete against the entire internet by themselves. Be ++hip, get with the new economic trend, before your competitors do. Send ++email to reiser@namesys.com ++ ++Hans Reiser was the primary architect of Reiser4, but a whole team ++chipped their ideas in. He invested everything he had into Namesys ++for 5.5 dark years of no money before Reiser3 finally started to work well ++enough to bring in money. He owns the copyright. ++ ++DARPA was the primary sponsor of Reiser4. DARPA does not endorse ++Reiser4, it merely sponsors it. DARPA is, in solely Hans's personal ++opinion, unique in its willingness to invest into things more ++theoretical than the VC community can readily understand, and more ++longterm than allows them to be sure that they will be the ones to ++extract the economic benefits from. DARPA also integrated us into a ++security community that transformed our security worldview. ++ ++Vladimir Saveliev is our lead programmer, with us from the beginning, ++and he worked long hours writing the cleanest code. This is why he is ++now the lead programmer after years of commitment to our work. He ++always made the effort to be the best he could be, and to make his ++code the best that it could be. What resulted was quite remarkable. I ++don't think that money can ever motivate someone to work the way he ++did, he is one of the most selfless men I know. ++ ++Alexander Lyamin was our sysadmin, and helped to educate us in ++security issues. Moscow State University and IMT were very generous ++in the internet access they provided us, and in lots of other little ++ways that a generous institution can be. ++ ++Alexander Zarochentcev (sometimes known as zam, or sasha), wrote the ++locking code, the block allocator, and finished the flushing code. ++His code is always crystal clean and well structured. ++ ++Nikita Danilov wrote the core of the balancing code, the core of the ++plugins code, and the directory code. He worked a steady pace of long ++hours that produced a whole lot of well abstracted code. He is our ++senior computer scientist. ++ ++Vladimir Demidov wrote the parser. Writing an in kernel parser is ++something very few persons have the skills for, and it is thanks to ++him that we can say that the parser is really not so big compared to ++various bits of our other code, and making a parser work in the kernel ++was not so complicated as everyone would imagine mainly because it was ++him doing it... ++ ++Joshua McDonald wrote the transaction manager, and the flush code. ++The flush code unexpectedly turned out be extremely hairy for reasons ++you can read about on our web page, and he did a great job on an ++extremely difficult task. ++ ++Nina Reiser handled our accounting, government relations, and much ++more. ++ ++Ramon Reiser developed our website. ++ ++Beverly Palmer drew our graphics. ++ ++Vitaly Fertman developed librepair, userspace plugins repair code, fsck ++and worked with Umka on developing libreiser4 and userspace plugins. ++ ++Yury Umanets (aka Umka) developed libreiser4, userspace plugins and ++userspace tools (reiser4progs). ++ ++Oleg Drokin (aka Green) is the release manager who fixes everything. ++It is so nice to have someone like that on the team. He (plus Chris ++and Jeff) make it possible for the entire rest of the Namesys team to ++focus on Reiser4, and he fixed a whole lot of Reiser4 bugs also. It ++is just amazing to watch his talent for spotting bugs in action. ++ ++Edward Shishkin wrote cryptcompress file plugin (which manages files ++built of encrypted and(or) compressed bodies) and other plugins related ++to transparent encryption and compression support. +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/reiser4.h linux-5.10.2/fs/reiser4/reiser4.h +--- linux-5.10.2.orig/fs/reiser4/reiser4.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/reiser4.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,274 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++ ++/* definitions of common constants used by reiser4 */ ++ ++#if !defined( __REISER4_H__ ) ++#define __REISER4_H__ ++ ++#include /* for HZ */ ++#include ++#include ++#include ++#include ++#include ++ ++/* ++ * reiser4 compilation options. ++ */ ++ ++#if defined(CONFIG_REISER4_DEBUG) ++/* turn on assertion checks */ ++#define REISER4_DEBUG (1) ++#else ++#define REISER4_DEBUG (0) ++#endif ++ ++#define REISER4_SHA256 (0) ++ ++#define REISER4_VERSION_PRINCIPAL (5) ++ ++/* ++ * Turn on large keys mode. In his mode (which is default), reiser4 key has 4 ++ * 8-byte components. In the old "small key" mode, it's 3 8-byte ++ * components. Additional component, referred to as "ordering" is used to ++ * order items from which given object is composed of. As such, ordering is ++ * placed between locality and objectid. For directory item ordering contains ++ * initial prefix of the file name this item is for. This sorts all directory ++ * items within given directory lexicographically (but see ++ * fibration.[ch]). For file body and stat-data, ordering contains initial ++ * prefix of the name file was initially created with. In the common case ++ * (files with single name) this allows to order file bodies and stat-datas in ++ * the same order as their respective directory entries, thus speeding up ++ * readdir. ++ * ++ * Note, that kernel can only mount file system with the same key size as one ++ * it is compiled for, so flipping this option may render your data ++ * inaccessible. ++ */ ++#define REISER4_LARGE_KEY (1) ++/*#define REISER4_LARGE_KEY (0)*/ ++ ++/*#define GUESS_EXISTS 1*/ ++ ++/* ++ * PLEASE update fs/reiser4/kattr.c:show_options() when adding new compilation ++ * option ++ */ ++ ++#define REISER4_SUPER_MAGIC_STRING "ReIsEr4" ++extern const int REISER4_MAGIC_OFFSET; /* offset to magic string from the ++ * beginning of device */ ++ ++/* here go tunable parameters that are not worth special entry in kernel ++ configuration */ ++ ++/* default number of slots in coord-by-key caches */ ++#define CBK_CACHE_SLOTS (16) ++/* how many elementary tree operation to carry on the next level */ ++#define CARRIES_POOL_SIZE (5) ++/* size of pool of preallocated nodes for carry process. */ ++#define NODES_LOCKED_POOL_SIZE (5) ++ ++#define REISER4_NEW_NODE_FLAGS (COPI_LOAD_LEFT | COPI_LOAD_RIGHT | COPI_GO_LEFT) ++#define REISER4_NEW_EXTENT_FLAGS (COPI_LOAD_LEFT | COPI_LOAD_RIGHT | COPI_GO_LEFT) ++#define REISER4_PASTE_FLAGS (COPI_GO_LEFT) ++#define REISER4_INSERT_FLAGS (COPI_GO_LEFT) ++ ++/* we are supporting reservation of disk space on uid basis */ ++#define REISER4_SUPPORT_UID_SPACE_RESERVATION (0) ++/* we are supporting reservation of disk space for groups */ ++#define REISER4_SUPPORT_GID_SPACE_RESERVATION (0) ++/* we are supporting reservation of disk space for root */ ++#define REISER4_SUPPORT_ROOT_SPACE_RESERVATION (0) ++/* we use rapid flush mode, see flush.c for comments. */ ++#define REISER4_USE_RAPID_FLUSH (1) ++ ++/* ++ * set this to 0 if you don't want to use wait-for-flush in ->writepage(). ++ */ ++#define REISER4_USE_ENTD (1) ++ ++#if defined(CONFIG_REISER4_OLD) ++/* key allocation is Plan-A */ ++#define REISER4_PLANA_KEY_ALLOCATION (1) ++#define REISER4_PLANB_KEY_ALLOCATION (0) ++#else ++/* key allocation is Plan-B */ ++#define REISER4_PLANA_KEY_ALLOCATION (0) ++#define REISER4_PLANB_KEY_ALLOCATION (1) ++#endif ++ ++/* key allocation follows good old 3.x scheme */ ++#define REISER4_3_5_KEY_ALLOCATION (0) ++ ++/* size of hash-table for znodes */ ++#define REISER4_ZNODE_HASH_TABLE_SIZE (1 << 13) ++ ++/* number of buckets in lnode hash-table */ ++#define LNODE_HTABLE_BUCKETS (1024) ++ ++/* some ridiculously high maximal limit on height of znode tree. This ++ is used in declaration of various per level arrays and ++ to allocate stattistics gathering array for per-level stats. */ ++#define REISER4_MAX_ZTREE_HEIGHT (8) ++ ++#define REISER4_PANIC_MSG_BUFFER_SIZE (1024) ++ ++/* If array contains less than REISER4_SEQ_SEARCH_BREAK elements then, ++ sequential search is on average faster than binary. This is because ++ of better optimization and because sequential search is more CPU ++ cache friendly. This number (25) was found by experiments on dual AMD ++ Athlon(tm), 1400MHz. ++ ++ NOTE: testing in kernel has shown that binary search is more effective than ++ implied by results of the user level benchmarking. Probably because in the ++ node keys are separated by other data. So value was adjusted after few ++ tests. More thorough tuning is needed. ++*/ ++#define REISER4_SEQ_SEARCH_BREAK (3) ++static_assert(REISER4_SEQ_SEARCH_BREAK > 2); ++ ++/* don't allow tree to be lower than this */ ++#define REISER4_MIN_TREE_HEIGHT (TWIG_LEVEL) ++ ++/* NOTE NIKITA this is no longer used: maximal atom size is auto-adjusted to ++ * available memory. */ ++/* Default value of maximal atom size. Can be ovewritten by ++ tmgr.atom_max_size mount option. By default infinity. */ ++#define REISER4_ATOM_MAX_SIZE ((unsigned)(~0)) ++ ++/* Default value of maximal atom age (in jiffies). After reaching this age ++ atom will be forced to commit, either synchronously or asynchronously. Can ++ be overwritten by tmgr.atom_max_age mount option. */ ++#define REISER4_ATOM_MAX_AGE (600 * HZ) ++ ++/* sleeping period for ktxnmrgd */ ++#define REISER4_TXNMGR_TIMEOUT (5 * HZ) ++ ++/* timeout to wait for ent thread in writepage. Default: 3 milliseconds. */ ++#define REISER4_ENTD_TIMEOUT (3 * HZ / 1000) ++ ++/* start complaining after that many restarts in coord_by_key(). ++ ++ This either means incredibly heavy contention for this part of a tree, or ++ some corruption or bug. ++*/ ++#define REISER4_CBK_ITERATIONS_LIMIT (100) ++ ++/* return -EIO after that many iterations in coord_by_key(). ++ ++ I have witnessed more than 800 iterations (in 30 thread test) before cbk ++ finished. --nikita ++*/ ++#define REISER4_MAX_CBK_ITERATIONS 500000 ++ ++/* put a per-inode limit on maximal number of directory entries with identical ++ keys in hashed directory. ++ ++ Disable this until inheritance interfaces stabilize: we need some way to ++ set per directory limit. ++*/ ++#define REISER4_USE_COLLISION_LIMIT (0) ++ ++/* If flush finds more than FLUSH_RELOCATE_THRESHOLD adjacent dirty leaf-level ++ blocks it will force them to be relocated. */ ++#define FLUSH_RELOCATE_THRESHOLD 64 ++/* If flush finds can find a block allocation closer than at most ++ FLUSH_RELOCATE_DISTANCE from the preceder it will relocate to that position. ++ */ ++#define FLUSH_RELOCATE_DISTANCE 64 ++ ++/* If we have written this much or more blocks before encountering busy jnode ++ in flush list - abort flushing hoping that next time we get called ++ this jnode will be clean already, and we will save some seeks. */ ++#define FLUSH_WRITTEN_THRESHOLD 50 ++ ++/* The maximum number of nodes to scan left on a level during flush. */ ++#define FLUSH_SCAN_MAXNODES 10000 ++ ++/* per-atom limit of flushers */ ++#define ATOM_MAX_FLUSHERS (1) ++ ++/* default tracing buffer size */ ++#define REISER4_TRACE_BUF_SIZE (1 << 15) ++ ++/* what size units of IO we would like cp, etc., to use, in writing to ++ reiser4. In bytes. ++ ++ Can be overwritten by optimal_io_size mount option. ++*/ ++#define REISER4_OPTIMAL_IO_SIZE (64 * 1024) ++ ++/* see comments in inode.c:oid_to_uino() */ ++#define REISER4_UINO_SHIFT (1 << 30) ++ ++/* Mark function argument as unused to avoid compiler warnings. */ ++#define UNUSED_ARG __attribute__((unused)) ++ ++#if ((__GNUC__ == 3) && (__GNUC_MINOR__ >= 3)) || (__GNUC__ > 3) ++#define NONNULL __attribute__((nonnull)) ++#else ++#define NONNULL ++#endif ++ ++/* master super block offset in bytes.*/ ++#define REISER4_MASTER_OFFSET 65536 ++ ++/* size of VFS block */ ++#define VFS_BLKSIZE 512 ++/* number of bits in size of VFS block (512==2^9) */ ++#define VFS_BLKSIZE_BITS 9 ++ ++#define REISER4_I reiser4_inode_data ++ ++/* implication */ ++#define ergo(antecedent, consequent) (!(antecedent) || (consequent)) ++/* logical equivalence */ ++#define equi(p1, p2) (ergo((p1), (p2)) && ergo((p2), (p1))) ++ ++#define sizeof_array(x) ((int) (sizeof(x) / sizeof(x[0]))) ++ ++#define NOT_YET (0) ++ ++/** Reiser4 specific error codes **/ ++ ++#define REISER4_ERROR_CODE_BASE 10000 ++ ++/* Neighbor is not available (side neighbor or parent) */ ++#define E_NO_NEIGHBOR (REISER4_ERROR_CODE_BASE) ++ ++/* Node was not found in cache */ ++#define E_NOT_IN_CACHE (REISER4_ERROR_CODE_BASE + 1) ++ ++/* node has no free space enough for completion of balancing operation */ ++#define E_NODE_FULL (REISER4_ERROR_CODE_BASE + 2) ++ ++/* repeat operation */ ++#define E_REPEAT (REISER4_ERROR_CODE_BASE + 3) ++ ++/* deadlock happens */ ++#define E_DEADLOCK (REISER4_ERROR_CODE_BASE + 4) ++ ++/* operation cannot be performed, because it would block and non-blocking mode ++ * was requested. */ ++#define E_BLOCK (REISER4_ERROR_CODE_BASE + 5) ++ ++/* wait some event (depends on context), then repeat */ ++#define E_WAIT (REISER4_ERROR_CODE_BASE + 6) ++ ++/* going beyond something */ ++#define E_OUTSTEP (REISER4_ERROR_CODE_BASE + 7) ++ ++#endif /* __REISER4_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/safe_link.c linux-5.10.2/fs/reiser4/safe_link.c +--- linux-5.10.2.orig/fs/reiser4/safe_link.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/safe_link.c 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,355 @@ ++/* Copyright 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Safe-links. */ ++ ++/* ++ * Safe-links are used to maintain file system consistency during operations ++ * that spawns multiple transactions. For example: ++ * ++ * 1. Unlink. UNIX supports "open-but-unlinked" files, that is files ++ * without user-visible names in the file system, but still opened by some ++ * active process. What happens here is that unlink proper (i.e., removal ++ * of the last file name) and file deletion (truncate of file body to zero ++ * and deletion of stat-data, that happens when last file descriptor is ++ * closed), may belong to different transactions T1 and T2. If a crash ++ * happens after T1 commit, but before T2 commit, on-disk file system has ++ * a file without name, that is, disk space leak. ++ * ++ * 2. Truncate. Truncate of large file may spawn multiple transactions. If ++ * system crashes while truncate was in-progress, file is left partially ++ * truncated, which violates "atomicity guarantees" of reiser4, viz. that ++ * every system is atomic. ++ * ++ * Safe-links address both above cases. Basically, safe-link is a way post ++ * some operation to be executed during commit of some other transaction than ++ * current one. (Another way to look at the safe-link is to interpret it as a ++ * logical logging.) ++ * ++ * Specifically, at the beginning of unlink safe-link in inserted in the ++ * tree. This safe-link is normally removed by file deletion code (during ++ * transaction T2 in the above terms). Truncate also inserts safe-link that is ++ * normally removed when truncate operation is finished. ++ * ++ * This means, that in the case of "clean umount" there are no safe-links in ++ * the tree. If safe-links are observed during mount, it means that (a) system ++ * was terminated abnormally, and (b) safe-link correspond to the "pending" ++ * (i.e., not finished) operations that were in-progress during system ++ * termination. Each safe-link record enough information to complete ++ * corresponding operation, and mount simply "replays" them (hence, the ++ * analogy with the logical logging). ++ * ++ * Safe-links are implemented as blackbox items (see ++ * plugin/item/blackbox.[ch]). ++ * ++ * For the reference: ext3 also has similar mechanism, it's called "an orphan ++ * list" there. ++ */ ++ ++#include "safe_link.h" ++#include "debug.h" ++#include "inode.h" ++ ++#include "plugin/item/blackbox.h" ++ ++#include ++ ++/* ++ * On-disk format of safe-link. ++ */ ++typedef struct safelink { ++ reiser4_key sdkey; /* key of stat-data for the file safe-link is ++ * for */ ++ d64 size; /* size to which file should be truncated */ ++} safelink_t; ++ ++/* ++ * locality where safe-link items are stored. Next to the objectid of root ++ * directory. ++ */ ++static oid_t safe_link_locality(reiser4_subvol *subv) ++{ ++ return get_key_objectid(subv->df_plug->root_dir_key(NULL)) + 1; ++} ++ ++/* ++ Construct a key for the safe-link. Key has the following format: ++ ++| 60 | 4 | 64 | 4 | 60 | 64 | +++---------------+---+------------------+---+---------------+------------------+ ++| locality | 0 | 0 | 0 | objectid | link type | +++---------------+---+------------------+---+---------------+------------------+ ++| | | | | ++| 8 bytes | 8 bytes | 8 bytes | 8 bytes | ++ ++ This is in large keys format. In small keys format second 8 byte chunk is ++ out. Locality is a constant returned by safe_link_locality(). objectid is ++ an oid of a file on which operation protected by this safe-link is ++ performed. link-type is used to distinguish safe-links for different ++ operations. ++ ++ */ ++static reiser4_key *build_link_key(reiser4_subvol *subv, oid_t oid, ++ reiser4_safe_link_t link, reiser4_key * key) ++{ ++ reiser4_key_init(key); ++ set_key_locality(key, safe_link_locality(subv)); ++ set_key_objectid(key, oid); ++ set_key_offset(key, link); ++ return key; ++} ++ ++/* ++ * how much disk space is necessary to insert and remove (in the ++ * error-handling path) safe-link. ++ */ ++static __u64 safe_link_tograb(reiser4_tree * tree) ++{ ++ return ++ /* insert safe link */ ++ estimate_one_insert_item(tree) + ++ /* remove safe link */ ++ estimate_one_item_removal(tree) + ++ /* drill to the leaf level during insertion */ ++ 1 + estimate_one_insert_item(tree) + ++ /* ++ * possible update of existing safe-link. Actually, if ++ * safe-link existed already (we failed to remove it), then no ++ * insertion is necessary, so this term is already "covered", ++ * but for simplicity let's left it. ++ */ ++ 1; ++} ++ ++/* ++ * grab enough disk space to insert and remove (in the error-handling path) ++ * safe-link. ++ */ ++int safe_link_grab(struct super_block *super, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv) ++{ ++ int result; ++ ++ grab_space_enable(); ++ /* ++ * The sbinfo->delete_mutex can be taken here. ++ * safe_link_release() should be called before leaving ++ * reiser4 context ++ */ ++ result = reiser4_grab_reserved(super, safe_link_tograb(&subv->tree), ++ flags, subv); ++ grab_space_enable(); ++ return result; ++} ++ ++/* ++ * release unused disk space reserved by safe_link_grab(). ++ */ ++void safe_link_release(struct super_block *super) ++{ ++ reiser4_release_reserved(super); ++} ++ ++/* ++ * insert into tree safe-link for operation @link on inode @inode. ++ */ ++int safe_link_add(struct inode *inode, reiser4_safe_link_t link) ++{ ++ reiser4_key key; ++ safelink_t sl; ++ int length; ++ int result; ++ reiser4_subvol *subv = get_meta_subvol(); ++ ++ build_sd_key(inode, &sl.sdkey); ++ length = sizeof sl.sdkey; ++ ++ if (link == SAFE_TRUNCATE) { ++ /* ++ * for truncate we have to store final file length also, ++ * expand item. ++ */ ++ length += sizeof(sl.size); ++ put_unaligned(cpu_to_le64(inode->i_size), &sl.size); ++ } ++ build_link_key(subv, get_inode_oid(inode), link, &key); ++ ++ result = store_black_box(&subv->tree, &key, &sl, length); ++ if (result == -EEXIST) ++ result = update_black_box(&subv->tree, &key, &sl, length); ++ return result; ++} ++ ++/* ++ * remove safe-link corresponding to the operation @link on inode @inode from ++ * the tree. ++ */ ++int safe_link_del(reiser4_subvol *subv, oid_t oid, reiser4_safe_link_t link) ++{ ++ reiser4_key key; ++ ++ return kill_black_box(&subv->tree, ++ build_link_key(subv, oid, link, &key)); ++} ++ ++/* ++ * in-memory structure to keep information extracted from safe-link. This is ++ * used to iterate over all safe-links. ++ */ ++struct safe_link_context { ++ reiser4_tree *tree; /* internal tree */ ++ reiser4_key key; /* safe-link key */ ++ reiser4_key sdkey; /* key of object stat-data */ ++ reiser4_safe_link_t link; /* safe-link type */ ++ oid_t oid; /* object oid */ ++ __u64 size; /* final size for truncate */ ++}; ++ ++/* ++ * start iterating over all safe-links. ++ */ ++static void safe_link_iter_begin(reiser4_subvol *subv, ++ struct safe_link_context *ctx) ++{ ++ reiser4_key_init(&ctx->key); ++ set_key_locality(&ctx->key, safe_link_locality(subv)); ++ set_key_objectid(&ctx->key, get_key_objectid(reiser4_max_key())); ++ set_key_offset(&ctx->key, get_key_offset(reiser4_max_key())); ++} ++ ++/* ++ * return next safe-link. ++ */ ++static int safe_link_iter_next(reiser4_subvol *subv, ++ struct safe_link_context *ctx) ++{ ++ int result; ++ safelink_t sl; ++ ++ result = load_black_box(&subv->tree, &ctx->key, &sl, sizeof sl, 0); ++ if (result == 0) { ++ ctx->oid = get_key_objectid(&ctx->key); ++ ctx->link = get_key_offset(&ctx->key); ++ ctx->sdkey = sl.sdkey; ++ if (ctx->link == SAFE_TRUNCATE) ++ ctx->size = le64_to_cpu(get_unaligned(&sl.size)); ++ } ++ return result; ++} ++ ++/* ++ * check are there any more safe-links left in the tree. ++ */ ++static int safe_link_iter_finished(reiser4_subvol *subv, ++ struct safe_link_context *ctx) ++{ ++ return get_key_locality(&ctx->key) != safe_link_locality(subv); ++} ++ ++/* ++ * finish safe-link iteration. ++ */ ++static void safe_link_iter_end(struct safe_link_context *ctx) ++{ ++ /* nothing special */ ++} ++ ++/* ++ * process single safe-link. ++ */ ++static int process_safelink(struct super_block *super, reiser4_subvol *subv, ++ reiser4_safe_link_t link, reiser4_key *sdkey, ++ oid_t oid, __u64 size) ++{ ++ int result; ++ struct inode *inode; ++ ++ /* ++ * obtain object inode by reiser4_iget(), then call object plugin ++ * ->safelink() method to do actual work, then delete safe-link on ++ * success. ++ */ ++ inode = reiser4_iget(super, sdkey, 1, 1); ++ if (!IS_ERR(inode)) { ++ file_plugin *fplug; ++ ++ fplug = inode_file_plugin(inode); ++ assert("nikita-3428", fplug != NULL); ++ assert("", oid == get_inode_oid(inode)); ++ if (fplug->safelink != NULL) { ++ /* reiser4_txn_restart_current is not necessary because ++ * mounting is signle thread. However, without it ++ * deadlock detection code will complain (see ++ * nikita-3361). */ ++ reiser4_txn_restart_current(); ++ result = fplug->safelink(inode, link, size); ++ } else { ++ warning("nikita-3430", ++ "Cannot handle safelink for %lli", ++ (unsigned long long)oid); ++ reiser4_print_key("key", sdkey); ++ result = 0; ++ } ++ if (result != 0) { ++ warning("nikita-3431", ++ "Error processing safelink for %lli: %i", ++ (unsigned long long)oid, result); ++ } ++ reiser4_iget_complete(inode); ++ iput(inode); ++ if (result == 0) { ++ result = safe_link_grab(super, BA_CAN_COMMIT, subv); ++ if (result == 0) ++ result = safe_link_del(subv, oid, link); ++ safe_link_release(super); ++ /* ++ * restart transaction: if there was large number of ++ * safe-links, their processing may fail to fit into ++ * single transaction. ++ */ ++ if (result == 0) ++ reiser4_txn_restart_current(); ++ } ++ } else ++ result = PTR_ERR(inode); ++ return result; ++} ++ ++/* ++ * iterate over all safe-links in the file-system processing them one by one. ++ */ ++int process_safelinks(struct super_block *super, reiser4_subvol *subv) ++{ ++ int result; ++ struct safe_link_context ctx; ++ ++ if (sb_rdonly(super)) ++ /* do nothing on the read-only file system */ ++ return 0; ++ safe_link_iter_begin(subv, &ctx); ++ result = 0; ++ do { ++ result = safe_link_iter_next(subv, &ctx); ++ if (safe_link_iter_finished(subv, &ctx) || result == -ENOENT) { ++ result = 0; ++ break; ++ } ++ if (result == 0) ++ result = process_safelink(super, subv, ctx.link, ++ &ctx.sdkey, ctx.oid, ++ ctx.size); ++ } while (result == 0); ++ safe_link_iter_end(&ctx); ++ return result; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/safe_link.h linux-5.10.2/fs/reiser4/safe_link.h +--- linux-5.10.2.orig/fs/reiser4/safe_link.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/safe_link.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,28 @@ ++/* Copyright 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Safe-links. See safe_link.c for details. */ ++ ++#if !defined(__FS_SAFE_LINK_H__) ++#define __FS_SAFE_LINK_H__ ++ ++#include "tree.h" ++int safe_link_grab(struct super_block *super, ++ reiser4_ba_flags_t flags, reiser4_subvol *subv); ++void safe_link_release(struct super_block *super); ++int safe_link_add(struct inode *inode, reiser4_safe_link_t link); ++int safe_link_del(reiser4_subvol *, oid_t oid, reiser4_safe_link_t link); ++int process_safelinks(struct super_block *super, reiser4_subvol *subv); ++ ++/* __FS_SAFE_LINK_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/seal.c linux-5.10.2/fs/reiser4/seal.c +--- linux-5.10.2.orig/fs/reiser4/seal.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/seal.c 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,223 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++/* Seals implementation. */ ++/* Seals are "weak" tree pointers. They are analogous to tree coords in ++ allowing to bypass tree traversal. But normal usage of coords implies that ++ node pointed to by coord is locked, whereas seals don't keep a lock (or ++ even a reference) to znode. In stead, each znode contains a version number, ++ increased on each znode modification. This version number is copied into a ++ seal when seal is created. Later, one can "validate" seal by calling ++ reiser4_seal_validate(). If znode is in cache and its version number is ++ still the same, seal is "pristine" and coord associated with it can be ++ re-used immediately. ++ ++ If, on the other hand, znode is out of cache, or it is obviously different ++ one from the znode seal was initially attached to (for example, it is on ++ the different level, or is being removed from the tree), seal is ++ irreparably invalid ("burned") and tree traversal has to be repeated. ++ ++ Otherwise, there is some hope, that while znode was modified (and seal was ++ "broken" as a result), key attached to the seal is still in the node. This ++ is checked by first comparing this key with delimiting keys of node and, if ++ key is ok, doing intra-node lookup. ++ ++ Znode version is maintained in the following way: ++ ++ there is reiser4_tree.znode_epoch counter. Whenever new znode is created, ++ znode_epoch is incremented and its new value is stored in ->version field ++ of new znode. Whenever znode is dirtied (which means it was probably ++ modified), znode_epoch is also incremented and its new value is stored in ++ znode->version. This is done so, because just incrementing znode->version ++ on each update is not enough: it may so happen, that znode get deleted, new ++ znode is allocated for the same disk block and gets the same version ++ counter, tricking seal code into false positive. ++*/ ++ ++#include "forward.h" ++#include "debug.h" ++#include "key.h" ++#include "coord.h" ++#include "seal.h" ++#include "plugin/item/item.h" ++#include "plugin/node/node.h" ++#include "jnode.h" ++#include "znode.h" ++#include "super.h" ++ ++static znode *seal_node(const seal_t *seal, reiser4_tree *tree); ++static int seal_matches(const seal_t *seal, znode * node); ++ ++/** ++ * Initialise seal. ++ * This can be called several times on the same seal. ++ * @coord: coord @seal will be attached to. Can be NULL. ++ * @key: key @seal will be attached to. Can be NULL. ++ */ ++void reiser4_seal_init(seal_t *seal, const coord_t *coord, ++ const reiser4_key *key ) ++{ ++ assert("nikita-1886", seal != NULL); ++ memset(seal, 0, sizeof *seal); ++ if (coord != NULL) { ++ znode *node; ++ ++ node = coord->node; ++ assert("nikita-1987", node != NULL); ++ spin_lock_znode(node); ++ seal->version = node->version; ++ assert("nikita-1988", seal->version != 0); ++ seal->block = *znode_get_block(node); ++#if REISER4_DEBUG ++ seal->coord1 = *coord; ++ if (key != NULL) ++ seal->key = *key; ++#endif ++ spin_unlock_znode(node); ++ } ++} ++ ++/* finish with seal */ ++void reiser4_seal_done(seal_t *seal/* seal to clear */) ++{ ++ assert("nikita-1887", seal != NULL); ++ seal->version = 0; ++} ++ ++/* true if seal was initialised */ ++int reiser4_seal_is_set(const seal_t *seal/* seal to query */) ++{ ++ assert("nikita-1890", seal != NULL); ++ return seal->version != 0; ++} ++ ++#if REISER4_DEBUG ++/* helper function for reiser4_seal_validate(). It checks that item at @coord ++ * has expected key. This is to detect cases where node was modified but wasn't ++ * marked dirty. */ ++static inline int check_seal_match(const coord_t *coord /* coord to check */ , ++ const reiser4_key *k__/* expected key */) ++{ ++ reiser4_key ukey; ++ ++ /* FIXME-VS: we only can compare keys for items whose units ++ represent exactly one key */ ++ if (coord->between != AT_UNIT) ++ return 1; ++ if (!coord_is_existing_unit(coord)) ++ return 0; ++ if (item_is_extent(coord)) ++ return 1; ++ if (item_is_ctail(coord)) ++ return keyge(k__, unit_key_by_coord(coord, &ukey)); ++ return keyeq(k__, unit_key_by_coord(coord, &ukey)); ++} ++#endif ++ ++/* this is used by reiser4_seal_validate. It accepts return value of ++ * longterm_lock_znode and returns 1 if it can be interpreted as seal ++ * validation failure. For instance, when longterm_lock_znode returns -EINVAL, ++ * reiser4_seal_validate returns -E_REPEAT and caller will call tre search. ++ * We cannot do this in longterm_lock_znode(), because sometimes we want to ++ * distinguish between -EINVAL and -E_REPEAT. */ ++static int should_repeat(int return_code) ++{ ++ return return_code == -EINVAL; ++} ++ ++/* (re-)validate seal. ++ ++ Checks whether seal is pristine, and try to revalidate it if possible. ++ ++ If seal was burned, or broken irreparably, return -E_REPEAT. ++ ++ NOTE-NIKITA currently reiser4_seal_validate() returns -E_REPEAT if key we are ++ looking for is in range of keys covered by the sealed node, but item wasn't ++ found by node ->lookup() method. Alternative is to return -ENOENT in this ++ case, but this would complicate callers logic. ++ ++*/ ++int reiser4_seal_validate(seal_t *seal /* seal to validate */, ++ reiser4_tree *tree, ++ coord_t *coord /* coord to validate against */, ++ const reiser4_key * key /* key to validate against */, ++ lock_handle * lh /* resulting lock handle */, ++ znode_lock_mode mode /* lock node */, ++ znode_lock_request request/* locking priority */) ++{ ++ znode *node; ++ int result; ++ ++ assert("nikita-1889", seal != NULL); ++ assert("nikita-1881", reiser4_seal_is_set(seal)); ++ assert("nikita-1882", key != NULL); ++ assert("nikita-1883", coord != NULL); ++ assert("nikita-1884", lh != NULL); ++ assert("nikita-1885", all_but_ordering_keyeq(&seal->key, key)); ++ assert("nikita-1989", coords_equal(&seal->coord1, coord)); ++ ++ /* obtain znode by block number */ ++ node = seal_node(seal, tree); ++ if (!node) ++ /* znode wasn't in cache */ ++ return RETERR(-E_REPEAT); ++ /* znode was in cache, lock it */ ++ result = longterm_lock_znode(lh, node, mode, request); ++ zput(node); ++ if (result == 0) { ++ if (seal_matches(seal, node)) { ++ /* if seal version and znode version ++ coincide */ ++ ON_DEBUG(coord_update_v(coord)); ++ assert("nikita-1990", ++ node == seal->coord1.node); ++ assert("nikita-1898", ++ WITH_DATA_RET(coord->node, 1, ++ check_seal_match(coord, ++ key))); ++ } else ++ result = RETERR(-E_REPEAT); ++ } ++ if (result != 0) { ++ if (should_repeat(result)) ++ result = RETERR(-E_REPEAT); ++ /* unlock node on failure */ ++ done_lh(lh); ++ } ++ return result; ++} ++ ++/* helpers functions */ ++ ++/* obtain reference to znode seal points to, if in cache */ ++static znode *seal_node(const seal_t *seal, reiser4_tree *tree) ++{ ++ assert("nikita-1891", seal != NULL); ++ assert("edward-1734", tree != NULL); ++ ++ return zlook(tree, &seal->block); ++} ++ ++/* true if @seal version and @node version coincide */ ++static int seal_matches(const seal_t *seal /* seal to check */ , ++ znode * node/* node to check */) ++{ ++ int result; ++ ++ assert("nikita-1991", seal != NULL); ++ assert("nikita-1993", node != NULL); ++ ++ spin_lock_znode(node); ++ result = (seal->version == node->version); ++ spin_unlock_znode(node); ++ return result; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/seal.h linux-5.10.2/fs/reiser4/seal.h +--- linux-5.10.2.orig/fs/reiser4/seal.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/seal.h 2020-12-23 16:07:46.133813348 +0100 +@@ -0,0 +1,49 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Declaration of seals: "weak" tree pointers. See seal.c for comments. */ ++ ++#ifndef __SEAL_H__ ++#define __SEAL_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++ ++/* for __u?? types */ ++/*#include */ ++ ++/* seal. See comment at the top of seal.c */ ++typedef struct seal_s { ++ /* version of znode recorder at the time of seal creation */ ++ __u64 version; ++ /* block number of znode attached to this seal */ ++ reiser4_block_nr block; ++#if REISER4_DEBUG ++ /* coord this seal is attached to. For debugging. */ ++ coord_t coord1; ++ /* key this seal is attached to. For debugging. */ ++ reiser4_key key; ++#endif ++} seal_t; ++ ++extern void reiser4_seal_init(seal_t *, const coord_t *, const reiser4_key *); ++extern void reiser4_seal_done(seal_t *); ++extern int reiser4_seal_is_set(const seal_t *); ++extern int reiser4_seal_validate(seal_t *, reiser4_tree *, coord_t *, ++ const reiser4_key *, lock_handle * , ++ znode_lock_mode mode, znode_lock_request request); ++ ++/* __SEAL_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/search.c linux-5.10.2/fs/reiser4/search.c +--- linux-5.10.2.orig/fs/reiser4/search.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/search.c 2020-12-23 16:07:46.134813363 +0100 +@@ -0,0 +1,1603 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "seal.h" ++#include "plugin/item/item.h" ++#include "plugin/node/node.h" ++#include "plugin/plugin.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "tree.h" ++#include "reiser4.h" ++#include "super.h" ++#include "inode.h" ++ ++#include ++ ++static const char *bias_name(lookup_bias bias); ++ ++/* tree searching algorithm, intranode searching algorithms are in ++ plugin/node/ */ ++ ++/* tree lookup cache ++ * ++ * The coord by key cache consists of small list of recently accessed nodes ++ * maintained according to the LRU discipline. Before doing real top-to-down ++ * tree traversal this cache is scanned for nodes that can contain key ++ * requested. ++ * ++ * The efficiency of coord cache depends heavily on locality of reference for ++ * tree accesses. Our user level simulations show reasonably good hit ratios ++ * for coord cache under most loads so far. ++ */ ++ ++/* Initialise coord cache slot */ ++static void cbk_cache_init_slot(cbk_cache_slot *slot) ++{ ++ assert("nikita-345", slot != NULL); ++ ++ INIT_LIST_HEAD(&slot->lru); ++ slot->node = NULL; ++} ++ ++/* Initialize coord cache */ ++int cbk_cache_init(cbk_cache * cache/* cache to init */) ++{ ++ int i; ++ ++ assert("nikita-346", cache != NULL); ++ ++ cache->slot = ++ kmalloc(sizeof(cbk_cache_slot) * cache->nr_slots, ++ reiser4_ctx_gfp_mask_get()); ++ if (cache->slot == NULL) ++ return RETERR(-ENOMEM); ++ ++ INIT_LIST_HEAD(&cache->lru); ++ for (i = 0; i < cache->nr_slots; ++i) { ++ cbk_cache_init_slot(cache->slot + i); ++ list_add_tail(&((cache->slot + i)->lru), &cache->lru); ++ } ++ rwlock_init(&cache->guard); ++ return 0; ++} ++ ++/* free cbk cache data */ ++void cbk_cache_done(cbk_cache * cache/* cache to release */) ++{ ++ assert("nikita-2493", cache != NULL); ++ if (cache->slot != NULL) { ++ kfree(cache->slot); ++ cache->slot = NULL; ++ } ++} ++ ++/* macro to iterate over all cbk cache slots */ ++#define for_all_slots(cache, slot) \ ++ for ((slot) = list_entry((cache)->lru.next, cbk_cache_slot, lru); \ ++ &(cache)->lru != &(slot)->lru; \ ++ (slot) = list_entry(slot->lru.next, cbk_cache_slot, lru)) ++ ++#if REISER4_DEBUG ++/* this function assures that [cbk-cache-invariant] invariant holds */ ++static int cbk_cache_invariant(const cbk_cache * cache) ++{ ++ cbk_cache_slot *slot; ++ int result; ++ int unused; ++ ++ if (cache->nr_slots == 0) ++ return 1; ++ ++ assert("nikita-2469", cache != NULL); ++ unused = 0; ++ result = 1; ++ read_lock(&((cbk_cache *)cache)->guard); ++ for_all_slots(cache, slot) { ++ /* in LRU first go all `used' slots followed by `unused' */ ++ if (unused && (slot->node != NULL)) ++ result = 0; ++ if (slot->node == NULL) ++ unused = 1; ++ else { ++ cbk_cache_slot *scan; ++ ++ /* all cached nodes are different */ ++ scan = slot; ++ while (result) { ++ scan = list_entry(scan->lru.next, ++ cbk_cache_slot, lru); ++ if (&cache->lru == &scan->lru) ++ break; ++ if (slot->node == scan->node) ++ result = 0; ++ } ++ } ++ if (!result) ++ break; ++ } ++ read_unlock(&((cbk_cache *)cache)->guard); ++ return result; ++} ++ ++#endif ++ ++/* Remove references, if any, to @node from coord cache */ ++void cbk_cache_invalidate(const znode * node /* node to remove from cache */ , ++ reiser4_tree * tree/* tree to remove node from */) ++{ ++ cbk_cache_slot *slot; ++ cbk_cache *cache; ++ int i; ++ ++ assert("nikita-350", node != NULL); ++ assert("nikita-1479", LOCK_CNT_GTZ(rw_locked_tree)); ++ ++ cache = &tree->cbk_cache; ++ assert("nikita-2470", cbk_cache_invariant(cache)); ++ ++ write_lock(&(cache->guard)); ++ for (i = 0, slot = cache->slot; i < cache->nr_slots; ++i, ++slot) { ++ if (slot->node == node) { ++ list_move_tail(&slot->lru, &cache->lru); ++ slot->node = NULL; ++ break; ++ } ++ } ++ write_unlock(&(cache->guard)); ++ assert("nikita-2471", cbk_cache_invariant(cache)); ++} ++ ++/* add to the cbk-cache in the "tree" information about "node". This ++ can actually be update of existing slot in a cache. */ ++static void cbk_cache_add(const znode * node/* node to add to the cache */) ++{ ++ cbk_cache *cache; ++ ++ cbk_cache_slot *slot; ++ int i; ++ ++ assert("nikita-352", node != NULL); ++ ++ cache = &znode_get_tree(node)->cbk_cache; ++ assert("nikita-2472", cbk_cache_invariant(cache)); ++ ++ if (cache->nr_slots == 0) ++ return; ++ ++ write_lock(&(cache->guard)); ++ /* find slot to update/add */ ++ for (i = 0, slot = cache->slot; i < cache->nr_slots; ++i, ++slot) { ++ /* oops, this node is already in a cache */ ++ if (slot->node == node) ++ break; ++ } ++ /* if all slots are used, reuse least recently used one */ ++ if (i == cache->nr_slots) { ++ slot = list_entry(cache->lru.prev, cbk_cache_slot, lru); ++ slot->node = (znode *) node; ++ } ++ list_move(&slot->lru, &cache->lru); ++ write_unlock(&(cache->guard)); ++ assert("nikita-2473", cbk_cache_invariant(cache)); ++} ++ ++static int setup_delimiting_keys(cbk_handle * h); ++static lookup_result coord_by_handle(cbk_handle * handle); ++static lookup_result traverse_tree(cbk_handle * h); ++static int cbk_cache_search(cbk_handle * h); ++ ++static level_lookup_result cbk_level_lookup(cbk_handle * h); ++static level_lookup_result cbk_node_lookup(cbk_handle * h); ++ ++/* helper functions */ ++ ++static void update_stale_dk(reiser4_tree * tree, znode * node); ++ ++/* release parent node during traversal */ ++static void put_parent(cbk_handle * h); ++/* check consistency of fields */ ++static int sanity_check(cbk_handle * h); ++/* release resources in handle */ ++static void hput(cbk_handle * h); ++ ++static level_lookup_result search_to_left(cbk_handle * h); ++ ++/* pack numerous (numberous I should say) arguments of coord_by_key() into ++ * cbk_handle */ ++static cbk_handle *cbk_pack(cbk_handle * handle, ++ reiser4_tree * tree, ++ const reiser4_key * key, ++ coord_t *coord, ++ lock_handle * active_lh, ++ lock_handle * parent_lh, ++ znode_lock_mode lock_mode, ++ lookup_bias bias, ++ tree_level lock_level, ++ tree_level stop_level, ++ __u32 flags, ra_info_t *info) ++{ ++ memset(handle, 0, sizeof *handle); ++ ++ handle->tree = tree; ++ handle->key = key; ++ handle->lock_mode = lock_mode; ++ handle->bias = bias; ++ handle->lock_level = lock_level; ++ handle->stop_level = stop_level; ++ handle->coord = coord; ++ /* set flags. See comment in tree.h:cbk_flags */ ++ handle->flags = flags | CBK_TRUST_DK | CBK_USE_CRABLOCK; ++ ++ handle->active_lh = active_lh; ++ handle->parent_lh = parent_lh; ++ handle->ra_info = info; ++ return handle; ++} ++ ++/* main tree lookup procedure ++ ++ Check coord cache. If key we are looking for is not found there, call cbk() ++ to do real tree traversal. ++ ++ As we have extents on the twig level, @lock_level and @stop_level can ++ be different from LEAF_LEVEL and each other. ++ ++ Thread cannot keep any reiser4 locks (tree, znode, dk spin-locks, or znode ++ long term locks) while calling this. ++*/ ++lookup_result coord_by_key(reiser4_tree * tree /* tree to perform search ++ * in. Usually this tree is ++ * part of file-system ++ * super-block */ , ++ const reiser4_key * key /* key to look for */ , ++ coord_t *coord /* where to store found ++ * position in a tree. Fields ++ * in "coord" are only valid if ++ * coord_by_key() returned ++ * "CBK_COORD_FOUND" */ , ++ lock_handle * lh, /* resulting lock handle */ ++ znode_lock_mode lock_mode /* type of lookup we ++ * want on node. Pass ++ * ZNODE_READ_LOCK here ++ * if you only want to ++ * read item found and ++ * ZNODE_WRITE_LOCK if ++ * you want to modify ++ * it */ , ++ lookup_bias bias /* what to return if coord ++ * with exactly the @key is ++ * not in the tree */ , ++ tree_level lock_level/* tree level where to start ++ * taking @lock type of ++ * locks */ , ++ tree_level stop_level/* tree level to stop. Pass ++ * LEAF_LEVEL or TWIG_LEVEL ++ * here Item being looked ++ * for has to be between ++ * @lock_level and ++ * @stop_level, inclusive */ , ++ __u32 flags /* search flags */ , ++ ra_info_t * ++ info ++ /* information about desired tree traversal ++ * readahead */ ++ ) ++{ ++ cbk_handle handle; ++ lock_handle parent_lh; ++ lookup_result result; ++ ++ init_lh(lh); ++ init_lh(&parent_lh); ++ ++ assert("nikita-3023", reiser4_schedulable()); ++ ++ assert("nikita-353", tree != NULL); ++ assert("nikita-354", key != NULL); ++ assert("nikita-355", coord != NULL); ++ assert("nikita-356", (bias == FIND_EXACT) ++ || (bias == FIND_MAX_NOT_MORE_THAN)); ++ assert("nikita-357", stop_level >= LEAF_LEVEL); ++ /* no locks can be held during tree traversal */ ++ assert("nikita-2104", lock_stack_isclean(get_current_lock_stack())); ++ ++ cbk_pack(&handle, ++ tree, ++ key, ++ coord, ++ lh, ++ &parent_lh, ++ lock_mode, bias, lock_level, stop_level, flags, info); ++ ++ result = coord_by_handle(&handle); ++ assert("nikita-3247", ++ ergo(!IS_CBKERR(result), coord->node == lh->node)); ++ return result; ++} ++ ++/* like coord_by_key(), but starts traversal from vroot of @object rather than ++ * from tree root. */ ++lookup_result reiser4_object_lookup(reiser4_tree *tree, ++ struct inode *object, ++ const reiser4_key * key, ++ coord_t *coord, ++ lock_handle * lh, ++ znode_lock_mode lock_mode, ++ lookup_bias bias, ++ tree_level lock_level, ++ tree_level stop_level, __u32 flags, ++ ra_info_t *info) ++{ ++ cbk_handle handle; ++ lock_handle parent_lh; ++ lookup_result result; ++ ++ init_lh(lh); ++ init_lh(&parent_lh); ++ ++ assert("nikita-3023", reiser4_schedulable()); ++ ++ assert("nikita-354", key != NULL); ++ assert("nikita-355", coord != NULL); ++ assert("nikita-356", (bias == FIND_EXACT) ++ || (bias == FIND_MAX_NOT_MORE_THAN)); ++ assert("nikita-357", stop_level >= LEAF_LEVEL); ++ /* no locks can be held during tree search by key */ ++ assert("nikita-2104", lock_stack_isclean(get_current_lock_stack())); ++ ++ cbk_pack(&handle, ++ tree, ++ key, ++ coord, ++ lh, ++ &parent_lh, ++ lock_mode, bias, lock_level, stop_level, flags, info); ++ handle.object = object; ++ ++ result = coord_by_handle(&handle); ++ assert("nikita-3247", ++ ergo(!IS_CBKERR(result), coord->node == lh->node)); ++ return result; ++} ++ ++/* lookup by cbk_handle. Common part of coord_by_key() and ++ reiser4_object_lookup(). */ ++static lookup_result coord_by_handle(cbk_handle * handle) ++{ ++ /* ++ * first check cbk_cache (which is look-aside cache for our tree) and ++ * of this fails, start traversal. ++ */ ++ /* first check whether "key" is in cache of recent lookups. */ ++ if (cbk_cache_search(handle) == 0) ++ return handle->result; ++ else ++ return traverse_tree(handle); ++} ++ ++/* Execute actor for each item (or unit, depending on @through_units_p), ++ starting from @coord, right-ward, until either: ++ ++ - end of the tree is reached ++ - unformatted node is met ++ - error occurred ++ - @actor returns 0 or less ++ ++ Error code, or last actor return value is returned. ++ ++ This is used by plugin/dir/hashe_dir.c:reiser4_find_entry() to move through ++ sequence of entries with identical keys and alikes. ++*/ ++int reiser4_iterate_tree(reiser4_tree * tree /* tree to scan */ , ++ coord_t *coord /* coord to start from */ , ++ lock_handle * lh /* lock handle to start with and to ++ * update along the way */ , ++ tree_iterate_actor_t actor /* function to call on each ++ * item/unit */ , ++ void *arg /* argument to pass to @actor */ , ++ znode_lock_mode mode /* lock mode on scanned nodes */ , ++ int through_units_p /* call @actor on each item or on ++ * each unit */ ) ++{ ++ int result; ++ ++ assert("nikita-1143", tree != NULL); ++ assert("nikita-1145", coord != NULL); ++ assert("nikita-1146", lh != NULL); ++ assert("nikita-1147", actor != NULL); ++ ++ result = zload(coord->node); ++ coord_clear_iplug(coord); ++ if (result != 0) ++ return result; ++ if (!coord_is_existing_unit(coord)) { ++ zrelse(coord->node); ++ return -ENOENT; ++ } ++ while ((result = actor(tree, coord, lh, arg)) > 0) { ++ /* move further */ ++ if ((through_units_p && coord_next_unit(coord)) || ++ (!through_units_p && coord_next_item(coord))) { ++ do { ++ lock_handle couple; ++ ++ /* move to the next node */ ++ init_lh(&couple); ++ result = ++ reiser4_get_right_neighbor(&couple, ++ coord->node, ++ (int)mode, ++ GN_CAN_USE_UPPER_LEVELS); ++ zrelse(coord->node); ++ if (result == 0) { ++ ++ result = zload(couple.node); ++ if (result != 0) { ++ done_lh(&couple); ++ return result; ++ } ++ ++ coord_init_first_unit(coord, ++ couple.node); ++ done_lh(lh); ++ move_lh(lh, &couple); ++ } else ++ return result; ++ } while (node_is_empty(coord->node)); ++ } ++ ++ assert("nikita-1149", coord_is_existing_unit(coord)); ++ } ++ zrelse(coord->node); ++ return result; ++} ++ ++/** ++ * Return locked uber znode for @tree ++ */ ++int get_uber_znode(reiser4_tree * tree, znode_lock_mode mode, ++ znode_lock_request pri, lock_handle * lh) ++{ ++ int result; ++ ++ result = longterm_lock_znode(lh, tree->uber, mode, pri); ++ return result; ++} ++ ++/* true if @key is strictly within @node ++ ++ we are looking for possibly non-unique key and it is item is at the edge of ++ @node. May be it is in the neighbor. ++*/ ++static int znode_contains_key_strict(znode * node /* node to check key ++ * against */ , ++ const reiser4_key * ++ key /* key to check */ , ++ int isunique) ++{ ++ int answer; ++ ++ assert("nikita-1760", node != NULL); ++ assert("nikita-1722", key != NULL); ++ ++ if (keyge(key, &node->rd_key)) ++ return 0; ++ ++ answer = keycmp(&node->ld_key, key); ++ ++ if (isunique) ++ return answer != GREATER_THAN; ++ else ++ return answer == LESS_THAN; ++} ++ ++/* ++ * Virtual Root (vroot) code. ++ * ++ * For given file system object (e.g., regular file or directory) let's ++ * define its "virtual root" as lowest in the tree (that is, furtherest ++ * from the tree root) node such that all body items of said object are ++ * located in a tree rooted at this node. ++ * ++ * Once vroot of object is found all tree lookups for items within body of ++ * this object ("object lookups") can be started from its vroot rather ++ * than from real root. This has following advantages: ++ * ++ * 1. amount of nodes traversed during lookup (and, hence, amount of ++ * key comparisons made) decreases, and ++ * ++ * 2. contention on tree root is decreased. This latter was actually ++ * motivating reason behind vroot, because spin lock of root node, ++ * which is taken when acquiring long-term lock on root node is the ++ * hottest lock in the reiser4. ++ * ++ * How to find vroot. ++ * ++ * When vroot of object F is not yet determined, all object lookups start ++ * from the root of the tree. At each tree level during traversal we have ++ * a node N such that a key we are looking for (which is the key inside ++ * object's body) is located within N. In function handle_vroot() called ++ * from cbk_level_lookup() we check whether N is possible vroot for ++ * F. Check is trivial---if neither leftmost nor rightmost item of N ++ * belongs to F (and we already have helpful ->owns_item() method of ++ * object plugin for this), then N is possible vroot of F. This, of ++ * course, relies on the assumption that each object occupies contiguous ++ * range of keys in the tree. ++ * ++ * Thus, traversing tree downward and checking each node as we go, we can ++ * find lowest such node, which, by definition, is vroot. ++ * ++ * How to track vroot. ++ * ++ * Nohow. If actual vroot changes, next object lookup will just restart ++ * from the actual tree root, refreshing object's vroot along the way. ++ * ++ */ ++ ++/* ++ * Check whether @node is possible vroot of @object. ++ */ ++static void handle_vroot(struct inode *object, znode * node) ++{ ++ file_plugin *fplug; ++ coord_t coord; ++ ++ fplug = inode_file_plugin(object); ++ assert("nikita-3353", fplug != NULL); ++ assert("nikita-3354", fplug->owns_item != NULL); ++ ++ if (unlikely(node_is_empty(node))) ++ return; ++ ++ coord_init_first_unit(&coord, node); ++ /* ++ * if leftmost item of @node belongs to @object, we cannot be sure ++ * that @node is vroot of @object, because, some items of @object are ++ * probably in the sub-tree rooted at the left neighbor of @node. ++ */ ++ if (fplug->owns_item(object, &coord)) ++ return; ++ coord_init_last_unit(&coord, node); ++ /* mutatis mutandis for the rightmost item */ ++ if (fplug->owns_item(object, &coord)) ++ return; ++ /* otherwise, @node is possible vroot of @object */ ++ inode_set_vroot(object, node); ++} ++ ++/* ++ * helper function used by traverse tree to start tree traversal not from the ++ * tree root, but from @h->object's vroot, if possible. ++ */ ++static int prepare_object_lookup(cbk_handle * h) ++{ ++ znode *vroot; ++ int result; ++ ++ vroot = inode_get_vroot(h->object); ++ if (vroot == NULL) { ++ /* ++ * object doesn't have known vroot, start from real tree root. ++ */ ++ return LOOKUP_CONT; ++ } ++ ++ h->level = znode_get_level(vroot); ++ /* take a long-term lock on vroot */ ++ h->result = longterm_lock_znode(h->active_lh, vroot, ++ cbk_lock_mode(h->level, h), ++ ZNODE_LOCK_LOPRI); ++ result = LOOKUP_REST; ++ if (h->result == 0) { ++ int isunique; ++ int inside; ++ ++ isunique = h->flags & CBK_UNIQUE; ++ /* check that key is inside vroot */ ++ read_lock_dk(h->tree); ++ inside = (znode_contains_key_strict(vroot, h->key, isunique) && ++ !ZF_ISSET(vroot, JNODE_HEARD_BANSHEE)); ++ read_unlock_dk(h->tree); ++ if (inside) { ++ h->result = zload(vroot); ++ if (h->result == 0) { ++ /* search for key in vroot. */ ++ result = cbk_node_lookup(h); ++ zrelse(vroot); /*h->active_lh->node); */ ++ if (h->active_lh->node != vroot) { ++ result = LOOKUP_REST; ++ } else if (result == LOOKUP_CONT) { ++ move_lh(h->parent_lh, h->active_lh); ++ h->flags &= ~CBK_DKSET; ++ } ++ } ++ } ++ } ++ ++ zput(vroot); ++ ++ if (IS_CBKERR(h->result) || result == LOOKUP_REST) ++ hput(h); ++ return result; ++} ++ ++/* main function that handles common parts of tree traversal: starting ++ (fake znode handling), restarts, error handling, completion */ ++static lookup_result traverse_tree(cbk_handle * h/* search handle */) ++{ ++ int done; ++ int iterations; ++ int vroot_used; ++ ++ assert("nikita-365", h != NULL); ++ assert("nikita-366", h->tree != NULL); ++ assert("nikita-367", h->key != NULL); ++ assert("nikita-368", h->coord != NULL); ++ assert("nikita-369", (h->bias == FIND_EXACT) ++ || (h->bias == FIND_MAX_NOT_MORE_THAN)); ++ assert("nikita-370", h->stop_level >= LEAF_LEVEL); ++ assert("nikita-2949", !(h->flags & CBK_DKSET)); ++ assert("zam-355", lock_stack_isclean(get_current_lock_stack())); ++ ++ done = 0; ++ iterations = 0; ++ vroot_used = 0; ++ ++ /* loop for restarts */ ++restart: ++ ++ assert("nikita-3024", reiser4_schedulable()); ++ ++ h->result = CBK_COORD_FOUND; ++ /* connect_znode() needs it */ ++ h->ld_key = *reiser4_min_key(); ++ h->rd_key = *reiser4_max_key(); ++ h->flags |= CBK_DKSET; ++ h->error = NULL; ++ ++ if (!vroot_used && h->object != NULL) { ++ vroot_used = 1; ++ done = prepare_object_lookup(h); ++ if (done == LOOKUP_REST) ++ goto restart; ++ else if (done == LOOKUP_DONE) ++ return h->result; ++ } ++ if (h->parent_lh->node == NULL) { ++ done = ++ get_uber_znode(h->tree, ZNODE_READ_LOCK, ZNODE_LOCK_LOPRI, ++ h->parent_lh); ++ ++ assert("nikita-1637", done != -E_DEADLOCK); ++ ++ h->block = h->tree->root_block; ++ h->level = h->tree->height; ++ h->coord->node = h->parent_lh->node; ++ ++ if (done != 0) ++ return done; ++ } ++ ++ /* loop descending a tree */ ++ while (!done) { ++ ++ if (unlikely((iterations > REISER4_CBK_ITERATIONS_LIMIT) && ++ IS_POW(iterations))) { ++ warning("nikita-1481", "Too many iterations: %i", ++ iterations); ++ reiser4_print_key("key", h->key); ++ ++iterations; ++ } else if (unlikely(iterations > REISER4_MAX_CBK_ITERATIONS)) { ++ h->error = ++ "reiser-2018: Too many iterations. Tree corrupted, or (less likely) starvation occurring."; ++ h->result = RETERR(-EIO); ++ break; ++ } ++ switch (cbk_level_lookup(h)) { ++ case LOOKUP_CONT: ++ move_lh(h->parent_lh, h->active_lh); ++ continue; ++ default: ++ wrong_return_value("nikita-372", "cbk_level"); ++ case LOOKUP_DONE: ++ done = 1; ++ break; ++ case LOOKUP_REST: ++ hput(h); ++ /* deadlock avoidance is normal case. */ ++ if (h->result != -E_DEADLOCK) ++ ++iterations; ++ reiser4_preempt_point(); ++ goto restart; ++ } ++ } ++ /* that's all. The rest is error handling */ ++ if (unlikely(h->error != NULL)) { ++ warning("nikita-373", "%s: level: %i, " ++ "lock_level: %i, stop_level: %i " ++ "lock_mode: %s, bias: %s", ++ h->error, h->level, h->lock_level, h->stop_level, ++ lock_mode_name(h->lock_mode), bias_name(h->bias)); ++ reiser4_print_address("block", &h->block); ++ reiser4_print_key("key", h->key); ++ print_coord_content("coord", h->coord); ++ } ++ /* `unlikely' error case */ ++ if (unlikely(IS_CBKERR(h->result))) { ++ /* failure. do cleanup */ ++ hput(h); ++ } else { ++ assert("nikita-1605", WITH_DATA_RET ++ (h->coord->node, 1, ++ ergo((h->result == CBK_COORD_FOUND) && ++ (h->bias == FIND_EXACT) && ++ (!node_is_empty(h->coord->node)), ++ coord_is_existing_item(h->coord)))); ++ } ++ return h->result; ++} ++ ++/* find delimiting keys of child ++ ++ Determine left and right delimiting keys for child pointed to by ++ @parent_coord. ++ ++*/ ++static void find_child_delimiting_keys(znode * parent /* parent znode, passed ++ * locked */ , ++ const coord_t *parent_coord ++ /* coord where pointer ++ * to child is stored ++ */ , ++ reiser4_key * ld /* where to store left ++ * delimiting key */ , ++ reiser4_key * rd /* where to store right ++ * delimiting key */ ) ++{ ++ coord_t neighbor; ++ ++ assert("nikita-1484", parent != NULL); ++ assert_rw_locked(&(znode_get_tree(parent)->dk_lock)); ++ ++ coord_dup(&neighbor, parent_coord); ++ ++ if (neighbor.between == AT_UNIT) ++ /* imitate item ->lookup() behavior. */ ++ neighbor.between = AFTER_UNIT; ++ ++ if (coord_set_to_left(&neighbor) == 0) ++ unit_key_by_coord(&neighbor, ld); ++ else { ++ assert("nikita-14851", 0); ++ *ld = *znode_get_ld_key(parent); ++ } ++ ++ coord_dup(&neighbor, parent_coord); ++ if (neighbor.between == AT_UNIT) ++ neighbor.between = AFTER_UNIT; ++ if (coord_set_to_right(&neighbor) == 0) ++ unit_key_by_coord(&neighbor, rd); ++ else ++ *rd = *znode_get_rd_key(parent); ++} ++ ++/* ++ * setup delimiting keys for a child ++ * ++ * @parent parent node ++ * ++ * @coord location in @parent where pointer to @child is ++ * ++ * @child child node ++ */ ++int ++set_child_delimiting_keys(znode * parent, const coord_t *coord, znode * child) ++{ ++ reiser4_tree *tree; ++ ++ assert("nikita-2952", ++ znode_get_level(parent) == znode_get_level(coord->node)); ++ ++ /* fast check without taking dk lock. This is safe, because ++ * JNODE_DKSET is never cleared once set. */ ++ if (!ZF_ISSET(child, JNODE_DKSET)) { ++ tree = znode_get_tree(parent); ++ write_lock_dk(tree); ++ if (likely(!ZF_ISSET(child, JNODE_DKSET))) { ++ find_child_delimiting_keys(parent, coord, ++ &child->ld_key, ++ &child->rd_key); ++ ON_DEBUG(child->ld_key_version = ++ atomic_inc_return(&delim_key_version); ++ child->rd_key_version = ++ atomic_inc_return(&delim_key_version);); ++ ZF_SET(child, JNODE_DKSET); ++ } ++ write_unlock_dk(tree); ++ return 1; ++ } ++ return 0; ++} ++ ++/* Perform tree lookup at one level. This is called from cbk_traverse() ++ function that drives lookup through tree and calls cbk_node_lookup() to ++ perform lookup within one node. ++ ++ See comments in a code. ++*/ ++static level_lookup_result cbk_level_lookup(cbk_handle * h/* search handle */) ++{ ++ int ret; ++ int setdk; ++ int ldkeyset = 0; ++ reiser4_key ldkey; ++ reiser4_key key; ++ znode *active; ++ ++ assert("nikita-3025", reiser4_schedulable()); ++ ++ /* acquire reference to @active node */ ++ active = zget(h->tree->subvol, &h->block, h->parent_lh->node, h->level, ++ reiser4_ctx_gfp_mask_get()); ++ ++ if (IS_ERR(active)) { ++ h->result = PTR_ERR(active); ++ return LOOKUP_DONE; ++ } ++ ++ /* lock @active */ ++ h->result = longterm_lock_znode(h->active_lh, ++ active, ++ cbk_lock_mode(h->level, h), ++ ZNODE_LOCK_LOPRI); ++ /* longterm_lock_znode() acquires additional reference to znode (which ++ will be later released by longterm_unlock_znode()). Release ++ reference acquired by zget(). ++ */ ++ zput(active); ++ if (unlikely(h->result != 0)) ++ goto fail_or_restart; ++ ++ setdk = 0; ++ /* if @active is accessed for the first time, setup delimiting keys on ++ it. Delimiting keys are taken from the parent node. See ++ setup_delimiting_keys() for details. ++ */ ++ if (h->flags & CBK_DKSET) { ++ setdk = setup_delimiting_keys(h); ++ h->flags &= ~CBK_DKSET; ++ } else { ++ znode *parent; ++ ++ parent = h->parent_lh->node; ++ h->result = zload(parent); ++ if (unlikely(h->result != 0)) ++ goto fail_or_restart; ++ ++ if (!ZF_ISSET(active, JNODE_DKSET)) ++ setdk = set_child_delimiting_keys(parent, ++ h->coord, active); ++ else { ++ read_lock_dk(h->tree); ++ find_child_delimiting_keys(parent, h->coord, &ldkey, ++ &key); ++ read_unlock_dk(h->tree); ++ ldkeyset = 1; ++ } ++ zrelse(parent); ++ } ++ ++ /* this is ugly kludge. Reminder: this is necessary, because ++ ->lookup() method returns coord with ->between field probably set ++ to something different from AT_UNIT. ++ */ ++ h->coord->between = AT_UNIT; ++ ++ if (znode_just_created(active) && (h->coord->node != NULL)) { ++ write_lock_tree(); ++ /* if we are going to load znode right now, setup ++ ->in_parent: coord where pointer to this node is stored in ++ parent. ++ */ ++ coord_to_parent_coord(h->coord, &active->in_parent); ++ write_unlock_tree(); ++ } ++ ++ /* check connectedness without holding tree lock---false negatives ++ * will be re-checked by connect_znode(), and false positives are ++ * impossible---@active cannot suddenly turn into unconnected ++ * state. */ ++ if (!znode_is_connected(active)) { ++ h->result = connect_znode(h->coord, active); ++ if (unlikely(h->result != 0)) { ++ put_parent(h); ++ goto fail_or_restart; ++ } ++ } ++ ++ jload_prefetch(ZJNODE(active)); ++ ++ if (setdk) ++ update_stale_dk(h->tree, active); ++ ++ /* put_parent() cannot be called earlier, because connect_znode() ++ assumes parent node is referenced; */ ++ put_parent(h); ++ ++ if ((!znode_contains_key_lock(active, h->key) && ++ (h->flags & CBK_TRUST_DK)) ++ || ZF_ISSET(active, JNODE_HEARD_BANSHEE)) { ++ /* 1. key was moved out of this node while this thread was ++ waiting for the lock. Restart. More elaborate solution is ++ to determine where key moved (to the left, or to the right) ++ and try to follow it through sibling pointers. ++ ++ 2. or, node itself is going to be removed from the ++ tree. Release lock and restart. ++ */ ++ h->result = -E_REPEAT; ++ } ++ if (h->result == -E_REPEAT) ++ return LOOKUP_REST; ++ ++ h->result = zload_ra(active, h->ra_info); ++ if (h->result) ++ return LOOKUP_DONE; ++ ++ /* sanity checks */ ++ if (sanity_check(h)) { ++ zrelse(active); ++ return LOOKUP_DONE; ++ } ++ ++ /* check that key of leftmost item in the @active is the same as in ++ * its parent */ ++ if (ldkeyset && !node_is_empty(active) && ++ !keyeq(leftmost_key_in_node(active, &key), &ldkey)) { ++ warning("vs-3533", "Keys are inconsistent. Fsck?"); ++ reiser4_print_key("inparent", &ldkey); ++ reiser4_print_key("inchild", &key); ++ h->result = RETERR(-EIO); ++ zrelse(active); ++ return LOOKUP_DONE; ++ } ++ ++ if (h->object != NULL) ++ handle_vroot(h->object, active); ++ ++ ret = cbk_node_lookup(h); ++ ++ /* h->active_lh->node might change, but active is yet to be zrelsed */ ++ zrelse(active); ++ ++ return ret; ++ ++fail_or_restart: ++ if (h->result == -E_DEADLOCK) ++ return LOOKUP_REST; ++ return LOOKUP_DONE; ++} ++ ++#if REISER4_DEBUG ++/* check left and right delimiting keys of a znode */ ++void check_dkeys(znode * node) ++{ ++ znode *left; ++ znode *right; ++ reiser4_tree *tree = znode_get_tree(node); ++ ++ read_lock_tree(); ++ read_lock_dk(tree); ++ ++ assert("vs-1710", znode_is_any_locked(node)); ++ assert("vs-1197", ++ !keygt(znode_get_ld_key(node), znode_get_rd_key(node))); ++ ++ left = node->left; ++ right = node->right; ++ ++ if (ZF_ISSET(node, JNODE_LEFT_CONNECTED) && ZF_ISSET(node, JNODE_DKSET) ++ && left != NULL && ZF_ISSET(left, JNODE_DKSET)) ++ /* check left neighbor. Note that left neighbor is not locked, ++ so it might get wrong delimiting keys therefore */ ++ assert("vs-1198", ++ (keyeq(znode_get_rd_key(left), znode_get_ld_key(node)) ++ || ZF_ISSET(left, JNODE_HEARD_BANSHEE))); ++ ++ if (ZF_ISSET(node, JNODE_RIGHT_CONNECTED) && ZF_ISSET(node, JNODE_DKSET) ++ && right != NULL && ZF_ISSET(right, JNODE_DKSET)) ++ /* check right neighbor. Note that right neighbor is not ++ locked, so it might get wrong delimiting keys therefore */ ++ assert("vs-1199", ++ (keyeq(znode_get_rd_key(node), znode_get_ld_key(right)) ++ || ZF_ISSET(right, JNODE_HEARD_BANSHEE))); ++ ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++} ++#endif ++ ++/* true if @key is left delimiting key of @node */ ++static int key_is_ld(znode * node, const reiser4_key * key) ++{ ++ int ld; ++ ++ assert("nikita-1716", node != NULL); ++ assert("nikita-1758", key != NULL); ++ ++ read_lock_dk(znode_get_tree(node)); ++ assert("nikita-1759", znode_contains_key(node, key)); ++ ld = keyeq(znode_get_ld_key(node), key); ++ read_unlock_dk(znode_get_tree(node)); ++ return ld; ++} ++ ++/* Process one node during tree traversal. ++ ++ This is called by cbk_level_lookup(). */ ++static level_lookup_result cbk_node_lookup(cbk_handle * h/* search handle */) ++{ ++ /* node plugin of @active */ ++ node_plugin *nplug; ++ /* item plugin of item that was found */ ++ item_plugin *iplug; ++ /* search bias */ ++ lookup_bias node_bias; ++ /* node we are operating upon */ ++ znode *active; ++ /* tree we are searching in */ ++ reiser4_tree *tree; ++ /* result */ ++ int result; ++ ++ assert("nikita-379", h != NULL); ++ ++ active = h->active_lh->node; ++ tree = h->tree; ++ ++ nplug = active->nplug; ++ assert("nikita-380", nplug != NULL); ++ ++ //ON_DEBUG(check_dkeys(active)); ++ ++ /* return item from "active" node with maximal key not greater than ++ "key" */ ++ node_bias = h->bias; ++ result = nplug->lookup(active, h->key, node_bias, h->coord); ++ if (unlikely(result != NS_FOUND && result != NS_NOT_FOUND)) { ++ /* error occurred */ ++ h->result = result; ++ return LOOKUP_DONE; ++ } ++ if (h->level == h->stop_level) { ++ /* welcome to the stop level */ ++ assert("nikita-381", h->coord->node == active); ++ if (result == NS_FOUND) { ++ /* success of tree lookup */ ++ if (!(h->flags & CBK_UNIQUE) ++ && key_is_ld(active, h->key)) ++ return search_to_left(h); ++ else ++ h->result = CBK_COORD_FOUND; ++ } else { ++ h->result = CBK_COORD_NOTFOUND; ++ } ++ if (!(h->flags & CBK_IN_CACHE)) ++ cbk_cache_add(active); ++ return LOOKUP_DONE; ++ } ++ ++ if (h->level > TWIG_LEVEL && result == NS_NOT_FOUND) { ++ h->error = "not found on internal node"; ++ h->result = result; ++ return LOOKUP_DONE; ++ } ++ ++ assert("vs-361", h->level > h->stop_level); ++ ++ if (handle_eottl(h, &result)) { ++ assert("vs-1674", (result == LOOKUP_DONE || ++ result == LOOKUP_REST)); ++ return result; ++ } ++ ++ /* go down to next level */ ++ check_me("vs-12", zload(h->coord->node) == 0); ++ assert("nikita-2116", item_is_internal(h->coord)); ++ iplug = item_plugin_by_coord(h->coord); ++ iplug->s.internal.down_link(h->coord, h->key, &h->block); ++ zrelse(h->coord->node); ++ --h->level; ++ return LOOKUP_CONT; /* continue */ ++} ++ ++/* scan cbk_cache slots looking for a match for @h */ ++static int cbk_cache_scan_slots(cbk_handle * h/* cbk handle */) ++{ ++ level_lookup_result llr; ++ znode *node; ++ reiser4_tree *tree; ++ cbk_cache_slot *slot; ++ cbk_cache *cache; ++ tree_level level; ++ int isunique; ++ const reiser4_key *key; ++ int result; ++ ++ assert("nikita-1317", h != NULL); ++ assert("nikita-1315", h->tree != NULL); ++ assert("nikita-1316", h->key != NULL); ++ ++ tree = h->tree; ++ cache = &tree->cbk_cache; ++ if (cache->nr_slots == 0) ++ /* size of cbk cache was set to 0 by mount time option. */ ++ return RETERR(-ENOENT); ++ ++ assert("nikita-2474", cbk_cache_invariant(cache)); ++ node = NULL; /* to keep gcc happy */ ++ level = h->level; ++ key = h->key; ++ isunique = h->flags & CBK_UNIQUE; ++ result = RETERR(-ENOENT); ++ ++ /* ++ * this is time-critical function and dragons had, hence, been settled ++ * here. ++ * ++ * Loop below scans cbk cache slots trying to find matching node with ++ * suitable range of delimiting keys and located at the h->level. ++ * ++ * Scan is done under cbk cache spin lock that protects slot->node ++ * pointers. If suitable node is found we want to pin it in ++ * memory. But slot->node can point to the node with x_count 0 ++ * (unreferenced). Such node can be recycled at any moment, or can ++ * already be in the process of being recycled (within jput()). ++ * ++ * As we found node in the cbk cache, it means that jput() hasn't yet ++ * called cbk_cache_invalidate(). ++ * ++ * We acquire reference to the node without holding tree lock, and ++ * later, check node's RIP bit. This avoids races with jput(). ++ */ ++ ++ rcu_read_lock(); ++ read_lock(&((cbk_cache *)cache)->guard); ++ ++ slot = list_entry(cache->lru.next, cbk_cache_slot, lru); ++ slot = list_entry(slot->lru.prev, cbk_cache_slot, lru); ++ BUG_ON(&slot->lru != &cache->lru);/*????*/ ++ while (1) { ++ ++ slot = list_entry(slot->lru.next, cbk_cache_slot, lru); ++ ++ if (&cache->lru != &slot->lru) ++ node = slot->node; ++ else ++ node = NULL; ++ ++ if (unlikely(node == NULL)) ++ break; ++ ++ /* ++ * this is (hopefully) the only place in the code where we are ++ * working with delimiting keys without holding dk lock. This ++ * is fine here, because this is only "guess" anyway---keys ++ * are rechecked under dk lock below. ++ */ ++ if (znode_get_level(node) == level && ++ /* reiser4_min_key < key < reiser4_max_key */ ++ znode_contains_key_strict(node, key, isunique)) { ++ zref(node); ++ result = 0; ++ spin_lock_prefetch(&get_current_super_private()->tree_lock); ++ break; ++ } ++ } ++ read_unlock(&((cbk_cache *)cache)->guard); ++ ++ assert("nikita-2475", cbk_cache_invariant(cache)); ++ ++ if (unlikely(result == 0 && ZF_ISSET(node, JNODE_RIP))) ++ result = -ENOENT; ++ ++ rcu_read_unlock(); ++ ++ if (result != 0) { ++ h->result = CBK_COORD_NOTFOUND; ++ return RETERR(-ENOENT); ++ } ++ ++ result = ++ longterm_lock_znode(h->active_lh, node, cbk_lock_mode(level, h), ++ ZNODE_LOCK_LOPRI); ++ zput(node); ++ if (result != 0) ++ return result; ++ result = zload(node); ++ if (result != 0) ++ return result; ++ ++ /* recheck keys */ ++ read_lock_dk(tree); ++ result = (znode_contains_key_strict(node, key, isunique) && ++ !ZF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ read_unlock_dk(tree); ++ if (result) { ++ /* do lookup inside node */ ++ llr = cbk_node_lookup(h); ++ /* if cbk_node_lookup() wandered to another node (due to eottl ++ or non-unique keys), adjust @node */ ++ /*node = h->active_lh->node; */ ++ ++ if (llr != LOOKUP_DONE) { ++ /* restart or continue on the next level */ ++ result = RETERR(-ENOENT); ++ } else if (IS_CBKERR(h->result)) ++ /* io or oom */ ++ result = RETERR(-ENOENT); ++ else { ++ /* good. Either item found or definitely not found. */ ++ result = 0; ++ ++ write_lock(&(cache->guard)); ++ if (slot->node == h->active_lh->node) { ++ /* if this node is still in cbk cache---move ++ its slot to the head of the LRU list. */ ++ list_move(&slot->lru, &cache->lru); ++ } ++ write_unlock(&(cache->guard)); ++ } ++ } else { ++ /* race. While this thread was waiting for the lock, node was ++ rebalanced and item we are looking for, shifted out of it ++ (if it ever was here). ++ ++ Continuing scanning is almost hopeless: node key range was ++ moved to, is almost certainly at the beginning of the LRU ++ list at this time, because it's hot, but restarting ++ scanning from the very beginning is complex. Just return, ++ so that cbk() will be performed. This is not that ++ important, because such races should be rare. Are they? ++ */ ++ result = RETERR(-ENOENT); /* -ERAUGHT */ ++ } ++ zrelse(node); ++ assert("nikita-2476", cbk_cache_invariant(cache)); ++ return result; ++} ++ ++/* look for item with given key in the coord cache ++ ++ This function, called by coord_by_key(), scans "coord cache" (&cbk_cache) ++ which is a small LRU list of znodes accessed lately. For each znode in ++ znode in this list, it checks whether key we are looking for fits into key ++ range covered by this node. If so, and in addition, node lies at allowed ++ level (this is to handle extents on a twig level), node is locked, and ++ lookup inside it is performed. ++ ++ we need a measurement of the cost of this cache search compared to the cost ++ of coord_by_key. ++ ++*/ ++static int cbk_cache_search(cbk_handle * h/* cbk handle */) ++{ ++ int result = 0; ++ tree_level level; ++ ++ /* add CBK_IN_CACHE to the handle flags. This means that ++ * cbk_node_lookup() assumes that cbk_cache is scanned and would add ++ * found node to the cache. */ ++ h->flags |= CBK_IN_CACHE; ++ for (level = h->stop_level; level <= h->lock_level; ++level) { ++ h->level = level; ++ result = cbk_cache_scan_slots(h); ++ if (result != 0) { ++ done_lh(h->active_lh); ++ done_lh(h->parent_lh); ++ } else { ++ assert("nikita-1319", !IS_CBKERR(h->result)); ++ break; ++ } ++ } ++ h->flags &= ~CBK_IN_CACHE; ++ return result; ++} ++ ++/* type of lock we want to obtain during tree traversal. On stop level ++ we want type of lock user asked for, on upper levels: read lock. */ ++znode_lock_mode cbk_lock_mode(tree_level level, cbk_handle * h) ++{ ++ assert("nikita-382", h != NULL); ++ ++ return (level <= h->lock_level) ? h->lock_mode : ZNODE_READ_LOCK; ++} ++ ++/* update outdated delimiting keys */ ++static void stale_dk(reiser4_tree * tree, znode * node) ++{ ++ znode *right; ++ ++ read_lock_tree(); ++ write_lock_dk(tree); ++ right = node->right; ++ ++ if (ZF_ISSET(node, JNODE_RIGHT_CONNECTED) && ++ right && ZF_ISSET(right, JNODE_DKSET) && ++ !keyeq(znode_get_rd_key(node), znode_get_ld_key(right))) ++ znode_set_rd_key(node, znode_get_ld_key(right)); ++ ++ write_unlock_dk(tree); ++ read_unlock_tree(); ++} ++ ++/* check for possibly outdated delimiting keys, and update them if ++ * necessary. */ ++static void update_stale_dk(reiser4_tree * tree, znode * node) ++{ ++ znode *right; ++ reiser4_key rd; ++ ++ read_lock_tree(); ++ read_lock_dk(tree); ++ rd = *znode_get_rd_key(node); ++ right = node->right; ++ if (unlikely(ZF_ISSET(node, JNODE_RIGHT_CONNECTED) && ++ right && ZF_ISSET(right, JNODE_DKSET) && ++ !keyeq(&rd, znode_get_ld_key(right)))) { ++ assert("nikita-38211", ZF_ISSET(node, JNODE_DKSET)); ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++ stale_dk(tree, node); ++ return; ++ } ++ read_unlock_dk(tree); ++ read_unlock_tree(); ++} ++ ++/* ++ * handle searches a the non-unique key. ++ * ++ * Suppose that we are looking for an item with possibly non-unique key 100. ++ * ++ * Root node contains two pointers: one to a node with left delimiting key 0, ++ * and another to a node with left delimiting key 100. Item we interested in ++ * may well happen in the sub-tree rooted at the first pointer. ++ * ++ * To handle this search_to_left() is called when search reaches stop ++ * level. This function checks it is _possible_ that item we are looking for ++ * is in the left neighbor (this can be done by comparing delimiting keys) and ++ * if so, tries to lock left neighbor (this is low priority lock, so it can ++ * deadlock, tree traversal is just restarted if it did) and then checks ++ * whether left neighbor actually contains items with our key. ++ * ++ * Note that this is done on the stop level only. It is possible to try such ++ * left-check on each level, but as duplicate keys are supposed to be rare ++ * (very unlikely that more than one node is completely filled with items with ++ * duplicate keys), it sis cheaper to scan to the left on the stop level once. ++ * ++ */ ++static level_lookup_result search_to_left(cbk_handle * h/* search handle */) ++{ ++ level_lookup_result result; ++ coord_t *coord; ++ znode *node; ++ znode *neighbor; ++ ++ lock_handle lh; ++ ++ assert("nikita-1761", h != NULL); ++ assert("nikita-1762", h->level == h->stop_level); ++ ++ init_lh(&lh); ++ coord = h->coord; ++ node = h->active_lh->node; ++ assert("nikita-1763", coord_is_leftmost_unit(coord)); ++ ++ h->result = ++ reiser4_get_left_neighbor(&lh, node, (int)h->lock_mode, ++ GN_CAN_USE_UPPER_LEVELS); ++ neighbor = NULL; ++ switch (h->result) { ++ case -E_DEADLOCK: ++ result = LOOKUP_REST; ++ break; ++ case 0:{ ++ node_plugin *nplug; ++ coord_t crd; ++ lookup_bias bias; ++ ++ neighbor = lh.node; ++ h->result = zload(neighbor); ++ if (h->result != 0) { ++ result = LOOKUP_DONE; ++ break; ++ } ++ ++ nplug = neighbor->nplug; ++ ++ coord_init_zero(&crd); ++ bias = h->bias; ++ h->bias = FIND_EXACT; ++ h->result = ++ nplug->lookup(neighbor, h->key, h->bias, &crd); ++ h->bias = bias; ++ ++ if (h->result == NS_NOT_FOUND) { ++ case -E_NO_NEIGHBOR: ++ h->result = CBK_COORD_FOUND; ++ if (!(h->flags & CBK_IN_CACHE)) ++ cbk_cache_add(node); ++ default: /* some other error */ ++ result = LOOKUP_DONE; ++ } else if (h->result == NS_FOUND) { ++ read_lock_dk(znode_get_tree(neighbor)); ++ h->rd_key = *znode_get_ld_key(node); ++ leftmost_key_in_node(neighbor, &h->ld_key); ++ read_unlock_dk(znode_get_tree(neighbor)); ++ h->flags |= CBK_DKSET; ++ ++ h->block = *znode_get_block(neighbor); ++ /* clear coord->node so that cbk_level_lookup() ++ wouldn't overwrite parent hint in neighbor. ++ ++ Parent hint was set up by ++ reiser4_get_left_neighbor() ++ */ ++ /* FIXME: why do we have to spinlock here? */ ++ write_lock_tree(); ++ h->coord->node = NULL; ++ write_unlock_tree(); ++ result = LOOKUP_CONT; ++ } else { ++ result = LOOKUP_DONE; ++ } ++ if (neighbor != NULL) ++ zrelse(neighbor); ++ } ++ } ++ done_lh(&lh); ++ return result; ++} ++ ++/* debugging aid: return symbolic name of search bias */ ++static const char *bias_name(lookup_bias bias/* bias to get name of */) ++{ ++ if (bias == FIND_EXACT) ++ return "exact"; ++ else if (bias == FIND_MAX_NOT_MORE_THAN) ++ return "left-slant"; ++/* else if( bias == RIGHT_SLANT_BIAS ) */ ++/* return "right-bias"; */ ++ else { ++ static char buf[30]; ++ ++ sprintf(buf, "unknown: %i", bias); ++ return buf; ++ } ++} ++ ++#if REISER4_DEBUG ++/* debugging aid: print human readable information about @p */ ++void print_coord_content(const char *prefix /* prefix to print */ , ++ coord_t *p/* coord to print */) ++{ ++ reiser4_key key; ++ ++ if (p == NULL) { ++ printk("%s: null\n", prefix); ++ return; ++ } ++ if ((p->node != NULL) && znode_is_loaded(p->node) ++ && coord_is_existing_item(p)) ++ printk("%s: data: %p, length: %i\n", prefix, ++ item_body_by_coord(p), item_length_by_coord(p)); ++ if (znode_is_loaded(p->node)) { ++ item_key_by_coord(p, &key); ++ reiser4_print_key(prefix, &key); ++ } ++} ++ ++/* debugging aid: print human readable information about @block */ ++void reiser4_print_address(const char *prefix /* prefix to print */ , ++ const reiser4_block_nr * block/* block number to print */) ++{ ++ printk("%s: %s\n", prefix, sprint_address(block)); ++} ++#endif ++ ++/* return string containing human readable representation of @block */ ++char *sprint_address(const reiser4_block_nr * ++ block/* block number to print */) ++{ ++ static char address[30]; ++ ++ if (block == NULL) ++ sprintf(address, "null"); ++ else if (reiser4_blocknr_is_fake(block)) ++ sprintf(address, "%llx", (unsigned long long)(*block)); ++ else ++ sprintf(address, "%llu", (unsigned long long)(*block)); ++ return address; ++} ++ ++/* release parent node during traversal */ ++static void put_parent(cbk_handle * h/* search handle */) ++{ ++ assert("nikita-383", h != NULL); ++ if (h->parent_lh->node != NULL) ++ longterm_unlock_znode(h->parent_lh); ++} ++ ++/* helper function used by coord_by_key(): release reference to parent znode ++ stored in handle before processing its child. */ ++static void hput(cbk_handle * h/* search handle */) ++{ ++ assert("nikita-385", h != NULL); ++ done_lh(h->parent_lh); ++ done_lh(h->active_lh); ++} ++ ++/* Helper function used by cbk(): update delimiting keys of child node (stored ++ in h->active_lh->node) using key taken from parent on the parent level. */ ++static int setup_delimiting_keys(cbk_handle * h/* search handle */) ++{ ++ znode *active; ++ reiser4_tree *tree; ++ ++ assert("nikita-1088", h != NULL); ++ ++ active = h->active_lh->node; ++ ++ /* fast check without taking dk lock. This is safe, because ++ * JNODE_DKSET is never cleared once set. */ ++ if (!ZF_ISSET(active, JNODE_DKSET)) { ++ tree = znode_get_tree(active); ++ write_lock_dk(tree); ++ if (!ZF_ISSET(active, JNODE_DKSET)) { ++ znode_set_ld_key(active, &h->ld_key); ++ znode_set_rd_key(active, &h->rd_key); ++ ZF_SET(active, JNODE_DKSET); ++ } ++ write_unlock_dk(tree); ++ return 1; ++ } ++ return 0; ++} ++ ++/* check consistency of fields */ ++static int sanity_check(cbk_handle * h/* search handle */) ++{ ++ assert("nikita-384", h != NULL); ++ ++ if (h->level < h->stop_level) { ++ h->error = "Buried under leaves"; ++ h->result = RETERR(-EIO); ++ return LOOKUP_DONE; ++ } else if (!reiser4_subvol_blocknr_is_sane(h->tree->subvol, ++ &h->block)) { ++ h->error = "bad block number"; ++ h->result = RETERR(-EIO); ++ return LOOKUP_DONE; ++ } else ++ return 0; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/status_flags.c linux-5.10.2/fs/reiser4/status_flags.c +--- linux-5.10.2.orig/fs/reiser4/status_flags.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/status_flags.c 2020-12-23 16:07:46.134813363 +0100 +@@ -0,0 +1,180 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Functions that deal with reiser4 status block, query status and update it, ++ * if needed */ ++ ++#include ++#include ++#include ++#include ++#include "debug.h" ++#include "dformat.h" ++#include "status_flags.h" ++#include "super.h" ++ ++/* This is our end I/O handler that marks page uptodate if IO was successful. ++ It also unconditionally unlocks the page, so we can see that io was done. ++ We do not free bio, because we hope to reuse that. */ ++static void reiser4_status_endio(struct bio *bio) ++{ ++ if (!bio->bi_status) ++ SetPageUptodate(bio->bi_io_vec->bv_page); ++ else { ++ ClearPageUptodate(bio->bi_io_vec->bv_page); ++ SetPageError(bio->bi_io_vec->bv_page); ++ } ++ unlock_page(bio->bi_io_vec->bv_page); ++} ++ ++/* Initialise status code. This is expected to be called from the disk format ++ code. block paremeter is where status block lives. */ ++int reiser4_status_init(reiser4_subvol *subv, reiser4_block_nr block) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ struct reiser4_status *statuspage; ++ struct bio *bio; ++ struct page *page; ++ ++ subv->status_page = NULL; ++ subv->status_bio = NULL; ++ ++ page = alloc_pages(reiser4_ctx_gfp_mask_get(), 0); ++ if (!page) ++ return -ENOMEM; ++ ++ bio = bio_alloc(reiser4_ctx_gfp_mask_get(), 1); ++ if (bio != NULL) { ++ bio->bi_iter.bi_sector = block * (sb->s_blocksize >> 9); ++ bio_set_dev(bio, subv->bdev); ++ bio->bi_io_vec[0].bv_page = page; ++ bio->bi_io_vec[0].bv_len = sb->s_blocksize; ++ bio->bi_io_vec[0].bv_offset = 0; ++ bio->bi_vcnt = 1; ++ bio->bi_iter.bi_size = sb->s_blocksize; ++ bio->bi_end_io = reiser4_status_endio; ++ } else { ++ __free_pages(page, 0); ++ return -ENOMEM; ++ } ++ lock_page(page); ++ bio_set_op_attrs(bio, READ, 0); ++ submit_bio(bio); ++ wait_on_page_locked(page); ++ if (!PageUptodate(page)) { ++ warning("green-2007", ++ "I/O error while tried to read status page\n"); ++ return -EIO; ++ } ++ ++ statuspage = (struct reiser4_status *)kmap_atomic(page); ++ if (memcmp ++ (statuspage->magic, REISER4_STATUS_MAGIC, ++ sizeof(REISER4_STATUS_MAGIC))) { ++ /* Magic does not match. */ ++ kunmap_atomic((char *)statuspage); ++ warning("green-2008", "Wrong magic in status block\n"); ++ __free_pages(page, 0); ++ bio_put(bio); ++ return -EINVAL; ++ } ++ kunmap_atomic((char *)statuspage); ++ ++ subv->status_page = page; ++ subv->status_bio = bio; ++ return 0; ++} ++ ++/** ++ * Query the status of fs. Returns if the FS can be safely mounted. ++ * Also if "status" and "extended" parameters are given, it will fill ++ * actual parts of status from disk there ++ */ ++int reiser4_status_query(reiser4_subvol *subv, u64 *status, u64 *extended) ++{ ++ struct reiser4_status *statuspage; ++ int retval; ++ ++ if (!subv->status_page) ++ /* No status page? */ ++ return REISER4_STATUS_MOUNT_UNKNOWN; ++ ++ statuspage = (struct reiser4_status *)kmap_atomic(subv->status_page); ++ ++ switch ((long)le64_to_cpu(get_unaligned(&statuspage->status))) { ++ /* FIXME: this cast is a hack for 32 bit arches to work. */ ++ case REISER4_STATUS_OK: ++ retval = REISER4_STATUS_MOUNT_OK; ++ break; ++ case REISER4_STATUS_CORRUPTED: ++ retval = REISER4_STATUS_MOUNT_WARN; ++ break; ++ case REISER4_STATUS_DAMAGED: ++ case REISER4_STATUS_DESTROYED: ++ case REISER4_STATUS_IOERROR: ++ retval = REISER4_STATUS_MOUNT_RO; ++ break; ++ default: ++ retval = REISER4_STATUS_MOUNT_UNKNOWN; ++ break; ++ } ++ ++ if (status) ++ *status = le64_to_cpu(get_unaligned(&statuspage->status)); ++ if (extended) ++ *extended = le64_to_cpu(get_unaligned(&statuspage->extended_status)); ++ ++ kunmap_atomic((char *)statuspage); ++ return retval; ++} ++ ++/* This function should be called when something bad happens (e.g. from ++ reiser4_panic). It fills the status structure and tries to push it to disk.*/ ++int reiser4_status_write(reiser4_subvol *subv, ++ __u64 status, __u64 extended_status, char *message) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ struct reiser4_status *statuspage; ++ struct bio *bio = subv->status_bio; ++ ++ if (!subv->status_page) ++ /* No status page? */ ++ return -1; ++ ++ statuspage = (struct reiser4_status *)kmap_atomic(subv->status_page); ++ ++ put_unaligned(cpu_to_le64(status), &statuspage->status); ++ put_unaligned(cpu_to_le64(extended_status), &statuspage->extended_status); ++ strncpy(statuspage->texterror, message, REISER4_TEXTERROR_LEN); ++ ++ kunmap_atomic((char *)statuspage); ++ bio_reset(bio); ++ bio_set_dev(bio, subv->bdev); ++ bio->bi_io_vec[0].bv_page = subv->status_page; ++ bio->bi_io_vec[0].bv_len = sb->s_blocksize; ++ bio->bi_io_vec[0].bv_offset = 0; ++ bio->bi_vcnt = 1; ++ bio->bi_iter.bi_size = sb->s_blocksize; ++ bio->bi_end_io = reiser4_status_endio; ++ lock_page(subv->status_page); /* Safe as nobody should touch our page */ ++ /* ++ * We can block now, but we have no other choice anyway ++ */ ++ bio_set_op_attrs(bio, WRITE, 0); ++ submit_bio(bio); ++ /* ++ * We do not wait for IO completon ++ */ ++ return 0; ++} ++ ++/* Frees the page with status and bio structure. Should be called by disk format ++ * at umount time */ ++int reiser4_status_finish(reiser4_subvol *subv) ++{ ++ __free_pages(subv->status_page, 0); ++ subv->status_page = NULL; ++ bio_put(subv->status_bio); ++ subv->status_bio = NULL; ++ return 0; ++} +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/status_flags.h linux-5.10.2/fs/reiser4/status_flags.h +--- linux-5.10.2.orig/fs/reiser4/status_flags.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/status_flags.h 2020-12-23 16:07:46.134813363 +0100 +@@ -0,0 +1,53 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Here we declare structures and flags that store reiser4 status on disk. ++ The status that helps us to find out if the filesystem is valid or if it ++ contains some critical, or not so critical errors */ ++ ++#if !defined(__REISER4_STATUS_FLAGS_H__) ++#define __REISER4_STATUS_FLAGS_H__ ++ ++#include "dformat.h" ++/* These are major status flags */ ++#define REISER4_STATUS_OK 0 ++#define REISER4_STATUS_CORRUPTED 0x1 ++#define REISER4_STATUS_DAMAGED 0x2 ++#define REISER4_STATUS_DESTROYED 0x4 ++#define REISER4_STATUS_IOERROR 0x8 ++ ++/* These are extended status flags */ ++ ++#define REISER4_ESTATUS_OK 0 ++#define REISER4_ESTATUS_MIRRORS_NOT_SYNCED 0x1 ++ ++/* Return values for reiser4_status_query() */ ++#define REISER4_STATUS_MOUNT_OK 0 ++#define REISER4_STATUS_MOUNT_WARN 1 ++#define REISER4_STATUS_MOUNT_RO 2 ++#define REISER4_STATUS_MOUNT_UNKNOWN -1 ++ ++#define REISER4_TEXTERROR_LEN 256 ++ ++#define REISER4_STATUS_MAGIC "ReiSeR4StATusBl" ++/* We probably need to keep its size under sector size which is 512 bytes */ ++struct reiser4_status { ++ char magic[16]; ++ d64 status; /* Current FS state */ ++ d64 extended_status; /* Any additional info that might have sense in ++ * addition to "status". E.g. last sector where ++ * io error happened if status is ++ * "io error encountered" */ ++ d64 stacktrace[10]; /* Last ten functional calls made (addresses) */ ++ char texterror[REISER4_TEXTERROR_LEN]; /* Any error message if ++ * appropriate, otherwise filled ++ * with zeroes */ ++}; ++ ++int reiser4_status_init(reiser4_subvol *subv, reiser4_block_nr block); ++int reiser4_status_query(reiser4_subvol *subv, u64 *status, u64 *extended); ++int reiser4_status_write(reiser4_subvol *subv, u64 status, ++ u64 extended_status, char *message); ++int reiser4_status_finish(reiser4_subvol *subv); ++ ++#endif +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/super.c linux-5.10.2/fs/reiser4/super.c +--- linux-5.10.2.orig/fs/reiser4/super.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/super.c 2020-12-23 16:07:46.134813363 +0100 +@@ -0,0 +1,361 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Super-block manipulations. */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "plugin/security/perm.h" ++#include "plugin/space/space_allocator.h" ++#include "plugin/plugin.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block */ ++ ++static __u64 reserved_for_gid(const struct super_block *sb, gid_t gid); ++static __u64 reserved_for_uid(const struct super_block *sb, uid_t uid); ++static __u64 reserved_for_root(const struct super_block *subv); ++ ++/* Return reiser4-specific part of super block */ ++reiser4_super_info_data *get_super_private_nocheck(const struct super_block *super) ++{ ++ return (reiser4_super_info_data *) super->s_fs_info; ++} ++ ++/* Return reiser4 fstype: value that is returned in ->f_type field by statfs() ++ */ ++long reiser4_statfs_type(const struct super_block *super UNUSED_ARG) ++{ ++ assert("nikita-448", super != NULL); ++ assert("nikita-449", is_reiser4_super(super)); ++ return (long)REISER4_SUPER_MAGIC; ++} ++ ++/* functions to read/modify fields of reiser4_super_info_data */ ++ ++/* get number of blocks in subvolume */ ++__u64 reiser4_subvol_block_count(const reiser4_subvol *subv) ++{ ++ assert("vs-494", subv != NULL); ++ return subv->block_count; ++} ++ ++/** ++ * Scan mslots and collect statistics from each subvolume of a logical volume ++ */ ++u64 reiser4_collect_super_stat(const struct super_block *sb, ++ u64 (*subvol_get_stat)(const reiser4_subvol *)) ++{ ++ u64 slot; ++ u64 result = 0; ++ ++ for (slot = 0;; slot++) { ++ u64 cnt; ++ lv_conf *conf; ++ reiser4_subvol *subv; ++ ++ rcu_read_lock(); ++ conf = super_conf(sb); ++ ++ if (slot >= conf->nr_mslots) { ++ rcu_read_unlock(); ++ break; ++ } ++ if (!conf_mslot_at(conf, slot)) { ++ rcu_read_unlock(); ++ continue; ++ } ++ subv = conf_origin(conf, slot); ++ assert("edward-2272", subv != NULL); ++ ++ cnt = subvol_get_stat(subv); ++ rcu_read_unlock(); ++ ++ result += cnt; ++ } ++ return result; ++} ++ ++/* get number of blocks in logical volume */ ++__u64 reiser4_volume_block_count(const struct super_block *super) ++{ ++ return reiser4_collect_super_stat(super, ++ reiser4_subvol_block_count); ++} ++ ++/* ++ * Set number of blocks and reserved space for a logical volume. ++ * Pre-condition: @nr is total number of blocks of all its subvolumes. ++ */ ++void reiser4_subvol_set_block_count(reiser4_subvol *subv, __u64 nr) ++{ ++ assert("vs-501", subv != NULL); ++ ++ subv->block_count = nr; ++ /* ++ * The proper calculation of the reserved space counter (%5 of device ++ * block counter) we need a 64 bit division which is missing in Linux ++ * on i386 platform. Because we do not need a precise calculation here ++ * we can replace a div64 operation by this combination of ++ * multiplication and shift: 51. / (2^10) == .0498 . ++ * FIXME: this is a bug. It comes up only for very small filesystems ++ * which probably are never used. Nevertheless, it is a bug. Number of ++ * reserved blocks must be not less than maximal number of blocks which ++ * get grabbed with BA_RESERVED. ++ */ ++ subv->blocks_reserved = ((nr * 51) >> 10); ++} ++ ++__u64 reiser4_subvol_blocks_reserved(const reiser4_subvol *subv) ++{ ++ return subv->blocks_reserved; ++} ++ ++__u64 reiser4_volume_blocks_reserved(const struct super_block *super) ++{ ++ return reiser4_collect_super_stat(super, ++ reiser4_subvol_blocks_reserved); ++} ++ ++/* amount of blocks used (allocated for data or meta-data) in subvolume */ ++__u64 reiser4_subvol_used_blocks(const reiser4_subvol *subv) ++{ ++ assert("nikita-452", subv != NULL); ++ return subv->blocks_used; ++} ++ ++/* set number of blocks used */ ++void reiser4_subvol_set_used_blocks(reiser4_subvol *subv, __u64 nr) ++{ ++ assert("vs-503", subv != NULL); ++ subv->blocks_used = nr; ++} ++ ++__u64 reiser4_subvol_min_blocks_used(const reiser4_subvol *subv) ++{ ++ assert("edward-2332", subv != NULL); ++ return subv->min_blocks_used; ++} ++ ++void reiser4_subvol_set_min_blocks_used(reiser4_subvol *subv, __u64 nr) ++{ ++ assert("edward-2333", subv != NULL); ++ subv->min_blocks_used = nr; ++} ++ ++/* amount of free blocks in subvolume */ ++__u64 reiser4_subvol_free_blocks(const reiser4_subvol *subv) ++{ ++ assert("nikita-454", subv != NULL); ++ return subv->blocks_free; ++} ++ ++/* set number of free blocks */ ++void reiser4_subvol_set_free_blocks(reiser4_subvol *subv, __u64 nr) ++{ ++ assert("vs-505", subv != NULL); ++ subv->blocks_free = nr; ++} ++ ++__u64 reiser4_subvol_data_capacity(reiser4_subvol *subv) ++{ ++ assert("edward-1796", subv != NULL); ++ assert("edward-1839", ++ subv->data_capacity <= reiser4_subvol_block_count(subv)); ++ return subv->data_capacity; ++} ++ ++void reiser4_subvol_set_data_capacity(reiser4_subvol *subv, __u64 value) ++{ ++ assert("edward-1797", subv != NULL); ++ subv->data_capacity = value; ++} ++ ++/* amount of free blocks in logical volume */ ++__u64 reiser4_volume_free_blocks(const struct super_block *super) ++{ ++ return reiser4_collect_super_stat(super, ++ reiser4_subvol_free_blocks); ++} ++ ++/* get mkfs unique identifier */ ++__u32 reiser4_mkfs_id(const struct super_block *super, __u32 subv_id) ++{ ++ assert("vpf-221", super != NULL); ++ return super_origin(super, subv_id)->mkfs_id; ++} ++ ++/* amount of free blocks */ ++__u64 reiser4_subvol_free_committed_blocks(const reiser4_subvol *subv) ++{ ++ return subv->blocks_free_committed; ++} ++ ++/** ++ * amount of blocks reserved for @uid and @gid in a volume ++ */ ++long reiser4_volume_reserved4user(const struct super_block *sb, ++ uid_t uid, /* user id */ ++ gid_t gid /* group id */) ++{ ++ long reserved = 0; ++ ++ assert("nikita-456", sb != NULL); ++ ++ if (REISER4_SUPPORT_GID_SPACE_RESERVATION) ++ reserved += reserved_for_gid(sb, gid); ++ if (REISER4_SUPPORT_UID_SPACE_RESERVATION) ++ reserved += reserved_for_uid(sb, uid); ++ if (REISER4_SUPPORT_ROOT_SPACE_RESERVATION && (uid == 0)) ++ reserved += reserved_for_root(sb); ++ return reserved; ++} ++ ++/* get/set value of/to grabbed blocks counter */ ++__u64 reiser4_subvol_grabbed_blocks(const reiser4_subvol *subv) ++{ ++ assert("zam-512", subv != NULL); ++ ++ return subv->blocks_grabbed; ++} ++ ++__u64 reiser4_subvol_flush_reserved(const reiser4_subvol *subv) ++{ ++ assert("vpf-285", subv != NULL); ++ ++ return subv->blocks_flush_reserved; ++} ++ ++/* get/set value of/to counter of fake allocated formatted blocks */ ++__u64 reiser4_subvol_fake_allocated_fmt(const reiser4_subvol *subv) ++{ ++ assert("zam-516", subv != NULL); ++ ++ return subv->blocks_fake_allocated; ++} ++ ++/* get/set value of/to counter of fake allocated unformatted blocks */ ++__u64 reiser4_subvol_fake_allocated_unf(const reiser4_subvol *subv) ++{ ++ assert("zam-516", subv != NULL); ++ ++ return subv->blocks_fake_allocated_unformatted; ++} ++ ++/* get/set value of/to counter of clustered blocks */ ++__u64 reiser4_subvol_clustered_blocks(const reiser4_subvol *subv) ++{ ++ assert("edward-601", subv != NULL); ++ ++ return subv->blocks_clustered; ++} ++ ++/* space allocator used by this subvolume */ ++reiser4_space_allocator *reiser4_get_space_allocator(reiser4_subvol *subv) ++{ ++ assert("edward-1800", subv != NULL); ++ return &subv->space_allocator; ++} ++ ++/* return fake inode used to bind formatted nodes in the page cache */ ++struct inode *reiser4_get_super_fake(const struct super_block *super) ++{ ++ assert("nikita-1757", super != NULL); ++ return get_super_private(super)->fake; ++} ++ ++/* return fake inode used to bind copied on capture nodes in the page cache */ ++struct inode *reiser4_get_cc_fake(const struct super_block *super) ++{ ++ assert("nikita-1757", super != NULL); ++ return get_super_private(super)->cc; ++} ++ ++/* return fake inode used to bind bitmaps and journlal heads */ ++struct inode *reiser4_get_bitmap_fake(const struct super_block *super) ++{ ++ assert("nikita-17571", super != NULL); ++ return get_super_private(super)->bitmap; ++} ++ ++/* Check that @super is (looks like) reiser4 super block. This is mainly for ++ use in assertions. */ ++int is_reiser4_super(const struct super_block *super) ++{ ++ return super != NULL && ++ get_super_private(super) != NULL && ++ super->s_op == &(get_super_private(super)->ops.super); ++} ++ ++/** ++ * amount of blocks reserved for given group in file system ++ */ ++static __u64 reserved_for_gid(const struct super_block *sb, gid_t gid) ++{ ++ return 0; ++} ++ ++/** ++ * amount of blocks reserved for given user in file system ++ */ ++static __u64 reserved_for_uid(const struct super_block *sb, uid_t uid) ++{ ++ return 0; ++} ++ ++/** ++ * amount of blocks reserved for super user in file system ++ */ ++static __u64 reserved_for_root(const struct super_block *sb) ++{ ++ return 0; ++} ++ ++/** ++ * true if block number @blk makes sense for the file system at @subv. ++ */ ++int reiser4_subvol_blocknr_is_sane(const reiser4_subvol *subv, ++ const reiser4_block_nr *blk) ++{ ++ assert("nikita-2957", subv != NULL); ++ assert("nikita-2958", blk != NULL); ++ ++ if (reiser4_blocknr_is_fake(blk)) ++ return 1; ++ return *blk < reiser4_subvol_block_count(subv); ++} ++ ++#if REISER4_DEBUG ++static u64 reiser4_subvol_fake_allocated(const reiser4_subvol *subv) ++{ ++ return reiser4_subvol_fake_allocated_fmt(subv) + ++ reiser4_subvol_fake_allocated_unf(subv); ++} ++ ++u64 reiser4_volume_fake_allocated(const struct super_block *sb) ++{ ++ u64 ret; ++ spin_lock_reiser4_super(get_super_private(sb)); ++ ret = reiser4_collect_super_stat(sb, ++ reiser4_subvol_fake_allocated); ++ spin_unlock_reiser4_super(get_super_private(sb)); ++ return ret; ++} ++#endif ++ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/super.h linux-5.10.2/fs/reiser4/super.h +--- linux-5.10.2.orig/fs/reiser4/super.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/super.h 2020-12-23 16:07:46.134813363 +0100 +@@ -0,0 +1,936 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Super-block functions. See super.c for details. */ ++ ++#if !defined(__REISER4_SUPER_H__) ++#define __REISER4_SUPER_H__ ++ ++#include ++ ++#include "ioctl.h" ++#include "tree.h" ++#include "entd.h" ++#include "wander.h" ++#include "fsdata.h" ++#include "plugin/object.h" ++#include "plugin/dst/dst.h" ++#include "plugin/space/space_allocator.h" ++ ++/* ++ * Flush algorithms parameters. ++ */ ++struct flush_params { ++ unsigned relocate_threshold; ++ unsigned relocate_distance; ++ unsigned written_threshold; ++ unsigned scan_maxnodes; ++}; ++ ++/* ++ * VFS related operation vectors. ++ */ ++struct object_ops { ++ struct super_operations super; ++ struct dentry_operations dentry; ++ struct export_operations export; ++}; ++ ++/* reiser4-specific part of super block ++ ++ Locking ++ ++ Fields immutable after mount: ++ ++ ->oid* ++ ->space* ++ ->default_[ug]id ++ ->mkfs_id ++ ->trace_flags ++ ->debug_flags ++ ->fs_flags ++ ->df_plug ++ ->optimal_io_size ++ ->plug ++ ->flush ++ ->u (bad name) ++ ->txnmgr ++ ->ra_params ++ ->journal_header ++ ->journal_footer ++ ++ Fields protected by per-super block spin lock ++ ++ ->block_count ++ ->blocks_used ++ ->blocks_free ++ ->blocks_free_committed ++ ->blocks_grabbed ++ ->blocks_fake_allocated_unformatted ++ ->blocks_fake_allocated ++ ->blocks_flush_reserved ++ ->eflushed ++ ->blocknr_hint_default ++ ++ After journal replaying during mount, ++ ++ ->last_committed_tx ++ ++ is protected by ->tmgr.commit_mutex ++ ++ Invariants involving this data-type: ++ ++ [sb-block-counts] ++ [sb-grabbed] ++ [sb-fake-allocated] ++*/ ++ ++/** ++ * Per-atom and per-subvolume commit info. ++ * This structure is accessed at atom commit time under commit_mutex. ++ * See also definition of per-logical-volume struct commit_handle. ++ */ ++struct commit_handle_subvol ++{ ++ struct list_head overwrite_set; ++ __u32 overwrite_set_size; ++ struct list_head tx_list; /* jnodes for wander record blocks */ ++ __u32 tx_size; /* number of wander records for this subvolume */ ++ struct list_head wander_map; /* The atom's wandered_block mapping. ++ * Earlier it was ->wandered_map of struct ++ * txn_atom. Edward moved it here, as ++ * wandered map is always constructed at ++ * commit time under commit_mutex, so ++ * actually there is nothing to do for this ++ * map in the struct txn_atom. ++ */ ++ reiser4_block_nr nr_bitmap; /* counter of modified bitmaps */ ++ u64 free_blocks; /*'committed' sb counters are saved here until ++ atom is completely flushed */ ++}; ++ ++/* ++ * In-memory subvolume header. ++ * It is always associated with a physical or logical (built with LVM, ++ * etc means) block device. ++ */ ++struct reiser4_subvol { ++ struct list_head list; /* all registered subvolumes are linked */ ++ u8 uuid[16]; /* external ID */ ++ char *name; ++ fmode_t mode; ++ struct block_device *bdev; ++ u64 id; /* internal ID (index in the array of slots) */ ++ int mirror_id; /* index in the array of mirrors (0 indicates origin) */ ++ u32 dsa_idx; /* index in Data Storage Array (DSA). That index is set ++ by ->create_buckets() operation */ ++ int num_replicas; /* number of replicas, (mirrors excluding original) */ ++ u64 data_capacity; /* "weight" of the brick in data storage array */ ++ u64 apx_len; ++ void *apx; ++ reiser4_block_nr volmap_loc[2]; /* location of first voltab blocks for ++ current and new volume configs */ ++ unsigned long flags; /* subvolume-wide flags, see subvol_flags enum */ ++ disk_format_plugin *df_plug; /* disk format of this subvolume */ ++ jnode *sb_jnode; ++ reiser4_block_nr loc_super; /* location of the format super-block */ ++ reiser4_space_allocator space_allocator; /* space manager plugin */ ++ reiser4_txmod_id txmod; /* transaction model for this subvolume */ ++ struct flush_params flush; /* parameters for the flush algorithm */ ++ reiser4_tree tree; /* internal tree */ ++ __u32 mkfs_id; /* mkfs identifier generated at mkfs time. */ ++ ++ __u64 block_count; /* amount of blocks in a subvolume */ ++ __u64 blocks_free; /* amount of free blocks. This is a "working" version ++ of free blocks counter. It is like "working" ++ bitmap, see block_alloc.c for description */ ++ __u64 blocks_reserved; /* inviolable reserve */ ++ __u64 blocks_used; /* amount of blocks used by file system data and ++ meta-data. */ ++ __u64 blocks_grabbed; /* number of blocks reserved for further ++ allocation, for all threads */ ++ __u64 blocks_fake_allocated_unformatted;/* number of fake allocated ++ unformatted blocks in tree */ ++ __u64 blocks_fake_allocated; /* number of fake allocated formatted ++ blocks in tree */ ++ __u64 blocks_flush_reserved; /* number of blocks reserved for flush ++ operations */ ++ __u64 blocks_clustered; /* number of blocks reserved for cluster ++ operations */ ++ ++ int version; /* On-disk format version. May be upgraded at mount time */ ++ jnode *journal_header; /* jnode of hournal header */ ++ jnode *journal_footer; /* jnode of journal footer */ ++ journal_location jloc; ++ __u64 last_committed_tx; /* head block number of last committed ++ transaction */ ++ __u64 blocknr_hint_default; /* we remember last written location ++ for using as a hint for new block ++ allocation */ ++ struct repacker *repacker; ++ struct page *status_page; /* Image of the status block */ ++ struct bio *status_bio; ++ ++ __u64 min_blocks_used; /* minimum used blocks value (includes super ++ blocks, bitmap blocks and other fs reserved ++ areas), depends on fs format and fs size. */ ++ /* ++ * Per-subvolume fields of commit handle. ++ * Access to them requires to acquire the commit_mutex. ++ */ ++ __u64 blocks_freed; /* number of blocks freed by the actor ++ apply_dset_to_commit_bmap */ ++ __u64 blocks_free_committed; /* "commit" version of free ++ block counter */ ++ struct commit_handle_subvol ch; ++ struct super_block *super; /* associated super-block */ ++}; ++ ++static inline int subvol_is_set(const reiser4_subvol *subv, ++ reiser4_subvol_flag f) ++{ ++ return test_bit((int)f, &subv->flags); ++} ++ ++/* ++ * In-memory superblock ++ */ ++struct reiser4_super_info_data { ++ spinlock_t guard; /* protects fields blocks_free, ++ blocks_free_committed, etc */ ++ oid_t next_to_use;/* next oid that will be returned by oid_allocate() */ ++ oid_t oids_in_use; /* total number of used oids */ ++ __u32 default_uid; /* default user id used for light-weight files ++ without their own stat-data */ ++ __u32 default_gid; /* default group id used for light-weight files ++ without their own stat-data */ ++ unsigned long fs_flags; /* file-system wide flags. See reiser4_fs_flag ++ enum */ ++ txn_mgr tmgr; /* transaction manager */ ++ entd_context entd; /* ent thread */ ++ struct inode *fake; /* fake inode used to bind formatted nodes */ ++ /* inode used to bind bitmaps (and journal heads) */ ++ struct inode *bitmap; /* fake inode used to bind bitmaps (and journal ++ heads) */ ++ struct inode *cc; /* fake inode used to bind copied on capture nodes */ ++ unsigned long optimal_io_size; /* value we return in st_blksize on ++ stat(2) */ ++ __u64 nr_files_committed; /* committed number of files (oid allocator ++ state variable ) */ ++ __u64 vol_block_count; /* amount of blocks in a (logical) volume */ ++ struct formatted_ra_params ra_params; ++ int onerror; /* What to do in case of IO error. Specified by a mount ++ option */ ++ struct object_ops ops; /* operations for objects on this volume */ ++ struct d_cursor_info d_info; /* structure to maintain d_cursors. ++ See plugin/file_ops_readdir.c for more ++ details */ ++ struct crypto_shash *csum_tfm; ++ j_hash_table jhash_table; /* hash table to look up jnodes by inode ++ and offset. */ ++ rwlock_t tree_lock; /* lock protecting: ++ - parent pointers; ++ - sibling pointers; ++ - znode hash table; ++ - coord cache. ++ NOTE: The "giant" tree lock can be replaced by ++ more spin locks, hoping they will be less ++ contented. We can use one spin lock per one ++ znode hash bucket. With adding of some code ++ complexity, sibling pointers can be protected by ++ both znode spin locks. However it looks more SMP ++ scalable we should test this locking change on ++ n-ways (n > 4) SMP machines. Current 4-ways ++ machine test does not show that tree lock is ++ contented and it is a bottleneck (2003.07.25) ++ */ ++ struct mutex delete_mutex;/* a mutex for serializing cut tree operation ++ if out-of-free-space: the only one cut_tree ++ thread is allowed to grab space from ++ reserved area (it is 5% of disk space) */ ++ struct task_struct *delete_mutex_owner; /* task owning ->delete_mutex */ ++#ifdef CONFIG_REISER4_BADBLOCKS ++ unsigned long altsuper; /* Alternative master superblock offset ++ (in bytes). Specified by a mount option */ ++#endif ++ struct dentry *debugfs_root; ++#if REISER4_DEBUG ++ /* ++ * when debugging is on, all jnodes (including znodes, bitmaps, etc.) ++ * are kept on a list anchored at sbinfo->all_jnodes. This list is ++ * protected by sbinfo->all_guard spin lock. This lock should be taken ++ * with _irq modifier, because it is also modified from interrupt ++ * contexts (by RCU). ++ */ ++ spinlock_t all_guard; ++ struct list_head all_jnodes; /* list of all jnodes */ ++#endif ++ struct reiser4_volume *vol; /* accociated volume header */ ++ reiser4_context *ctx; ++}; ++ ++static inline struct reiser4_super_info_data *sbinfo_by_vol(struct reiser4_volume *vol) ++{ ++ return container_of(&vol, struct reiser4_super_info_data, vol); ++} ++ ++/* ++ * On-disk volume configuraion ++ */ ++struct reiser4_volinfo { ++ jnode **volmap_nodes; ++ int num_volmaps; ++ jnode **voltab_nodes; ++ int num_voltabs; ++}; ++ ++#define CUR_VOL_CONF 0 ++#define NEW_VOL_CONF 1 ++ ++/* ++ * In-memory volume configuration ++ */ ++struct lv_conf { ++ void *tab; /* distribution config */ ++ u64 nr_mslots; /* number of columns in the table of activated ++ * subvolumes. Each column represents a set of ++ * mirrors (see the picture below) */ ++ slot_t mslots[0]; /* pointer to a table of activated subvolumes, ++ * where: ++ * mslots[i] : array of mirrors at the i-th slot; ++ * mslots[i][j]: j-th mirror in the array above ++ * (see the picture below) */ ++}; ++ ++/* ++ Table of activated subvolumes: ++ ++ ******* <- @mslots ++ ooo o o ++ o o ++ o ++ ++ * - original subvolumes ++ o - replicas ++ ++ An original subvolume with all its replicas are called mirrors. ++ An original subvolume always have mirror_id = 0. Replicas have ++ mirror_id > 0. ++*/ ++ ++/* ++ * In-memory header of compound (logical) volume. ++ */ ++struct reiser4_volume { ++ struct list_head list; ++ u8 uuid[16]; /* volume id */ ++ int num_sgs_bits; /* logarithm of number of hash space segments */ ++ int stripe_bits; /* logarithm of stripe size */ ++ atomic_t nr_origins; /* number of original subvolumes (w/o replicas) */ ++ distribution_plugin *dist_plug; ++ struct rw_semaphore volume_sem; /* protect volume configuration */ ++ struct rw_semaphore brick_removal_sem; ++ volume_plugin *vol_plug; ++ reiser4_dcx dcx; /* distribution context */ ++ reiser4_volinfo volinfo[2]; /* on-disk volume configurations: current ++ and new (for volume operations). They ++ need co-exist some time until we make ++ sure that new info is written to disk ++ successfully */ ++ struct list_head subvols_list; /* list of registered subvolumes */ ++ bucket_t *buckets; /* set of abstract buckets */ ++ struct lv_conf *conf; /* current working in-memory volume ++ configuration */ ++ struct lv_conf *new_conf; /* new volume configuration */ ++ reiser4_subvol *proxy; /* burst buffers */ ++ reiser4_subvol *victim; /* brick to be removed from the volume */ ++}; ++ ++typedef enum { ++ VBF_MIGRATE_ALL = 0x1, ++ VBF_CLR_IMMOBILE = 0x2 ++} volume_balancing_flags; ++ ++extern reiser4_super_info_data *get_super_private_nocheck(const struct ++ super_block *super); ++ ++/* Return reiser4-specific part of super block */ ++static inline reiser4_super_info_data *get_super_private(const struct ++ super_block *super) ++{ ++ assert("nikita-447", super != NULL); ++ ++ return (reiser4_super_info_data *) super->s_fs_info; ++} ++ ++static inline reiser4_volume *super_volume(const struct super_block *super) ++{ ++ return get_super_private(super)->vol; ++} ++ ++static inline volume_plugin *super_vol_plug(const struct super_block *super) ++{ ++ return super_volume(super)->vol_plug; ++} ++ ++static inline lv_conf *sbinfo_conf(reiser4_super_info_data *info) ++{ ++ assert("edward-1719", info != NULL); ++ assert("edward-1720", info->vol != NULL); ++ ++ return info->vol->conf; ++} ++ ++static inline slot_t *conf_mslots(lv_conf *conf) ++{ ++ return conf->mslots; ++} ++ ++static inline u32 conf_nr_mslots(lv_conf *conf) ++{ ++ return conf->nr_mslots; ++} ++ ++static inline mirror_t *conf_mslot_at(lv_conf *conf, u32 id) ++{ ++ return conf_mslots(conf)[id]; ++} ++ ++static inline reiser4_subvol *conf_mirror(lv_conf *conf, ++ u32 slot_idx, u32 mirr_id) ++{ ++ assert("edward-2473", conf_mslot_at(conf, slot_idx) != NULL); ++ ++ return ((mirror_t *)conf_mslot_at(conf, slot_idx))[mirr_id]; ++} ++ ++static inline reiser4_subvol *conf_origin(lv_conf *conf, u32 subv_id) ++{ ++ return conf_mirror(conf, subv_id, 0); ++} ++ ++static inline lv_conf *super_conf(const struct super_block *sb) ++{ ++ return sbinfo_conf(get_super_private(sb)); ++} ++ ++static inline u32 vol_nr_origins(reiser4_volume *vol) ++{ ++ return atomic_read(&vol->nr_origins); ++} ++ ++static inline u32 sbinfo_nr_origins(reiser4_super_info_data *info) ++{ ++ return vol_nr_origins(info->vol); ++} ++ ++/** ++ * Return a pointer to a subvolume. ++ * The caller should have a guarantee that subvolume will be valid ++ * while working with it. ++ */ ++static inline reiser4_subvol *super_mirror(const struct super_block *super, ++ u32 slot_idx, u32 mirror_id) ++{ ++ lv_conf *conf; ++ reiser4_subvol *ret; ++ reiser4_volume *vol = super_volume(super); ++ ++ rcu_read_lock(); ++ conf = rcu_dereference(vol->conf); ++ ret = conf_mirror(conf, slot_idx, mirror_id); ++ rcu_read_unlock(); ++ ++ return ret; ++} ++ ++static inline reiser4_subvol *super_origin(const struct super_block *super, ++ u32 id) ++{ ++ return super_mirror(super, id, 0); ++} ++ ++static inline u32 super_nr_origins(const struct super_block *super) ++{ ++ return sbinfo_nr_origins(get_super_private(super)); ++} ++ ++/* get ent context for the @super */ ++static inline entd_context *get_entd_context(struct super_block *super) ++{ ++ return &get_super_private(super)->entd; ++} ++ ++/** ++ * Get the super block used during current system call. ++ * Reference to this super block is stored in reiser4_context ++ */ ++static inline struct super_block *reiser4_get_current_sb(void) ++{ ++ return get_current_context()->super; ++} ++ ++/** ++ * Reiser4-specific part of "current" super-block: main super block used ++ * during current system call. Reference to this super block is stored in ++ * reiser4_context ++ */ ++static inline reiser4_super_info_data *get_current_super_private(void) ++{ ++ return get_super_private(reiser4_get_current_sb()); ++} ++ ++static inline reiser4_volume *current_volume(void) ++{ ++ assert("edward-2158", get_current_super_private() != NULL); ++ ++ return get_current_super_private()->vol; ++} ++ ++static inline volume_plugin *current_vol_plug(void) ++{ ++ return current_volume()->vol_plug; ++} ++ ++static inline lv_conf *current_lv_conf(void) ++{ ++ return sbinfo_conf(get_current_super_private()); ++} ++ ++static inline bucket_t *current_buckets(void) ++{ ++ return current_volume()->buckets; ++} ++ ++static inline struct bucket_ops *current_bucket_ops(void) ++{ ++ return ¤t_volume()->vol_plug->bucket_ops; ++} ++ ++static inline struct formatted_ra_params *get_current_super_ra_params(void) ++{ ++ return &(get_current_super_private()->ra_params); ++} ++ ++static inline struct distribution_plugin *current_dist_plug(void) ++{ ++ return get_current_super_private()->vol->dist_plug; ++} ++ ++static inline struct reiser4_subvol *current_mirror(u32 slot_idx, ++ u32 mirror_id) ++{ ++ return super_mirror(reiser4_get_current_sb(), slot_idx, mirror_id); ++} ++ ++static inline struct reiser4_subvol *current_origin(u32 slot_idx) ++{ ++ return current_mirror(slot_idx, 0); ++} ++ ++static inline u32 current_nr_origins(void) ++{ ++ return sbinfo_nr_origins(get_current_super_private()); ++} ++ ++static inline u32 current_num_replicas(u32 orig_id) ++{ ++ assert("edward-1723", current_origin(orig_id) != NULL); ++ ++ return current_origin(orig_id)->num_replicas; ++} ++ ++static inline u32 subvol_num_mirrors(reiser4_subvol *subv) ++{ ++ assert("edward-1724", subv != NULL); ++ return 1 + subv->num_replicas; ++} ++ ++static inline u32 current_num_mirrors(u32 orig_id) ++{ ++ return 1 + current_num_replicas(orig_id); ++} ++ ++#define current_stripe_bits (current_volume()->stripe_bits) ++#define current_stripe_size (1 << current_stripe_bits) ++ ++#define for_each_mslot(_conf, _subv_id) \ ++ for (_subv_id = 0; \ ++ _subv_id < _conf->nr_mslots; \ ++ _subv_id ++) ++ ++#define for_each_data_mslot(_conf, _subv_id) \ ++ for (_subv_id = 1; \ ++ _subv_id < _conf->nr_mslots; \ ++ _subv_id ++) ++ ++#define for_each_mirror(_orig_id, _mirr_id) \ ++ for (_mirr_id = 0; \ ++ _mirr_id < current_num_mirrors(_orig_id); \ ++ _mirr_id ++) ++ ++#define for_each_replica(_orig_id, _mirr_id) \ ++ for (_mirr_id = 1; \ ++ _mirr_id < current_num_mirrors(_orig_id); \ ++ _mirr_id ++) ++ ++#define __for_each_mirror(_orig, _mirr_id) \ ++ for (_mirr_id = 0; \ ++ _mirr_id < subvol_num_mirrors(_orig); \ ++ _mirr_id ++) ++ ++#define __for_each_replica(_orig, _mirr_id) \ ++ for (_mirr_id = 1; \ ++ _mirr_id < subvol_num_mirrors(_orig); \ ++ _mirr_id ++) ++ ++#define DEFAULT_WRITE_GRANULARITY 32 /* always a power of 2 */ ++ ++static inline int is_replica(struct reiser4_subvol *subv) ++{ ++ assert("edward-1725", subv != NULL); ++ ++ return subv->mirror_id; ++} ++ ++static inline int is_origin(struct reiser4_subvol *subv) ++{ ++ assert("edward-1726", subv != NULL); ++ ++ return !is_replica(subv); ++} ++ ++static inline int has_replicas(struct reiser4_subvol *subv) ++{ ++ assert("edward-1727", subv != NULL); ++ ++ return subv->num_replicas; ++} ++ ++/* ++ * true, if file system where @node lives on, is read-only ++ */ ++static inline int rofs_jnode(jnode *node) ++{ ++ return sb_rdonly(jnode_get_super(node)); ++} ++ ++extern void build_object_ops(struct super_block *super, struct object_ops *ops); ++ ++#define REISER4_SUPER_MAGIC 0x52345362 /* (*(__u32 *)"R4Sb"); */ ++ ++static inline void spin_lock_reiser4_super(reiser4_super_info_data *sbinfo) ++{ ++ spin_lock(&(sbinfo->guard)); ++} ++ ++static inline void spin_unlock_reiser4_super(reiser4_super_info_data *sbinfo) ++{ ++ assert_spin_locked(&(sbinfo->guard)); ++ spin_unlock(&(sbinfo->guard)); ++} ++ ++static inline void __init_ch_sub(struct commit_handle_subvol *ch_sub) ++{ ++ memset(ch_sub, 0, sizeof(*ch_sub)); ++ INIT_LIST_HEAD(&ch_sub->overwrite_set); ++ INIT_LIST_HEAD(&ch_sub->tx_list); ++ INIT_LIST_HEAD(&ch_sub->wander_map); ++} ++ ++static inline void __read_lock_tree(reiser4_super_info_data *sbinfo) ++{ ++ /* check that tree is not locked */ ++ assert("", (LOCK_CNT_NIL(rw_locked_tree) && ++ LOCK_CNT_NIL(read_locked_tree) && ++ LOCK_CNT_NIL(write_locked_tree))); ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(spin_locked_stack))); ++ ++ read_lock(&(sbinfo->tree_lock)); ++ ++ LOCK_CNT_INC(read_locked_tree); ++ LOCK_CNT_INC(rw_locked_tree); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void __read_unlock_tree(reiser4_super_info_data *sbinfo) ++{ ++ assert("nikita-1375", LOCK_CNT_GTZ(read_locked_tree)); ++ assert("nikita-1376", LOCK_CNT_GTZ(rw_locked_tree)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(read_locked_tree); ++ LOCK_CNT_DEC(rw_locked_tree); ++ LOCK_CNT_DEC(spin_locked); ++ ++ read_unlock(&(sbinfo->tree_lock)); ++} ++ ++static inline void __write_lock_tree(reiser4_super_info_data *sbinfo) ++{ ++ /* check that tree is not locked */ ++ assert("", (LOCK_CNT_NIL(rw_locked_tree) && ++ LOCK_CNT_NIL(read_locked_tree) && ++ LOCK_CNT_NIL(write_locked_tree))); ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(spin_locked_stack))); ++ ++ write_lock(&(sbinfo->tree_lock)); ++ ++ LOCK_CNT_INC(write_locked_tree); ++ LOCK_CNT_INC(rw_locked_tree); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void __write_unlock_tree(reiser4_super_info_data *sbinfo) ++{ ++ assert("nikita-1375", LOCK_CNT_GTZ(write_locked_tree)); ++ assert("nikita-1376", LOCK_CNT_GTZ(rw_locked_tree)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(write_locked_tree); ++ LOCK_CNT_DEC(rw_locked_tree); ++ LOCK_CNT_DEC(spin_locked); ++ ++ write_unlock(&(sbinfo->tree_lock)); ++} ++ ++static inline void read_lock_tree(void) ++{ ++ __read_lock_tree(get_current_super_private()); ++} ++ ++static inline void read_unlock_tree(void) ++{ ++ __read_unlock_tree(get_current_super_private()); ++} ++static inline void write_lock_tree(void) ++{ ++ __write_lock_tree(get_current_super_private()); ++} ++ ++static inline void write_unlock_tree(void) ++{ ++ __write_unlock_tree(get_current_super_private()); ++} ++ ++/* set/clear/test per-volume flags */ ++ ++static inline int reiser4_is_set(const struct super_block *super, ++ reiser4_fs_flag f) ++{ ++ return test_bit((int)f, &get_super_private(super)->fs_flags); ++} ++ ++static inline int reiser4_volume_is_unbalanced(const struct super_block *sb) ++{ ++ assert("edward-1945", sb != NULL); ++ return reiser4_is_set(sb, REISER4_UNBALANCED_VOL); ++} ++ ++static inline void reiser4_volume_set_unbalanced(struct super_block *sb) ++{ ++ assert("edward-1946", sb != NULL); ++ set_bit(REISER4_UNBALANCED_VOL, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_clear_unbalanced(struct super_block *sb) ++{ ++ assert("edward-1948", sb != NULL); ++ clear_bit(REISER4_UNBALANCED_VOL, &get_super_private(sb)->fs_flags); ++} ++ ++static inline int reiser4_volume_has_incomplete_removal(const struct super_block *sb) ++{ ++ assert("edward-2247", sb != NULL); ++ return reiser4_is_set(sb, REISER4_INCOMPLETE_BRICK_REMOVAL); ++} ++ ++static inline void reiser4_volume_set_incomplete_removal(struct super_block *sb) ++{ ++ assert("edward-2248", sb != NULL); ++ set_bit(REISER4_INCOMPLETE_BRICK_REMOVAL, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_clear_incomplete_removal(struct super_block *sb) ++{ ++ assert("edward-2249", sb != NULL); ++ clear_bit(REISER4_INCOMPLETE_BRICK_REMOVAL, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_set_activated(struct super_block *sb) ++{ ++ assert("edward-2084", sb != NULL); ++ set_bit(REISER4_ACTIVATED_VOL, &get_super_private(sb)->fs_flags); ++} ++ ++static inline int reiser4_volume_is_activated(struct super_block *sb) ++{ ++ assert("edward-2085", sb != NULL); ++ return reiser4_is_set(sb, REISER4_ACTIVATED_VOL); ++} ++ ++static inline void reiser4_volume_set_proxy_enabled(struct super_block *sb) ++{ ++ assert("edward-2439", sb != NULL); ++ set_bit(REISER4_PROXY_ENABLED, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_clear_proxy_enabled(struct super_block *sb) ++{ ++ assert("edward-2440", sb != NULL); ++ clear_bit(REISER4_PROXY_ENABLED, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_set_proxy_io(struct super_block *sb) ++{ ++ assert("edward-2450", sb != NULL); ++ set_bit(REISER4_PROXY_IO, &get_super_private(sb)->fs_flags); ++} ++ ++static inline void reiser4_volume_clear_proxy_io(struct super_block *sb) ++{ ++ assert("edward-2451", sb != NULL); ++ clear_bit(REISER4_PROXY_IO, &get_super_private(sb)->fs_flags); ++} ++ ++/* operations on subvolume */ ++extern u64 get_meta_subvol_id(void); ++extern reiser4_subvol *get_meta_subvol(void); ++static inline reiser4_tree *meta_subvol_tree(void) ++{ ++ return &get_meta_subvol()->tree; ++} ++ ++extern reiser4_subvol *super_meta_subvol(struct super_block *super); ++ ++#define find_data_subvol(coord) \ ++current_origin(current_vol_plug()->find_brick(coord)) ++ ++static inline reiser4_subvol *calc_data_subvol(const struct inode *inode, ++ loff_t offset) ++{ ++ reiser4_subvol *ret; ++ lv_conf *conf; ++ reiser4_volume *vol = current_volume(); ++ ++ rcu_read_lock(); ++ conf = rcu_dereference(vol->conf); ++ ret = conf_origin(conf, vol->vol_plug->calc_brick(conf, inode, offset)); ++ rcu_read_unlock(); ++ return ret; ++} ++ ++struct file_system_type *get_reiser4_fs_type(void); ++extern long reiser4_statfs_type(const struct super_block *super); ++ ++extern __u64 reiser4_subvol_flush_reserved(const reiser4_subvol *); ++extern __u64 reiser4_subvol_block_count(const reiser4_subvol *); ++extern void reiser4_subvol_set_block_count(reiser4_subvol *subv, __u64 nr); ++extern __u64 reiser4_subvol_blocks_reserved(const reiser4_subvol *subv); ++ ++extern __u64 reiser4_subvol_used_blocks(const reiser4_subvol *); ++extern void reiser4_subvol_set_used_blocks(reiser4_subvol *, __u64 nr); ++ ++extern __u64 reiser4_subvol_min_blocks_used(const reiser4_subvol *); ++extern void reiser4_subvol_set_min_blocks_used(reiser4_subvol *, __u64 nr); ++ ++extern __u64 reiser4_subvol_free_blocks(const reiser4_subvol *); ++extern void reiser4_subvol_set_free_blocks(reiser4_subvol *, __u64 nr); ++ ++extern __u64 reiser4_subvol_data_capacity(reiser4_subvol *); ++extern void reiser4_subvol_set_data_capacity(reiser4_subvol *, __u64 len); ++ ++extern __u64 reiser4_subvol_free_committed_blocks(const reiser4_subvol *); ++extern __u64 reiser4_subvol_grabbed_blocks(const reiser4_subvol *); ++extern __u64 reiser4_subvol_fake_allocated_fmt(const reiser4_subvol *); ++extern __u64 reiser4_subvol_fake_allocated_unf(const reiser4_subvol *); ++extern __u64 reiser4_subvol_clustered_blocks(const reiser4_subvol *); ++extern long reiser4_subvol_reserved4user(const reiser4_subvol *, ++ uid_t uid, gid_t gid); ++extern int reiser4_subvol_blocknr_is_sane(const reiser4_subvol *subv, ++ const reiser4_block_nr *blk); ++/* operations on volume */ ++extern long reiser4_ioctl_volume(struct file *file, ++ unsigned int cmd, unsigned long arg, ++ int (*volume_op)(struct file *file, ++ struct reiser4_vol_op_args *args)); ++extern int reiser4_volume_op_file(struct file *, struct reiser4_vol_op_args *); ++extern int reiser4_volume_op_dir(struct file *, struct reiser4_vol_op_args *); ++extern int reiser4_volume_header(struct reiser4_vol_op_args *); ++extern int reiser4_brick_header(struct reiser4_vol_op_args *); ++extern __u64 reiser4_volume_block_count(const struct super_block *); ++extern __u64 reiser4_volume_blocks_reserved(const struct super_block *super); ++extern __u64 reiser4_volume_free_blocks(const struct super_block *super); ++extern __u64 reiser4_volume_fake_allocated(const struct super_block *sb); ++extern long reiser4_volume_reserved4user(const struct super_block *, ++ uid_t uid, gid_t gid); ++extern __u32 reiser4_mkfs_id(const struct super_block *super, __u32 subv_id); ++extern reiser4_space_allocator * reiser4_get_space_allocator(reiser4_subvol *); ++extern reiser4_oid_allocator * ++reiser4_get_oid_allocator(const struct super_block *super); ++extern struct inode *reiser4_get_super_fake(const struct super_block *super); ++extern struct inode *reiser4_get_cc_fake(const struct super_block *super); ++extern struct inode *reiser4_get_bitmap_fake(const struct super_block *super); ++extern int is_reiser4_super(const struct super_block *super); ++extern int reiser4_done_super(struct super_block *s); ++extern int reiser4_scan_device(const char *path, fmode_t flags, void *holder, ++ reiser4_subvol **result, reiser4_volume **host); ++ ++/* step of fill super */ ++extern int reiser4_offline_op(struct reiser4_vol_op_args *); ++extern int reiser4_init_fs_info(struct super_block *); ++extern void reiser4_done_fs_info(struct super_block *); ++extern int reiser4_init_super_data(struct super_block *, char *opt_string); ++int reiser4_activate_subvol(struct super_block *super, reiser4_subvol *subv); ++void reiser4_deactivate_subvol(struct super_block *super, reiser4_subvol *subv); ++extern int reiser4_activate_volume(struct super_block *, u8 *vol_uuid); ++extern void reiser4_deactivate_volume(struct super_block *); ++extern void reiser4_unregister_subvol(struct reiser4_subvol *subv); ++extern int reiser4_unregister_brick(struct reiser4_vol_op_args *args); ++extern void reiser4_unregister_volumes(void); ++extern struct reiser4_volume *reiser4_search_volume(u8 *vol_uuid); ++extern int reiser4_read_master(struct super_block *, int silent, u8 *vol_uuid); ++extern int reiser4_init_root_inode(struct super_block *); ++extern reiser4_plugin *get_default_plugin(pset_member memb); ++ ++#define INVALID_OID ((oid_t)0) ++/* Maximal possible object id. */ ++#define ABSOLUTE_MAX_OID ((oid_t)~0) ++ ++#define OIDS_RESERVED (1 << 16) ++int oid_init_allocator(struct super_block *, oid_t nr_files, oid_t next); ++oid_t oid_allocate(struct super_block *); ++int oid_release(struct super_block *, oid_t); ++oid_t oid_next(const struct super_block *); ++void oid_count_allocated(void); ++void oid_count_released(void); ++long oids_used(const struct super_block *); ++ ++#if REISER4_DEBUG ++void print_fs_info(const char *prefix, const struct super_block *); ++#endif ++ ++extern void destroy_reiser4_cache(struct kmem_cache **); ++ ++extern struct super_operations reiser4_super_operations; ++extern struct export_operations reiser4_export_operations; ++extern struct dentry_operations reiser4_dentry_operations; ++ ++/* __REISER4_SUPER_H__ */ ++#endif ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 120 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/super_ops.c linux-5.10.2/fs/reiser4/super_ops.c +--- linux-5.10.2.orig/fs/reiser4/super_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/super_ops.c 2020-12-23 16:08:55.164816614 +0100 +@@ -0,0 +1,921 @@ ++/* Copyright 2005 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++#include "inode.h" ++#include "page_cache.h" ++#include "ktxnmgrd.h" ++#include "flush.h" ++#include "safe_link.h" ++#include "checksum.h" ++#include "plugin/volume/volume.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* slab cache for inodes */ ++static struct kmem_cache *inode_cache; ++ ++static struct dentry *reiser4_debugfs_root = NULL; ++ ++/** ++ * init_once - constructor for reiser4 inodes ++ * @cache: cache @obj belongs to ++ * @obj: inode to be initialized ++ * ++ * Initialization function to be called when new page is allocated by reiser4 ++ * inode cache. It is set on inode cache creation. ++ */ ++static void init_once(void *obj) ++{ ++ struct reiser4_inode_object *info; ++ ++ info = obj; ++ ++ /* initialize vfs inode */ ++ inode_init_once(&info->vfs_inode); ++ ++ /* ++ * initialize reiser4 specific part fo inode. ++ * NOTE-NIKITA add here initializations for locks, list heads, ++ * etc. that will be added to our private inode part. ++ */ ++ INIT_LIST_HEAD(get_readdir_list(&info->vfs_inode)); ++ init_rwsem(&info->p.conv_sem); ++ /* init semaphore which is used during inode loading */ ++ loading_init_once(&info->p); ++ INIT_RADIX_TREE(jnode_tree_by_reiser4_inode(&info->p), ++ GFP_ATOMIC); ++#if REISER4_DEBUG ++ info->p.nr_jnodes = 0; ++#endif ++} ++ ++/** ++ * init_inodes - create znode cache ++ * ++ * Initializes slab cache of inodes. It is part of reiser4 module initialization ++ */ ++static int init_inodes(void) ++{ ++ inode_cache = kmem_cache_create("reiser4_inode", ++ sizeof(struct reiser4_inode_object), ++ 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, init_once); ++ if (inode_cache == NULL) ++ return RETERR(-ENOMEM); ++ return 0; ++} ++ ++/** ++ * done_inodes - delete inode cache ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++static void done_inodes(void) ++{ ++ destroy_reiser4_cache(&inode_cache); ++} ++ ++/** ++ * reiser4_alloc_inode - alloc_inode of super operations ++ * @super: super block new inode is allocated for ++ * ++ * Allocates new inode, initializes reiser4 specific part of it. ++ */ ++static struct inode *reiser4_alloc_inode(struct super_block *super) ++{ ++ struct reiser4_inode_object *obj; ++ ++ assert("nikita-1696", super != NULL); ++ obj = kmem_cache_alloc(inode_cache, reiser4_ctx_gfp_mask_get()); ++ if (obj != NULL) { ++ reiser4_inode *info; ++ ++ info = &obj->p; ++ ++ info->pset = plugin_set_get_empty(); ++ info->hset = plugin_set_get_empty(); ++ info->extmask = 0; ++ info->locality_id = 0ull; ++ info->plugin_mask = 0; ++ info->heir_mask = 0; ++#if !REISER4_INO_IS_OID ++ info->oid_hi = 0; ++#endif ++ reiser4_seal_init(&info->sd_seal, NULL, NULL); ++ coord_init_invalid(&info->sd_coord, NULL); ++ info->flags = 0; ++ spin_lock_init(&info->guard); ++ /* this deals with info's loading semaphore */ ++ loading_alloc(info); ++ info->vroot = UBER_TREE_ADDR; ++ return &obj->vfs_inode; ++ } else ++ return NULL; ++} ++ ++/** ++ * reiser4_destroy_inode - destroy_inode of super operations ++ * @inode: inode being destroyed ++ * ++ * Puts reiser4 specific portion of inode, frees memory occupied by inode. ++ */ ++static void reiser4_destroy_inode(struct inode *inode) ++{ ++ reiser4_inode *info; ++ ++ info = reiser4_inode_data(inode); ++ ++ assert("vs-1220", inode_has_no_jnodes(info)); ++ ++ if (!is_bad_inode(inode) && is_inode_loaded(inode)) { ++ file_plugin *fplug = inode_file_plugin(inode); ++ if (fplug->destroy_inode != NULL) ++ fplug->destroy_inode(inode); ++ } ++ reiser4_dispose_cursors(inode); ++ if (info->pset) ++ plugin_set_put(info->pset); ++ if (info->hset) ++ plugin_set_put(info->hset); ++ ++ /* ++ * cannot add similar assertion about ->i_list as prune_icache return ++ * inode into slab with dangling ->list.{next,prev}. This is safe, ++ * because they are re-initialized in the new_inode(). ++ */ ++ assert("nikita-2895", hlist_empty(&inode->i_dentry)); ++ assert("nikita-2896", hlist_unhashed(&inode->i_hash)); ++ assert("nikita-2898", list_empty_careful(get_readdir_list(inode))); ++ ++ /* this deals with info's loading semaphore */ ++ loading_destroy(info); ++ ++ kmem_cache_free(inode_cache, ++ container_of(info, struct reiser4_inode_object, p)); ++} ++ ++/** ++ * reiser4_dirty_inode - dirty_inode of super operations ++ * @inode: inode being dirtied ++ * ++ * Updates stat data. ++ */ ++static void reiser4_dirty_inode(struct inode *inode, int flags) ++{ ++ int result; ++ reiser4_context *ctx; ++ ++ if (!is_in_reiser4_context()) ++ return; ++ ctx = get_current_context(); ++ ++ if (ctx->ro) { ++ warning("edward-2200", ++ "failed to make inode %llu dirty (read-only FS)", ++ (unsigned long long)get_inode_oid(inode)); ++ return; ++ } ++ assert("edward-1606", !IS_RDONLY(inode)); ++ assert("edward-1607", ++ (inode_file_plugin(inode)->estimate.update(inode) <= ++ ctx_subvol_grabbed(ctx, get_meta_subvol()->id))); ++ ++ if (ctx->locked_page) ++ unlock_page(ctx->locked_page); ++ ++ result = reiser4_update_sd(inode); ++ ++ if (ctx->locked_page) ++ lock_page(ctx->locked_page); ++ if (result) ++ warning("edward-1605", "failed to dirty inode for %llu: %d", ++ get_inode_oid(inode), result); ++} ++ ++/** ++ * ->evict_inode() of super operations ++ * @inode: inode to delete ++ * ++ * Calls file plugin's delete_object method to delete object items from ++ * filesystem tree and calls clear_inode(). ++ */ ++static void reiser4_evict_inode(struct inode *inode) ++{ ++ reiser4_context *ctx; ++ file_plugin *fplug; ++ ++ ctx = reiser4_init_context(inode->i_sb); ++ if (IS_ERR(ctx)) { ++ warning("vs-15", "failed to init context"); ++ return; ++ } ++ ++ if (inode->i_nlink == 0 && is_inode_loaded(inode)) { ++ fplug = inode_file_plugin(inode); ++ if (fplug != NULL && fplug->delete_object != NULL) ++ fplug->delete_object(inode); ++ } ++ ++ truncate_inode_pages_final(&inode->i_data); ++ inode->i_blocks = 0; ++ clear_inode(inode); ++ reiser4_exit_context(ctx); ++} ++ ++/** ++ * reiser4_put_super - put_super of super operations ++ * @super: super block to free ++ * ++ * Stops daemons, release resources, umounts in short. ++ */ ++static void reiser4_put_super(struct super_block *super) ++{ ++ reiser4_super_info_data *sbinfo; ++ reiser4_context *ctx; ++ ++ sbinfo = get_super_private(super); ++ assert("vs-1699", sbinfo); ++ ++ debugfs_remove(sbinfo->tmgr.debugfs_atom_count); ++ debugfs_remove(sbinfo->tmgr.debugfs_id_count); ++ debugfs_remove(sbinfo->debugfs_root); ++ ++ ctx = reiser4_init_context(super); ++ if (IS_ERR(ctx)) { ++ warning("vs-17", "failed to init context"); ++ return; ++ } ++ /* ++ * release disk format related resources ++ */ ++ reiser4_deactivate_volume(super); ++ reiser4_jnodes_done(); ++ reiser4_done_formatted_fake(super); ++ reiser4_done_csum_tfm(sbinfo->csum_tfm); ++ ++ /* stop daemons: ktxnmgr and entd */ ++ reiser4_done_entd(super); ++ reiser4_done_ktxnmgrd(super); ++ reiser4_done_txnmgr(&sbinfo->tmgr); ++ ++ assert("edward-1890", list_empty(&get_super_private(super)->all_jnodes)); ++ assert("edward-1891", get_current_context()->trans->atom == NULL); ++ ++ reiser4_exit_context(ctx); ++ reiser4_done_fs_info(super); ++} ++ ++/** ++ * reiser4_statfs - statfs of super operations ++ * @super: super block of file system in queried ++ * @stafs: buffer to fill with statistics ++ * ++ * Returns information about filesystem. ++ */ ++static int reiser4_statfs(struct dentry *dentry, struct kstatfs *statfs) ++{ ++ sector_t total; ++ sector_t reserved; ++ sector_t free; ++ sector_t forroot; ++ sector_t deleted; ++ reiser4_context *ctx; ++ struct super_block *super = dentry->d_sb; ++ ++ assert("nikita-408", super != NULL); ++ assert("nikita-409", statfs != NULL); ++ ++ ctx = reiser4_init_context(super); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ statfs->f_type = reiser4_statfs_type(super); ++ statfs->f_bsize = super->s_blocksize; ++ ++ /* ++ * 5% of total block space is reserved. This is needed for flush and ++ * for truncates (so that we are able to perform truncate/unlink even ++ * on the otherwise completely full file system). If this reservation ++ * is hidden from statfs(2), users will mistakenly guess that they ++ * have enough free space to complete some operation, which is ++ * frustrating. ++ * ++ * Another possible solution is to subtract ->blocks_reserved from ++ * ->f_bfree, but changing available space seems less intrusive than ++ * letting user to see 5% of disk space to be used directly after ++ * mkfs. ++ */ ++ total = reiser4_volume_block_count(super); ++ reserved = reiser4_volume_blocks_reserved(super); ++ deleted = txnmgr_count_deleted_blocks(); ++ free = reiser4_volume_free_blocks(super) + deleted; ++ forroot = reiser4_volume_reserved4user(super, 0, 0); ++ ++ /* ++ * These counters may be in inconsistent state because we take the ++ * values without keeping any global spinlock. Here we do a sanity ++ * check that free block counter does not exceed the number of all ++ * blocks. ++ */ ++ if (free > total) ++ free = total; ++ statfs->f_blocks = total - reserved; ++ /* make sure statfs->f_bfree is never larger than statfs->f_blocks */ ++ if (free > reserved) ++ free -= reserved; ++ else ++ free = 0; ++ statfs->f_bfree = free; ++ ++ if (free > forroot) ++ free -= forroot; ++ else ++ free = 0; ++ statfs->f_bavail = free; ++ ++ statfs->f_files = 0; ++ statfs->f_ffree = 0; ++ /* ++ * maximal acceptable name length depends on directory plugin ++ */ ++ assert("nikita-3351", super->s_root->d_inode != NULL); ++ statfs->f_namelen = reiser4_max_filename_len(super->s_root->d_inode); ++ reiser4_exit_context(ctx); ++ return 0; ++} ++ ++/** ++ * reiser4_writeback_inodes - writeback_inodes of super operations ++ * @super: ++ * @wb: ++ * @wbc: ++ * ++ * This method is called by background and non-backgound writeback. ++ * Reiser4's implementation uses generic_writeback_sb_inodes to call ++ * reiser4_writepages_dispatch for each of dirty inodes. ++ * reiser4_writepages_dispatch handles pages dirtied via shared ++ * mapping - dirty pages get into atoms. Writeout is called to flush ++ * some atoms. ++ */ ++static long reiser4_writeback_inodes(struct super_block *super, ++ struct bdi_writeback *wb, ++ struct writeback_control *wbc, ++ struct wb_writeback_work *work, ++ bool flush_all) ++{ ++ long result; ++ reiser4_context *ctx; ++ ++ if (wbc->for_kupdate) ++ /* reiser4 has its own means of periodical write-out */ ++ goto skip; ++ ++ spin_unlock(&wb->list_lock); ++ ctx = reiser4_init_context(super); ++ if (IS_ERR(ctx)) { ++ warning("vs-13", "failed to init context"); ++ spin_lock(&wb->list_lock); ++ goto skip; ++ } ++ ctx->flush_bd_task = 1; ++ /* ++ * call reiser4_writepages for each of dirty inodes to turn ++ * dirty pages into transactions if they were not yet. ++ */ ++ spin_lock(&wb->list_lock); ++ result = generic_writeback_sb_inodes(super, wb, wbc, work, flush_all); ++ spin_unlock(&wb->list_lock); ++ ++ if (result <= 0) ++ goto exit; ++ wbc->nr_to_write = result; ++ ++ /* flush goes here */ ++ reiser4_writeout(super, wbc); ++ exit: ++ /* avoid recursive calls to ->writeback_inodes */ ++ context_set_commit_async(ctx); ++ reiser4_exit_context(ctx); ++ spin_lock(&wb->list_lock); ++ ++ return result; ++ skip: ++ writeback_skip_sb_inodes(super, wb); ++ return 0; ++} ++ ++/** ++ * ->sync_fs() of super operations ++ */ ++static int reiser4_sync_fs(struct super_block *super, int wait) ++{ ++ reiser4_context *ctx; ++ struct bdi_writeback *wb; ++ struct wb_writeback_work work = { ++ .sb = super, ++ .sync_mode = WB_SYNC_ALL, ++ .range_cyclic = 0, ++ .nr_pages = LONG_MAX, ++ .reason = WB_REASON_SYNC, ++ .for_sync = 1, ++ }; ++ struct writeback_control wbc = { ++ .sync_mode = work.sync_mode, ++ .range_cyclic = work.range_cyclic, ++ .range_start = 0, ++ .range_end = LLONG_MAX, ++ }; ++ ctx = reiser4_init_context(super); ++ if (IS_ERR(ctx)) { ++ warning("edward-1567", "failed to init context"); ++ return PTR_ERR(ctx); ++ } ++ /* ++ * We don't capture superblock here. ++ * Superblock is captured only by operations, which change ++ * its fields different from free_blocks, nr_files, next_oid. ++ * After system crash the mentioned fields are recovered from ++ * journal records, see reiser4_journal_recover_sb_data(). ++ * Also superblock is captured at final commit when releasing ++ * disk format. ++ */ ++ wb = &inode_to_bdi(reiser4_get_super_fake(super))->wb; ++ spin_lock(&wb->list_lock); ++ generic_writeback_sb_inodes(super, wb, &wbc, &work, true); ++ spin_unlock(&wb->list_lock); ++ wbc.nr_to_write = LONG_MAX; ++ /* ++ * (flush goes here) ++ * commit all transactions ++ */ ++ reiser4_writeout(super, &wbc); ++ ++ reiser4_exit_context(ctx); ++ return 0; ++} ++ ++static int reiser4_remount(struct super_block *s, int *mount_flags, char *arg) ++{ ++ sync_filesystem(s); ++ return 0; ++} ++ ++/** ++ * reiser4_show_options - show_options of super operations ++ * @m: file where to write information ++ * @mnt: mount structure ++ * ++ * Makes reiser4 mount options visible in /proc/mounts. ++ */ ++static int reiser4_show_options(struct seq_file *m, struct dentry *dentry) ++{ ++ struct super_block *super; ++ reiser4_super_info_data *sbinfo; ++ ++ super = dentry->d_sb; ++ sbinfo = get_super_private(super); ++ ++ seq_printf(m, ",atom_max_size=0x%x", sbinfo->tmgr.atom_max_size); ++ seq_printf(m, ",atom_max_age=0x%x", sbinfo->tmgr.atom_max_age); ++ seq_printf(m, ",atom_min_size=0x%x", sbinfo->tmgr.atom_min_size); ++ seq_printf(m, ",atom_max_flushers=0x%x", ++ sbinfo->tmgr.atom_max_flushers); ++ seq_printf(m, ",cbk_cache_slots=0x%x", ++ super_meta_subvol(super)->tree.cbk_cache.nr_slots); ++ return 0; ++} ++ ++struct super_operations reiser4_super_operations = { ++ .alloc_inode = reiser4_alloc_inode, ++ .destroy_inode = reiser4_destroy_inode, ++ .dirty_inode = reiser4_dirty_inode, ++ .evict_inode = reiser4_evict_inode, ++ .put_super = reiser4_put_super, ++ .sync_fs = reiser4_sync_fs, ++ .statfs = reiser4_statfs, ++ .remount_fs = reiser4_remount, ++ .writeback_inodes = reiser4_writeback_inodes, ++ .show_options = reiser4_show_options ++}; ++ ++/** ++ * fill_super - initialize super block on mount. ++ * All subvolumes of the volume should be already registered in the system ++ * ++ * @super: super block to fill ++ * @data: reiser4 specific mount option ++ * @silent: ++ */ ++static int fill_super(struct super_block *super, void *data, int silent) ++{ ++ u32 subv_id; ++ reiser4_context ctx; ++ int result; ++ reiser4_super_info_data *sbinfo; ++ lv_conf *conf; ++ u8 vol_uuid[16]; ++ ++ assert("zam-989", super != NULL); ++ ++ super->s_op = NULL; ++ /* ++ * context initialization will be completed after init_volume(), ++ * as we don't know number of subvolumes yet. ++ */ ++ init_stack_context(&ctx, super); ++ /* ++ * allocate reiser4 private super info ++ */ ++ if ((result = reiser4_init_fs_info(super)) != 0) ++ goto failed_init_sinfo; ++ ++ sbinfo = get_super_private(super); ++ ++ if ((result = reiser4_init_csum_tfm(&sbinfo->csum_tfm)) != 0) ++ goto failed_init_csum_tfm; ++ ++ /* initialize various reiser4 parameters, parse mount options */ ++ if ((result = reiser4_init_super_data(super, data)) != 0) ++ goto failed_init_super_data; ++ ++ /* set filesystem blocksize */ ++ if ((result = reiser4_read_master(super, silent, vol_uuid)) != 0) ++ goto failed_read_master; ++ ++ /* initialize transaction manager */ ++ reiser4_init_txnmgr(&sbinfo->tmgr); ++ ++ /* initialize ktxnmgrd context and start kernel thread ktxnmrgd */ ++ if ((result = reiser4_init_ktxnmgrd(super)) != 0) ++ goto failed_init_ktxnmgrd; ++ ++ /* initialize entd context and start kernel thread entd */ ++ if ((result = reiser4_init_entd(super)) != 0) ++ goto failed_init_entd; ++ ++ /* initialize address spaces for formatted nodes and bitmaps */ ++ if ((result = reiser4_init_formatted_fake(super)) != 0) ++ goto failed_init_formatted_fake; ++ ++ /* initialize jnode hash table */ ++ if ((result = reiser4_jnodes_init()) != 0) ++ goto failed_jnodes_init; ++ ++ /* initialize disk formats of all subvolumes */ ++ if ((result = reiser4_activate_volume(super, vol_uuid)) != 0) ++ goto failed_activate_volume; ++ ++ sbinfo->default_uid = 0; ++ sbinfo->default_gid = 0; ++ sbinfo->nr_files_committed = oids_used(super); ++ ++ /* calculate total number of blocks in the logical volume */ ++ conf = sbinfo_conf(sbinfo); ++ for_each_mslot(conf, subv_id) { ++ if (!conf_mslot_at(conf, subv_id)) ++ continue; ++ sbinfo->vol_block_count += ++ conf_origin(conf, subv_id)->block_count; ++ } ++ /* get inode of root directory */ ++ if ((result = reiser4_init_root_inode(super)) != 0) ++ goto failed_init_root_inode; ++ ++ /* finish unfinished truncates */ ++ if ((result = process_safelinks(super, get_meta_subvol()) != 0)) ++ goto failed_process_safelinks; ++ ++ reiser4_exit_context(&ctx); ++ ++ sbinfo->debugfs_root = debugfs_create_dir(super->s_id, ++ reiser4_debugfs_root); ++ if (sbinfo->debugfs_root) { ++ debugfs_create_u32("atom_count", S_IFREG|S_IRUSR, ++ sbinfo->debugfs_root, ++ &sbinfo->tmgr.atom_count); ++ debugfs_create_u32("id_count", S_IFREG|S_IRUSR, ++ sbinfo->debugfs_root, ++ &sbinfo->tmgr.id_count); ++ } ++ return 0; ++ failed_process_safelinks: ++ dput(super->s_root); ++ failed_init_root_inode: ++ reiser4_deactivate_volume(super); ++ failed_activate_volume: ++ reiser4_jnodes_done(); ++ failed_jnodes_init: ++ reiser4_done_formatted_fake(super); ++ failed_init_formatted_fake: ++ reiser4_done_entd(super); ++ failed_init_entd: ++ reiser4_done_ktxnmgrd(super); ++ failed_init_ktxnmgrd: ++ reiser4_done_txnmgr(&sbinfo->tmgr); ++ failed_read_master: ++ failed_init_super_data: ++ failed_init_csum_tfm: ++ reiser4_done_fs_info(super); ++ failed_init_sinfo: ++ reiser4_exit_context(&ctx); ++ return result; ++} ++ ++/** ++ * reiser4_mount - mount of file_system_type operations ++ * @fs_type: ++ * @flags: mount flags ++ * @dev_name: block device file name ++ * @data: specific mount options ++ * ++ * Reiser4 mount entry. ++ */ ++static struct dentry *reiser4_mount(struct file_system_type *fs_type, int flags, ++ const char *dev_name, void *data) ++{ ++ int ret; ++ reiser4_volume *host = NULL; ++ reiser4_subvol *subv = NULL; ++ /* ++ * the volume could be created by old version of reiser4progs, ++ * so try to register it here. ++ */ ++ ret = reiser4_scan_device(dev_name, flags, fs_type, &subv, &host); ++ if (ret) ++ return ERR_PTR(ret); ++ ++ assert("edward-1966", host != NULL); ++ assert("edward-1967", subv != NULL); ++ ++ if (!is_meta_brick_id(subv->id)) { ++ /* ++ * Scan all registered bricks to find meta-data brick ++ */ ++ subv = find_meta_brick_by_id(host); ++ if (subv == NULL) { ++ warning("edward-1968", ++ "%s: meta-data brick is not registered.", ++ dev_name); ++ return ERR_PTR(-EINVAL); ++ } ++ dev_name = subv->name; ++ } ++ return mount_bdev(fs_type, flags, dev_name, data, fill_super); ++} ++ ++/* structure describing the reiser4 filesystem implementation */ ++static struct file_system_type reiser4_fs_type = { ++ .owner = THIS_MODULE, ++ .name = "reiser4", ++ .fs_flags = FS_REQUIRES_DEV, ++ .mount = reiser4_mount, ++ .kill_sb = kill_block_super, ++ .next = NULL ++}; ++ ++void destroy_reiser4_cache(struct kmem_cache **cachep) ++{ ++ BUG_ON(*cachep == NULL); ++ kmem_cache_destroy(*cachep); ++ *cachep = NULL; ++} ++ ++struct file_system_type *get_reiser4_fs_type(void) ++{ ++ return &reiser4_fs_type; ++} ++ ++/** ++ * Used by volume.reiser4 to scan devices when no FS is mounted ++ */ ++static long reiser4_control_ioctl(struct file *file, unsigned int cmd, ++ unsigned long arg) ++{ ++ int ret; ++ struct reiser4_vol_op_args *op_args; ++ ++ if (!capable(CAP_SYS_ADMIN)) ++ return -EPERM; ++ ++ switch (cmd) { ++ case REISER4_IOC_SCAN_DEV: ++ op_args = memdup_user((void __user *)arg, sizeof(*op_args)); ++ if (IS_ERR(op_args)) ++ return PTR_ERR(op_args); ++ ++ ret = reiser4_offline_op(op_args); ++ if (ret) { ++ ON_DEBUG(warning("edward-2315", ++ "off-line volume operation failed (%d)", ret)); ++ kfree(op_args); ++ break; ++ } ++ if (copy_to_user((struct reiser4_vol_op_args __user *)arg, ++ op_args, sizeof(*op_args))) ++ ret = RETERR(-EFAULT); ++ kfree(op_args); ++ break; ++ default: ++ ret = -ENOTTY; ++ break; ++ } ++ return ret; ++} ++ ++static const struct file_operations reiser4_ctl_fops = { ++ .unlocked_ioctl = reiser4_control_ioctl, ++ .compat_ioctl = reiser4_control_ioctl, ++ .owner = THIS_MODULE, ++ .llseek = noop_llseek, ++}; ++ ++static struct miscdevice reiser4_misc = { ++ .minor = REISER4_MINOR, ++ .name = "reiser4-control", ++ .fops = &reiser4_ctl_fops ++}; ++ ++MODULE_ALIAS_MISCDEV(REISER4_MINOR); ++MODULE_ALIAS("devname:reiser4-control"); ++ ++static int reiser4_interface_init(void) ++{ ++ return misc_register(&reiser4_misc); ++} ++ ++static void reiser4_interface_exit(void) ++{ ++ misc_deregister(&reiser4_misc); ++} ++ ++/** ++ * init_reiser4 - reiser4 initialization entry point ++ * ++ * Initializes reiser4 slabs, registers reiser4 filesystem type. It is called ++ * on kernel initialization or during reiser4 module load. ++ */ ++static int __init init_reiser4(void) ++{ ++ int result; ++ ++ printk(KERN_INFO ++ "Loading Reiser4 (Software Framework Release: %d.%d.%d). " ++ "See reiser4.wiki.kernel.org for a description of Reiser4.\n", ++ get_release_number_principal(), ++ get_release_number_major(), ++ get_release_number_minor()); ++ ++ /* initialize slab cache of inodes */ ++ if ((result = init_inodes()) != 0) ++ goto failed_inode_cache; ++ ++ /* initialize cache of znodes */ ++ if ((result = init_znodes()) != 0) ++ goto failed_init_znodes; ++ ++ /* initialize all plugins */ ++ if ((result = init_plugins()) != 0) ++ goto failed_init_plugins; ++ ++ /* initialize cache of plugin_set-s and plugin_set's hash table */ ++ if ((result = init_plugin_set()) != 0) ++ goto failed_init_plugin_set; ++ ++ /* initialize caches of txn_atom-s and txn_handle-s */ ++ if ((result = init_txnmgr_static()) != 0) ++ goto failed_init_txnmgr_static; ++ ++ /* initialize cache of jnodes */ ++ if ((result = init_jnodes()) != 0) ++ goto failed_init_jnodes; ++ ++ /* initialize cache of flush queues */ ++ if ((result = reiser4_init_fqs()) != 0) ++ goto failed_init_fqs; ++ ++ /* initialize cache of structures attached to dentry->d_fsdata */ ++ if ((result = reiser4_init_dentry_fsdata()) != 0) ++ goto failed_init_dentry_fsdata; ++ ++ /* initialize cache of structures attached to file->private_data */ ++ if ((result = reiser4_init_file_fsdata()) != 0) ++ goto failed_init_file_fsdata; ++ /* ++ * initialize cache of d_cursors. See plugin/file_ops_readdir.c for ++ * more details ++ */ ++ if ((result = reiser4_init_d_cursor()) != 0) ++ goto failed_init_d_cursor; ++ ++ /* initialize cache of blocknr set entries */ ++ if ((result = blocknr_set_init_static()) != 0) ++ goto failed_init_blocknr_set; ++ ++ /* initialize cache of blocknr list entries */ ++ if ((result = blocknr_list_init_static()) != 0) ++ goto failed_init_blocknr_list; ++ ++ /* initialize cache of ctx_brick_info */ ++ if ((result = ctx_brick_info_init_static()) != 0) ++ goto failed_init_ctx_brick_info; ++ ++ /* initialize cache of ctx_stack_info */ ++ if ((result = flush_init_static()) != 0) ++ goto failed_init_flush; ++ ++ /* initialize interface */ ++ if ((result = reiser4_interface_init()) != 0) ++ goto failed_init_interface; ++ ++ if ((result = register_filesystem(&reiser4_fs_type)) == 0) { ++ reiser4_debugfs_root = debugfs_create_dir("reiser4", NULL); ++ return 0; ++ } ++ reiser4_interface_exit(); ++ failed_init_interface: ++ done_flush_static(); ++ failed_init_flush: ++ ctx_brick_info_done_static(); ++ failed_init_ctx_brick_info: ++ blocknr_list_done_static(); ++ failed_init_blocknr_list: ++ blocknr_set_done_static(); ++ failed_init_blocknr_set: ++ reiser4_done_d_cursor(); ++ failed_init_d_cursor: ++ reiser4_done_file_fsdata(); ++ failed_init_file_fsdata: ++ reiser4_done_dentry_fsdata(); ++ failed_init_dentry_fsdata: ++ reiser4_done_fqs(); ++ failed_init_fqs: ++ done_jnodes(); ++ failed_init_jnodes: ++ done_txnmgr_static(); ++ failed_init_txnmgr_static: ++ done_plugin_set(); ++ failed_init_plugin_set: ++ failed_init_plugins: ++ done_znodes(); ++ failed_init_znodes: ++ done_inodes(); ++ failed_inode_cache: ++ return result; ++} ++ ++/** ++ * done_reiser4 - reiser4 exit entry point ++ * ++ * Unregister reiser4 filesystem type, deletes caches. It is called on shutdown ++ * or at module unload. ++ */ ++static void __exit done_reiser4(void) ++{ ++ int result; ++ ++ debugfs_remove(reiser4_debugfs_root); ++ result = unregister_filesystem(&reiser4_fs_type); ++ BUG_ON(result != 0); ++ reiser4_interface_exit(); ++ ctx_brick_info_done_static(); ++ blocknr_list_done_static(); ++ blocknr_set_done_static(); ++ reiser4_done_d_cursor(); ++ reiser4_done_file_fsdata(); ++ reiser4_done_dentry_fsdata(); ++ reiser4_done_fqs(); ++ done_jnodes(); ++ done_txnmgr_static(); ++ done_plugin_set(); ++ done_znodes(); ++ destroy_reiser4_cache(&inode_cache); ++ reiser4_unregister_volumes(); ++} ++ ++module_init(init_reiser4); ++module_exit(done_reiser4); ++ ++MODULE_ALIAS_FS("reiser4"); ++ ++MODULE_DESCRIPTION("Reiser4 filesystem"); ++MODULE_AUTHOR("Hans Reiser "); ++ ++MODULE_LICENSE("GPL"); ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tap.c linux-5.10.2/fs/reiser4/tap.c +--- linux-5.10.2.orig/fs/reiser4/tap.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tap.c 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,376 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* ++ Tree Access Pointer (tap). ++ ++ tap is data structure combining coord and lock handle (mostly). It is ++ useful when one has to scan tree nodes (for example, in readdir, or flush), ++ for tap functions allow to move tap in either direction transparently ++ crossing unit/item/node borders. ++ ++ Tap doesn't provide automatic synchronization of its fields as it is ++ supposed to be per-thread object. ++*/ ++ ++#include "forward.h" ++#include "debug.h" ++#include "coord.h" ++#include "tree.h" ++#include "context.h" ++#include "tap.h" ++#include "znode.h" ++#include "tree_walk.h" ++ ++#if REISER4_DEBUG ++static int tap_invariant(const tap_t *tap); ++static void tap_check(const tap_t *tap); ++#else ++#define tap_check(tap) noop ++#endif ++ ++/** load node tap is pointing to, if not loaded already */ ++int reiser4_tap_load(tap_t *tap) ++{ ++ tap_check(tap); ++ if (tap->loaded == 0) { ++ int result; ++ ++ result = zload_ra(tap->coord->node, &tap->ra_info); ++ if (result != 0) ++ return result; ++ coord_clear_iplug(tap->coord); ++ } ++ ++tap->loaded; ++ tap_check(tap); ++ return 0; ++} ++ ++/** release node tap is pointing to. Dual to tap_load() */ ++void reiser4_tap_relse(tap_t *tap) ++{ ++ tap_check(tap); ++ if (tap->loaded > 0) { ++ --tap->loaded; ++ if (tap->loaded == 0) ++ zrelse(tap->coord->node); ++ } ++ tap_check(tap); ++} ++ ++/** ++ * init tap to consist of @coord and @lh. Locks on nodes will be acquired with ++ * @mode ++ */ ++void reiser4_tap_init(tap_t *tap, coord_t *coord, lock_handle * lh, ++ znode_lock_mode mode) ++{ ++ tap->coord = coord; ++ tap->lh = lh; ++ tap->mode = mode; ++ tap->loaded = 0; ++ INIT_LIST_HEAD(&tap->linkage); ++ reiser4_init_ra_info(&tap->ra_info); ++} ++ ++/** add @tap to the per-thread list of all taps */ ++void reiser4_tap_monitor(tap_t *tap) ++{ ++ assert("nikita-2623", tap != NULL); ++ tap_check(tap); ++ list_add(&tap->linkage, reiser4_taps_list()); ++ tap_check(tap); ++} ++ ++/* duplicate @src into @dst. Copy lock handle. @dst is not initially ++ * loaded. */ ++void reiser4_tap_copy(tap_t *dst, tap_t *src) ++{ ++ assert("nikita-3193", src != NULL); ++ assert("nikita-3194", dst != NULL); ++ ++ *dst->coord = *src->coord; ++ if (src->lh->node) ++ copy_lh(dst->lh, src->lh); ++ dst->mode = src->mode; ++ dst->loaded = 0; ++ INIT_LIST_HEAD(&dst->linkage); ++ dst->ra_info = src->ra_info; ++} ++ ++/** finish with @tap */ ++void reiser4_tap_done(tap_t *tap) ++{ ++ assert("nikita-2565", tap != NULL); ++ tap_check(tap); ++ if (tap->loaded > 0) ++ zrelse(tap->coord->node); ++ done_lh(tap->lh); ++ tap->loaded = 0; ++ list_del_init(&tap->linkage); ++ tap->coord->node = NULL; ++} ++ ++/** ++ * move @tap to the new node, locked with @target. Load @target, if @tap was ++ * already loaded. ++ */ ++int reiser4_tap_move(tap_t *tap, lock_handle * target) ++{ ++ int result = 0; ++ ++ assert("nikita-2567", tap != NULL); ++ assert("nikita-2568", target != NULL); ++ assert("nikita-2570", target->node != NULL); ++ assert("nikita-2569", tap->coord->node == tap->lh->node); ++ ++ tap_check(tap); ++ if (tap->loaded > 0) ++ result = zload_ra(target->node, &tap->ra_info); ++ ++ if (result == 0) { ++ if (tap->loaded > 0) ++ zrelse(tap->coord->node); ++ done_lh(tap->lh); ++ copy_lh(tap->lh, target); ++ tap->coord->node = target->node; ++ coord_clear_iplug(tap->coord); ++ } ++ tap_check(tap); ++ return result; ++} ++ ++/** ++ * move @tap to @target. Acquire lock on @target, if @tap was already ++ * loaded. ++ */ ++static int tap_to(tap_t *tap, znode * target) ++{ ++ int result; ++ ++ assert("nikita-2624", tap != NULL); ++ assert("nikita-2625", target != NULL); ++ ++ tap_check(tap); ++ result = 0; ++ if (tap->coord->node != target) { ++ lock_handle here; ++ ++ init_lh(&here); ++ result = longterm_lock_znode(&here, target, ++ tap->mode, ZNODE_LOCK_HIPRI); ++ if (result == 0) { ++ result = reiser4_tap_move(tap, &here); ++ done_lh(&here); ++ } ++ } ++ tap_check(tap); ++ return result; ++} ++ ++/** ++ * move @tap to given @target, loading and locking @target->node if ++ * necessary ++ */ ++int tap_to_coord(tap_t *tap, coord_t *target) ++{ ++ int result; ++ ++ tap_check(tap); ++ result = tap_to(tap, target->node); ++ if (result == 0) ++ coord_dup(tap->coord, target); ++ tap_check(tap); ++ return result; ++} ++ ++/** return list of all taps */ ++struct list_head *reiser4_taps_list(void) ++{ ++ return &get_current_context()->taps; ++} ++ ++/** helper function for go_{next,prev}_{item,unit,node}() */ ++int go_dir_el(tap_t *tap, sideof dir, int units_p) ++{ ++ coord_t dup; ++ coord_t *coord; ++ int result; ++ ++ int (*coord_dir) (coord_t *); ++ int (*get_dir_neighbor) (lock_handle *, znode *, int, int); ++ void (*coord_init) (coord_t *, const znode *); ++ ON_DEBUG(int (*coord_check) (const coord_t *)); ++ ++ assert("nikita-2556", tap != NULL); ++ assert("nikita-2557", tap->coord != NULL); ++ assert("nikita-2558", tap->lh != NULL); ++ assert("nikita-2559", tap->coord->node != NULL); ++ ++ tap_check(tap); ++ if (dir == LEFT_SIDE) { ++ coord_dir = units_p ? coord_prev_unit : coord_prev_item; ++ get_dir_neighbor = reiser4_get_left_neighbor; ++ coord_init = coord_init_last_unit; ++ } else { ++ coord_dir = units_p ? coord_next_unit : coord_next_item; ++ get_dir_neighbor = reiser4_get_right_neighbor; ++ coord_init = coord_init_first_unit; ++ } ++ ON_DEBUG(coord_check = ++ units_p ? coord_is_existing_unit : coord_is_existing_item); ++ assert("nikita-2560", coord_check(tap->coord)); ++ ++ coord = tap->coord; ++ coord_dup(&dup, coord); ++ if (coord_dir(&dup) != 0) { ++ do { ++ /* move to the left neighboring node */ ++ lock_handle dup; ++ ++ init_lh(&dup); ++ result = ++ get_dir_neighbor(&dup, coord->node, (int)tap->mode, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result == 0) { ++ result = reiser4_tap_move(tap, &dup); ++ if (result == 0) ++ coord_init(tap->coord, dup.node); ++ done_lh(&dup); ++ } ++ /* skip empty nodes */ ++ } while ((result == 0) && node_is_empty(coord->node)); ++ } else { ++ result = 0; ++ coord_dup(coord, &dup); ++ } ++ assert("nikita-2564", ergo(!result, coord_check(tap->coord))); ++ tap_check(tap); ++ return result; ++} ++ ++/** ++ * move @tap to the next unit, transparently crossing item and node ++ * boundaries ++ */ ++int go_next_unit(tap_t *tap) ++{ ++ return go_dir_el(tap, RIGHT_SIDE, 1); ++} ++ ++/** ++ * move @tap to the previous unit, transparently crossing item and node ++ * boundaries ++ */ ++int go_prev_unit(tap_t *tap) ++{ ++ return go_dir_el(tap, LEFT_SIDE, 1); ++} ++ ++/** ++ * @shift times apply @actor to the @tap. This is used to move @tap by ++ * @shift units (or items, or nodes) in either direction. ++ */ ++static int rewind_to(tap_t *tap, go_actor_t actor, int shift) ++{ ++ int result; ++ ++ assert("nikita-2555", shift >= 0); ++ assert("nikita-2562", tap->coord->node == tap->lh->node); ++ ++ tap_check(tap); ++ result = reiser4_tap_load(tap); ++ if (result != 0) ++ return result; ++ ++ for (; shift > 0; --shift) { ++ result = actor(tap); ++ assert("nikita-2563", tap->coord->node == tap->lh->node); ++ if (result != 0) ++ break; ++ } ++ reiser4_tap_relse(tap); ++ tap_check(tap); ++ return result; ++} ++ ++/** move @tap @shift units rightward */ ++int rewind_right(tap_t *tap, int shift) ++{ ++ return rewind_to(tap, go_next_unit, shift); ++} ++ ++/** move @tap @shift units leftward */ ++int rewind_left(tap_t *tap, int shift) ++{ ++ return rewind_to(tap, go_prev_unit, shift); ++} ++ ++#if REISER4_DEBUG ++/** debugging function: print @tap content in human readable form */ ++static void print_tap(const char *prefix, const tap_t *tap) ++{ ++ if (tap == NULL) { ++ printk("%s: null tap\n", prefix); ++ return; ++ } ++ printk("%s: loaded: %i, in-list: %i, node: %p, mode: %s\n", prefix, ++ tap->loaded, (&tap->linkage == tap->linkage.next && ++ &tap->linkage == tap->linkage.prev), ++ tap->lh->node, ++ lock_mode_name(tap->mode)); ++ print_coord("\tcoord", tap->coord, 0); ++} ++ ++/** check [tap-sane] invariant */ ++static int tap_invariant(const tap_t *tap) ++{ ++ /* [tap-sane] invariant */ ++ ++ if (tap == NULL) ++ return 1; ++ /* tap->mode is one of ++ * ++ * {ZNODE_NO_LOCK, ZNODE_READ_LOCK, ZNODE_WRITE_LOCK}, and ++ */ ++ if (tap->mode != ZNODE_NO_LOCK && ++ tap->mode != ZNODE_READ_LOCK && tap->mode != ZNODE_WRITE_LOCK) ++ return 2; ++ /* tap->coord != NULL, and */ ++ if (tap->coord == NULL) ++ return 3; ++ /* tap->lh != NULL, and */ ++ if (tap->lh == NULL) ++ return 4; ++ /* tap->loaded > 0 => znode_is_loaded(tap->coord->node), and */ ++ if (!ergo(tap->loaded, znode_is_loaded(tap->coord->node))) ++ return 5; ++ /* tap->coord->node == tap->lh->node if tap->lh->node is not 0 */ ++ if (tap->lh->node != NULL && tap->coord->node != tap->lh->node) ++ return 6; ++ return 0; ++} ++ ++/** debugging function: check internal @tap consistency */ ++static void tap_check(const tap_t *tap) ++{ ++ int result; ++ ++ result = tap_invariant(tap); ++ if (result != 0) { ++ print_tap("broken", tap); ++ reiser4_panic("nikita-2831", "tap broken: %i\n", result); ++ } ++} ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tap.h linux-5.10.2/fs/reiser4/tap.h +--- linux-5.10.2.orig/fs/reiser4/tap.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tap.h 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,70 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* Tree Access Pointers. See tap.c for more details. */ ++ ++#if !defined(__REISER4_TAP_H__) ++#define __REISER4_TAP_H__ ++ ++#include "forward.h" ++#include "readahead.h" ++ ++/** ++ tree_access_pointer aka tap. Data structure combining coord_t and lock ++ handle. ++ Invariants involving this data-type, see doc/lock-ordering for details: ++ ++ [tap-sane] ++ */ ++struct tree_access_pointer { ++ /* coord tap is at */ ++ coord_t *coord; ++ /* lock handle on ->coord->node */ ++ lock_handle *lh; ++ /* mode of lock acquired by this tap */ ++ znode_lock_mode mode; ++ /* incremented by reiser4_tap_load(). ++ Decremented by reiser4_tap_relse(). */ ++ int loaded; ++ /* list of taps */ ++ struct list_head linkage; ++ /* read-ahead hint */ ++ ra_info_t ra_info; ++}; ++ ++typedef int (*go_actor_t) (tap_t *tap); ++ ++extern int reiser4_tap_load(tap_t *tap); ++extern void reiser4_tap_relse(tap_t *tap); ++extern void reiser4_tap_init(tap_t *tap, coord_t *coord, lock_handle * lh, ++ znode_lock_mode mode); ++extern void reiser4_tap_monitor(tap_t *tap); ++extern void reiser4_tap_copy(tap_t *dst, tap_t *src); ++extern void reiser4_tap_done(tap_t *tap); ++extern int reiser4_tap_move(tap_t *tap, lock_handle * target); ++extern int tap_to_coord(tap_t *tap, coord_t *target); ++ ++extern int go_dir_el(tap_t *tap, sideof dir, int units_p); ++extern int go_next_unit(tap_t *tap); ++extern int go_prev_unit(tap_t *tap); ++extern int rewind_right(tap_t *tap, int shift); ++extern int rewind_left(tap_t *tap, int shift); ++ ++extern struct list_head *reiser4_taps_list(void); ++ ++#define for_all_taps(tap) \ ++ for (tap = list_entry(reiser4_taps_list()->next, tap_t, linkage); \ ++ reiser4_taps_list() != &tap->linkage; \ ++ tap = list_entry(tap->linkage.next, tap_t, linkage)) ++ ++/* __REISER4_TAP_H__ */ ++#endif ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree.c linux-5.10.2/fs/reiser4/tree.c +--- linux-5.10.2.orig/fs/reiser4/tree.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree.c 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,1964 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* ++ * KEYS IN A TREE. ++ * ++ * The tree consists of nodes located on the disk. Node in the tree is either ++ * formatted or unformatted. Formatted node is one that has structure ++ * understood by the tree balancing and traversal code. Formatted nodes are ++ * further classified into leaf and internal nodes. Latter distinctions is ++ * (almost) of only historical importance: general structure of leaves and ++ * internal nodes is the same in Reiser4. Unformatted nodes contain raw data ++ * that are part of bodies of ordinary files and attributes. ++ * ++ * Each node in the tree spawns some interval in the key space. Key ranges for ++ * all nodes in the tree are disjoint. Actually, this only holds in some weak ++ * sense, because of the non-unique keys: intersection of key ranges for ++ * different nodes is either empty, or consists of exactly one key. ++ * ++ * Formatted node consists of a sequence of items. Each item spawns some ++ * interval in key space. Key ranges for all items in a tree are disjoint, ++ * modulo non-unique keys again. Items within nodes are ordered in the key ++ * order of the smallest key in a item. ++ * ++ * Particular type of item can be further split into units. Unit is piece of ++ * item that can be cut from item and moved into another item of the same ++ * time. Units are used by balancing code to repack data during balancing. ++ * ++ * Unit can be further split into smaller entities (for example, extent unit ++ * represents several pages, and it is natural for extent code to operate on ++ * particular pages and even bytes within one unit), but this is of no ++ * relevance to the generic balancing and lookup code. ++ * ++ * Although item is said to "spawn" range or interval of keys, it is not ++ * necessary that item contains piece of data addressable by each and every ++ * key in this range. For example, compound directory item, consisting of ++ * units corresponding to directory entries and keyed by hashes of file names, ++ * looks more as having "discrete spectrum": only some disjoint keys inside ++ * range occupied by this item really address data. ++ * ++ * No than less, each item always has well-defined least (minimal) key, that ++ * is recorded in item header, stored in the node this item is in. Also, item ++ * plugin can optionally define method ->max_key_inside() returning maximal ++ * key that can _possibly_ be located within this item. This method is used ++ * (mainly) to determine when given piece of data should be merged into ++ * existing item, in stead of creating new one. Because of this, even though ++ * ->max_key_inside() can be larger that any key actually located in the item, ++ * intervals ++ * ++ * [ reiser4_min_key( item ), ->max_key_inside( item ) ] ++ * ++ * are still disjoint for all items within the _same_ node. ++ * ++ * In memory node is represented by znode. It plays several roles: ++ * ++ * . something locks are taken on ++ * ++ * . something tracked by transaction manager (this is going to change) ++ * ++ * . something used to access node data ++ * ++ * . something used to maintain tree structure in memory: sibling and ++ * parental linkage. ++ * ++ * . something used to organize nodes into "slums" ++ * ++ * More on znodes see in znode.[ch] ++ * ++ * DELIMITING KEYS ++ * ++ * To simplify balancing, allow some flexibility in locking and speed up ++ * important coord cache optimization, we keep delimiting keys of nodes in ++ * memory. Depending on disk format (implemented by appropriate node plugin) ++ * node on disk can record both left and right delimiting key, only one of ++ * them, or none. Still, our balancing and tree traversal code keep both ++ * delimiting keys for a node that is in memory stored in the znode. When ++ * node is first brought into memory during tree traversal, its left ++ * delimiting key is taken from its parent, and its right delimiting key is ++ * either next key in its parent, or is right delimiting key of parent if ++ * node is the rightmost child of parent. ++ * ++ * Physical consistency of delimiting key is protected by special dk ++ * read-write lock. That is, delimiting keys can only be inspected or ++ * modified under this lock. But dk lock is only sufficient for fast ++ * "pessimistic" check, because to simplify code and to decrease lock ++ * contention, balancing (carry) only updates delimiting keys right before ++ * unlocking all locked nodes on the given tree level. For example, ++ * coord-by-key cache scans LRU list of recently accessed znodes. For each ++ * node it first does fast check under dk spin lock. If key looked for is ++ * not between delimiting keys for this node, next node is inspected and so ++ * on. If key is inside of the key range, long term lock is taken on node ++ * and key range is rechecked. ++ * ++ * COORDINATES ++ * ++ * To find something in the tree, you supply a key, and the key is resolved ++ * by coord_by_key() into a coord (coordinate) that is valid as long as the ++ * node the coord points to remains locked. As mentioned above trees ++ * consist of nodes that consist of items that consist of units. A unit is ++ * the smallest and indivisible piece of tree as far as balancing and tree ++ * search are concerned. Each node, item, and unit can be addressed by ++ * giving its level in the tree and the key occupied by this entity. A node ++ * knows what the key ranges are of the items within it, and how to find its ++ * items and invoke their item handlers, but it does not know how to access ++ * individual units within its items except through the item handlers. ++ * coord is a structure containing a pointer to the node, the ordinal number ++ * of the item within this node (a sort of item offset), and the ordinal ++ * number of the unit within this item. ++ * ++ * TREE LOOKUP ++ * ++ * There are two types of access to the tree: lookup and modification. ++ * ++ * Lookup is a search for the key in the tree. Search can look for either ++ * exactly the key given to it, or for the largest key that is not greater ++ * than the key given to it. This distinction is determined by "bias" ++ * parameter of search routine (coord_by_key()). coord_by_key() either ++ * returns error (key is not in the tree, or some kind of external error ++ * occurred), or successfully resolves key into coord. ++ * ++ * This resolution is done by traversing tree top-to-bottom from root level ++ * to the desired level. On levels above twig level (level one above the ++ * leaf level) nodes consist exclusively of internal items. Internal item is ++ * nothing more than pointer to the tree node on the child level. On twig ++ * level nodes consist of internal items intermixed with extent ++ * items. Internal items form normal search tree structure used by traversal ++ * to descent through the tree. ++ * ++ * TREE LOOKUP OPTIMIZATIONS ++ * ++ * Tree lookup described above is expensive even if all nodes traversed are ++ * already in the memory: for each node binary search within it has to be ++ * performed and binary searches are CPU consuming and tend to destroy CPU ++ * caches. ++ * ++ * Several optimizations are used to work around this: ++ * ++ * . cbk_cache (look-aside cache for tree traversals, see search.c for ++ * details) ++ * ++ * . seals (see seal.[ch]) ++ * ++ * . vroot (see search.c) ++ * ++ * General search-by-key is layered thusly: ++ * ++ * [check seal, if any] --ok--> done ++ * | ++ * failed ++ * | ++ * V ++ * [vroot defined] --no--> node = tree_root ++ * | | ++ * yes | ++ * | | ++ * V | ++ * node = vroot | ++ * | | ++ * | | ++ * | | ++ * V V ++ * [check cbk_cache for key] --ok--> done ++ * | ++ * failed ++ * | ++ * V ++ * [start tree traversal from node] ++ * ++ */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/item/static_stat.h" ++#include "plugin/item/item.h" ++#include "plugin/node/node.h" ++#include "plugin/plugin.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "carry.h" ++#include "carry_ops.h" ++#include "tap.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "page_cache.h" ++#include "super.h" ++#include "reiser4.h" ++#include "inode.h" ++ ++#include /* for struct super_block */ ++#include ++ ++/* Disk address (block number) never ever used for any real tree node. This is ++ used as block number of "uber" znode. ++ ++ Invalid block addresses are 0 by tradition. ++ ++*/ ++const reiser4_block_nr UBER_TREE_ADDR = 0ull; ++ ++#define CUT_TREE_MIN_ITERATIONS 64 ++ ++static int find_child_by_addr(znode * parent, znode * child, coord_t *result); ++ ++/* return node plugin of coord->node */ ++node_plugin *node_plugin_by_coord(const coord_t *coord) ++{ ++ assert("vs-1", coord != NULL); ++ assert("vs-2", coord->node != NULL); ++ ++ return coord->node->nplug; ++} ++ ++/* insert item into tree. Fields of @coord are updated so that they can be ++ * used by consequent insert operation. */ ++insert_result insert_by_key(reiser4_tree * tree /* tree to insert new item ++ * into */ , ++ const reiser4_key * key /* key of new item */ , ++ reiser4_item_data * data /* parameters for item ++ * creation */ , ++ coord_t *coord /* resulting insertion coord */ , ++ lock_handle * lh /* resulting lock ++ * handle */ , ++ tree_level stop_level /* level where to insert */ , ++ __u32 flags/* insertion flags */) ++{ ++ int result; ++ ++ assert("nikita-358", tree != NULL); ++ assert("nikita-360", coord != NULL); ++ ++ result = coord_by_key(tree, key, coord, lh, ZNODE_WRITE_LOCK, ++ FIND_EXACT, stop_level, stop_level, ++ flags | CBK_FOR_INSERT, NULL/*ra_info */); ++ switch (result) { ++ default: ++ break; ++ case CBK_COORD_FOUND: ++ result = IBK_ALREADY_EXISTS; ++ break; ++ case CBK_COORD_NOTFOUND: ++ assert("nikita-2017", coord->node != NULL); ++ result = insert_by_coord(coord, data, key, lh, 0/*flags */); ++ break; ++ } ++ return result; ++} ++ ++/* insert item by calling carry. Helper function called if short-cut ++ insertion failed */ ++static insert_result insert_with_carry_by_coord(coord_t *coord, ++ /* coord where to insert */ ++ lock_handle * lh, ++ /* lock handle of insertion node */ ++ reiser4_item_data * data, ++ /* parameters of new item */ ++ const reiser4_key * key, ++ /* key of new item */ ++ carry_opcode cop, ++ /* carry operation to perform */ ++ cop_insert_flag flags ++ /* carry flags */ ) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ carry_insert_data *cdata; ++ carry_op *op; ++ ++ assert("umka-314", coord != NULL); ++ ++ /* allocate carry_pool and 3 carry_level-s */ ++ pool = ++ init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(*cdata)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ ++ op = reiser4_post_carry(lowest_level, cop, coord->node, 0); ++ if (IS_ERR(op) || (op == NULL)) { ++ done_carry_pool(pool); ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ } ++ cdata = (carry_insert_data *) (lowest_level + 3); ++ cdata->coord = coord; ++ cdata->data = data; ++ cdata->key = key; ++ op->u.insert.d = cdata; ++ if (flags == 0) ++ flags = znode_get_tree(coord->node)->carry.insert_flags; ++ op->u.insert.flags = flags; ++ op->u.insert.type = COPT_ITEM_DATA; ++ op->u.insert.child = NULL; ++ if (lh != NULL) { ++ assert("nikita-3245", lh->node == coord->node); ++ lowest_level->track_type = CARRY_TRACK_CHANGE; ++ lowest_level->tracked = lh; ++ } ++ ++ result = reiser4_carry(lowest_level, NULL); ++ done_carry_pool(pool); ++ ++ return result; ++} ++ ++/* form carry queue to perform paste of @data with @key at @coord, and launch ++ its execution by calling carry(). ++ ++ Instruct carry to update @lh it after balancing insertion coord moves into ++ different block. ++ ++*/ ++static int paste_with_carry(coord_t *coord, /* coord of paste */ ++ lock_handle * lh, /* lock handle of node ++ * where item is ++ * pasted */ ++ reiser4_item_data * data, /* parameters of new ++ * item */ ++ const reiser4_key * key, /* key of new item */ ++ unsigned flags/* paste flags */) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ carry_insert_data *cdata; ++ carry_op *op; ++ ++ assert("umka-315", coord != NULL); ++ assert("umka-316", key != NULL); ++ ++ pool = ++ init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(*cdata)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ ++ op = reiser4_post_carry(lowest_level, COP_PASTE, coord->node, 0); ++ if (IS_ERR(op) || (op == NULL)) { ++ done_carry_pool(pool); ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ } ++ cdata = (carry_insert_data *) (lowest_level + 3); ++ cdata->coord = coord; ++ cdata->data = data; ++ cdata->key = key; ++ op->u.paste.d = cdata; ++ if (flags == 0) ++ flags = znode_get_tree(coord->node)->carry.paste_flags; ++ op->u.paste.flags = flags; ++ op->u.paste.type = COPT_ITEM_DATA; ++ if (lh != NULL) { ++ lowest_level->track_type = CARRY_TRACK_CHANGE; ++ lowest_level->tracked = lh; ++ } ++ ++ result = reiser4_carry(lowest_level, NULL); ++ done_carry_pool(pool); ++ ++ return result; ++} ++ ++/* insert item at the given coord. ++ ++ First try to skip carry by directly calling ->create_item() method of node ++ plugin. If this is impossible (there is not enough free space in the node, ++ or leftmost item in the node is created), call insert_with_carry_by_coord() ++ that will do full carry(). ++ ++*/ ++insert_result insert_by_coord(coord_t *coord /* coord where to ++ * insert. coord->node has ++ * to be write locked by ++ * caller */ , ++ reiser4_item_data * data /* data to be ++ * inserted */ , ++ const reiser4_key * key /* key of new item */ , ++ lock_handle * lh /* lock handle of write ++ * lock on node */ , ++ __u32 flags/* insertion flags */) ++{ ++ unsigned item_size; ++ int result; ++ znode *node; ++ ++ assert("vs-247", coord != NULL); ++ assert("vs-248", data != NULL); ++ assert("vs-249", data->length >= 0); ++ assert("nikita-1191", znode_is_write_locked(coord->node)); ++ ++ node = coord->node; ++ coord_clear_iplug(coord); ++ result = zload(node); ++ if (result != 0) ++ return result; ++ ++ item_size = space_needed(node, NULL, data, 1); ++ if (item_size > znode_free_space(node) && ++ (flags & COPI_DONT_SHIFT_LEFT) && (flags & COPI_DONT_SHIFT_RIGHT) ++ && (flags & COPI_DONT_ALLOCATE)) { ++ /* we are forced to use free space of coord->node and new item ++ does not fit into it. ++ ++ Currently we get here only when we allocate and copy units ++ of extent item from a node to its left neighbor during ++ "squalloc"-ing. If @node (this is left neighbor) does not ++ have enough free space - we do not want to attempt any ++ shifting and allocations because we are in squeezing and ++ everything to the left of @node is tightly packed. ++ */ ++ result = -E_NODE_FULL; ++ } else if ((item_size <= znode_free_space(node)) && ++ !coord_is_before_leftmost(coord) && ++ (node_plugin_by_node(node)->fast_insert != NULL) ++ && node_plugin_by_node(node)->fast_insert(coord)) { ++ /* shortcut insertion without carry() overhead. ++ ++ Only possible if: ++ ++ - there is enough free space ++ ++ - insertion is not into the leftmost position in a node ++ (otherwise it would require updating of delimiting key in a ++ parent) ++ ++ - node plugin agrees with this ++ ++ */ ++ result = ++ node_plugin_by_node(node)->create_item(coord, key, data, ++ NULL); ++ znode_make_dirty(node); ++ } else { ++ /* otherwise do full-fledged carry(). */ ++ result = ++ insert_with_carry_by_coord(coord, lh, data, key, COP_INSERT, ++ flags); ++ } ++ zrelse(node); ++ return result; ++} ++ ++/* @coord is set to leaf level and @data is to be inserted to twig level */ ++insert_result ++insert_extent_by_coord(coord_t *coord, /* coord where to insert. ++ * coord->node has to be write ++ * locked by caller */ ++ reiser4_item_data *data,/* data to be inserted */ ++ const reiser4_key *key, /* key of new item */ ++ lock_handle *lh /* lock handle of write lock ++ on node */) ++{ ++ assert("vs-405", coord != NULL); ++ assert("vs-406", data != NULL); ++ assert("vs-407", data->length > 0); ++ assert("vs-408", znode_is_write_locked(coord->node)); ++ assert("vs-409", znode_get_level(coord->node) == LEAF_LEVEL); ++ ++ return insert_with_carry_by_coord(coord, lh, data, key, COP_EXTENT, ++ 0 /*flags */ ); ++} ++ ++/* Insert into the item at the given coord. ++ ++ First try to skip carry by directly calling ->paste() method of item ++ plugin. If this is impossible (there is not enough free space in the node, ++ or we are pasting into leftmost position in the node), call ++ paste_with_carry() that will do full carry(). ++ ++*/ ++/* paste_into_item */ ++int insert_into_item(coord_t * coord /* coord of pasting */ , ++ lock_handle * lh /* lock handle on node involved */ , ++ const reiser4_key * key /* key of unit being pasted */ , ++ reiser4_item_data * data /* parameters for new unit */ , ++ unsigned flags /* insert/paste flags */ ) ++{ ++ int result; ++ int size_change; ++ node_plugin *nplug; ++ item_plugin *iplug; ++ ++ assert("umka-317", coord != NULL); ++ assert("umka-318", key != NULL); ++ ++ iplug = item_plugin_by_coord(coord); ++ nplug = node_plugin_by_coord(coord); ++ ++ assert("nikita-1480", iplug == data->iplug); ++ ++ size_change = space_needed(coord->node, coord, data, 0); ++ if (size_change > (int)znode_free_space(coord->node) && ++ (flags & COPI_DONT_SHIFT_LEFT) && (flags & COPI_DONT_SHIFT_RIGHT) ++ && (flags & COPI_DONT_ALLOCATE)) { ++ /* we are forced to use free space of coord->node and new data ++ does not fit into it. */ ++ return -E_NODE_FULL; ++ } ++ ++ /* shortcut paste without carry() overhead. ++ ++ Only possible if: ++ ++ - there is enough free space ++ ++ - paste is not into the leftmost unit in a node (otherwise ++ it would require updating of delimiting key in a parent) ++ ++ - node plugin agrees with this ++ ++ - item plugin agrees with us ++ */ ++ if (size_change <= (int)znode_free_space(coord->node) && ++ (coord->item_pos != 0 || ++ coord->unit_pos != 0 || coord->between == AFTER_UNIT) && ++ coord->unit_pos != 0 && nplug->fast_paste != NULL && ++ nplug->fast_paste(coord) && ++ iplug->b.fast_paste != NULL && iplug->b.fast_paste(coord)) { ++ if (size_change > 0) ++ nplug->change_item_size(coord, size_change); ++ /* NOTE-NIKITA: huh? where @key is used? */ ++ result = iplug->b.paste(coord, data, NULL); ++ if (size_change < 0) ++ nplug->change_item_size(coord, size_change); ++ znode_make_dirty(coord->node); ++ } else ++ /* otherwise do full-fledged carry(). */ ++ result = paste_with_carry(coord, lh, data, key, flags); ++ return result; ++} ++ ++/* this either appends or truncates item @coord */ ++int reiser4_resize_item(coord_t * coord /* coord of item being resized */ , ++ reiser4_item_data * data /* parameters of resize */ , ++ reiser4_key * key /* key of new unit */ , ++ lock_handle * lh /* lock handle of node ++ * being modified */ , ++ cop_insert_flag flags /* carry flags */ ) ++{ ++ int result; ++ znode *node; ++ ++ assert("nikita-362", coord != NULL); ++ assert("nikita-363", data != NULL); ++ assert("vs-245", data->length != 0); ++ ++ node = coord->node; ++ coord_clear_iplug(coord); ++ result = zload(node); ++ if (result != 0) ++ return result; ++ ++ if (data->length < 0) ++ result = node_plugin_by_coord(coord)->shrink_item(coord, ++ -data->length); ++ else ++ result = insert_into_item(coord, lh, key, data, flags); ++ ++ zrelse(node); ++ return result; ++} ++ ++/* insert flow @f */ ++int reiser4_insert_flow(coord_t * coord, lock_handle * lh, flow_t * f) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ reiser4_item_data *data; ++ carry_op *op; ++ ++ pool = ++ init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(*data)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ ++ op = reiser4_post_carry(lowest_level, COP_INSERT_FLOW, coord->node, ++ 0 /* operate directly on coord -> node */ ); ++ if (IS_ERR(op) || (op == NULL)) { ++ done_carry_pool(pool); ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ } ++ ++ /* these are permanent during insert_flow */ ++ data = (reiser4_item_data *) (lowest_level + 3); ++ data->user = 1; ++ data->iplug = item_plugin_by_id(FORMATTING_ID); ++ data->arg = NULL; ++ /* data.length and data.data will be set before calling paste or ++ insert */ ++ data->length = 0; ++ data->data = NULL; ++ ++ op->u.insert_flow.flags = 0; ++ op->u.insert_flow.insert_point = coord; ++ op->u.insert_flow.flow = f; ++ op->u.insert_flow.data = data; ++ op->u.insert_flow.new_nodes = 0; ++ ++ lowest_level->track_type = CARRY_TRACK_CHANGE; ++ lowest_level->tracked = lh; ++ ++ result = reiser4_carry(lowest_level, NULL); ++ done_carry_pool(pool); ++ ++ return result; ++} ++ ++/* Given a coord in parent node, obtain a znode for the corresponding child */ ++znode *child_znode(const coord_t * parent_coord /* coord of pointer to ++ * child */ , ++ znode * parent /* parent of child */ , ++ int incore_p /* if !0 only return child if already in ++ * memory */ , ++ int setup_dkeys_p /* if !0 update delimiting keys of ++ * child */ ) ++{ ++ znode *child; ++ ++ assert("nikita-1374", parent_coord != NULL); ++ assert("nikita-1482", parent != NULL); ++#if REISER4_DEBUG ++ if (setup_dkeys_p) ++ assert_rw_not_locked(&(znode_get_tree(parent)->dk_lock)); ++#endif ++ assert("nikita-2947", znode_is_any_locked(parent)); ++ ++ if (znode_get_level(parent) <= LEAF_LEVEL) { ++ /* trying to get child of leaf node */ ++ warning("nikita-1217", "Child of maize?"); ++ return ERR_PTR(RETERR(-EIO)); ++ } ++ if (item_is_internal(parent_coord)) { ++ reiser4_block_nr addr; ++ item_plugin *iplug; ++ struct reiser4_subvol *subv; ++ ++ iplug = item_plugin_by_coord(parent_coord); ++ assert("vs-512", iplug->s.internal.down_link); ++ iplug->s.internal.down_link(parent_coord, NULL, &addr); ++ ++ subv = znode_get_subvol(parent); ++ if (incore_p) ++ child = zlook(&subv->tree, &addr); ++ else ++ child = zget(subv, &addr, parent, ++ znode_get_level(parent) - 1, ++ reiser4_ctx_gfp_mask_get()); ++ if ((child != NULL) && !IS_ERR(child) && setup_dkeys_p) ++ set_child_delimiting_keys(parent, parent_coord, child); ++ } else { ++ warning("nikita-1483", "Internal item expected"); ++ child = ERR_PTR(RETERR(-EIO)); ++ } ++ return child; ++} ++ ++/* remove znode from transaction */ ++static void uncapture_znode(znode *node) ++{ ++ struct page *page; ++ ++ assert("zam-1001", ZF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ ++ if (!reiser4_blocknr_is_fake(znode_get_block(node))) { ++ int ret; ++ /* ++ * An already allocated block goes right to the atom's ++ * delete set ++ */ ++ ret = reiser4_dealloc_block(znode_get_block(node), 0, ++ BA_DEFER | BA_FORMATTED, ++ znode_get_subvol(node)); ++ if (ret) ++ warning("zam-942", ++ "can\'t add a block (%llu) number to atom's delete set\n", ++ (unsigned long long)(*znode_get_block(node))); ++ ++ spin_lock_znode(node); ++ /* ++ * Here we return flush reserved block which was reserved ++ * at the moment when this allocated node was marked dirty ++ * and still not used by flush in node relocation procedure ++ */ ++ if (ZF_ISSET(node, JNODE_FLUSH_RESERVED)) { ++ txn_atom *atom; ++ atom_brick_info *abi; ++ ctx_brick_info *cbi; ++ ++ atom = jnode_get_atom(ZJNODE(node)); ++ assert("zam-939", atom != NULL); ++ ++ spin_unlock_znode(node); ++ ++ cbi = find_context_brick_info(get_current_context(), ++ znode_get_subvol(node)->id); ++ assert("edward-2005", cbi != NULL); ++ ++ abi = find_atom_brick_info(&atom->bricks_info, ++ znode_get_subvol(node)->id); ++ assert("edward-2006", abi != NULL); ++ ++ flush_reserved2grabbed(abi, cbi, ++ (__u64) 1, ++ znode_get_subvol(node)); ++ spin_unlock_atom(atom); ++ } else ++ spin_unlock_znode(node); ++ } else { ++ /* ++ * znode has assigned block which is counted as "fake ++ * allocated". Return it back to "free blocks" ++ */ ++ fake_allocated2free((__u64) 1, ++ BA_FORMATTED, znode_get_subvol(node)); ++ } ++ /* ++ * uncapture page from transaction. There is a possibility of a race ++ * with ->releasepage(): reiser4_releasepage() detaches page from this ++ * jnode and we have nothing to uncapture. To avoid this, get ++ * reference of node->pg under jnode spin lock. reiser4_uncapture_page() ++ * will deal with released page itself. ++ */ ++ spin_lock_znode(node); ++ page = znode_page(node); ++ if (likely(page != NULL)) { ++ /* ++ * reiser4_uncapture_page() can only be called when we are sure ++ * that znode is pinned in memory, which we are, because ++ * forget_znode() is only called from longterm_unlock_znode(). ++ */ ++ get_page(page); ++ spin_unlock_znode(node); ++ lock_page(page); ++ reiser4_uncapture_page(page); ++ unlock_page(page); ++ put_page(page); ++ } else { ++ txn_atom *atom; ++ ++ /* handle "flush queued" znodes */ ++ while (1) { ++ atom = jnode_get_atom(ZJNODE(node)); ++ assert("zam-943", atom != NULL); ++ ++ if (!ZF_ISSET(node, JNODE_FLUSH_QUEUED) ++ || !atom->nr_running_queues) ++ break; ++ ++ spin_unlock_znode(node); ++ reiser4_atom_wait_event(atom); ++ spin_lock_znode(node); ++ } ++ ++ reiser4_uncapture_block(ZJNODE(node)); ++ spin_unlock_atom(atom); ++ zput(node); ++ } ++} ++ ++/* This is called from longterm_unlock_znode() when last lock is released from ++ the node that has been removed from the tree. At this point node is removed ++ from sibling list and its lock is invalidated. */ ++void forget_znode(lock_handle * handle) ++{ ++ znode *node; ++ reiser4_tree *tree; ++ ++ assert("umka-319", handle != NULL); ++ ++ node = handle->node; ++ tree = znode_get_tree(node); ++ ++ assert("vs-164", znode_is_write_locked(node)); ++ assert("nikita-1280", ZF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ assert_rw_locked(&(node->lock.guard)); ++ ++ /* We assume that this node was detached from its parent before ++ * unlocking, it gives no way to reach this node from parent through a ++ * down link. The node should have no children and, thereby, can't be ++ * reached from them by their parent pointers. The only way to obtain a ++ * reference to the node is to use sibling pointers from its left and ++ * right neighbors. In the next several lines we remove the node from ++ * the sibling list. */ ++ ++ write_lock_tree(); ++ sibling_list_remove(node); ++ znode_remove(node); ++ write_unlock_tree(); ++ ++ /* Here we set JNODE_DYING and cancel all pending lock requests. It ++ * forces all lock requestor threads to repeat iterations of getting ++ * lock on a child, neighbor or parent node. But, those threads can't ++ * come to this node again, because this node is no longer a child, ++ * neighbor or parent of any other node. This order of znode ++ * invalidation does not allow other threads to waste cpu time is a busy ++ * loop, trying to lock dying object. The exception is in the flush ++ * code when we take node directly from atom's capture list.*/ ++ reiser4_invalidate_lock(handle); ++ uncapture_znode(node); ++} ++ ++/* Check that internal item at @pointer really contains pointer to @child. */ ++int check_tree_pointer(const coord_t * pointer /* would-be pointer to ++ * @child */ , ++ const znode * child /* child znode */ ) ++{ ++ assert("nikita-1016", pointer != NULL); ++ assert("nikita-1017", child != NULL); ++ assert("nikita-1018", pointer->node != NULL); ++ ++ assert("nikita-1325", znode_is_any_locked(pointer->node)); ++ ++ assert("nikita-2985", ++ znode_get_level(pointer->node) == znode_get_level(child) + 1); ++ ++ coord_clear_iplug((coord_t *) pointer); ++ ++ if (coord_is_existing_unit(pointer)) { ++ item_plugin *iplug; ++ reiser4_block_nr addr; ++ ++ if (item_is_internal(pointer)) { ++ iplug = item_plugin_by_coord(pointer); ++ assert("vs-513", iplug->s.internal.down_link); ++ iplug->s.internal.down_link(pointer, NULL, &addr); ++ /* check that cached value is correct */ ++ if (disk_addr_eq(&addr, znode_get_block(child))) { ++ return NS_FOUND; ++ } ++ } ++ } ++ /* warning ("jmacd-1002", "tree pointer incorrect"); */ ++ return NS_NOT_FOUND; ++} ++ ++/* find coord of pointer to new @child in @parent. ++ ++ Find the &coord_t in the @parent where pointer to a given @child will ++ be in. ++ ++*/ ++int find_new_child_ptr(znode * parent /* parent znode, passed locked */ , ++ znode * ++ child UNUSED_ARG /* child znode, passed locked */ , ++ znode * left /* left brother of new node */ , ++ coord_t * result /* where result is stored in */ ) ++{ ++ int ret; ++ ++ assert("nikita-1486", parent != NULL); ++ assert("nikita-1487", child != NULL); ++ assert("nikita-1488", result != NULL); ++ ++ ret = find_child_ptr(parent, left, result); ++ if (ret != NS_FOUND) { ++ warning("nikita-1489", "Cannot find brother position: %i", ret); ++ return RETERR(-EIO); ++ } else { ++ result->between = AFTER_UNIT; ++ return RETERR(NS_NOT_FOUND); ++ } ++} ++ ++/* find coord of pointer to @child in @parent. ++ ++ Find the &coord_t in the @parent where pointer to a given @child is in. ++ ++*/ ++int find_child_ptr(znode * parent /* parent znode, passed locked */ , ++ znode * child /* child znode, passed locked */ , ++ coord_t * result /* where result is stored in */ ) ++{ ++ int lookup_res; ++ node_plugin *nplug; ++ /* left delimiting key of a child */ ++ reiser4_key ld; ++ reiser4_tree *tree; ++ ++ assert("nikita-934", parent != NULL); ++ assert("nikita-935", child != NULL); ++ assert("nikita-936", result != NULL); ++ assert("zam-356", znode_is_loaded(parent)); ++ ++ coord_init_zero(result); ++ result->node = parent; ++ ++ nplug = parent->nplug; ++ assert("nikita-939", nplug != NULL); ++ ++ tree = znode_get_tree(parent); ++ /* NOTE-NIKITA taking read-lock on tree here assumes that @result is ++ * not aliased to ->in_parent of some znode. Otherwise, ++ * parent_coord_to_coord() below would modify data protected by tree ++ * lock. */ ++ read_lock_tree(); ++ /* fast path. Try to use cached value. Lock tree to keep ++ node->pos_in_parent and pos->*_blocknr consistent. */ ++ if (child->in_parent.item_pos + 1 != 0) { ++ parent_coord_to_coord(&child->in_parent, result); ++ if (check_tree_pointer(result, child) == NS_FOUND) { ++ read_unlock_tree(); ++ return NS_FOUND; ++ } ++ ++ child->in_parent.item_pos = (unsigned short)~0; ++ } ++ read_unlock_tree(); ++ ++ /* is above failed, find some key from @child. We are looking for the ++ least key in a child. */ ++ read_lock_dk(tree); ++ ld = *znode_get_ld_key(child); ++ read_unlock_dk(tree); ++ /* ++ * now, lookup parent with key just found. Note, that left delimiting ++ * key doesn't identify node uniquely, because (in extremely rare ++ * case) two nodes can have equal left delimiting keys, if one of them ++ * is completely filled with directory entries that all happened to be ++ * hash collision. But, we check block number in check_tree_pointer() ++ * and, so, are safe. ++ */ ++ lookup_res = nplug->lookup(parent, &ld, FIND_EXACT, result); ++ /* update cached pos_in_node */ ++ if (lookup_res == NS_FOUND) { ++ write_lock_tree(); ++ coord_to_parent_coord(result, &child->in_parent); ++ write_unlock_tree(); ++ lookup_res = check_tree_pointer(result, child); ++ } ++ if (lookup_res == NS_NOT_FOUND) ++ lookup_res = find_child_by_addr(parent, child, result); ++ return lookup_res; ++} ++ ++/* find coord of pointer to @child in @parent by scanning ++ ++ Find the &coord_t in the @parent where pointer to a given @child ++ is in by scanning all internal items in @parent and comparing block ++ numbers in them with that of @child. ++ ++*/ ++static int find_child_by_addr(znode * parent /* parent znode, passed locked */ , ++ znode * child /* child znode, passed locked */ , ++ coord_t * result /* where result is stored in */ ) ++{ ++ int ret; ++ ++ assert("nikita-1320", parent != NULL); ++ assert("nikita-1321", child != NULL); ++ assert("nikita-1322", result != NULL); ++ ++ ret = NS_NOT_FOUND; ++ ++ for_all_units(result, parent) { ++ if (check_tree_pointer(result, child) == NS_FOUND) { ++ write_lock_tree(); ++ coord_to_parent_coord(result, &child->in_parent); ++ write_unlock_tree(); ++ ret = NS_FOUND; ++ break; ++ } ++ } ++ return ret; ++} ++ ++/* true, if @addr is "unallocated block number", which is just address, with ++ highest bit set. */ ++int is_disk_addr_unallocated(const reiser4_block_nr * addr /* address to ++ * check */ ) ++{ ++ assert("nikita-1766", addr != NULL); ++ ++ return (*addr & REISER4_BLOCKNR_STATUS_BIT_MASK) == ++ REISER4_UNALLOCATED_STATUS_VALUE; ++} ++ ++/* helper function for prepare_twig_kill(): @left and @right are formatted ++ * neighbors of extent item being completely removed. Load and lock neighbors ++ * and store lock handles into @cdata for later use by kill_hook_extent() */ ++static int ++prepare_children(znode * left, znode * right, carry_kill_data * kdata) ++{ ++ int result; ++ int left_loaded; ++ int right_loaded; ++ ++ result = 0; ++ left_loaded = right_loaded = 0; ++ ++ if (left != NULL) { ++ result = zload(left); ++ if (result == 0) { ++ left_loaded = 1; ++ result = longterm_lock_znode(kdata->left, left, ++ ZNODE_READ_LOCK, ++ ZNODE_LOCK_LOPRI); ++ } ++ } ++ if (result == 0 && right != NULL) { ++ result = zload(right); ++ if (result == 0) { ++ right_loaded = 1; ++ result = longterm_lock_znode(kdata->right, right, ++ ZNODE_READ_LOCK, ++ ZNODE_LOCK_HIPRI | ++ ZNODE_LOCK_NONBLOCK); ++ } ++ } ++ if (result != 0) { ++ done_lh(kdata->left); ++ done_lh(kdata->right); ++ if (left_loaded != 0) ++ zrelse(left); ++ if (right_loaded != 0) ++ zrelse(right); ++ } ++ return result; ++} ++ ++static void done_children(carry_kill_data * kdata) ++{ ++ if (kdata->left != NULL && kdata->left->node != NULL) { ++ zrelse(kdata->left->node); ++ done_lh(kdata->left); ++ } ++ if (kdata->right != NULL && kdata->right->node != NULL) { ++ zrelse(kdata->right->node); ++ done_lh(kdata->right); ++ } ++} ++ ++/** ++ * returns true if removing bytes of given range of key [from_key, to_key] ++ * causes removing of whole item @from ++ */ ++static int item_removed_completely(coord_t *from, ++ const reiser4_key *from_key, ++ const reiser4_key *to_key) ++{ ++ reiser4_key key_in_item; ++ ++ assert("umka-325", from != NULL); ++ assert("edward-2093", item_is_extent(from)); ++ ++ /* check first unit */ ++ item_key_by_coord(from, &key_in_item); ++ if (keygt(from_key, &key_in_item)) ++ /* first byte is not removed */ ++ return 0; ++ ++ /* check last key */ ++ max_item_key_by_coord(from, &key_in_item); ++ if (keylt(to_key, &key_in_item)) ++ /* last byte is not removed */ ++ return 0; ++ return 1; ++} ++ ++/* part of cut_node. It is called when cut_node is called to remove or cut part ++ of extent item. When head of that item is removed - we have to update right ++ delimiting of left neighbor of extent. When item is removed completely - we ++ have to set sibling link between left and right neighbor of removed ++ extent. This may return -E_DEADLOCK because of trying to get left neighbor ++ locked. So, caller should repeat an attempt ++*/ ++/* Audited by: umka (2002.06.16) */ ++static int ++prepare_twig_kill(carry_kill_data * kdata, znode * locked_left_neighbor) ++{ ++ int result; ++ reiser4_key key; ++ lock_handle left_lh; ++ lock_handle right_lh; ++ coord_t left_coord; ++ coord_t *from; ++ znode *left_child; ++ znode *right_child; ++ reiser4_tree *tree; ++ int left_zloaded_here, right_zloaded_here; ++ ++ from = kdata->params.from; ++ assert("umka-326", from != NULL); ++ assert("umka-327", kdata->params.to != NULL); ++ ++ assert("vs-591", item_is_extent(from)); ++ assert("vs-592", ergo(item_id_by_coord(from) == EXTENT40_POINTER_ID, ++ from->item_pos == kdata->params.to->item_pos)); ++ ++ if ((kdata->params.from_key ++ && keygt(kdata->params.from_key, item_key_by_coord(from, &key))) ++ || from->unit_pos != 0) { ++ /* head of item @from is not removed, there is nothing to ++ worry about */ ++ return 0; ++ } ++ ++ result = 0; ++ left_zloaded_here = 0; ++ right_zloaded_here = 0; ++ ++ left_child = right_child = NULL; ++ ++ coord_dup(&left_coord, from); ++ init_lh(&left_lh); ++ init_lh(&right_lh); ++ if (coord_prev_unit(&left_coord)) { ++ /* @from is leftmost item in its node */ ++ if (!locked_left_neighbor) { ++ result = ++ reiser4_get_left_neighbor(&left_lh, from->node, ++ ZNODE_READ_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ switch (result) { ++ case 0: ++ break; ++ case -E_NO_NEIGHBOR: ++ /* there is no formatted node to the left of ++ from->node */ ++ warning("vs-605", ++ "extent item has smallest key in " ++ "the tree and it is about to be removed"); ++ return 0; ++ case -E_DEADLOCK: ++ /* need to restart */ ++ default: ++ return result; ++ } ++ ++ /* we have acquired left neighbor of from->node */ ++ result = zload(left_lh.node); ++ if (result) ++ goto done; ++ ++ locked_left_neighbor = left_lh.node; ++ } else { ++ /* squalloc_right_twig_cut should have supplied locked ++ * left neighbor */ ++ assert("vs-834", ++ znode_is_write_locked(locked_left_neighbor)); ++ result = zload(locked_left_neighbor); ++ if (result) ++ return result; ++ } ++ ++ left_zloaded_here = 1; ++ coord_init_last_unit(&left_coord, locked_left_neighbor); ++ } ++ ++ if (!item_is_internal(&left_coord)) { ++ /* what else but extent can be on twig level */ ++ assert("vs-606", item_is_extent(&left_coord)); ++ ++ /* there is no left formatted child */ ++ if (left_zloaded_here) ++ zrelse(locked_left_neighbor); ++ done_lh(&left_lh); ++ return 0; ++ } ++ ++ tree = znode_get_tree(left_coord.node); ++ left_child = child_znode(&left_coord, left_coord.node, 1, 0); ++ ++ if (IS_ERR(left_child)) { ++ result = PTR_ERR(left_child); ++ goto done; ++ } ++ /* ++ * left child is acquired, calculate new right delimiting ++ * key for it and get right child if it is necessary ++ */ ++ if (item_removed_completely(from, ++ kdata->params.from_key, ++ kdata->params.to_key)) { ++ /* ++ * try to get right child of removed item ++ */ ++ coord_t right_coord; ++ ++ assert("vs-607", ++ kdata->params.to->unit_pos == ++ coord_last_unit_pos(kdata->params.to)); ++ coord_dup(&right_coord, kdata->params.to); ++ if (coord_next_unit(&right_coord)) { ++ /* @to is rightmost unit in the node */ ++ result = ++ reiser4_get_right_neighbor(&right_lh, from->node, ++ ZNODE_READ_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ switch (result) { ++ case 0: ++ result = zload(right_lh.node); ++ if (result) ++ goto done; ++ ++ right_zloaded_here = 1; ++ coord_init_first_unit(&right_coord, ++ right_lh.node); ++ item_key_by_coord(&right_coord, &key); ++ break; ++ ++ case -E_NO_NEIGHBOR: ++ /* there is no formatted node to the right of ++ from->node */ ++ read_lock_dk(tree); ++ key = *znode_get_rd_key(from->node); ++ read_unlock_dk(tree); ++ right_coord.node = NULL; ++ result = 0; ++ break; ++ default: ++ /* real error */ ++ goto done; ++ } ++ } else { ++ /* there is an item to the right of @from - take its key */ ++ item_key_by_coord(&right_coord, &key); ++ } ++ ++ /* try to get right child of @from */ ++ if (right_coord.node && /* there is right neighbor of @from */ ++ item_is_internal(&right_coord)) { /* it is internal item */ ++ right_child = child_znode(&right_coord, ++ right_coord.node, 1, 0); ++ ++ if (IS_ERR(right_child)) { ++ result = PTR_ERR(right_child); ++ goto done; ++ } ++ ++ } ++ /* whole extent is removed between znodes left_child and right_child. Prepare them for linking and ++ update of right delimiting key of left_child */ ++ result = prepare_children(left_child, right_child, kdata); ++ } else { ++ /* head of item @to is removed. left_child has to get right delimting key update. Prepare it for that */ ++ result = prepare_children(left_child, NULL, kdata); ++ } ++ ++ done: ++ if (right_child) ++ zput(right_child); ++ if (right_zloaded_here) ++ zrelse(right_lh.node); ++ done_lh(&right_lh); ++ ++ if (left_child) ++ zput(left_child); ++ if (left_zloaded_here) ++ zrelse(locked_left_neighbor); ++ done_lh(&left_lh); ++ return result; ++} ++ ++/* this is used to remove part of node content between coordinates @from and @to. Units to which @from and @to are set ++ are to be cut completely */ ++/* for try_to_merge_with_left, delete_copied, reiser4_delete_node */ ++int cut_node_content(coord_t * from, coord_t * to, const reiser4_key * from_key, /* first key to be removed */ ++ const reiser4_key * to_key, /* last key to be removed */ ++ reiser4_key * ++ smallest_removed /* smallest key actually removed */ ) ++{ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ carry_cut_data *cut_data; ++ carry_op *op; ++ ++ assert("vs-1715", coord_compare(from, to) != COORD_CMP_ON_RIGHT); ++ ++ pool = ++ init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(*cut_data)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ ++ op = reiser4_post_carry(lowest_level, COP_CUT, from->node, 0); ++ assert("vs-1509", op != 0); ++ if (IS_ERR(op)) { ++ done_carry_pool(pool); ++ return PTR_ERR(op); ++ } ++ ++ cut_data = (carry_cut_data *) (lowest_level + 3); ++ cut_data->params.from = from; ++ cut_data->params.to = to; ++ cut_data->params.from_key = from_key; ++ cut_data->params.to_key = to_key; ++ cut_data->params.smallest_removed = smallest_removed; ++ ++ op->u.cut_or_kill.is_cut = 1; ++ op->u.cut_or_kill.u.cut = cut_data; ++ ++ result = reiser4_carry(lowest_level, NULL); ++ done_carry_pool(pool); ++ ++ return result; ++} ++ ++/* cut part of the node ++ ++ Cut part or whole content of node. ++ ++ cut data between @from and @to of @from->node and call carry() to make ++ corresponding changes in the tree. @from->node may become empty. If so - ++ pointer to it will be removed. Neighboring nodes are not changed. Smallest ++ removed key is stored in @smallest_removed ++ ++*/ ++int kill_node_content(coord_t * from, /* coord of the first unit/item that will be eliminated */ ++ coord_t * to, /* coord of the last unit/item that will be eliminated */ ++ const reiser4_key * from_key, /* first key to be removed */ ++ const reiser4_key * to_key, /* last key to be removed */ ++ reiser4_key * smallest_removed, /* smallest key actually removed */ ++ znode * locked_left_neighbor, /* this is set when kill_node_content is called with left neighbor ++ * locked (in squalloc_right_twig_cut, namely) */ ++ struct inode *inode, /* inode of file whose item (or its part) is to be killed. This is necessary to ++ invalidate pages together with item pointing to them */ ++ int truncate) ++{ /* this call is made for file truncate) */ ++ int result; ++ carry_pool *pool; ++ carry_level *lowest_level; ++ carry_kill_data *kdata; ++ lock_handle *left_child; ++ lock_handle *right_child; ++ carry_op *op; ++ ++ assert("umka-328", from != NULL); ++ assert("vs-316", !node_is_empty(from->node)); ++ assert("nikita-1812", coord_is_existing_unit(from) ++ && coord_is_existing_unit(to)); ++ ++ /* allocate carry_pool, 3 carry_level-s, carry_kill_data and structures for kill_hook_extent */ ++ pool = init_carry_pool(sizeof(*pool) + 3 * sizeof(*lowest_level) + ++ sizeof(carry_kill_data) + ++ 2 * sizeof(lock_handle) + ++ 5 * sizeof(reiser4_key) + 2 * sizeof(coord_t)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ ++ lowest_level = (carry_level *) (pool + 1); ++ init_carry_level(lowest_level, pool); ++ ++ kdata = (carry_kill_data *) (lowest_level + 3); ++ left_child = (lock_handle *) (kdata + 1); ++ right_child = left_child + 1; ++ ++ init_lh(left_child); ++ init_lh(right_child); ++ ++ kdata->params.from = from; ++ kdata->params.to = to; ++ kdata->params.from_key = from_key; ++ kdata->params.to_key = to_key; ++ kdata->params.smallest_removed = smallest_removed; ++ kdata->params.truncate = truncate; ++ kdata->flags = 0; ++ kdata->inode = inode; ++ kdata->left = left_child; ++ kdata->right = right_child; ++ /* memory for 5 reiser4_key and 2 coord_t will be used in kill_hook_extent */ ++ kdata->buf = (char *)(right_child + 1); ++ ++ if (znode_get_level(from->node) == TWIG_LEVEL && item_is_extent(from)) { ++ /* left child of extent item may have to get updated right ++ delimiting key and to get linked with right child of extent ++ @from if it will be removed completely */ ++ result = prepare_twig_kill(kdata, locked_left_neighbor); ++ if (result) { ++ done_children(kdata); ++ done_carry_pool(pool); ++ return result; ++ } ++ } ++ ++ op = reiser4_post_carry(lowest_level, COP_CUT, from->node, 0); ++ if (IS_ERR(op) || (op == NULL)) { ++ done_children(kdata); ++ done_carry_pool(pool); ++ return RETERR(op ? PTR_ERR(op) : -EIO); ++ } ++ ++ op->u.cut_or_kill.is_cut = 0; ++ op->u.cut_or_kill.u.kill = kdata; ++ ++ result = reiser4_carry(lowest_level, NULL); ++ ++ done_children(kdata); ++ done_carry_pool(pool); ++ return result; ++} ++ ++void ++fake_kill_hook_tail(struct inode *inode, loff_t start, loff_t end, int truncate) ++{ ++ if (reiser4_inode_get_flag(inode, REISER4_HAS_MMAP)) { ++ pgoff_t start_pg, end_pg; ++ ++ start_pg = start >> PAGE_SHIFT; ++ end_pg = (end - 1) >> PAGE_SHIFT; ++ ++ if ((start & (PAGE_SIZE - 1)) == 0) { ++ /* ++ * kill up to the page boundary. ++ */ ++ assert("vs-123456", start_pg == end_pg); ++ reiser4_invalidate_pages(inode->i_mapping, start_pg, 1, ++ truncate); ++ } else if (start_pg != end_pg) { ++ /* ++ * page boundary is within killed portion of node. ++ */ ++ assert("vs-654321", end_pg - start_pg == 1); ++ reiser4_invalidate_pages(inode->i_mapping, end_pg, ++ end_pg - start_pg, 1); ++ } ++ } ++ inode_sub_bytes(inode, end - start); ++} ++ ++/** ++ * Delete whole @node from the reiser4 tree without loading it. ++ * ++ * @left: locked left neighbor, ++ * @node: node to be deleted, ++ * @smallest_removed: leftmost key of deleted node, ++ * @object: inode pointer, if we truncate a file body. ++ * @truncate: true if called for file truncate. ++ * ++ * @return: 0 if success, error code otherwise. ++ * ++ * NOTE: if @object!=NULL we assume that @smallest_removed != NULL and it ++ * contains the right value of the smallest removed key from the previous ++ * cut_worker() iteration. This is needed for proper accounting of ++ * "i_blocks" and "i_bytes" fields of the @object. ++ */ ++int reiser4_delete_node(znode *node, reiser4_key *smallest_removed, ++ struct inode *object, int truncate) ++{ ++ lock_handle parent_lock; ++ coord_t cut_from; ++ coord_t cut_to; ++ reiser4_tree *tree; ++ int ret; ++ ++ assert("zam-937", node != NULL); ++ assert("zam-933", znode_is_write_locked(node)); ++ assert("zam-999", smallest_removed != NULL); ++ ++ init_lh(&parent_lock); ++ ++ ret = reiser4_get_parent(&parent_lock, node, ZNODE_WRITE_LOCK); ++ if (ret) ++ return ret; ++ ++ assert("zam-934", !znode_above_root(parent_lock.node)); ++ ++ ret = zload(parent_lock.node); ++ if (ret) ++ goto failed_nozrelse; ++ ++ ret = find_child_ptr(parent_lock.node, node, &cut_from); ++ if (ret) ++ goto failed; ++ ++ /* decrement child counter and set parent pointer to NULL before ++ deleting the list from parent node because of checks in ++ internal_kill_item_hook (we can delete the last item from the parent ++ node, the parent node is going to be deleted and its c_count should ++ be zero). */ ++ ++ tree = znode_get_tree(node); ++ write_lock_tree(); ++ init_parent_coord(&node->in_parent, NULL); ++ --parent_lock.node->c_count; ++ write_unlock_tree(); ++ ++ assert("zam-989", item_is_internal(&cut_from)); ++ ++ /* @node should be deleted after unlocking. */ ++ ZF_SET(node, JNODE_HEARD_BANSHEE); ++ ++ /* remove a pointer from the parent node to the node being deleted. */ ++ coord_dup(&cut_to, &cut_from); ++ /* FIXME: shouldn't this be kill_node_content */ ++ ret = cut_node_content(&cut_from, &cut_to, NULL, NULL, NULL); ++ if (ret) ++ /* FIXME(Zam): Should we re-connect the node to its parent if ++ * cut_node fails? */ ++ goto failed; ++ ++ { ++ __u64 start_offset = 0, end_offset = 0; ++ ++ read_lock_tree(); ++ write_lock_dk(tree); ++ if (object) { ++ /* We use @smallest_removed and the left delimiting of ++ * the current node for @object->i_blocks, i_bytes ++ * calculation. We assume that the items after the ++ * *@smallest_removed key have been deleted from the ++ * file body. */ ++ start_offset = get_key_offset(znode_get_ld_key(node)); ++ end_offset = get_key_offset(smallest_removed); ++ } ++ ++ assert("zam-1021", znode_is_connected(node)); ++ if (node->left) ++ znode_set_rd_key(node->left, znode_get_rd_key(node)); ++ ++ *smallest_removed = *znode_get_ld_key(node); ++ ++ write_unlock_dk(tree); ++ read_unlock_tree(); ++ ++ if (object) { ++ /* we used to perform actions which are to be performed on items on their removal from tree in ++ special item method - kill_hook. Here for optimization reasons we avoid reading node ++ containing item we remove and can not call item's kill hook. Instead we call function which ++ does exactly the same things as tail kill hook in assumption that node we avoid reading ++ contains only one item and that item is a tail one. */ ++ fake_kill_hook_tail(object, start_offset, end_offset, ++ truncate); ++ } ++ } ++ failed: ++ zrelse(parent_lock.node); ++ failed_nozrelse: ++ done_lh(&parent_lock); ++ ++ return ret; ++} ++ ++static int can_delete(const reiser4_key *key, znode *node) ++{ ++ int result; ++ reiser4_tree *tree = znode_get_tree(node); ++ ++ read_lock_dk(tree); ++ result = keyle(key, znode_get_ld_key(node)); ++ read_unlock_dk(tree); ++ return result; ++} ++ ++/** ++ * This subroutine is not optimal but implementation seems to ++ * be easier). ++ * ++ * @tap: the point deletion process begins from, ++ * @from_key: the beginning of the deleted key range, ++ * @to_key: the end of the deleted key range, ++ * @smallest_removed: the smallest removed key, ++ * @truncate: true if called for file truncate. ++ * @progress: return true if a progress in file items deletions was made, ++ * @smallest_removed value is actual in that case. ++ * ++ * @return: 0 if success, error code otherwise, -E_REPEAT means that long ++ * reiser4_cut_tree operation was interrupted for allowing atom commit. ++ */ ++int ++cut_tree_worker_common(tap_t * tap, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed, struct inode *object, ++ int truncate, int *progress) ++{ ++ lock_handle next_node_lock; ++ coord_t left_coord; ++ int result; ++ ++ assert("zam-931", tap->coord->node != NULL); ++ assert("zam-932", znode_is_write_locked(tap->coord->node)); ++ ++ *progress = 0; ++ init_lh(&next_node_lock); ++ ++ while (1) { ++ znode *node; /* node from which items are cut */ ++ node_plugin *nplug; /* node plugin for @node */ ++ ++ node = tap->coord->node; ++ ++ /* Move next_node_lock to the next node on the left. */ ++ result = ++ reiser4_get_left_neighbor(&next_node_lock, node, ++ ZNODE_WRITE_LOCK, ++ GN_CAN_USE_UPPER_LEVELS); ++ if (result != 0 && result != -E_NO_NEIGHBOR) ++ break; ++ /* Check can we delete the node as a whole. */ ++ if (*progress && znode_get_level(node) == LEAF_LEVEL && ++ can_delete(from_key, node)) { ++ result = reiser4_delete_node(node, smallest_removed, ++ object, truncate); ++ } else { ++ result = reiser4_tap_load(tap); ++ if (result) ++ return result; ++ ++ /* Prepare the second (right) point for cut_node() */ ++ if (*progress) ++ coord_init_last_unit(tap->coord, node); ++ ++ else if (item_plugin_by_coord(tap->coord)->b.lookup == ++ NULL) ++ /* set rightmost unit for the items without lookup method */ ++ tap->coord->unit_pos = ++ coord_last_unit_pos(tap->coord); ++ ++ nplug = node->nplug; ++ ++ assert("vs-686", nplug); ++ assert("vs-687", nplug->lookup); ++ ++ /* left_coord is leftmost unit cut from @node */ ++ result = nplug->lookup(node, from_key, ++ FIND_MAX_NOT_MORE_THAN, ++ &left_coord); ++ ++ if (IS_CBKERR(result)) ++ break; ++ ++ /* adjust coordinates so that they are set to existing units */ ++ if (coord_set_to_right(&left_coord) ++ || coord_set_to_left(tap->coord)) { ++ result = 0; ++ break; ++ } ++ ++ if (coord_compare(&left_coord, tap->coord) == ++ COORD_CMP_ON_RIGHT) { ++ /* keys from @from_key to @to_key are not in the tree */ ++ result = 0; ++ break; ++ } ++ ++ if (left_coord.item_pos != tap->coord->item_pos) { ++ /* do not allow to cut more than one item. It is added to solve problem of truncating ++ partially converted files. If file is partially converted there may exist a twig node ++ containing both internal item or items pointing to leaf nodes with formatting items ++ and extent item. We do not want to kill internal items being at twig node here ++ because cut_tree_worker assumes killing them from level level */ ++ coord_dup(&left_coord, tap->coord); ++ assert("vs-1652", ++ coord_is_existing_unit(&left_coord)); ++ left_coord.unit_pos = 0; ++ } ++ ++ /* cut data from one node */ ++ /* *smallest_removed = *reiser4_min_key(); */ ++ result = ++ kill_node_content(&left_coord, tap->coord, from_key, ++ to_key, smallest_removed, ++ next_node_lock.node, object, ++ truncate); ++ reiser4_tap_relse(tap); ++ } ++ if (result) ++ break; ++ ++ ++(*progress); ++ ++ /* Check whether all items with keys >= from_key were removed ++ * from the tree. */ ++ if (keyle(smallest_removed, from_key)) ++ /* result = 0; */ ++ break; ++ ++ if (next_node_lock.node == NULL) ++ break; ++ ++ result = reiser4_tap_move(tap, &next_node_lock); ++ done_lh(&next_node_lock); ++ if (result) ++ break; ++ ++ /* Break long reiser4_cut_tree operation (deletion of a large ++ file) if atom requires commit. */ ++ if (*progress > CUT_TREE_MIN_ITERATIONS ++ && current_atom_should_commit()) { ++ result = -E_REPEAT; ++ break; ++ } ++ } ++ done_lh(&next_node_lock); ++ /* assert("vs-301", !keyeq(&smallest_removed, reiser4_min_key())); */ ++ return result; ++} ++ ++/* there is a fundamental problem with optimizing deletes: VFS does it ++ one file at a time. Another problem is that if an item can be ++ anything, then deleting items must be done one at a time. It just ++ seems clean to writes this to specify a from and a to key, and cut ++ everything between them though. */ ++ ++/* use this function with care if deleting more than what is part of a single file. */ ++/* do not use this when cutting a single item, it is suboptimal for that */ ++ ++/* You are encouraged to write plugin specific versions of this. It ++ cannot be optimal for all plugins because it works item at a time, ++ and some plugins could sometimes work node at a time. Regular files ++ however are not optimizable to work node at a time because of ++ extents needing to free the blocks they point to. ++ ++ Optimizations compared to v3 code: ++ ++ It does not balance (that task is left to memory pressure code). ++ ++ Nodes are deleted only if empty. ++ ++ Uses extents. ++ ++ Performs read-ahead of formatted nodes whose contents are part of ++ the deletion. ++*/ ++ ++/** ++ * Delete everything from the reiser4 tree between two keys: @from_key and ++ * @to_key. ++ * ++ * @from_key: the beginning of the deleted key range, ++ * @to_key: the end of the deleted key range, ++ * @smallest_removed: the smallest removed key, ++ * @object: owner of cutting items. ++ * @truncate: true if called for file truncate. ++ * @progress: return true if a progress in file items deletions was made, ++ * @smallest_removed value is actual in that case. ++ * ++ * @return: 0 if success, error code otherwise, -E_REPEAT means that long cut_tree ++ * operation was interrupted for allowing atom commit . ++ */ ++ ++int reiser4_cut_tree_object(reiser4_tree * tree, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed_p, ++ struct inode *object, int truncate, int *progress) ++{ ++ lock_handle lock; ++ int result; ++ tap_t tap; ++ coord_t right_coord; ++ reiser4_key smallest_removed; ++ int (*cut_tree_worker) (tap_t *, const reiser4_key *, ++ const reiser4_key *, reiser4_key *, ++ struct inode *, int, int *); ++ STORE_COUNTERS; ++ ++ assert("umka-329", tree != NULL); ++ assert("umka-330", from_key != NULL); ++ assert("umka-331", to_key != NULL); ++ assert("zam-936", keyle(from_key, to_key)); ++ ++ if (smallest_removed_p == NULL) ++ smallest_removed_p = &smallest_removed; ++ ++ init_lh(&lock); ++ ++ do { ++ /* Find rightmost item to cut away from the tree. */ ++ result = reiser4_object_lookup(tree, ++ object, to_key, &right_coord, ++ &lock, ZNODE_WRITE_LOCK, ++ FIND_MAX_NOT_MORE_THAN, ++ TWIG_LEVEL, LEAF_LEVEL, ++ CBK_UNIQUE, NULL /*ra_info */); ++ if (result != CBK_COORD_FOUND) ++ break; ++ if (object == NULL ++ || inode_file_plugin(object)->cut_tree_worker == NULL) ++ cut_tree_worker = cut_tree_worker_common; ++ else ++ cut_tree_worker = ++ inode_file_plugin(object)->cut_tree_worker; ++ reiser4_tap_init(&tap, &right_coord, &lock, ZNODE_WRITE_LOCK); ++ result = ++ cut_tree_worker(&tap, from_key, to_key, smallest_removed_p, ++ object, truncate, progress); ++ reiser4_tap_done(&tap); ++ ++ reiser4_preempt_point(); ++ ++ } while (0); ++ ++ done_lh(&lock); ++ ++ if (result) { ++ switch (result) { ++ case -E_DEADLOCK: ++ result = -E_REPEAT; ++ case -E_NO_NEIGHBOR: ++ case -E_REPEAT: ++ case -ENOMEM: ++ case -ENOENT: ++ break; ++ default: ++ warning("nikita-2861", "failure: %i", result); ++ } ++ } ++ ++ CHECK_COUNTERS; ++ return result; ++} ++ ++/* repeat reiser4_cut_tree_object until everything is deleted. ++ * unlike cut_file_items, it does not end current transaction if -E_REPEAT ++ * is returned by cut_tree_object. */ ++int reiser4_cut_tree(reiser4_tree * tree, const reiser4_key * from, ++ const reiser4_key * to, struct inode *inode, int truncate) ++{ ++ int result; ++ int progress; ++ ++ do { ++ result = reiser4_cut_tree_object(tree, from, to, NULL, ++ inode, truncate, &progress); ++ if (result == -E_NO_NEIGHBOR) ++ result = 0; ++ } while (result == -E_REPEAT); ++ ++ return result; ++} ++ ++/** ++ * Update item key and respectively delimiting keys on the upper ++ * levels (if needed). ++ * ++ * @target: item, whose key needs to be updated ++ * @key: new value of the key ++ */ ++int update_item_key(coord_t *target, const reiser4_key *key) ++{ ++ znode *node; ++ carry_pool *pool; ++ carry_level *todo; ++ carry_plugin_info info; ++ ++ pool = init_carry_pool(sizeof(*pool) + 3 * sizeof(*todo)); ++ if (IS_ERR(pool)) ++ return PTR_ERR(pool); ++ todo = (carry_level *) (pool + 1); ++ init_carry_level(todo, pool); ++ ++ info.doing = NULL; ++ info.todo = todo; ++ ++ node = target->node; ++ node_plugin_by_node(node)->update_item_key(target, key, &info); ++ ++ if (target->item_pos == 0) { ++ int ret; ++ reiser4_tree *tree; ++ ++ /* ++ * ->update_item_key() could post COP_UPDATE ++ */ ++ ret = reiser4_carry(todo, NULL /* previous level */); ++ if (ret) { ++ done_carry_pool(pool); ++ return ret; ++ } ++ tree = znode_get_tree(node); ++ read_lock_tree(); ++ write_lock_dk(tree); ++ ++ znode_set_ld_key(node, key); ++ if (znode_is_left_connected(node) && node->left) ++ znode_set_rd_key(node->left, key); ++ ++ write_unlock_dk(tree); ++ read_unlock_tree(); ++ } ++ znode_make_dirty(node); ++ ++ done_carry_pool(pool); ++ return 0; ++} ++ ++int reiser4_subvol_init_tree(struct reiser4_subvol *subv, ++ const reiser4_block_nr *root_block, ++ tree_level height, node_plugin *nplug) ++{ ++ int result; ++ reiser4_tree *tree = &subv->tree; ++ ++ assert("nikita-307", root_block != NULL); ++ assert("nikita-308", height > 0); ++ assert("nikita-309", nplug != NULL); ++ assert("edward-171", get_current_context() != NULL); ++ /* ++ * We'll perform costly memory allocations for znode hash table, etc. ++ * So, set proper allocation flags ++ */ ++ get_current_context()->gfp_mask |= (__GFP_NOWARN); ++ ++ tree->subvol = subv; ++ /* ++ * Set default tree options (came from init_super) ++ */ ++ tree->cbk_cache.nr_slots = CBK_CACHE_SLOTS; ++ tree->carry.new_node_flags = REISER4_NEW_NODE_FLAGS; ++ tree->carry.new_extent_flags = REISER4_NEW_EXTENT_FLAGS; ++ tree->carry.paste_flags = REISER4_PASTE_FLAGS; ++ tree->carry.insert_flags = REISER4_INSERT_FLAGS; ++ ++ spin_lock_init(&(tree->epoch_lock)); ++ ++ tree->root_block = *root_block; ++ tree->height = height; ++ tree->estimate_one_insert = calc_estimate_one_insert(height); ++ tree->nplug = nplug; ++ ++ tree->znode_epoch = 1ull; ++ ++ cbk_cache_init(&tree->cbk_cache); ++ ++ result = znodes_tree_init(tree); ++ if (result == 0) { ++ tree->uber = zget(subv, &UBER_TREE_ADDR, NULL, 0, ++ reiser4_ctx_gfp_mask_get()); ++ if (IS_ERR(tree->uber)) { ++ result = PTR_ERR(tree->uber); ++ tree->uber = NULL; ++ } ++ } ++ return result; ++} ++ ++/* release resources associated with @tree */ ++void reiser4_done_tree(reiser4_tree * tree /* tree to release */ ) ++{ ++ if (tree == NULL) ++ return; ++ ++ if (tree->uber != NULL) { ++ zput(tree->uber); ++ tree->uber = NULL; ++ } ++ znodes_tree_done(tree); ++ cbk_cache_done(&tree->cbk_cache); ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree.h linux-5.10.2/fs/reiser4/tree.h +--- linux-5.10.2.orig/fs/reiser4/tree.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree.h 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,497 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Tree operations. See fs/reiser4/tree.c for comments */ ++ ++#if !defined( __REISER4_TREE_H__ ) ++#define __REISER4_TREE_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "plugin/node/node.h" ++#include "plugin/plugin.h" ++#include "znode.h" ++#include "tap.h" ++ ++#include /* for __u?? */ ++#include /* for struct super_block */ ++#include ++#include /* for struct task_struct */ ++ ++/* fictive block number never actually used */ ++extern const reiser4_block_nr UBER_TREE_ADDR; ++ ++/* &cbk_cache_slot - entry in a coord cache. ++ ++ This is entry in a coord_by_key (cbk) cache, represented by ++ &cbk_cache. ++ ++*/ ++typedef struct cbk_cache_slot { ++ /* cached node */ ++ znode *node; ++ /* linkage to the next cbk cache slot in a LRU order */ ++ struct list_head lru; ++} cbk_cache_slot; ++ ++/* &cbk_cache - coord cache. This is part of reiser4_tree. ++ ++ cbk_cache is supposed to speed up tree lookups by caching results of recent ++ successful lookups (we don't cache negative results as dentry cache ++ does). Cache consists of relatively small number of entries kept in a LRU ++ order. Each entry (&cbk_cache_slot) contains a pointer to znode, from ++ which we can obtain a range of keys that covered by this znode. Before ++ embarking into real tree traversal we scan cbk_cache slot by slot and for ++ each slot check whether key we are looking for is between minimal and ++ maximal keys for node pointed to by this slot. If no match is found, real ++ tree traversal is performed and if result is successful, appropriate entry ++ is inserted into cache, possibly pulling least recently used entry out of ++ it. ++ ++ Tree spin lock is used to protect coord cache. If contention for this ++ lock proves to be too high, more finer grained locking can be added. ++ ++ Invariants involving parts of this data-type: ++ ++ [cbk-cache-invariant] ++*/ ++typedef struct cbk_cache { ++ /* serializator */ ++ rwlock_t guard; ++ int nr_slots; ++ /* head of LRU list of cache slots */ ++ struct list_head lru; ++ /* actual array of slots */ ++ cbk_cache_slot *slot; ++} cbk_cache; ++ ++/* level_lookup_result - possible outcome of looking up key at some level. ++ This is used by coord_by_key when traversing tree downward. */ ++typedef enum { ++ /* continue to the next level */ ++ LOOKUP_CONT, ++ /* done. Either required item was found, or we can prove it ++ doesn't exist, or some error occurred. */ ++ LOOKUP_DONE, ++ /* restart traversal from the root. Infamous "repetition". */ ++ LOOKUP_REST ++} level_lookup_result; ++ ++/* This is representation of internal reiser4 tree where all file-system ++ data and meta-data are stored. This structure is passed to all tree ++ manipulation functions. It's different from the super block because: ++ we don't want to limit ourselves to strictly one to one mapping ++ between super blocks and trees, and, because they are logically ++ different: there are things in a super block that have no relation to ++ the tree (bitmaps, journalling area, mount options, etc.) and there ++ are things in a tree that bear no relation to the super block, like ++ tree of znodes. ++ ++ At this time, there is only one tree ++ per filesystem, and this struct is part of the super block. We only ++ call the super block the super block for historical reasons (most ++ other filesystems call the per filesystem metadata the super block). ++*/ ++ ++struct reiser4_tree { ++ /* block_nr == 0 is fake znode. Write lock it, while changing ++ tree height. */ ++ /* disk address of root node of a tree */ ++ reiser4_block_nr root_block; ++ ++ /* level of the root node. If this is 1, tree consists of root ++ node only */ ++ tree_level height; ++ ++ /* ++ * this is cached here avoid calling plugins through function ++ * dereference all the time. ++ */ ++ __u64 estimate_one_insert; ++ ++ /* cache of recent tree lookup results */ ++ cbk_cache cbk_cache; ++ ++ /* hash table to look up znodes by block number. */ ++ z_hash_table zhash_table; ++ z_hash_table zfake_table; ++ /* lock protecting delimiting keys */ ++ rwlock_t dk_lock; ++ ++ /* spin lock protecting znode_epoch */ ++ spinlock_t epoch_lock; ++ /* version stamp used to mark znode updates. See seal.[ch] for more ++ * information. */ ++ __u64 znode_epoch; ++ ++ znode *uber; ++ node_plugin *nplug; ++ reiser4_subvol *subvol; ++ struct { ++ /* carry flags used for insertion of new nodes */ ++ __u32 new_node_flags; ++ /* carry flags used for insertion of new extents */ ++ __u32 new_extent_flags; ++ /* carry flags used for paste operations */ ++ __u32 paste_flags; ++ /* carry flags used for insert operations */ ++ __u32 insert_flags; ++ } carry; ++}; ++ ++extern int reiser4_subvol_init_tree(struct reiser4_subvol *subvol, ++ const reiser4_block_nr *root_block, ++ tree_level height, node_plugin *nplug); ++extern void reiser4_done_tree(reiser4_tree * tree); ++ ++/* cbk flags: options for coord_by_key() */ ++typedef enum { ++ /* coord_by_key() is called for insertion. This is necessary because ++ of extents being located at the twig level. For explanation, see ++ comment just above is_next_item_internal(). ++ */ ++ CBK_FOR_INSERT = (1 << 0), ++ /* coord_by_key() is called with key that is known to be unique */ ++ CBK_UNIQUE = (1 << 1), ++ /* coord_by_key() can trust delimiting keys. This options is not user ++ accessible. coord_by_key() will set it automatically. It will be ++ only cleared by special-case in extents-on-the-twig-level handling ++ where it is necessary to insert item with a key smaller than ++ leftmost key in a node. This is necessary because of extents being ++ located at the twig level. For explanation, see comment just above ++ is_next_item_internal(). ++ */ ++ CBK_TRUST_DK = (1 << 2), ++ CBK_READA = (1 << 3), /* original: readahead leaves which contain items of certain file */ ++ CBK_READDIR_RA = (1 << 4), /* readdir: readahead whole directory and all its stat datas */ ++ CBK_DKSET = (1 << 5), ++ CBK_EXTENDED_COORD = (1 << 6), /* coord_t is actually */ ++ CBK_IN_CACHE = (1 << 7), /* node is already in cache */ ++ CBK_USE_CRABLOCK = (1 << 8) /* use crab_lock in stead of long term ++ * lock */ ++} cbk_flags; ++ ++/* insertion outcome. IBK = insert by key */ ++typedef enum { ++ IBK_INSERT_OK = 0, ++ IBK_ALREADY_EXISTS = -EEXIST, ++ IBK_IO_ERROR = -EIO, ++ IBK_NO_SPACE = -E_NODE_FULL, ++ IBK_OOM = -ENOMEM ++} insert_result; ++ ++#define IS_CBKERR(err) ((err) != CBK_COORD_FOUND && (err) != CBK_COORD_NOTFOUND) ++ ++typedef int (*tree_iterate_actor_t) (reiser4_tree * tree, coord_t * coord, ++ lock_handle * lh, void *arg); ++extern int reiser4_iterate_tree(reiser4_tree * tree, coord_t * coord, ++ lock_handle * lh, ++ tree_iterate_actor_t actor, void *arg, ++ znode_lock_mode mode, int through_units_p); ++extern int get_uber_znode(reiser4_tree * tree, znode_lock_mode mode, ++ znode_lock_request pri, lock_handle * lh); ++ ++/* return node plugin of @node */ ++static inline node_plugin *node_plugin_by_node(const znode * ++ node /* node to query */ ) ++{ ++ assert("vs-213", node != NULL); ++ assert("vs-214", znode_is_loaded(node)); ++ ++ return node->nplug; ++} ++ ++/* number of items in @node */ ++static inline pos_in_node_t node_num_items(const znode * node) ++{ ++ assert("nikita-2754", znode_is_loaded(node)); ++ assert("nikita-2468", ++ node_plugin_by_node(node)->num_of_items(node) == node->nr_items); ++ ++ return node->nr_items; ++} ++ ++/* Return the number of items at the present node. Asserts coord->node != ++ NULL. */ ++static inline unsigned coord_num_items(const coord_t * coord) ++{ ++ assert("jmacd-9805", coord->node != NULL); ++ ++ return node_num_items(coord->node); ++} ++ ++/* true if @node is empty */ ++static inline int node_is_empty(const znode * node) ++{ ++ return node_num_items(node) == 0; ++} ++ ++typedef enum { ++ SHIFTED_SOMETHING = 0, ++ SHIFT_NO_SPACE = -E_NODE_FULL, ++ SHIFT_IO_ERROR = -EIO, ++ SHIFT_OOM = -ENOMEM, ++} shift_result; ++ ++extern node_plugin *node_plugin_by_coord(const coord_t * coord); ++extern int is_coord_in_node(const coord_t * coord); ++extern int key_in_node(const reiser4_key *, const coord_t *); ++extern void coord_item_move_to(coord_t * coord, int items); ++extern void coord_unit_move_to(coord_t * coord, int units); ++ ++/* there are two types of repetitive accesses (ra): intra-syscall ++ (local) and inter-syscall (global). Local ra is used when ++ during single syscall we add/delete several items and units in the ++ same place in a tree. Note that plan-A fragments local ra by ++ separating stat-data and file body in key-space. Global ra is ++ used when user does repetitive modifications in the same place in a ++ tree. ++ ++ Our ra implementation serves following purposes: ++ 1 it affects balancing decisions so that next operation in a row ++ can be performed faster; ++ 2 it affects lower-level read-ahead in page-cache; ++ 3 it allows to avoid unnecessary lookups by maintaining some state ++ across several operations (this is only for local ra); ++ 4 it leaves room for lazy-micro-balancing: when we start a sequence of ++ operations they are performed without actually doing any intra-node ++ shifts, until we finish sequence or scope of sequence leaves ++ current node, only then we really pack node (local ra only). ++*/ ++ ++/* another thing that can be useful is to keep per-tree and/or ++ per-process cache of recent lookups. This cache can be organised as a ++ list of block numbers of formatted nodes sorted by starting key in ++ this node. Balancings should invalidate appropriate parts of this ++ cache. ++*/ ++ ++lookup_result coord_by_key(reiser4_tree * tree, const reiser4_key * key, ++ coord_t * coord, lock_handle * handle, ++ znode_lock_mode lock, lookup_bias bias, ++ tree_level lock_level, tree_level stop_level, ++ __u32 flags, ra_info_t *); ++ ++lookup_result reiser4_object_lookup(reiser4_tree *tree, ++ struct inode *object, ++ const reiser4_key * key, ++ coord_t * coord, ++ lock_handle * lh, ++ znode_lock_mode lock_mode, ++ lookup_bias bias, ++ tree_level lock_level, ++ tree_level stop_level, ++ __u32 flags, ra_info_t * info); ++ ++insert_result insert_by_key(reiser4_tree * tree, const reiser4_key * key, ++ reiser4_item_data * data, coord_t * coord, ++ lock_handle * lh, ++ tree_level stop_level, __u32 flags); ++insert_result insert_by_coord(coord_t * coord, ++ reiser4_item_data * data, const reiser4_key * key, ++ lock_handle * lh, __u32); ++insert_result insert_extent_by_coord(coord_t * coord, ++ reiser4_item_data * data, ++ const reiser4_key * key, lock_handle * lh); ++int cut_node_content(coord_t * from, coord_t * to, const reiser4_key * from_key, ++ const reiser4_key * to_key, ++ reiser4_key * smallest_removed); ++int kill_node_content(coord_t * from, coord_t * to, ++ const reiser4_key * from_key, const reiser4_key * to_key, ++ reiser4_key * smallest_removed, ++ znode * locked_left_neighbor, struct inode *inode, ++ int truncate); ++ ++int reiser4_resize_item(coord_t * coord, reiser4_item_data * data, ++ reiser4_key * key, lock_handle * lh, cop_insert_flag); ++int insert_into_item(coord_t * coord, lock_handle * lh, const reiser4_key * key, ++ reiser4_item_data * data, unsigned); ++int reiser4_insert_flow(coord_t * coord, lock_handle * lh, flow_t * f); ++int find_new_child_ptr(znode * parent, znode * child, znode * left, ++ coord_t * result); ++ ++int shift_right_of_but_excluding_insert_coord(coord_t * insert_coord); ++int shift_left_of_and_including_insert_coord(coord_t * insert_coord); ++ ++void fake_kill_hook_tail(struct inode *, loff_t start, loff_t end, int); ++ ++extern int cut_tree_worker_common(tap_t *, const reiser4_key *, ++ const reiser4_key *, reiser4_key *, ++ struct inode *, int, int *); ++extern int reiser4_cut_tree_object(reiser4_tree *, const reiser4_key *, ++ const reiser4_key *, reiser4_key *, ++ struct inode *, int, int *); ++extern int reiser4_cut_tree(reiser4_tree * tree, const reiser4_key * from, ++ const reiser4_key * to, struct inode *, int); ++ ++extern int reiser4_delete_node(znode *, reiser4_key *, struct inode *, int); ++extern int check_tree_pointer(const coord_t * pointer, const znode * child); ++extern int find_new_child_ptr(znode * parent, znode * child UNUSED_ARG, ++ znode * left, coord_t * result); ++extern int find_child_ptr(znode * parent, znode * child, coord_t * result); ++extern int set_child_delimiting_keys(znode * parent, const coord_t * in_parent, ++ znode * child); ++extern znode *child_znode(const coord_t * in_parent, znode * parent, ++ int incore_p, int setup_dkeys_p); ++ ++extern int cbk_cache_init(cbk_cache * cache); ++extern void cbk_cache_done(cbk_cache * cache); ++extern void cbk_cache_invalidate(const znode * node, reiser4_tree * tree); ++ ++extern char *sprint_address(const reiser4_block_nr * block); ++ ++#if REISER4_DEBUG ++extern void print_coord_content(const char *prefix, coord_t * p); ++extern void reiser4_print_address(const char *prefix, ++ const reiser4_block_nr * block); ++extern void print_tree_rec(const char *prefix, reiser4_tree * tree, ++ __u32 flags); ++extern void check_dkeys(znode *node); ++#else ++#define print_coord_content(p, c) noop ++#define reiser4_print_address(p, b) noop ++#endif ++ ++extern void forget_znode(lock_handle * handle); ++extern int deallocate_znode(znode * node); ++ ++extern int is_disk_addr_unallocated(const reiser4_block_nr * addr); ++ ++/* struct used internally to pack all numerous arguments of tree lookup. ++ Used to avoid passing a lot of arguments to helper functions. */ ++typedef struct cbk_handle { ++ /* tree we are in */ ++ reiser4_tree *tree; ++ /* key we are going after */ ++ const reiser4_key *key; ++ /* coord we will store result in */ ++ coord_t *coord; ++ /* type of lock to take on target node */ ++ znode_lock_mode lock_mode; ++ /* lookup bias. See comments at the declaration of lookup_bias */ ++ lookup_bias bias; ++ /* lock level: level starting from which tree traversal starts taking ++ * write locks. */ ++ tree_level lock_level; ++ /* level where search will stop. Either item will be found between ++ lock_level and stop_level, or CBK_COORD_NOTFOUND will be ++ returned. ++ */ ++ tree_level stop_level; ++ /* level we are currently at */ ++ tree_level level; ++ /* block number of @active node. Tree traversal operates on two ++ nodes: active and parent. */ ++ reiser4_block_nr block; ++ /* put here error message to be printed by caller */ ++ const char *error; ++ /* result passed back to caller */ ++ int result; ++ /* lock handles for active and parent */ ++ lock_handle *parent_lh; ++ lock_handle *active_lh; ++ reiser4_key ld_key; ++ reiser4_key rd_key; ++ /* flags, passed to the cbk routine. Bits of this bitmask are defined ++ in tree.h:cbk_flags enum. */ ++ __u32 flags; ++ ra_info_t *ra_info; ++ struct inode *object; ++} cbk_handle; ++ ++extern znode_lock_mode cbk_lock_mode(tree_level level, cbk_handle * h); ++ ++/* eottl.c */ ++extern int handle_eottl(cbk_handle *h, int *outcome); ++ ++int lookup_multikey(cbk_handle * handle, int nr_keys); ++int lookup_couple(reiser4_tree * tree, ++ const reiser4_key * key1, const reiser4_key * key2, ++ coord_t * coord1, coord_t * coord2, ++ lock_handle * lh1, lock_handle * lh2, ++ znode_lock_mode lock_mode, lookup_bias bias, ++ tree_level lock_level, tree_level stop_level, __u32 flags, ++ int *result1, int *result2); ++ ++static inline void read_lock_dk(reiser4_tree *tree) ++{ ++ /* check that dk is not locked */ ++ assert("", (LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(read_locked_dk) && ++ LOCK_CNT_NIL(write_locked_dk))); ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", LOCK_CNT_NIL(spin_locked_stack)); ++ ++ read_lock(&((tree)->dk_lock)); ++ ++ LOCK_CNT_INC(read_locked_dk); ++ LOCK_CNT_INC(rw_locked_dk); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void read_unlock_dk(reiser4_tree *tree) ++{ ++ assert("nikita-1375", LOCK_CNT_GTZ(read_locked_dk)); ++ assert("nikita-1376", LOCK_CNT_GTZ(rw_locked_dk)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(read_locked_dk); ++ LOCK_CNT_DEC(rw_locked_dk); ++ LOCK_CNT_DEC(spin_locked); ++ ++ read_unlock(&(tree->dk_lock)); ++} ++ ++static inline void write_lock_dk(reiser4_tree *tree) ++{ ++ /* check that dk is not locked */ ++ assert("", (LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(read_locked_dk) && ++ LOCK_CNT_NIL(write_locked_dk))); ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", LOCK_CNT_NIL(spin_locked_stack)); ++ ++ write_lock(&((tree)->dk_lock)); ++ ++ LOCK_CNT_INC(write_locked_dk); ++ LOCK_CNT_INC(rw_locked_dk); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void write_unlock_dk(reiser4_tree *tree) ++{ ++ assert("nikita-1375", LOCK_CNT_GTZ(write_locked_dk)); ++ assert("nikita-1376", LOCK_CNT_GTZ(rw_locked_dk)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(write_locked_dk); ++ LOCK_CNT_DEC(rw_locked_dk); ++ LOCK_CNT_DEC(spin_locked); ++ ++ write_unlock(&(tree->dk_lock)); ++} ++ ++/* estimate api. Implementation is in estimate.c */ ++reiser4_block_nr estimate_one_insert_item(reiser4_tree *); ++reiser4_block_nr estimate_one_insert_into_item(reiser4_tree *); ++reiser4_block_nr estimate_insert_flow(tree_level); ++reiser4_block_nr estimate_one_item_removal(reiser4_tree *); ++reiser4_block_nr calc_estimate_one_insert(tree_level); ++reiser4_block_nr estimate_dirty_cluster(struct inode *); ++reiser4_block_nr estimate_insert_cluster(struct inode *); ++reiser4_block_nr estimate_update_cluster(struct inode *); ++ ++/* __REISER4_TREE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree_mod.c linux-5.10.2/fs/reiser4/tree_mod.c +--- linux-5.10.2.orig/fs/reiser4/tree_mod.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree_mod.c 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,391 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* ++ * Functions to add/delete new nodes to/from the tree. ++ * ++ * Functions from this file are used by carry (see carry*) to handle: ++ * ++ * . insertion of new formatted node into tree ++ * ++ * . addition of new tree root, increasing tree height ++ * ++ * . removing tree root, decreasing tree height ++ * ++ */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/plugin.h" ++#include "jnode.h" ++#include "znode.h" ++#include "tree_mod.h" ++#include "block_alloc.h" ++#include "tree_walk.h" ++#include "tree.h" ++#include "super.h" ++ ++#include ++ ++static int add_child_ptr(znode * parent, znode * child); ++/* warning only issued if error is not -E_REPEAT */ ++#define ewarning( error, ... ) \ ++ if( ( error ) != -E_REPEAT ) \ ++ warning( __VA_ARGS__ ) ++ ++/* ++ * allocate new node on the @level and immediately on the right of @brother ++ */ ++znode *reiser4_new_node(znode *brother, /* existing left neighbor of new node */ ++ tree_level level /* tree level at which new node is to ++ * be allocated */) ++{ ++ znode *result; ++ int retcode; ++ reiser4_subvol *subv; ++ reiser4_block_nr blocknr; ++ ++ assert("nikita-930", brother != NULL); ++ assert("umka-264", level < REAL_MAX_ZTREE_HEIGHT); ++ ++ subv = znode_get_subvol(brother); ++ assert("edward-1735", subv != NULL); ++ ++ retcode = assign_fake_blocknr_formatted(&blocknr, subv); ++ if (retcode == 0) { ++ result = zget(subv, &blocknr, NULL, level, ++ reiser4_ctx_gfp_mask_get()); ++ if (IS_ERR(result)) { ++ ewarning(PTR_ERR(result), "nikita-929", ++ "Cannot allocate znode for carry: %li", ++ PTR_ERR(result)); ++ return result; ++ } ++ /* cheap test, can be executed even when debugging is off */ ++ if (!znode_just_created(result)) { ++ warning("nikita-2213", ++ "Allocated already existing block: %llu", ++ (unsigned long long)blocknr); ++ zput(result); ++ return ERR_PTR(RETERR(-EIO)); ++ } ++ ++ assert("nikita-931", result != NULL); ++ result->nplug = znode_get_tree(brother)->nplug; ++ assert("nikita-933", result->nplug != NULL); ++ ++ retcode = zinit_new(result, reiser4_ctx_gfp_mask_get()); ++ if (retcode == 0) { ++ ZF_SET(result, JNODE_CREATED); ++ zrelse(result); ++ } else { ++ zput(result); ++ result = ERR_PTR(retcode); ++ } ++ } else { ++ /* failure to allocate new node during balancing. ++ This should never happen. Ever. Returning -E_REPEAT ++ is not viable solution, because "out of disk space" ++ is not transient error that will go away by itself. ++ */ ++ ewarning(retcode, "nikita-928", ++ "Cannot allocate block for carry: %i", retcode); ++ result = ERR_PTR(retcode); ++ } ++ assert("nikita-1071", result != NULL); ++ return result; ++} ++ ++/* allocate new root and add it to the tree ++ ++ This helper function is called by add_new_root(). ++ ++*/ ++znode *reiser4_add_tree_root(znode * old_root /* existing tree root */ , ++ znode * fake /* "fake" znode */ ) ++{ ++ reiser4_tree *tree = znode_get_tree(old_root); ++ znode *new_root = NULL; /* to shut gcc up */ ++ int result; ++ ++ assert("nikita-1069", old_root != NULL); ++ assert("umka-262", fake != NULL); ++ assert("umka-263", tree != NULL); ++ ++ /* "fake" znode---one always hanging just above current root. This ++ node is locked when new root is created or existing root is ++ deleted. Downward tree traversal takes lock on it before taking ++ lock on a root node. This avoids race conditions with root ++ manipulations. ++ ++ */ ++ assert("nikita-1348", znode_above_root(fake)); ++ assert("nikita-1211", znode_is_root(old_root)); ++ ++ result = 0; ++ if (tree->height >= REAL_MAX_ZTREE_HEIGHT) { ++ warning("nikita-1344", "Tree is too tall: %i", tree->height); ++ /* ext2 returns -ENOSPC when it runs out of free inodes with a ++ following comment (fs/ext2/ialloc.c:441): Is it really ++ ENOSPC? ++ ++ -EXFULL? -EINVAL? ++ */ ++ result = RETERR(-ENOSPC); ++ } else { ++ /* Allocate block for new root. It's not that ++ important where it will be allocated, as root is ++ almost always in memory. Moreover, allocate on ++ flush can be going here. ++ */ ++ assert("nikita-1448", znode_is_root(old_root)); ++ new_root = reiser4_new_node(fake, tree->height + 1); ++ if (!IS_ERR(new_root) && (result = zload(new_root)) == 0) { ++ lock_handle rlh; ++ ++ init_lh(&rlh); ++ result = ++ longterm_lock_znode(&rlh, new_root, ++ ZNODE_WRITE_LOCK, ++ ZNODE_LOCK_LOPRI); ++ if (result == 0) { ++ parent_coord_t *in_parent; ++ ++ znode_make_dirty(fake); ++ ++ /* new root is a child of "fake" node */ ++ write_lock_tree(); ++ ++ ++tree->height; ++ ++ /* recalculate max balance overhead */ ++ tree->estimate_one_insert = ++ calc_estimate_one_insert(tree->height); ++ ++ tree->root_block = *znode_get_block(new_root); ++ in_parent = &new_root->in_parent; ++ init_parent_coord(in_parent, fake); ++ /* manually insert new root into sibling ++ * list. With this all nodes involved into ++ * balancing are connected after balancing is ++ * done---useful invariant to check. */ ++ sibling_list_insert_nolock(new_root, NULL); ++ write_unlock_tree(); ++ ++ /* insert into new root pointer to the ++ @old_root. */ ++ assert("nikita-1110", ++ WITH_DATA(new_root, ++ node_is_empty(new_root))); ++ write_lock_dk(tree); ++ znode_set_ld_key(new_root, reiser4_min_key()); ++ znode_set_rd_key(new_root, reiser4_max_key()); ++ write_unlock_dk(tree); ++ if (REISER4_DEBUG) { ++ ZF_CLR(old_root, JNODE_LEFT_CONNECTED); ++ ZF_CLR(old_root, JNODE_RIGHT_CONNECTED); ++ ZF_SET(old_root, JNODE_ORPHAN); ++ } ++ result = add_child_ptr(new_root, old_root); ++ done_lh(&rlh); ++ } ++ zrelse(new_root); ++ } ++ } ++ if (result != 0) ++ new_root = ERR_PTR(result); ++ return new_root; ++} ++ ++/* build &reiser4_item_data for inserting child pointer ++ ++ Build &reiser4_item_data that can be later used to insert pointer to @child ++ in its parent. ++ ++*/ ++void build_child_ptr_data(znode * child /* node pointer to which will be ++ * inserted */ , ++ reiser4_item_data * data /* where to store result */ ) ++{ ++ assert("nikita-1116", child != NULL); ++ assert("nikita-1117", data != NULL); ++ ++ /* ++ * NOTE: use address of child's blocknr as address of data to be ++ * inserted. As result of this data gets into on-disk structure in cpu ++ * byte order. internal's create_hook converts it to little endian byte ++ * order. ++ */ ++ data->data = (char *)znode_get_block(child); ++ /* data -> data is kernel space */ ++ data->user = 0; ++ data->length = sizeof(reiser4_block_nr); ++ /* FIXME-VS: hardcoded internal item? */ ++ ++ /* AUDIT: Is it possible that "item_plugin_by_id" may find nothing? */ ++ data->iplug = item_plugin_by_id(NODE_POINTER_ID); ++} ++ ++/* add pointer to @child into empty @parent. ++ ++ This is used when pointer to old root is inserted into new root which is ++ empty. ++*/ ++static int add_child_ptr(znode * parent, znode * child) ++{ ++ coord_t coord; ++ reiser4_item_data data; ++ int result; ++ reiser4_key key; ++ ++ assert("nikita-1111", parent != NULL); ++ assert("nikita-1112", child != NULL); ++ assert("nikita-1115", ++ znode_get_level(parent) == znode_get_level(child) + 1); ++ ++ result = zload(parent); ++ if (result != 0) ++ return result; ++ assert("nikita-1113", node_is_empty(parent)); ++ coord_init_first_unit(&coord, parent); ++ ++ build_child_ptr_data(child, &data); ++ data.arg = NULL; ++ ++ read_lock_dk(znode_get_tree(parent)); ++ key = *znode_get_ld_key(child); ++ read_unlock_dk(znode_get_tree(parent)); ++ ++ result = node_plugin_by_node(parent)->create_item(&coord, &key, &data, ++ NULL); ++ znode_make_dirty(parent); ++ zrelse(parent); ++ return result; ++} ++ ++/* actually remove tree root */ ++static int reiser4_kill_root(reiser4_tree * tree /* tree from which root is ++ * being removed */, ++ znode * old_root /* root node that is being ++ * removed */ , ++ znode * new_root /* new root---sole child of ++ * @old_root */, ++ const reiser4_block_nr * new_root_blk /* disk address of ++ * @new_root */) ++{ ++ znode *uber; ++ int result; ++ lock_handle handle_for_uber; ++ ++ assert("umka-265", tree != NULL); ++ assert("nikita-1198", new_root != NULL); ++ assert("nikita-1199", ++ znode_get_level(new_root) + 1 == znode_get_level(old_root)); ++ ++ assert("nikita-1201", znode_is_write_locked(old_root)); ++ ++ assert("nikita-1203", ++ disk_addr_eq(new_root_blk, znode_get_block(new_root))); ++ ++ init_lh(&handle_for_uber); ++ /* obtain and lock "fake" znode protecting changes in tree height. */ ++ result = get_uber_znode(tree, ZNODE_WRITE_LOCK, ZNODE_LOCK_HIPRI, ++ &handle_for_uber); ++ if (result == 0) { ++ uber = handle_for_uber.node; ++ ++ znode_make_dirty(uber); ++ ++ /* don't take long term lock a @new_root. Take spinlock. */ ++ ++ write_lock_tree(); ++ ++ tree->root_block = *new_root_blk; ++ --tree->height; ++ ++ /* recalculate max balance overhead */ ++ tree->estimate_one_insert = ++ calc_estimate_one_insert(tree->height); ++ ++ assert("nikita-1202", ++ tree->height == znode_get_level(new_root)); ++ ++ /* new root is child on "fake" node */ ++ init_parent_coord(&new_root->in_parent, uber); ++ ++uber->c_count; ++ ++ /* sibling_list_insert_nolock(new_root, NULL); */ ++ write_unlock_tree(); ++ ++ /* reinitialise old root. */ ++ result = init_znode(ZJNODE(old_root)); ++ znode_make_dirty(old_root); ++ if (result == 0) { ++ assert("nikita-1279", node_is_empty(old_root)); ++ ZF_SET(old_root, JNODE_HEARD_BANSHEE); ++ old_root->c_count = 0; ++ } ++ } ++ done_lh(&handle_for_uber); ++ ++ return result; ++} ++ ++/* remove tree root ++ ++ This function removes tree root, decreasing tree height by one. Tree root ++ and its only child (that is going to become new tree root) are write locked ++ at the entry. ++ ++ To remove tree root we need to take lock on special "fake" znode that ++ protects changes of tree height. See comments in reiser4_add_tree_root() for ++ more on this. ++ ++ Also parent pointers have to be updated in ++ old and new root. To simplify code, function is split into two parts: outer ++ reiser4_kill_tree_root() collects all necessary arguments and calls ++ reiser4_kill_root() to do the actual job. ++ ++*/ ++int reiser4_kill_tree_root(znode * old_root /* tree root that we are ++ removing*/) ++{ ++ int result; ++ coord_t down_link; ++ znode *new_root; ++ reiser4_tree *tree; ++ ++ assert("edward-1736", znode_get_subvol(old_root) != NULL); ++ assert("nikita-1194", old_root != NULL); ++ assert("nikita-1196", znode_is_root(old_root)); ++ assert("nikita-1200", node_num_items(old_root) == 1); ++ assert("nikita-1401", znode_is_write_locked(old_root)); ++ ++ coord_init_first_unit(&down_link, old_root); ++ ++ tree = znode_get_tree(old_root); ++ new_root = child_znode(&down_link, old_root, 0, 1); ++ if (!IS_ERR(new_root)) { ++ result = ++ reiser4_kill_root(tree, old_root, new_root, ++ znode_get_block(new_root)); ++ zput(new_root); ++ } else ++ result = PTR_ERR(new_root); ++ ++ return result; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree_mod.h linux-5.10.2/fs/reiser4/tree_mod.h +--- linux-5.10.2.orig/fs/reiser4/tree_mod.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree_mod.h 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,29 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Functions to add/delete new nodes to/from the tree. See tree_mod.c for ++ * comments. */ ++ ++#if !defined( __REISER4_TREE_MOD_H__ ) ++#define __REISER4_TREE_MOD_H__ ++ ++#include "forward.h" ++ ++znode *reiser4_new_node(znode * brother, tree_level level); ++znode *reiser4_add_tree_root(znode * old_root, znode * fake); ++int reiser4_kill_tree_root(znode * old_root); ++void build_child_ptr_data(znode * child, reiser4_item_data * data); ++ ++/* __REISER4_TREE_MOD_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree_walk.c linux-5.10.2/fs/reiser4/tree_walk.c +--- linux-5.10.2.orig/fs/reiser4/tree_walk.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree_walk.c 2020-12-23 16:07:46.135813378 +0100 +@@ -0,0 +1,922 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Routines and macros to: ++ ++ get_left_neighbor() ++ ++ get_right_neighbor() ++ ++ get_parent() ++ ++ get_first_child() ++ ++ get_last_child() ++ ++ various routines to walk the whole tree and do things to it like ++ repack it, or move it to tertiary storage. Please make them as ++ generic as is reasonable. ++ ++*/ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "jnode.h" ++#include "znode.h" ++#include "tree_walk.h" ++#include "tree.h" ++#include "super.h" ++ ++/* These macros are used internally in tree_walk.c in attempt to make ++ lock_neighbor() code usable to build lock_parent(), lock_right_neighbor, ++ lock_left_neighbor */ ++#define GET_NODE_BY_PTR_OFFSET(node, off) (*(znode**)(((unsigned long)(node)) + (off))) ++#define FIELD_OFFSET(name) offsetof(znode, name) ++#define PARENT_PTR_OFFSET FIELD_OFFSET(in_parent.node) ++#define LEFT_PTR_OFFSET FIELD_OFFSET(left) ++#define RIGHT_PTR_OFFSET FIELD_OFFSET(right) ++ ++/* This is the generic procedure to get and lock `generic' neighbor (left or ++ right neighbor or parent). It implements common algorithm for all cases of ++ getting lock on neighbor node, only znode structure field is different in ++ each case. This is parameterized by ptr_offset argument, which is byte ++ offset for the pointer to the desired neighbor within the current node's ++ znode structure. This function should be called with the tree lock held */ ++static int lock_neighbor( ++ /* resulting lock handle */ ++ lock_handle * result, ++ /* znode to lock */ ++ znode * node, ++ /* pointer to neighbor (or parent) znode field offset, in bytes from ++ the base address of znode structure */ ++ int ptr_offset, ++ /* lock mode for longterm_lock_znode call */ ++ znode_lock_mode mode, ++ /* lock request for longterm_lock_znode call */ ++ znode_lock_request req, ++ /* GN_* flags */ ++ int flags, int rlocked) ++{ ++ int ret; ++ znode *neighbor; ++ ++ assert("umka-236", node != NULL); ++ assert("umka-237", znode_get_tree(node) != NULL); ++ assert_rw_locked(&(znode_get_tree(node)->tree_lock)); ++ ++ if (flags & GN_TRY_LOCK) ++ req |= ZNODE_LOCK_NONBLOCK; ++ if (flags & GN_SAME_ATOM) ++ req |= ZNODE_LOCK_DONT_FUSE; ++ ++ /* get neighbor's address by using of sibling link, quit while loop ++ (and return) if link is not available. */ ++ while (1) { ++ neighbor = GET_NODE_BY_PTR_OFFSET(node, ptr_offset); ++ ++ /* return -E_NO_NEIGHBOR if parent or side pointer is NULL or if ++ * node pointed by it is not connected. ++ * ++ * However, GN_ALLOW_NOT_CONNECTED option masks "connected" ++ * check and allows passing reference to not connected znode to ++ * subsequent longterm_lock_znode() call. This kills possible ++ * busy loop if we are trying to get longterm lock on locked but ++ * not yet connected parent node. */ ++ if (neighbor == NULL || !((flags & GN_ALLOW_NOT_CONNECTED) ++ || znode_is_connected(neighbor))) { ++ return RETERR(-E_NO_NEIGHBOR); ++ } ++ ++ /* protect it from deletion. */ ++ zref(neighbor); ++ ++ rlocked ? read_unlock_tree() : write_unlock_tree(); ++ ++ ret = longterm_lock_znode(result, neighbor, mode, req); ++ ++ /* The lock handle obtains its own reference, release the one from above. */ ++ zput(neighbor); ++ ++ rlocked ? read_lock_tree() : write_lock_tree(); ++ ++ /* restart if node we got reference to is being ++ invalidated. we should not get reference to this node ++ again. */ ++ if (ret == -EINVAL) ++ continue; ++ if (ret) ++ return ret; ++ ++ /* check if neighbor link still points to just locked znode; ++ the link could have been changed while the process slept. */ ++ if (neighbor == GET_NODE_BY_PTR_OFFSET(node, ptr_offset)) ++ return 0; ++ ++ /* znode was locked by mistake; unlock it and restart locking ++ process from beginning. */ ++ rlocked ? read_unlock_tree() : write_unlock_tree(); ++ longterm_unlock_znode(result); ++ rlocked ? read_lock_tree() : write_lock_tree(); ++ } ++} ++ ++/* get parent node with longterm lock, accepts GN* flags. */ ++int reiser4_get_parent_flags(lock_handle * lh /* resulting lock handle */ , ++ znode * node /* child node */ , ++ znode_lock_mode mode ++ /* type of lock: read or write */ , ++ int flags /* GN_* flags */ ) ++{ ++ int result; ++ ++ read_lock_tree(); ++ result = lock_neighbor(lh, node, PARENT_PTR_OFFSET, mode, ++ ZNODE_LOCK_HIPRI, flags, 1); ++ read_unlock_tree(); ++ return result; ++} ++ ++/* wrapper function to lock right or left neighbor depending on GN_GO_LEFT ++ bit in @flags parameter */ ++/* Audited by: umka (2002.06.14) */ ++static inline int ++lock_side_neighbor(lock_handle * result, ++ znode * node, znode_lock_mode mode, int flags, int rlocked) ++{ ++ int ret; ++ int ptr_offset; ++ znode_lock_request req; ++ ++ if (flags & GN_GO_LEFT) { ++ ptr_offset = LEFT_PTR_OFFSET; ++ req = ZNODE_LOCK_LOPRI; ++ } else { ++ ptr_offset = RIGHT_PTR_OFFSET; ++ req = ZNODE_LOCK_HIPRI; ++ } ++ ++ ret = ++ lock_neighbor(result, node, ptr_offset, mode, req, flags, rlocked); ++ ++ if (ret == -E_NO_NEIGHBOR) /* if we walk left or right -E_NO_NEIGHBOR does not ++ * guarantee that neighbor is absent in the ++ * tree; in this case we return -ENOENT -- ++ * means neighbor at least not found in ++ * cache */ ++ return RETERR(-ENOENT); ++ ++ return ret; ++} ++ ++#if REISER4_DEBUG ++ ++int check_sibling_list(znode * node) ++{ ++ znode *scan; ++ znode *next; ++ ++ assert("nikita-3283", LOCK_CNT_GTZ(write_locked_tree)); ++ ++ if (node == NULL) ++ return 1; ++ ++ if (ZF_ISSET(node, JNODE_RIP)) ++ return 1; ++ ++ assert("nikita-3270", node != NULL); ++ assert_rw_write_locked(&(znode_get_tree(node)->tree_lock)); ++ ++ for (scan = node; znode_is_left_connected(scan); scan = next) { ++ next = scan->left; ++ if (next != NULL && !ZF_ISSET(next, JNODE_RIP)) { ++ assert("nikita-3271", znode_is_right_connected(next)); ++ assert("nikita-3272", next->right == scan); ++ } else ++ break; ++ } ++ for (scan = node; znode_is_right_connected(scan); scan = next) { ++ next = scan->right; ++ if (next != NULL && !ZF_ISSET(next, JNODE_RIP)) { ++ assert("nikita-3273", znode_is_left_connected(next)); ++ assert("nikita-3274", next->left == scan); ++ } else ++ break; ++ } ++ return 1; ++} ++ ++#endif ++ ++/* Znode sibling pointers maintenence. */ ++ ++/* Znode sibling pointers are established between any neighbored nodes which are ++ in cache. There are two znode state bits (JNODE_LEFT_CONNECTED, ++ JNODE_RIGHT_CONNECTED), if left or right sibling pointer contains actual ++ value (even NULL), corresponded JNODE_*_CONNECTED bit is set. ++ ++ Reiser4 tree operations which may allocate new znodes (CBK, tree balancing) ++ take care about searching (hash table lookup may be required) of znode ++ neighbors, establishing sibling pointers between them and setting ++ JNODE_*_CONNECTED state bits. */ ++ ++/* adjusting of sibling pointers and `connected' states for two ++ neighbors; works if one neighbor is NULL (was not found). */ ++ ++/* FIXME-VS: this is unstatic-ed to use in tree.c in prepare_twig_cut */ ++void link_left_and_right(znode * left, znode * right) ++{ ++ assert("nikita-3275", check_sibling_list(left)); ++ assert("nikita-3275", check_sibling_list(right)); ++ ++ if (left != NULL) { ++ if (left->right == NULL) { ++ left->right = right; ++ ZF_SET(left, JNODE_RIGHT_CONNECTED); ++ ++ ON_DEBUG(left->right_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ ++ } else if (ZF_ISSET(left->right, JNODE_HEARD_BANSHEE) ++ && left->right != right) { ++ ++ ON_DEBUG(left->right->left_version = ++ atomic_inc_return(&delim_key_version); ++ left->right_version = ++ atomic_inc_return(&delim_key_version);); ++ ++ left->right->left = NULL; ++ left->right = right; ++ ZF_SET(left, JNODE_RIGHT_CONNECTED); ++ } else ++ /* ++ * there is a race condition in renew_sibling_link() ++ * and assertions below check that it is only one ++ * there. Thread T1 calls renew_sibling_link() without ++ * GN_NO_ALLOC flag. zlook() doesn't find neighbor ++ * node, but before T1 gets to the ++ * link_left_and_right(), another thread T2 creates ++ * neighbor node and connects it. check for ++ * left->right == NULL above protects T1 from ++ * overwriting correct left->right pointer installed ++ * by T2. ++ */ ++ assert("nikita-3302", ++ right == NULL || left->right == right); ++ } ++ if (right != NULL) { ++ if (right->left == NULL) { ++ right->left = left; ++ ZF_SET(right, JNODE_LEFT_CONNECTED); ++ ++ ON_DEBUG(right->left_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ ++ } else if (ZF_ISSET(right->left, JNODE_HEARD_BANSHEE) ++ && right->left != left) { ++ ++ ON_DEBUG(right->left->right_version = ++ atomic_inc_return(&delim_key_version); ++ right->left_version = ++ atomic_inc_return(&delim_key_version);); ++ ++ right->left->right = NULL; ++ right->left = left; ++ ZF_SET(right, JNODE_LEFT_CONNECTED); ++ ++ } else ++ assert("nikita-3303", ++ left == NULL || right->left == left); ++ } ++ assert("nikita-3275", check_sibling_list(left)); ++ assert("nikita-3275", check_sibling_list(right)); ++} ++ ++/* Audited by: umka (2002.06.14) */ ++static void link_znodes(znode * first, znode * second, int to_left) ++{ ++ if (to_left) ++ link_left_and_right(second, first); ++ else ++ link_left_and_right(first, second); ++} ++ ++/* getting of next (to left or to right, depend on gn_to_left bit in flags) ++ coord's unit position in horizontal direction, even across node ++ boundary. Should be called under tree lock, it protects nonexistence of ++ sibling link on parent level, if lock_side_neighbor() fails with ++ -ENOENT. */ ++static int far_next_coord(coord_t * coord, lock_handle * handle, int flags) ++{ ++ int ret; ++ znode *node; ++ reiser4_tree *tree; ++ ++ assert("umka-243", coord != NULL); ++ assert("umka-244", handle != NULL); ++ assert("zam-1069", handle->node == NULL); ++ ++ ret = ++ (flags & GN_GO_LEFT) ? coord_prev_unit(coord) : ++ coord_next_unit(coord); ++ if (!ret) ++ return 0; ++ ++ ret = ++ lock_side_neighbor(handle, coord->node, ZNODE_READ_LOCK, flags, 0); ++ if (ret) ++ return ret; ++ ++ node = handle->node; ++ tree = znode_get_tree(node); ++ write_unlock_tree(); ++ ++ coord_init_zero(coord); ++ ++ /* We avoid synchronous read here if it is specified by flag. */ ++ if ((flags & GN_ASYNC) && znode_page(handle->node) == NULL) { ++ ret = jstartio(ZJNODE(handle->node)); ++ if (!ret) ++ ret = -E_REPEAT; ++ goto error_locked; ++ } ++ ++ /* corresponded zrelse() should be called by the clients of ++ far_next_coord(), in place when this node gets unlocked. */ ++ ret = zload(handle->node); ++ if (ret) ++ goto error_locked; ++ ++ if (flags & GN_GO_LEFT) ++ coord_init_last_unit(coord, node); ++ else ++ coord_init_first_unit(coord, node); ++ ++ if (0) { ++ error_locked: ++ longterm_unlock_znode(handle); ++ } ++ write_lock_tree(); ++ return ret; ++} ++ ++/* Very significant function which performs a step in horizontal direction ++ when sibling pointer is not available. Actually, it is only function which ++ does it. ++ Note: this function does not restore locking status at exit, ++ caller should does care about proper unlocking and zrelsing */ ++static int ++renew_sibling_link(coord_t * coord, lock_handle * handle, znode * child, ++ tree_level level, int flags, int *nr_locked) ++{ ++ int ret; ++ int to_left = flags & GN_GO_LEFT; ++ reiser4_block_nr da; ++ /* parent of the neighbor node; we set it to parent until not sharing ++ of one parent between child and neighbor node is detected */ ++ znode *side_parent = coord->node; ++ reiser4_subvol *subv = ZJNODE(child)->subvol; ++ reiser4_tree *tree = znode_get_tree(child); ++ znode *neighbor = NULL; ++ ++ assert("umka-245", coord != NULL); ++ assert("umka-246", handle != NULL); ++ assert("umka-247", child != NULL); ++ assert("umka-303", tree != NULL); ++ ++ init_lh(handle); ++ write_lock_tree(); ++ ret = far_next_coord(coord, handle, flags); ++ ++ if (ret) { ++ if (ret != -ENOENT) { ++ write_unlock_tree(); ++ return ret; ++ } ++ } else { ++ item_plugin *iplug; ++ ++ if (handle->node != NULL) { ++ (*nr_locked)++; ++ side_parent = handle->node; ++ } ++ ++ /* does coord object points to internal item? We do not ++ support sibling pointers between znode for formatted and ++ unformatted nodes and return -E_NO_NEIGHBOR in that case. */ ++ iplug = item_plugin_by_coord(coord); ++ if (!item_is_internal(coord)) { ++ link_znodes(child, NULL, to_left); ++ write_unlock_tree(); ++ /* we know there can't be formatted neighbor */ ++ return RETERR(-E_NO_NEIGHBOR); ++ } ++ write_unlock_tree(); ++ ++ iplug->s.internal.down_link(coord, NULL, &da); ++ ++ if (flags & GN_NO_ALLOC) ++ neighbor = zlook(tree, &da); ++ else ++ neighbor = zget(subv, &da, side_parent, level, ++ reiser4_ctx_gfp_mask_get()); ++ ++ if (IS_ERR(neighbor)) { ++ ret = PTR_ERR(neighbor); ++ return ret; ++ } ++ ++ if (neighbor) ++ /* update delimiting keys */ ++ set_child_delimiting_keys(coord->node, coord, neighbor); ++ ++ write_lock_tree(); ++ } ++ ++ if (likely(neighbor == NULL || ++ (znode_get_level(child) == znode_get_level(neighbor) ++ && child != neighbor))) ++ link_znodes(child, neighbor, to_left); ++ else { ++ warning("nikita-3532", ++ "Sibling nodes on the different levels: %i != %i\n", ++ znode_get_level(child), znode_get_level(neighbor)); ++ ret = RETERR(-EIO); ++ } ++ ++ write_unlock_tree(); ++ ++ /* if GN_NO_ALLOC isn't set we keep reference to neighbor znode */ ++ if (neighbor != NULL && (flags & GN_NO_ALLOC)) ++ /* atomic_dec(&ZJNODE(neighbor)->x_count); */ ++ zput(neighbor); ++ ++ return ret; ++} ++ ++/* This function is for establishing of one side relation. */ ++/* Audited by: umka (2002.06.14) */ ++static int connect_one_side(coord_t * coord, znode * node, int flags) ++{ ++ coord_t local; ++ lock_handle handle; ++ int nr_locked; ++ int ret; ++ ++ assert("umka-248", coord != NULL); ++ assert("umka-249", node != NULL); ++ ++ coord_dup_nocheck(&local, coord); ++ ++ init_lh(&handle); ++ ++ ret = ++ renew_sibling_link(&local, &handle, node, znode_get_level(node), ++ flags | GN_NO_ALLOC, &nr_locked); ++ ++ if (handle.node != NULL) { ++ /* complementary operations for zload() and lock() in far_next_coord() */ ++ zrelse(handle.node); ++ longterm_unlock_znode(&handle); ++ } ++ ++ /* we catch error codes which are not interesting for us because we ++ run renew_sibling_link() only for znode connection. */ ++ if (ret == -ENOENT || ret == -E_NO_NEIGHBOR) ++ return 0; ++ ++ return ret; ++} ++ ++/* if @child is not in `connected' state, performs hash searches for left and ++ right neighbor nodes and establishes horizontal sibling links */ ++/* Audited by: umka (2002.06.14), umka (2002.06.15) */ ++int connect_znode(coord_t * parent_coord, znode * child) ++{ ++ int ret = 0; ++ ++ assert("zam-330", parent_coord != NULL); ++ assert("zam-331", child != NULL); ++ assert("zam-332", parent_coord->node != NULL); ++ assert("umka-305", znode_get_tree(child) != NULL); ++ ++ /* it is trivial to `connect' root znode because it can't have ++ neighbors */ ++ if (znode_above_root(parent_coord->node)) { ++ child->left = NULL; ++ child->right = NULL; ++ ZF_SET(child, JNODE_LEFT_CONNECTED); ++ ZF_SET(child, JNODE_RIGHT_CONNECTED); ++ ++ ON_DEBUG(child->left_version = ++ atomic_inc_return(&delim_key_version); ++ child->right_version = ++ atomic_inc_return(&delim_key_version);); ++ ++ return 0; ++ } ++ ++ /* load parent node */ ++ coord_clear_iplug(parent_coord); ++ ret = zload(parent_coord->node); ++ ++ if (ret != 0) ++ return ret; ++ ++ /* protect `connected' state check by tree_lock */ ++ read_lock_tree(); ++ ++ if (!znode_is_right_connected(child)) { ++ read_unlock_tree(); ++ /* connect right (default is right) */ ++ ret = connect_one_side(parent_coord, child, GN_NO_ALLOC); ++ if (ret) ++ goto zrelse_and_ret; ++ ++ read_lock_tree(); ++ } ++ ++ ret = znode_is_left_connected(child); ++ ++ read_unlock_tree(); ++ ++ if (!ret) { ++ ret = ++ connect_one_side(parent_coord, child, ++ GN_NO_ALLOC | GN_GO_LEFT); ++ } else ++ ret = 0; ++ ++ zrelse_and_ret: ++ zrelse(parent_coord->node); ++ ++ return ret; ++} ++ ++/* this function is like renew_sibling_link() but allocates neighbor node if ++ it doesn't exist and `connects' it. It may require making two steps in ++ horizontal direction, first one for neighbor node finding/allocation, ++ second one is for finding neighbor of neighbor to connect freshly allocated ++ znode. */ ++/* Audited by: umka (2002.06.14), umka (2002.06.15) */ ++static int ++renew_neighbor(coord_t * coord, znode * node, tree_level level, int flags) ++{ ++ coord_t local; ++ lock_handle empty[2]; ++ znode *neighbor = NULL; ++ int nr_locked = 0; ++ int ret; ++ ++ assert("umka-250", coord != NULL); ++ assert("umka-251", node != NULL); ++ assert("umka-307", znode_get_tree(node) != NULL); ++ assert("umka-308", level <= znode_get_tree(node)->height); ++ ++ /* umka (2002.06.14) ++ Here probably should be a check for given "level" validness. ++ Something like assert("xxx-yyy", level < REAL_MAX_ZTREE_HEIGHT); ++ */ ++ ++ coord_dup(&local, coord); ++ ++ ret = ++ renew_sibling_link(&local, &empty[0], node, level, ++ flags & ~GN_NO_ALLOC, &nr_locked); ++ if (ret) ++ goto out; ++ ++ /* tree lock is not needed here because we keep parent node(s) locked ++ and reference to neighbor znode incremented */ ++ neighbor = (flags & GN_GO_LEFT) ? node->left : node->right; ++ ++ read_lock_tree(); ++ ret = znode_is_connected(neighbor); ++ read_unlock_tree(); ++ if (ret) { ++ ret = 0; ++ goto out; ++ } ++ ++ ret = ++ renew_sibling_link(&local, &empty[nr_locked], neighbor, level, ++ flags | GN_NO_ALLOC, &nr_locked); ++ /* second renew_sibling_link() call is used for znode connection only, ++ so we can live with these errors */ ++ if (-ENOENT == ret || -E_NO_NEIGHBOR == ret) ++ ret = 0; ++ ++ out: ++ ++ for (--nr_locked; nr_locked >= 0; --nr_locked) { ++ zrelse(empty[nr_locked].node); ++ longterm_unlock_znode(&empty[nr_locked]); ++ } ++ ++ if (neighbor != NULL) ++ /* decrement znode reference counter without actually ++ releasing it. */ ++ atomic_dec(&ZJNODE(neighbor)->x_count); ++ ++ return ret; ++} ++ ++/* ++ reiser4_get_neighbor() -- lock node's neighbor. ++ ++ reiser4_get_neighbor() locks node's neighbor (left or right one, depends on ++ given parameter) using sibling link to it. If sibling link is not available ++ (i.e. neighbor znode is not in cache) and flags allow read blocks, we go one ++ level up for information about neighbor's disk address. We lock node's ++ parent, if it is common parent for both 'node' and its neighbor, neighbor's ++ disk address is in next (to left or to right) down link from link that points ++ to original node. If not, we need to lock parent's neighbor, read its content ++ and take first(last) downlink with neighbor's disk address. That locking ++ could be done by using sibling link and lock_neighbor() function, if sibling ++ link exists. In another case we have to go level up again until we find ++ common parent or valid sibling link. Then go down ++ allocating/connecting/locking/reading nodes until neighbor of first one is ++ locked. ++ ++ @neighbor: result lock handle, ++ @node: a node which we lock neighbor of, ++ @lock_mode: lock mode {LM_READ, LM_WRITE}, ++ @flags: logical OR of {GN_*} (see description above) subset. ++ ++ @return: 0 if success, negative value if lock was impossible due to an error ++ or lack of neighbor node. ++*/ ++ ++/* Audited by: umka (2002.06.14), umka (2002.06.15) */ ++int ++reiser4_get_neighbor(lock_handle * neighbor, znode * node, ++ znode_lock_mode lock_mode, int flags) ++{ ++ lock_handle path[REAL_MAX_ZTREE_HEIGHT]; ++ ++ coord_t coord; ++ ++ tree_level base_level; ++ tree_level h = 0; ++ int ret; ++ ++ assert("umka-252", znode_get_tree(node) != NULL); ++ assert("umka-253", neighbor != NULL); ++ assert("umka-254", node != NULL); ++ ++ base_level = znode_get_level(node); ++ ++ assert("umka-310", base_level <= znode_get_tree(node)->height); ++ ++ coord_init_zero(&coord); ++ ++ again: ++ /* first, we try to use simple lock_neighbor() which requires sibling ++ link existence */ ++ read_lock_tree(); ++ ret = lock_side_neighbor(neighbor, node, lock_mode, flags, 1); ++ read_unlock_tree(); ++ if (!ret) { ++ /* load znode content if it was specified */ ++ if (flags & GN_LOAD_NEIGHBOR) { ++ ret = zload(node); ++ if (ret) ++ longterm_unlock_znode(neighbor); ++ } ++ return ret; ++ } ++ ++ /* only -ENOENT means we may look upward and try to connect ++ @node with its neighbor (if @flags allow us to do it) */ ++ if (ret != -ENOENT || !(flags & GN_CAN_USE_UPPER_LEVELS)) ++ return ret; ++ ++ /* before establishing of sibling link we lock parent node; it is ++ required by renew_neighbor() to work. */ ++ init_lh(&path[0]); ++ ret = reiser4_get_parent(&path[0], node, ZNODE_READ_LOCK); ++ if (ret) ++ return ret; ++ if (znode_above_root(path[0].node)) { ++ longterm_unlock_znode(&path[0]); ++ return RETERR(-E_NO_NEIGHBOR); ++ } ++ ++ while (1) { ++ znode *child = (h == 0) ? node : path[h - 1].node; ++ znode *parent = path[h].node; ++ ++ ret = zload(parent); ++ if (ret) ++ break; ++ ++ ret = find_child_ptr(parent, child, &coord); ++ ++ if (ret) { ++ zrelse(parent); ++ break; ++ } ++ ++ /* try to establish missing sibling link */ ++ ret = renew_neighbor(&coord, child, h + base_level, flags); ++ ++ zrelse(parent); ++ ++ switch (ret) { ++ case 0: ++ /* unlocking of parent znode prevents simple ++ deadlock situation */ ++ done_lh(&path[h]); ++ ++ /* depend on tree level we stay on we repeat first ++ locking attempt ... */ ++ if (h == 0) ++ goto again; ++ ++ /* ... or repeat establishing of sibling link at ++ one level below. */ ++ --h; ++ break; ++ ++ case -ENOENT: ++ /* sibling link is not available -- we go ++ upward. */ ++ init_lh(&path[h + 1]); ++ ret = ++ reiser4_get_parent(&path[h + 1], parent, ++ ZNODE_READ_LOCK); ++ if (ret) ++ goto fail; ++ ++h; ++ if (znode_above_root(path[h].node)) { ++ ret = RETERR(-E_NO_NEIGHBOR); ++ goto fail; ++ } ++ break; ++ ++ case -E_DEADLOCK: ++ /* there was lock request from hi-pri locker. if ++ it is possible we unlock last parent node and ++ re-lock it again. */ ++ for (; reiser4_check_deadlock(); h--) { ++ done_lh(&path[h]); ++ if (h == 0) ++ goto fail; ++ } ++ ++ break; ++ ++ default: /* other errors. */ ++ goto fail; ++ } ++ } ++ fail: ++ ON_DEBUG(check_lock_node_data(node)); ++ ON_DEBUG(check_lock_data()); ++ ++ /* unlock path */ ++ do { ++ /* FIXME-Zam: when we get here from case -E_DEADLOCK's goto ++ fail; path[0] is already done_lh-ed, therefore ++ longterm_unlock_znode(&path[h]); is not applicable */ ++ done_lh(&path[h]); ++ --h; ++ } while (h + 1 != 0); ++ ++ return ret; ++} ++ ++/* remove node from sibling list */ ++/* Audited by: umka (2002.06.14) */ ++void sibling_list_remove(znode * node) ++{ ++ reiser4_tree *tree; ++ ++ tree = znode_get_tree(node); ++ assert("umka-255", node != NULL); ++ assert_rw_write_locked(&(tree->tree_lock)); ++ assert("nikita-3275", check_sibling_list(node)); ++ ++ write_lock_dk(tree); ++ if (znode_is_right_connected(node) && node->right != NULL && ++ znode_is_left_connected(node) && node->left != NULL) { ++ assert("zam-32245", ++ keyeq(znode_get_rd_key(node), ++ znode_get_ld_key(node->right))); ++ znode_set_rd_key(node->left, znode_get_ld_key(node->right)); ++ } ++ write_unlock_dk(tree); ++ ++ if (znode_is_right_connected(node) && node->right != NULL) { ++ assert("zam-322", znode_is_left_connected(node->right)); ++ node->right->left = node->left; ++ ON_DEBUG(node->right->left_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } ++ if (znode_is_left_connected(node) && node->left != NULL) { ++ assert("zam-323", znode_is_right_connected(node->left)); ++ node->left->right = node->right; ++ ON_DEBUG(node->left->right_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } ++ ++ ZF_CLR(node, JNODE_LEFT_CONNECTED); ++ ZF_CLR(node, JNODE_RIGHT_CONNECTED); ++ ON_DEBUG(node->left = node->right = NULL; ++ node->left_version = atomic_inc_return(&delim_key_version); ++ node->right_version = atomic_inc_return(&delim_key_version);); ++ assert("nikita-3276", check_sibling_list(node)); ++} ++ ++/* disconnect node from sibling list */ ++void sibling_list_drop(znode * node) ++{ ++ znode *right; ++ znode *left; ++ ++ assert("nikita-2464", node != NULL); ++ assert("nikita-3277", check_sibling_list(node)); ++ ++ right = node->right; ++ if (right != NULL) { ++ assert("nikita-2465", znode_is_left_connected(right)); ++ right->left = NULL; ++ ON_DEBUG(right->left_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } ++ left = node->left; ++ if (left != NULL) { ++ assert("zam-323", znode_is_right_connected(left)); ++ left->right = NULL; ++ ON_DEBUG(left->right_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } ++ ZF_CLR(node, JNODE_LEFT_CONNECTED); ++ ZF_CLR(node, JNODE_RIGHT_CONNECTED); ++ ON_DEBUG(node->left = node->right = NULL; ++ node->left_version = atomic_inc_return(&delim_key_version); ++ node->right_version = atomic_inc_return(&delim_key_version);); ++} ++ ++/* Insert new node into sibling list. Regular balancing inserts new node ++ after (at right side) existing and locked node (@before), except one case ++ of adding new tree root node. @before should be NULL in that case. */ ++void sibling_list_insert_nolock(znode * new, znode * before) ++{ ++ assert("zam-334", new != NULL); ++ assert("nikita-3298", !znode_is_left_connected(new)); ++ assert("nikita-3299", !znode_is_right_connected(new)); ++ assert("nikita-3300", new->left == NULL); ++ assert("nikita-3301", new->right == NULL); ++ assert("nikita-3278", check_sibling_list(new)); ++ assert("nikita-3279", check_sibling_list(before)); ++ ++ if (before != NULL) { ++ assert("zam-333", znode_is_connected(before)); ++ new->right = before->right; ++ new->left = before; ++ ON_DEBUG(new->right_version = ++ atomic_inc_return(&delim_key_version); ++ new->left_version = ++ atomic_inc_return(&delim_key_version);); ++ if (before->right != NULL) { ++ before->right->left = new; ++ ON_DEBUG(before->right->left_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } ++ before->right = new; ++ ON_DEBUG(before->right_version = ++ atomic_inc_return(&delim_key_version); ++ ); ++ } else { ++ new->right = NULL; ++ new->left = NULL; ++ ON_DEBUG(new->right_version = ++ atomic_inc_return(&delim_key_version); ++ new->left_version = ++ atomic_inc_return(&delim_key_version);); ++ } ++ ZF_SET(new, JNODE_LEFT_CONNECTED); ++ ZF_SET(new, JNODE_RIGHT_CONNECTED); ++ assert("nikita-3280", check_sibling_list(new)); ++ assert("nikita-3281", check_sibling_list(before)); ++} ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/tree_walk.h linux-5.10.2/fs/reiser4/tree_walk.h +--- linux-5.10.2.orig/fs/reiser4/tree_walk.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/tree_walk.h 2020-12-23 16:07:46.136813392 +0100 +@@ -0,0 +1,125 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++/* definitions of reiser4 tree walk functions */ ++ ++#ifndef __FS_REISER4_TREE_WALK_H__ ++#define __FS_REISER4_TREE_WALK_H__ ++ ++#include "debug.h" ++#include "forward.h" ++ ++/* establishes horizontal links between cached znodes */ ++int connect_znode(coord_t * coord, znode * node); ++ ++/* tree traversal functions (reiser4_get_parent(), reiser4_get_neighbor()) ++ have the following common arguments: ++ ++ return codes: ++ ++ @return : 0 - OK, ++ ++ZAM-FIXME-HANS: wrong return code name. Change them all. ++ -ENOENT - neighbor is not in cache, what is detected by sibling ++ link absence. ++ ++ -E_NO_NEIGHBOR - we are sure that neighbor (or parent) node cannot be ++ found (because we are left-/right- most node of the ++ tree, for example). Also, this return code is for ++ reiser4_get_parent() when we see no parent link -- it ++ means that our node is root node. ++ ++ -E_DEADLOCK - deadlock detected (request from high-priority process ++ received), other error codes are conformed to ++ /usr/include/asm/errno.h . ++*/ ++ ++int ++reiser4_get_parent_flags(lock_handle * result, znode * node, ++ znode_lock_mode mode, int flags); ++ ++/* bits definition for reiser4_get_neighbor function `flags' arg. */ ++typedef enum { ++ /* If sibling pointer is NULL, this flag allows get_neighbor() to try to ++ * find not allocated not connected neigbor by going though upper ++ * levels */ ++ GN_CAN_USE_UPPER_LEVELS = 0x1, ++ /* locking left neighbor instead of right one */ ++ GN_GO_LEFT = 0x2, ++ /* automatically load neighbor node content */ ++ GN_LOAD_NEIGHBOR = 0x4, ++ /* return -E_REPEAT if can't lock */ ++ GN_TRY_LOCK = 0x8, ++ /* used internally in tree_walk.c, causes renew_sibling to not ++ allocate neighbor znode, but only search for it in znode cache */ ++ GN_NO_ALLOC = 0x10, ++ /* do not go across atom boundaries */ ++ GN_SAME_ATOM = 0x20, ++ /* allow to lock not connected nodes */ ++ GN_ALLOW_NOT_CONNECTED = 0x40, ++ /* Avoid synchronous jload, instead, call jstartio() and return -E_REPEAT. */ ++ GN_ASYNC = 0x80 ++} znode_get_neigbor_flags; ++ ++/* A commonly used wrapper for reiser4_get_parent_flags(). */ ++static inline int reiser4_get_parent(lock_handle * result, znode * node, ++ znode_lock_mode mode) ++{ ++ return reiser4_get_parent_flags(result, node, mode, ++ GN_ALLOW_NOT_CONNECTED); ++} ++ ++int reiser4_get_neighbor(lock_handle * neighbor, znode * node, ++ znode_lock_mode lock_mode, int flags); ++ ++/* there are wrappers for most common usages of reiser4_get_neighbor() */ ++static inline int ++reiser4_get_left_neighbor(lock_handle * result, znode * node, int lock_mode, ++ int flags) ++{ ++ return reiser4_get_neighbor(result, node, lock_mode, ++ flags | GN_GO_LEFT); ++} ++ ++static inline int ++reiser4_get_right_neighbor(lock_handle * result, znode * node, int lock_mode, ++ int flags) ++{ ++ ON_DEBUG(check_lock_node_data(node)); ++ ON_DEBUG(check_lock_data()); ++ return reiser4_get_neighbor(result, node, lock_mode, ++ flags & (~GN_GO_LEFT)); ++} ++ ++extern void sibling_list_remove(znode * node); ++extern void sibling_list_drop(znode * node); ++extern void sibling_list_insert_nolock(znode * new, znode * before); ++extern void link_left_and_right(znode * left, znode * right); ++ ++/* Functions called by tree_walk() when tree_walk() ... */ ++struct tree_walk_actor { ++ /* ... meets a formatted node, */ ++ int (*process_znode) (tap_t *, void *); ++ /* ... meets an extent, */ ++ int (*process_extent) (tap_t *, void *); ++ /* ... begins tree traversal or repeats it after -E_REPEAT was returned by ++ * node or extent processing functions. */ ++ int (*before) (void *); ++}; ++ ++#if REISER4_DEBUG ++int check_sibling_list(znode * node); ++#else ++#define check_sibling_list(n) (1) ++#endif ++ ++#endif /* __FS_REISER4_TREE_WALK_H__ */ ++ ++/* ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/txnmgr.c linux-5.10.2/fs/reiser4/txnmgr.c +--- linux-5.10.2.orig/fs/reiser4/txnmgr.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/txnmgr.c 2020-12-23 16:12:07.563664794 +0100 +@@ -0,0 +1,3556 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Joshua MacDonald wrote the first draft of this code. */ ++ ++/* ZAM-LONGTERM-FIXME-HANS: The locking in this file is badly designed, and a ++filesystem scales only as well as its worst locking design. You need to ++substantially restructure this code. Josh was not as experienced a programmer ++as you. Particularly review how the locking style differs from what you did ++for znodes usingt hi-lo priority locking, and present to me an opinion on ++whether the differences are well founded. */ ++ ++/* I cannot help but to disagree with the sentiment above. Locking of ++ * transaction manager is _not_ badly designed, and, at the very least, is not ++ * the scaling bottleneck. Scaling bottleneck is _exactly_ hi-lo priority ++ * locking on znodes, especially on the root node of the tree. --nikita, ++ * 2003.10.13 */ ++ ++/* The txnmgr is a set of interfaces that keep track of atoms and transcrash handles. The ++ txnmgr processes capture_block requests and manages the relationship between jnodes and ++ atoms through the various stages of a transcrash, and it also oversees the fusion and ++ capture-on-copy processes. The main difficulty with this task is maintaining a ++ deadlock-free lock ordering between atoms and jnodes/handles. The reason for the ++ difficulty is that jnodes, handles, and atoms contain pointer circles, and the cycle ++ must be broken. The main requirement is that atom-fusion be deadlock free, so once you ++ hold the atom_lock you may then wait to acquire any jnode or handle lock. This implies ++ that any time you check the atom-pointer of a jnode or handle and then try to lock that ++ atom, you must use trylock() and possibly reverse the order. ++ ++ This code implements the design documented at: ++ ++ http://namesys.com/txn-doc.html ++ ++ZAM-FIXME-HANS: update v4.html to contain all of the information present in the above (but updated), and then remove the ++above document and reference the new. Be sure to provide some credit to Josh. I already have some writings on this ++topic in v4.html, but they are lacking in details present in the above. Cure that. Remember to write for the bright 12 ++year old --- define all technical terms used. ++ ++*/ ++ ++/* Thoughts on the external transaction interface: ++ ++ In the current code, a TRANSCRASH handle is created implicitly by reiser4_init_context() (which ++ creates state that lasts for the duration of a system call and is called at the start ++ of ReiserFS methods implementing VFS operations), and closed by reiser4_exit_context(), ++ occupying the scope of a single system call. We wish to give certain applications an ++ interface to begin and close (commit) transactions. Since our implementation of ++ transactions does not yet support isolation, allowing an application to open a ++ transaction implies trusting it to later close the transaction. Part of the ++ transaction interface will be aimed at enabling that trust, but the interface for ++ actually using transactions is fairly narrow. ++ ++ BEGIN_TRANSCRASH: Returns a transcrash identifier. It should be possible to translate ++ this identifier into a string that a shell-script could use, allowing you to start a ++ transaction by issuing a command. Once open, the transcrash should be set in the task ++ structure, and there should be options (I suppose) to allow it to be carried across ++ fork/exec. A transcrash has several options: ++ ++ - READ_FUSING or WRITE_FUSING: The default policy is for txn-capture to capture only ++ on writes (WRITE_FUSING) and allow "dirty reads". If the application wishes to ++ capture on reads as well, it should set READ_FUSING. ++ ++ - TIMEOUT: Since a non-isolated transcrash cannot be undone, every transcrash must ++ eventually close (or else the machine must crash). If the application dies an ++ unexpected death with an open transcrash, for example, or if it hangs for a long ++ duration, one solution (to avoid crashing the machine) is to simply close it anyway. ++ This is a dangerous option, but it is one way to solve the problem until isolated ++ transcrashes are available for untrusted applications. ++ ++ It seems to be what databases do, though it is unclear how one avoids a DoS attack ++ creating a vulnerability based on resource starvation. Guaranteeing that some ++ minimum amount of computational resources are made available would seem more correct ++ than guaranteeing some amount of time. When we again have someone to code the work, ++ this issue should be considered carefully. -Hans ++ ++ RESERVE_BLOCKS: A running transcrash should indicate to the transaction manager how ++ many dirty blocks it expects. The reserve_blocks interface should be called at a point ++ where it is safe for the application to fail, because the system may not be able to ++ grant the allocation and the application must be able to back-out. For this reason, ++ the number of reserve-blocks can also be passed as an argument to BEGIN_TRANSCRASH, but ++ the application may also wish to extend the allocation after beginning its transcrash. ++ ++ CLOSE_TRANSCRASH: The application closes the transcrash when it is finished making ++ modifications that require transaction protection. When isolated transactions are ++ supported the CLOSE operation is replaced by either COMMIT or ABORT. For example, if a ++ RESERVE_BLOCKS call fails for the application, it should "abort" by calling ++ CLOSE_TRANSCRASH, even though it really commits any changes that were made (which is ++ why, for safety, the application should call RESERVE_BLOCKS before making any changes). ++ ++ For actually implementing these out-of-system-call-scopped transcrashes, the ++ reiser4_context has a "txn_handle *trans" pointer that may be set to an open ++ transcrash. Currently there are no dynamically-allocated transcrashes, but there is a ++ "struct kmem_cache *_txnh_slab" created for that purpose in this file. ++*/ ++ ++/* Extending the other system call interfaces for future transaction features: ++ ++ Specialized applications may benefit from passing flags to the ordinary system call ++ interface such as read(), write(), or stat(). For example, the application specifies ++ WRITE_FUSING by default but wishes to add that a certain read() command should be ++ treated as READ_FUSING. But which read? Is it the directory-entry read, the stat-data ++ read, or the file-data read? These issues are straight-forward, but there are a lot of ++ them and adding the necessary flags-passing code will be tedious. ++ ++ When supporting isolated transactions, there is a corresponding READ_MODIFY_WRITE (RMW) ++ flag, which specifies that although it is a read operation being requested, a ++ write-lock should be taken. The reason is that read-locks are shared while write-locks ++ are exclusive, so taking a read-lock when a later-write is known in advance will often ++ leads to deadlock. If a reader knows it will write later, it should issue read ++ requests with the RMW flag set. ++*/ ++ ++/* ++ The znode/atom deadlock avoidance. ++ ++ FIXME(Zam): writing of this comment is in progress. ++ ++ The atom's special stage ASTAGE_CAPTURE_WAIT introduces a kind of atom's ++ long-term locking, which makes reiser4 locking scheme more complex. It had ++ deadlocks until we implement deadlock avoidance algorithms. That deadlocks ++ looked as the following: one stopped thread waits for a long-term lock on ++ znode, the thread who owns that lock waits when fusion with another atom will ++ be allowed. ++ ++ The source of the deadlocks is an optimization of not capturing index nodes ++ for read. Let's prove it. Suppose we have dumb node capturing scheme which ++ unconditionally captures each block before locking it. ++ ++ That scheme has no deadlocks. Let's begin with the thread which stage is ++ ASTAGE_CAPTURE_WAIT and it waits for a znode lock. The thread can't wait for ++ a capture because it's stage allows fusion with any atom except which are ++ being committed currently. A process of atom commit can't deadlock because ++ atom commit procedure does not acquire locks and does not fuse with other ++ atoms. Reiser4 does capturing right before going to sleep inside the ++ longtertm_lock_znode() function, it means the znode which we want to lock is ++ already captured and its atom is in ASTAGE_CAPTURE_WAIT stage. If we ++ continue the analysis we understand that no one process in the sequence may ++ waits atom fusion. Thereby there are no deadlocks of described kind. ++ ++ The capturing optimization makes the deadlocks possible. A thread can wait a ++ lock which owner did not captured that node. The lock owner's current atom ++ is not fused with the first atom and it does not get a ASTAGE_CAPTURE_WAIT ++ state. A deadlock is possible when that atom meets another one which is in ++ ASTAGE_CAPTURE_WAIT already. ++ ++ The deadlock avoidance scheme includes two algorithms: ++ ++ First algorithm is used when a thread captures a node which is locked but not ++ captured by another thread. Those nodes are marked MISSED_IN_CAPTURE at the ++ moment we skip their capturing. If such a node (marked MISSED_IN_CAPTURE) is ++ being captured by a thread with current atom is in ASTAGE_CAPTURE_WAIT, the ++ routine which forces all lock owners to join with current atom is executed. ++ ++ Second algorithm does not allow to skip capturing of already captured nodes. ++ ++ Both algorithms together prevent waiting a longterm lock without atom fusion ++ with atoms of all lock owners, which is a key thing for getting atom/znode ++ locking deadlocks. ++*/ ++ ++/* ++ * Transactions and mmap(2). ++ * ++ * 1. Transactions are not supported for accesses through mmap(2), because ++ * this would effectively amount to user-level transactions whose duration ++ * is beyond control of the kernel. ++ * ++ * 2. That said, we still want to preserve some decency with regard to ++ * mmap(2). During normal write(2) call, following sequence of events ++ * happens: ++ * ++ * 1. page is created; ++ * ++ * 2. jnode is created, dirtied and captured into current atom. ++ * ++ * 3. extent is inserted and modified. ++ * ++ * Steps (2) and (3) take place under long term lock on the twig node. ++ * ++ * When file is accessed through mmap(2) page is always created during ++ * page fault. ++ * After this (in reiser4_readpage_dispatch()->reiser4_readpage_extent()): ++ * ++ * 1. if access is made to non-hole page new jnode is created, (if ++ * necessary) ++ * ++ * 2. if access is made to the hole page, jnode is not created (XXX ++ * not clear why). ++ * ++ * Also, even if page is created by write page fault it is not marked ++ * dirty immediately by handle_mm_fault(). Probably this is to avoid races ++ * with page write-out. ++ * ++ * Dirty bit installed by hardware is only transferred to the struct page ++ * later, when page is unmapped (in zap_pte_range(), or ++ * try_to_unmap_one()). ++ * ++ * So, with mmap(2) we have to handle following irksome situations: ++ * ++ * 1. there exists modified page (clean or dirty) without jnode ++ * ++ * 2. there exists modified page (clean or dirty) with clean jnode ++ * ++ * 3. clean page which is a part of atom can be transparently modified ++ * at any moment through mapping without becoming dirty. ++ * ++ * (1) and (2) can lead to the out-of-memory situation: ->writepage() ++ * doesn't know what to do with such pages and ->sync_sb()/->writepages() ++ * don't see them, because these methods operate on atoms. ++ * ++ * (3) can lead to the loss of data: suppose we have dirty page with dirty ++ * captured jnode captured by some atom. As part of early flush (for ++ * example) page was written out. Dirty bit was cleared on both page and ++ * jnode. After this page is modified through mapping, but kernel doesn't ++ * notice and just discards page and jnode as part of commit. (XXX ++ * actually it doesn't, because to reclaim page ->releasepage() has to be ++ * called and before this dirty bit will be transferred to the struct ++ * page). ++ * ++ */ ++ ++#include "debug.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "wander.h" ++#include "ktxnmgrd.h" ++#include "super.h" ++#include "page_cache.h" ++#include "reiser4.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "flush.h" ++#include "discard.h" ++#include "plugin/volume/volume.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include /* for totalram_pages */ ++ ++static void free_atom(txn_atom * atom); ++ ++static int commit_txnh(txn_handle * txnh); ++ ++static void wakeup_atom_waitfor_list(txn_atom * atom); ++static void wakeup_atom_waiting_list(txn_atom * atom); ++ ++static void capture_assign_txnh_nolock(txn_atom * atom, txn_handle * txnh); ++ ++static void capture_assign_block_nolock(txn_atom * atom, jnode * node); ++ ++static void fuse_not_fused_lock_owners(txn_handle * txnh, znode * node); ++ ++static int capture_init_fusion(jnode * node, txn_handle * txnh, ++ txn_capture mode); ++ ++static int capture_fuse_wait(txn_handle *, txn_atom *, txn_atom *, txn_capture); ++ ++static void capture_fuse_into(txn_atom * small, txn_atom * large); ++ ++void reiser4_invalidate_list(struct list_head *); ++ ++/* GENERIC STRUCTURES */ ++ ++typedef struct _txn_wait_links txn_wait_links; ++ ++struct _txn_wait_links { ++ lock_stack *_lock_stack; ++ struct list_head _fwaitfor_link; ++ struct list_head _fwaiting_link; ++ int (*waitfor_cb) (txn_atom * atom, struct _txn_wait_links * wlinks); ++ int (*waiting_cb) (txn_atom * atom, struct _txn_wait_links * wlinks); ++}; ++ ++/* FIXME: In theory, we should be using the slab cache init & destructor ++ methods instead of, e.g., jnode_init, etc. */ ++static struct kmem_cache *_atom_slab = NULL; ++/* this is for user-visible, cross system-call transactions. */ ++static struct kmem_cache *_txnh_slab = NULL; ++static struct kmem_cache *_abi_slab = NULL; ++ ++struct atom_brick_info *alloc_atom_brick_info(void) ++{ ++ return kmem_cache_alloc(_abi_slab, reiser4_ctx_gfp_mask_get()); ++} ++ ++void free_atom_brick_info(struct atom_brick_info *abi) ++{ ++ assert("edward-1979", abi != NULL); ++ ++ kmem_cache_free(_abi_slab, abi); ++} ++ ++struct atom_brick_info *find_atom_brick_info(const struct rb_root *root, ++ u32 brick_id) ++{ ++ struct rb_node *node = root->rb_node; ++ ++ while (node) { ++ struct atom_brick_info *abi = ++ rb_entry(node, struct atom_brick_info, node); ++ ++ if (abi->brick_id > brick_id) ++ node = node->rb_left; ++ else if (abi->brick_id < brick_id) ++ node = node->rb_right; ++ else ++ return abi; ++ } ++ return NULL; ++} ++ ++#if REISER4_DEBUG ++void __check_atom_brick_info(struct rb_root *root) ++{ ++ struct rb_node *node; ++ ++ for (node = rb_first(root); ++ node; ++ node = rb_next(node)) { ++ struct atom_brick_info *abi; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ assert("edward-2007", ++ abi == find_atom_brick_info(root, abi->brick_id)); ++ } ++} ++ ++void check_atom_brick_info(txn_atom *atom) ++{ ++ struct rb_root *root = &atom->bricks_info; ++ struct rb_node *node; ++ ++ for (node = rb_first(root); ++ node; ++ node = rb_next(node)) { ++ atom->abi = rb_entry(node, struct atom_brick_info, node); ++ atom->abi_found = ++ find_atom_brick_info(root, atom->abi->brick_id); ++ assert("edward-2008", atom->abi == atom->abi_found); ++ } ++} ++#endif /* REISER4_DEBUG */ ++ ++/** ++ * Try to insert item @this to rb-tree @root ++ * Return NULL on success. Otherwise, return node of existing item ++ */ ++struct atom_brick_info *insert_atom_brick_info(struct rb_root *root, ++ struct atom_brick_info *this) ++{ ++ struct rb_node *parent = NULL; ++ struct rb_node **pos = &(root->rb_node); ++ ++ while (*pos) { ++ struct atom_brick_info *abi; ++ ++ abi = rb_entry(*pos, struct atom_brick_info, node); ++ parent = *pos; ++ ++ if (this->brick_id < abi->brick_id) ++ pos = &((*pos)->rb_left); ++ else if (this->brick_id > abi->brick_id) ++ pos = &((*pos)->rb_right); ++ else ++ return abi; ++ } ++ rb_link_node(&this->node, parent, pos); ++ rb_insert_color(&this->node, root); ++ ++ __check_atom_brick_info(root); ++ ++ return NULL; ++} ++ ++/** ++ * On sucess: 0 is returned and @this points ++ * to existing or inserted atom brick info. ++ */ ++int __check_insert_atom_brick_info(txn_atom **atom, u32 brick_id, ++ struct atom_brick_info **this) ++{ ++ struct atom_brick_info *abi; ++ ++ assert("edward-2009", atom != NULL); ++ assert("edward-2010", *atom != NULL); ++ assert("edward-2011", this != NULL); ++ assert_spin_locked(&((*atom)->alock)); ++ ++ if (brick_id == METADATA_SUBVOL_ID) { ++ /* ++ * It is known to be preallocated ++ */ ++ *this = atom_meta_brick_info(*atom); ++ return 0; ++ } ++ abi = find_atom_brick_info(&((*atom)->bricks_info), brick_id); ++ if (abi == NULL) { ++ /* ++ * Insert a new item to the tree ++ */ ++ spin_unlock_atom(*atom); ++ abi = alloc_atom_brick_info(); ++ if (abi == NULL) ++ return -ENOMEM; ++ init_atom_brick_info(abi, brick_id); ++ *atom = get_current_atom_locked(); ++ *this = insert_atom_brick_info(&(*atom)->bricks_info, abi); ++ if (*this != NULL) { ++ /* ++ * someone has already inserted ++ * an item with such key after we ++ * unlocked the atom ++ */ ++ free_atom_brick_info(abi); ++ return 0; ++ } ++ } ++ *this = abi; ++ return 0; ++} ++ ++int check_insert_atom_brick_info(u32 brick_id, struct atom_brick_info **this) ++{ ++ int ret; ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked(); ++ ret = __check_insert_atom_brick_info(&atom, brick_id, this); ++ if (ret) ++ return ret; ++ spin_unlock_atom(atom); ++ return 0; ++} ++ ++static void done_atom_bricks_info(txn_atom *atom) ++{ ++ struct rb_root *root; ++ ++ root = &atom->bricks_info; ++ /* ++ * remove pre-allocated info ++ */ ++ rb_erase(&atom->mabi.node, root); ++ RB_CLEAR_NODE(&atom->mabi.node); ++ ++ while (!RB_EMPTY_ROOT(root)) { ++ struct rb_node *node; ++ struct atom_brick_info *abi; ++ ++ node = rb_first(root); ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ++ rb_erase(&abi->node, root); ++ RB_CLEAR_NODE(&abi->node); ++ free_atom_brick_info(abi); ++ } ++} ++ ++#if REISER4_DEBUG ++void check_atom_flush_reserved(txn_atom *atom) ++{ ++ struct rb_node *node; ++ ++ assert_spin_locked(&(atom->alock)); ++ ++ check_atom_brick_info(atom); ++ ++ spin_lock_reiser4_super(get_current_super_private()); ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ struct atom_brick_info *abi; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ assert("edward-2012", ++ abi->atom_flush_reserved <= ++ current_origin(abi->brick_id)->blocks_flush_reserved); ++ } ++ spin_unlock_reiser4_super(get_current_super_private()); ++} ++#endif ++ ++/** ++ * merge items representing per-brick atom's info ++ */ ++static void fuse_abi(txn_atom *from, txn_atom *to) ++{ ++ struct rb_node *node; ++ struct atom_brick_info *mabi_from, *mabi_to; ++ /* ++ * start from fusing data of pre-allocated items ++ */ ++ mabi_from = atom_meta_brick_info(from); ++ mabi_to = atom_meta_brick_info(to); ++ ++ mabi_to->atom_flush_reserved += mabi_from->atom_flush_reserved; ++ mabi_to->nr_blocks_allocated += mabi_from->nr_blocks_allocated; ++ ++ mabi_from->atom_flush_reserved = 0; ++ mabi_from->nr_blocks_allocated = 0; ++ ++ node = rb_next(&mabi_from->node); ++ while (node) { ++ struct rb_node *node_from; ++ struct atom_brick_info *abi_from; ++ struct atom_brick_info *abi_to; ++ ++ node_from = node; ++ node = rb_next(node); ++ ++ /* try to move the item to the @to's tree */ ++ ++ rb_erase(node_from, &from->bricks_info); ++ RB_CLEAR_NODE(node_from); ++ ++ abi_from = rb_entry(node_from, struct atom_brick_info, node); ++ abi_to = insert_atom_brick_info(&to->bricks_info, abi_from); ++ ++ if (abi_to != NULL) { ++ /* ++ * can't insert: an item with such brick_id ++ * already exists in the @to's rb-tree, so ++ * simply update the existing item, and ++ * release the item that we wanted to insert ++ */ ++ assert("edward-2013", abi_to->brick_id != 0); ++ assert("edward-2014", abi_from->brick_id == abi_to->brick_id); ++ ++ abi_to->atom_flush_reserved += abi_from->atom_flush_reserved; ++ abi_to->nr_blocks_allocated += abi_from->nr_blocks_allocated; ++ free_atom_brick_info(abi_from); ++ } ++ } ++ /* ++ * after fusion the @from's rb-tree contains only pre-allocated item ++ */ ++ assert("edward-2015", ++ from->bricks_info.rb_node != NULL && ++ from->bricks_info.rb_node->rb_left == NULL && ++ from->bricks_info.rb_node->rb_right == NULL); ++ ++ check_atom_brick_info(to); ++} ++ ++/** ++ * init_txnmgr_static - create transaction manager slab caches ++ * ++ * Initializes caches of txn-atoms and txn_handle. It is part of reiser4 module ++ * initialization. ++ */ ++int init_txnmgr_static(void) ++{ ++ assert("jmacd-600", _atom_slab == NULL); ++ assert("jmacd-601", _txnh_slab == NULL); ++ assert("edward-2016", _abi_slab == NULL); ++ ++ ON_DEBUG(atomic_set(&flush_cnt, 0)); ++ ++ _atom_slab = kmem_cache_create("txn_atom", sizeof(txn_atom), 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ if (_atom_slab == NULL) ++ return RETERR(-ENOMEM); ++ ++ _txnh_slab = kmem_cache_create("txn_handle", sizeof(txn_handle), 0, ++ SLAB_HWCACHE_ALIGN, NULL); ++ if (_txnh_slab == NULL) { ++ kmem_cache_destroy(_atom_slab); ++ _atom_slab = NULL; ++ return RETERR(-ENOMEM); ++ } ++ ++ _abi_slab = kmem_cache_create("atom_brick_info", ++ sizeof(struct atom_brick_info), 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ if (_abi_slab == NULL) { ++ kmem_cache_destroy(_atom_slab); ++ kmem_cache_destroy(_txnh_slab); ++ _atom_slab = NULL; ++ _txnh_slab = NULL; ++ return RETERR(-ENOMEM); ++ } ++ return 0; ++} ++ ++/** ++ * done_txnmgr_static - delete txn_atom and txn_handle caches ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void done_txnmgr_static(void) ++{ ++ destroy_reiser4_cache(&_atom_slab); ++ destroy_reiser4_cache(&_txnh_slab); ++ destroy_reiser4_cache(&_abi_slab); ++} ++ ++/** ++ * init_txnmgr - initialize a new transaction manager ++ * @mgr: pointer to transaction manager embedded in reiser4 super block ++ * ++ * This is called on mount. Makes necessary initializations. ++ */ ++void reiser4_init_txnmgr(txn_mgr *mgr) ++{ ++ assert("umka-169", mgr != NULL); ++ ++ mgr->atom_count = 0; ++ mgr->id_count = 1; ++ INIT_LIST_HEAD(&mgr->atoms_list); ++ spin_lock_init(&mgr->tmgr_lock); ++ mutex_init(&mgr->commit_mutex); ++} ++ ++/** ++ * reiser4_done_txnmgr - stop transaction manager ++ * @mgr: pointer to transaction manager embedded in reiser4 super block ++ * ++ * This is called on umount. Does sanity checks. ++ */ ++void reiser4_done_txnmgr(txn_mgr *mgr) ++{ ++ assert("umka-170", mgr != NULL); ++ assert("umka-1701", list_empty_careful(&mgr->atoms_list)); ++ assert("umka-1702", mgr->atom_count == 0); ++} ++ ++/* Initialize a transaction handle. */ ++/* Audited by: umka (2002.06.13) */ ++static void txnh_init(txn_handle * txnh, txn_mode mode) ++{ ++ assert("umka-171", txnh != NULL); ++ ++ txnh->mode = mode; ++ txnh->atom = NULL; ++ reiser4_ctx_gfp_mask_set(); ++ txnh->flags = 0; ++ spin_lock_init(&txnh->hlock); ++ INIT_LIST_HEAD(&txnh->txnh_link); ++} ++ ++#if REISER4_DEBUG ++/* Check if a transaction handle is clean. */ ++static int txnh_isclean(txn_handle * txnh) ++{ ++ assert("umka-172", txnh != NULL); ++ return txnh->atom == NULL && ++ LOCK_CNT_NIL(spin_locked_txnh); ++} ++#endif ++ ++/* Initialize an atom. */ ++static void init_atom(txn_atom * atom) ++{ ++ int level; ++ ++ assert("umka-173", atom != NULL); ++ ++ atom->stage = ASTAGE_FREE; ++ atom->start_time = jiffies; ++ /* ++ * init set of per-brick info and populate it ++ * with pree-allocated item for meta-data brick ++ */ ++ atom->bricks_info = RB_ROOT; ++ init_atom_brick_info(&atom->mabi, METADATA_SUBVOL_ID); ++ insert_atom_brick_info(&atom->bricks_info, &atom->mabi); ++ ++ for (level = 0; level < REAL_MAX_ZTREE_HEIGHT + 1; level += 1) ++ INIT_LIST_HEAD(ATOM_DIRTY_LIST(atom, level)); ++ ++ INIT_LIST_HEAD(ATOM_CLEAN_LIST(atom)); ++ INIT_LIST_HEAD(ATOM_OVRWR_LIST(atom)); ++ INIT_LIST_HEAD(ATOM_WB_LIST(atom)); ++ INIT_LIST_HEAD(&atom->inodes); ++ spin_lock_init(&(atom->alock)); ++ /* list of transaction handles */ ++ INIT_LIST_HEAD(&atom->txnh_list); ++ /* link to transaction manager's list of atoms */ ++ INIT_LIST_HEAD(&atom->atom_link); ++ INIT_LIST_HEAD(&atom->fwaitfor_list); ++ INIT_LIST_HEAD(&atom->fwaiting_list); ++ atom_dset_init(atom); ++ init_atom_fq_parts(atom); ++} ++ ++#if REISER4_DEBUG ++/* Check if an atom is clean. */ ++static int atom_isclean(txn_atom * atom) ++{ ++ int level; ++ ++ assert("umka-174", atom != NULL); ++ ++ for (level = 0; level < REAL_MAX_ZTREE_HEIGHT + 1; level += 1) { ++ if (!list_empty_careful(ATOM_DIRTY_LIST(atom, level))) { ++ return 0; ++ } ++ } ++ ++ return atom->stage == ASTAGE_FREE && ++ atom->txnh_count == 0 && ++ atom->capture_count == 0 && ++ atomic_read(&atom->refcount) == 0 && ++ (&atom->atom_link == atom->atom_link.next && ++ &atom->atom_link == atom->atom_link.prev) && ++ list_empty_careful(&atom->txnh_list) && ++ list_empty_careful(ATOM_CLEAN_LIST(atom)) && ++ list_empty_careful(ATOM_OVRWR_LIST(atom)) && ++ list_empty_careful(ATOM_WB_LIST(atom)) && ++ list_empty_careful(&atom->fwaitfor_list) && ++ list_empty_careful(&atom->fwaiting_list) && ++ atom_fq_parts_are_clean(atom); ++} ++#endif ++ ++/* Begin a transaction in this context. Currently this uses the reiser4_context's ++ trans_in_ctx, which means that transaction handles are stack-allocated. Eventually ++ this will be extended to allow transaction handles to span several contexts. */ ++/* Audited by: umka (2002.06.13) */ ++void reiser4_txn_begin(reiser4_context * context) ++{ ++ assert("jmacd-544", context->trans == NULL); ++ ++ context->trans = &context->trans_in_ctx; ++ ++ /* FIXME_LATER_JMACD Currently there's no way to begin a TXN_READ_FUSING ++ transcrash. Default should be TXN_WRITE_FUSING. Also, the _trans variable is ++ stack allocated right now, but we would like to allow for dynamically allocated ++ transcrashes that span multiple system calls. ++ */ ++ txnh_init(context->trans, TXN_WRITE_FUSING); ++} ++ ++/* Finish a transaction handle context. */ ++int reiser4_txn_end(reiser4_context * context) ++{ ++ long ret = 0; ++ txn_handle *txnh; ++ ++ assert("umka-283", context != NULL); ++ assert("nikita-3012", reiser4_schedulable()); ++ assert("vs-24", context == get_current_context()); ++ assert("nikita-2967", lock_stack_isclean(get_current_lock_stack())); ++ ++ txnh = context->trans; ++ if (txnh != NULL) { ++ if (txnh->atom != NULL) ++ ret = commit_txnh(txnh); ++ assert("jmacd-633", txnh_isclean(txnh)); ++ context->trans = NULL; ++ } ++ return ret; ++} ++ ++void reiser4_txn_restart(reiser4_context * context) ++{ ++ reiser4_txn_end(context); ++ reiser4_preempt_point(); ++ reiser4_txn_begin(context); ++} ++ ++void reiser4_txn_restart_current(void) ++{ ++ reiser4_txn_restart(get_current_context()); ++} ++ ++/* TXN_ATOM */ ++ ++/* Get the atom belonging to a txnh, which is not locked. Return txnh locked. Locks atom, if atom ++ is not NULL. This performs the necessary spin_trylock to break the lock-ordering cycle. May ++ return NULL. */ ++static txn_atom *txnh_get_atom(txn_handle * txnh) ++{ ++ txn_atom *atom; ++ ++ assert("umka-180", txnh != NULL); ++ assert_spin_not_locked(&(txnh->hlock)); ++ ++ while (1) { ++ spin_lock_txnh(txnh); ++ atom = txnh->atom; ++ ++ if (atom == NULL) ++ break; ++ ++ if (spin_trylock_atom(atom)) ++ break; ++ ++ atomic_inc(&atom->refcount); ++ ++ spin_unlock_txnh(txnh); ++ spin_lock_atom(atom); ++ spin_lock_txnh(txnh); ++ ++ if (txnh->atom == atom) { ++ atomic_dec(&atom->refcount); ++ break; ++ } ++ ++ spin_unlock_txnh(txnh); ++ atom_dec_and_unlock(atom); ++ } ++ ++ return atom; ++} ++ ++/* Get the current atom and spinlock it if current atom present. May return NULL */ ++txn_atom *get_current_atom_locked_nocheck(void) ++{ ++ reiser4_context *cx; ++ txn_atom *atom; ++ txn_handle *txnh; ++ ++ cx = get_current_context(); ++ assert("zam-437", cx != NULL); ++ ++ txnh = cx->trans; ++ assert("zam-435", txnh != NULL); ++ ++ atom = txnh_get_atom(txnh); ++ ++ spin_unlock_txnh(txnh); ++ return atom; ++} ++ ++/* Get the atom belonging to a jnode, which is initially locked. Return with ++ both jnode and atom locked. This performs the necessary spin_trylock to ++ break the lock-ordering cycle. Assumes the jnode is already locked, and ++ returns NULL if atom is not set. */ ++txn_atom *jnode_get_atom(jnode * node) ++{ ++ txn_atom *atom; ++ ++ assert("umka-181", node != NULL); ++ ++ while (1) { ++ assert_spin_locked(&(node->guard)); ++ ++ atom = node->atom; ++ /* node is not in any atom */ ++ if (atom == NULL) ++ break; ++ ++ /* If atom is not locked, grab the lock and return */ ++ if (spin_trylock_atom(atom)) ++ break; ++ ++ /* At least one jnode belongs to this atom it guarantees that ++ * atom->refcount > 0, we can safely increment refcount. */ ++ atomic_inc(&atom->refcount); ++ spin_unlock_jnode(node); ++ ++ /* re-acquire spin locks in the right order */ ++ spin_lock_atom(atom); ++ spin_lock_jnode(node); ++ ++ /* check if node still points to the same atom. */ ++ if (node->atom == atom) { ++ atomic_dec(&atom->refcount); ++ break; ++ } ++ ++ /* releasing of atom lock and reference requires not holding ++ * locks on jnodes. */ ++ spin_unlock_jnode(node); ++ ++ /* We do not sure that this atom has extra references except our ++ * one, so we should call proper function which may free atom if ++ * last reference is released. */ ++ atom_dec_and_unlock(atom); ++ ++ /* lock jnode again for getting valid node->atom pointer ++ * value. */ ++ spin_lock_jnode(node); ++ } ++ ++ return atom; ++} ++ ++/** ++ * Returns true if @node is dirty and part of the same atom as ++ * one of its neighbors. Used by flush code to indicate whether ++ * the next node (in some direction) is suitable for flushing ++ */ ++int same_slum_check(jnode *node, jnode *check, int alloc_check, int alloc_value) ++{ ++ int compat; ++ txn_atom *atom; ++ ++ assert("umka-182", node != NULL); ++ assert("umka-183", check != NULL); ++ /* ++ * Not sure what this function is supposed to do if supplied ++ * with @check that is neither formatted nor unformatted (bitmap ++ * or so) ++ */ ++ assert("nikita-2373", jnode_is_znode(check) || ++ jnode_is_unformatted(check)); ++ /* ++ * Need a lock on CHECK to get its atom and to check various state bits. ++ * Don't need a lock on NODE once we get the atom lock. ++ * ++ * It is not enough to lock two nodes and check (node->atom == ++ * check->atom) because atom could be locked and being fused at that ++ * moment, jnodes of the atom of that state (being fused) can point to ++ * different objects, but the atom is the same. ++ */ ++ spin_lock_jnode(check); ++ atom = jnode_get_atom(check); ++ ++ if (atom == NULL) ++ compat = 0; ++ else { ++ compat = (node->atom == atom && JF_ISSET(check, JNODE_DIRTY)); ++ if (compat && jnode_is_znode(check)) ++ compat &= znode_is_connected(JZNODE(check)); ++ if (compat && alloc_check) ++ compat &= (alloc_value == jnode_is_flushprepped(check)); ++ spin_unlock_atom(atom); ++ } ++ spin_unlock_jnode(check); ++ return compat; ++} ++ ++/** ++ * Decrement the atom's reference count and if it falls to zero, free it ++ */ ++void atom_dec_and_unlock(txn_atom * atom) ++{ ++ txn_mgr *mgr = &get_super_private(reiser4_get_current_sb())->tmgr; ++ ++ assert("umka-186", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ assert("zam-1039", atomic_read(&atom->refcount) > 0); ++ ++ if (atomic_dec_and_test(&atom->refcount)) { ++ /* ++ * take txnmgr lock and atom lock in proper order ++ */ ++ if (!spin_trylock_txnmgr(mgr)) { ++ /* ++ * This atom should exist after we re-acquire its ++ * spinlock, so we increment its reference counter ++ */ ++ atomic_inc(&atom->refcount); ++ spin_unlock_atom(atom); ++ spin_lock_txnmgr(mgr); ++ spin_lock_atom(atom); ++ ++ if (!atomic_dec_and_test(&atom->refcount)) { ++ spin_unlock_atom(atom); ++ spin_unlock_txnmgr(mgr); ++ return; ++ } ++ } ++ assert_spin_locked(&(mgr->tmgr_lock)); ++ free_atom(atom); ++ spin_unlock_txnmgr(mgr); ++ } else ++ spin_unlock_atom(atom); ++} ++ ++static txn_atom *__alloc_atom(void) ++{ ++ txn_atom *atom; ++ ++ atom = kmem_cache_alloc(_atom_slab, reiser4_ctx_gfp_mask_get()); ++ if (atom == NULL) ++ return NULL; ++ memset(atom, 0, sizeof(txn_atom)); ++ return atom; ++} ++ ++static void __free_atom(txn_atom *atom) ++{ ++ kmem_cache_free(_atom_slab, atom); ++} ++ ++ ++/* Create new atom and connect it to given transaction handle. This adds the ++ atom to the transaction manager's list and sets its reference count to 1, an ++ artificial reference which is kept until it commits. We play strange games ++ to avoid allocation under jnode & txnh spinlocks.*/ ++ ++static int atom_begin_and_assign_to_txnh(txn_atom ** atom_alloc, txn_handle * txnh) ++{ ++ txn_atom *atom; ++ txn_mgr *mgr; ++ ++ if (REISER4_DEBUG && sb_rdonly(reiser4_get_current_sb())) { ++ warning("nikita-3366", "Creating atom on read-only fs"); ++ dump_stack(); ++ } ++ if (*atom_alloc == NULL) { ++ *atom_alloc = __alloc_atom(); ++ ++ if (*atom_alloc == NULL) ++ return RETERR(-ENOMEM); ++ } ++ /* ++ * and, also, txnmgr spin lock should be taken ++ * before jnode and txnh locks ++ */ ++ mgr = &get_super_private(reiser4_get_current_sb())->tmgr; ++ spin_lock_txnmgr(mgr); ++ spin_lock_txnh(txnh); ++ ++ /* Check whether new atom still needed */ ++ if (txnh->atom != NULL) { ++ /* NOTE-NIKITA probably it is rather better to free ++ * atom_alloc here than thread it up to reiser4_try_capture() */ ++ ++ spin_unlock_txnh(txnh); ++ spin_unlock_txnmgr(mgr); ++ ++ return -E_REPEAT; ++ } ++ ++ atom = *atom_alloc; ++ *atom_alloc = NULL; ++ ++ init_atom(atom); ++ assert("jmacd-17", atom_isclean(atom)); ++ /* ++ * lock ordering is broken here. It is ok, as long as @atom is new ++ * and inaccessible for others. We can't use spin_lock_atom or ++ * spin_lock(&atom->alock) because they care about locking ++ * dependencies. spin_trylock_lock doesn't. ++ */ ++ check_me("", spin_trylock_atom(atom)); ++ ++ /* add atom to the end of transaction manager's list of atoms */ ++ list_add_tail(&atom->atom_link, &mgr->atoms_list); ++ atom->atom_id = mgr->id_count++; ++ mgr->atom_count += 1; ++ ++ /* Release txnmgr lock */ ++ spin_unlock_txnmgr(mgr); ++ ++ /* One reference until it commits. */ ++ atomic_inc(&atom->refcount); ++ atom->stage = ASTAGE_CAPTURE_FUSE; ++ atom->super = reiser4_get_current_sb(); ++ capture_assign_txnh_nolock(atom, txnh); ++ ++ spin_unlock_atom(atom); ++ spin_unlock_txnh(txnh); ++ ++ return -E_REPEAT; ++} ++ ++/** ++ * In some rare cases we need atom to exist before capturing ++ * any nodes ++ */ ++int reiser4_create_atom(void) ++{ ++ txn_atom *atom_alloc = NULL; ++ txn_handle *txnh = get_current_context()->trans; ++ int ret; ++ ++ do { ++ spin_lock_txnh(txnh); ++ if (txnh->atom == NULL) { ++ spin_unlock_txnh(txnh); ++ /* ++ * assign empty atom to the txnh and repeat ++ */ ++ ret = atom_begin_and_assign_to_txnh(&atom_alloc, txnh); ++ } else { ++ spin_unlock_txnh(txnh); ++ ret = 0; ++ } ++ } while (ret == -E_REPEAT); ++ return ret; ++} ++ ++/* Return true if an atom is currently "open". */ ++static int atom_isopen(const txn_atom * atom) ++{ ++ assert("umka-185", atom != NULL); ++ ++ return atom->stage > 0 && atom->stage < ASTAGE_PRE_COMMIT; ++} ++ ++/** ++ * Return the number of pointers to this atom that must be ++ * updated during fusion. This approximates the amount of work to be done. ++ * Fusion chooses the atom with fewer pointers to fuse into the atom with ++ * more pointers ++ */ ++static int atom_pointer_count(const txn_atom * atom) ++{ ++ assert("umka-187", atom != NULL); ++ /* ++ * This is a measure of the amount of work needed ++ * to fuse this atom into another one ++ */ ++ return atom->txnh_count + atom->capture_count; ++} ++ ++/** ++ * Called holding the atom lock, this removes the atom ++ * from the transaction manager list and frees it ++ */ ++static void free_atom(txn_atom * atom) ++{ ++ txn_mgr *mgr = &get_super_private(reiser4_get_current_sb())->tmgr; ++ ++ assert("umka-188", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ /* Remove from the txn_mgr's atom list */ ++ assert_spin_locked(&(mgr->tmgr_lock)); ++ mgr->atom_count -= 1; ++ list_del_init(&atom->atom_link); ++ ++ /* Clean the atom */ ++ assert("jmacd-16", ++ (atom->stage == ASTAGE_INVALID || atom->stage == ASTAGE_DONE)); ++ atom->stage = ASTAGE_FREE; ++ ++ atom_dset_destroy(atom); ++ ++ assert("jmacd-16", atom_isclean(atom)); ++ ++ done_atom_bricks_info(atom); ++ ++ spin_unlock_atom(atom); ++ ++ __free_atom(atom); ++} ++ ++static int atom_is_dotard(const txn_atom * atom) ++{ ++ return time_after(jiffies, atom->start_time + ++ get_current_super_private()->tmgr.atom_max_age); ++} ++ ++static int atom_can_be_committed(txn_atom * atom) ++{ ++ assert_spin_locked(&(atom->alock)); ++ assert("zam-885", atom->txnh_count > atom->nr_waiters); ++ return atom->txnh_count == atom->nr_waiters + 1; ++} ++ ++/* Return true if an atom should commit now. This is determined by aging, atom ++ size or atom flags. */ ++static int atom_should_commit(const txn_atom * atom) ++{ ++ assert("umka-189", atom != NULL); ++ return ++ (atom->flags & ATOM_FORCE_COMMIT) || ++ ((unsigned)atom_pointer_count(atom) > ++ get_current_super_private()->tmgr.atom_max_size) ++ || atom_is_dotard(atom); ++} ++ ++/* return 1 if current atom exists and requires commit. */ ++int current_atom_should_commit(void) ++{ ++ txn_atom *atom; ++ int result = 0; ++ ++ atom = get_current_atom_locked_nocheck(); ++ if (atom) { ++ result = atom_should_commit(atom); ++ spin_unlock_atom(atom); ++ } ++ return result; ++} ++ ++static int atom_should_commit_asap(const txn_atom * atom) ++{ ++ unsigned int captured; ++ unsigned int pinnedpages; ++ ++ assert("nikita-3309", atom != NULL); ++ ++ captured = (unsigned)atom->capture_count; ++ pinnedpages = (captured >> PAGE_SHIFT) * sizeof(znode); ++ ++ return (pinnedpages > (totalram_pages() >> 3)) || (atom->flushed > 100); ++} ++ ++static jnode *find_first_dirty_in_list(struct list_head *head, int flags) ++{ ++ jnode *first_dirty; ++ ++ list_for_each_entry(first_dirty, head, capture_link) { ++ if (!(flags & JNODE_FLUSH_COMMIT)) { ++ /* ++ * skip jnodes which "heard banshee" or having active ++ * I/O ++ */ ++ if (JF_ISSET(first_dirty, JNODE_HEARD_BANSHEE) || ++ JF_ISSET(first_dirty, JNODE_WRITEBACK)) ++ continue; ++ } ++ return first_dirty; ++ } ++ return NULL; ++} ++ ++/** ++ * Get first dirty node from the atom's dirty_nodes[n] lists; ++ * return NULL if atom has no dirty nodes on atom's lists ++ */ ++jnode *find_first_dirty_jnode(txn_atom *atom, int flags) ++{ ++ jnode *first_dirty; ++ tree_level level; ++ ++ assert_spin_locked(&(atom->alock)); ++ /* ++ * The flush starts from LEAF_LEVEL (=1) ++ */ ++ for (level = 1; level < REAL_MAX_ZTREE_HEIGHT + 1; level += 1) { ++ if (list_empty_careful(ATOM_DIRTY_LIST(atom, level))) ++ continue; ++ ++ first_dirty = ++ find_first_dirty_in_list(ATOM_DIRTY_LIST(atom, level), ++ flags); ++ if (first_dirty) ++ return first_dirty; ++ } ++ /* ++ * znode-above-root is on the list #0 ++ */ ++ return find_first_dirty_in_list(ATOM_DIRTY_LIST(atom, 0), flags); ++} ++ ++static void dispatch_wb_list(txn_atom *atom, flush_queue_t *fq) ++{ ++ jnode *cur; ++ ++ assert("zam-905", atom_is_protected(atom)); ++ ++ cur = list_entry(ATOM_WB_LIST(atom)->next, jnode, capture_link); ++ ++ while (ATOM_WB_LIST(atom) != &cur->capture_link) { ++ ++ jnode *next = list_entry(cur->capture_link.next, ++ jnode, capture_link); ++ spin_lock_jnode(cur); ++ if (!JF_ISSET(cur, JNODE_WRITEBACK)) { ++ if (JF_ISSET(cur, JNODE_DIRTY)) { ++ queue_jnode(fq, cur); ++ } else { ++ /* ++ * move jnode to atom's clean list ++ */ ++ list_move_tail(&cur->capture_link, ++ ATOM_CLEAN_LIST(atom)); ++ } ++ } ++ spin_unlock_jnode(cur); ++ cur = next; ++ } ++} ++ ++/** ++ * Scan current atom->writeback_nodes list, ++ * re-submit dirty and !writeback jnodes to disk ++ */ ++static int submit_wb_list(void) ++{ ++ int ret; ++ flush_queue_t *fq; ++ ++ fq = get_fq_for_current_atom(); ++ if (IS_ERR(fq)) ++ return PTR_ERR(fq); ++ ++ dispatch_wb_list(fq->atom, fq); ++ spin_unlock_atom(fq->atom); ++ ++ ret = reiser4_write_fq(fq, NULL, 1); ++ reiser4_fq_put(fq); ++ ++ return ret; ++} ++ ++/** ++ * Wait completion of all writes, ++ * re-submit atom writeback list if needed ++ */ ++static int current_atom_complete_writes(void) ++{ ++ int ret; ++ /* ++ * Each jnode from that list was modified and dirtied when it had i/o ++ * request running already. After i/o completion we have to resubmit ++ * them to disk again ++ */ ++ ret = submit_wb_list(); ++ if (ret < 0) ++ return ret; ++ /* ++ * Wait all i/o completion ++ */ ++ ret = current_atom_finish_all_fq(); ++ if (ret) ++ return ret; ++ /* ++ * Scan wb list again; all i/o should be completed, we re-submit dirty ++ * nodes to disk ++ */ ++ ret = submit_wb_list(); ++ if (ret < 0) ++ return ret; ++ /* ++ * Wait all nodes we just submitted ++ */ ++ return current_atom_finish_all_fq(); ++} ++ ++#if REISER4_DEBUG ++ ++static void reiser4_info_atom(const char *prefix, const txn_atom * atom) ++{ ++ if (atom == NULL) { ++ printk("%s: no atom\n", prefix); ++ return; ++ } ++ ++ printk("%s: refcount: %i id: %i flags: %x txnh_count: %i" ++ " capture_count: %i stage: %x start: %lu, flushed: %i\n", prefix, ++ atomic_read(&atom->refcount), atom->atom_id, atom->flags, ++ atom->txnh_count, atom->capture_count, atom->stage, ++ atom->start_time, atom->flushed); ++} ++#else /* REISER4_DEBUG */ ++static inline void reiser4_info_atom(const char *prefix, ++ const txn_atom *atom) {} ++#endif /* REISER4_DEBUG */ ++ ++#define TOOMANYFLUSHES (1 << 13) ++ ++/* Called with the atom locked and no open "active" transaction handlers except ++ ours, this function calls flush_current_atom() until all dirty nodes are ++ processed. Then it initiates commit processing. ++ ++ Called by the single remaining open "active" txnh, which is closing. Other ++ open txnhs belong to processes which wait atom commit in commit_txnh() ++ routine. They are counted as "waiters" in atom->nr_waiters. Therefore as ++ long as we hold the atom lock none of the jnodes can be captured and/or ++ locked. ++ ++ Return value is an error code if commit fails. ++*/ ++static int commit_current_atom(long *nr_submitted, txn_atom ** atom) ++{ ++ long ret = 0; ++ reiser4_super_info_data *sbinfo = get_current_super_private(); ++ int flushiters; /* how many times jnode_flush() was called as a part ++ of attempt to commit this atom. */ ++ ++ assert("zam-888", atom != NULL && *atom != NULL); ++ assert_spin_locked(&((*atom)->alock)); ++ assert("zam-887", get_current_context()->trans->atom == *atom); ++ assert("jmacd-151", atom_isopen(*atom)); ++ ++ assert("nikita-3184", ++ get_current_super_private()->delete_mutex_owner != current); ++ ++ for (flushiters = 0;; ++flushiters) { ++ ret = ++ flush_current_atom(JNODE_FLUSH_WRITE_BLOCKS | ++ JNODE_FLUSH_COMMIT, ++ LONG_MAX /* nr_to_write */ , ++ nr_submitted, atom, NULL); ++ if (ret != -E_REPEAT) ++ break; ++ /* ++ * if atom's dirty list contains one znode which is ++ * HEARD_BANSHEE and is locked we have to allow lock ++ * owner to continue and uncapture that znode ++ */ ++ reiser4_preempt_point(); ++ ++ *atom = get_current_atom_locked(); ++ ++ if (flushiters > TOOMANYFLUSHES && IS_POW(flushiters)) { ++ warning("nikita-3176", ++ "Flushing like mad: %i", flushiters); ++ reiser4_info_atom("atom", *atom); ++ DEBUGON(flushiters > (1 << 20)); ++ } ++ } ++ if (ret) ++ return ret; ++ assert_spin_locked(&((*atom)->alock)); ++ ++ if (!atom_can_be_committed(*atom)) { ++ spin_unlock_atom(*atom); ++ return RETERR(-E_REPEAT); ++ } ++ if ((*atom)->capture_count == 0) ++ goto done; ++ /* ++ * Up to this point we have been flushing and after flush is called we ++ * return -E_REPEAT. Now we can commit. We cannot return -E_REPEAT ++ * at this point, commit should be successful ++ */ ++ reiser4_atom_set_stage(*atom, ASTAGE_PRE_COMMIT); ++ ON_DEBUG(((*atom)->committer = current)); ++ spin_unlock_atom(*atom); ++ ++ ret = current_atom_complete_writes(); ++ if (ret) ++ return ret; ++ ++ assert("zam-906", list_empty(ATOM_WB_LIST(*atom))); ++ /* ++ * isolate critical code path which should be executed by only one ++ * thread using tmgr mutex ++ */ ++ mutex_lock(&sbinfo->tmgr.commit_mutex); ++ ++ ret = reiser4_write_logs(nr_submitted); ++ if (ret < 0) ++ reiser4_panic("zam-597", "write log failed (%ld)\n", ret); ++ /* ++ * The atom->ovrwr_nodes list is processed under commit mutex held ++ * because of bitmap nodes which are captured by special way in ++ * reiser4_pre_commit_hook_bitmap(), that way does not include ++ * capture_fuse_wait() as a capturing of other nodes does -- the commit ++ * mutex is used for transaction isolation instead ++ */ ++ assert("edward-1774", list_empty(ATOM_OVRWR_LIST(*atom))); ++ ++ mutex_unlock(&sbinfo->tmgr.commit_mutex); ++ ++ reiser4_invalidate_list(ATOM_CLEAN_LIST(*atom)); ++ reiser4_invalidate_list(ATOM_WB_LIST(*atom)); ++ assert("zam-927", list_empty(&(*atom)->inodes)); ++ ++ spin_lock_atom(*atom); ++ done: ++ reiser4_atom_set_stage(*atom, ASTAGE_DONE); ++ ON_DEBUG((*atom)->committer = NULL); ++ ++ /* Atom's state changes, so wake up everybody waiting for this ++ event. */ ++ wakeup_atom_waiting_list(*atom); ++ /* ++ * Decrement the "until commit" reference, at least one txnh ++ * (the caller) is still open ++ */ ++ atomic_dec(&(*atom)->refcount); ++ ++ assert("jmacd-1070", atomic_read(&(*atom)->refcount) > 0); ++ assert("jmacd-1062", (*atom)->capture_count == 0); ++ BUG_ON((*atom)->capture_count != 0); ++ assert_spin_locked(&((*atom)->alock)); ++ ++ return ret; ++} ++ ++/* TXN_TXNH */ ++ ++/** ++ * force_commit_atom - commit current atom and wait commit completion ++ * @txnh: ++ * ++ * Commits current atom and wait commit completion; current atom and @txnh have ++ * to be spinlocked before call, this function unlocks them on exit. ++ */ ++int force_commit_atom(txn_handle *txnh) ++{ ++ txn_atom *atom; ++ ++ assert("zam-837", txnh != NULL); ++ assert_spin_locked(&(txnh->hlock)); ++ assert("nikita-2966", lock_stack_isclean(get_current_lock_stack())); ++ ++ atom = txnh->atom; ++ ++ assert("zam-834", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ /* ++ * Set flags for atom and txnh: forcing atom commit and waiting for ++ * commit completion ++ */ ++ txnh->flags |= TXNH_WAIT_COMMIT; ++ atom->flags |= ATOM_FORCE_COMMIT; ++ ++ spin_unlock_txnh(txnh); ++ spin_unlock_atom(atom); ++ ++ /* commit is here */ ++ reiser4_txn_restart_current(); ++ return 0; ++} ++ ++int force_commit_current_atom(void) ++{ ++ txn_atom *atom; ++ txn_handle *th; ++ ++ th = get_current_context()->trans; ++ atom = get_current_atom_locked(); ++ assert("vpf-1906", atom != NULL); ++ spin_lock_txnh(th); ++ return force_commit_atom(th); ++} ++ ++/* Called to force commit of any outstanding atoms. @commit_all_atoms controls ++ * should we commit all atoms including new ones which are created after this ++ * functions is called. */ ++int txnmgr_force_commit_all(struct super_block *super, int commit_all_atoms) ++{ ++ int ret; ++ txn_atom *atom; ++ txn_mgr *mgr; ++ txn_handle *txnh; ++ unsigned long start_time = jiffies; ++ reiser4_context *ctx = get_current_context(); ++ ++ assert("nikita-2965", lock_stack_isclean(get_current_lock_stack())); ++ assert("nikita-3058", reiser4_commit_check_locks()); ++ ++ reiser4_txn_restart_current(); ++ ++ mgr = &get_super_private(super)->tmgr; ++ ++ txnh = ctx->trans; ++ ++ again: ++ ++ spin_lock_txnmgr(mgr); ++ ++ list_for_each_entry(atom, &mgr->atoms_list, atom_link) { ++ spin_lock_atom(atom); ++ ++ /* Commit any atom which can be committed. If @commit_new_atoms ++ * is not set we commit only atoms which were created before ++ * this call is started. */ ++ if (commit_all_atoms ++ || time_before_eq(atom->start_time, start_time)) { ++ if (atom->stage <= ASTAGE_POST_COMMIT) { ++ spin_unlock_txnmgr(mgr); ++ ++ if (atom->stage < ASTAGE_PRE_COMMIT) { ++ spin_lock_txnh(txnh); ++ /* Add force-context txnh */ ++ capture_assign_txnh_nolock(atom, txnh); ++ ret = force_commit_atom(txnh); ++ if (ret) ++ return ret; ++ } else ++ /* wait atom commit */ ++ reiser4_atom_wait_event(atom); ++ ++ goto again; ++ } ++ } ++ ++ spin_unlock_atom(atom); ++ } ++ assert("edward-2273", ++ ergo(commit_all_atoms, ++ reiser4_volume_fake_allocated(super) == 0)); ++ ++ spin_unlock_txnmgr(mgr); ++ return 0; ++} ++ ++/* check whether commit_some_atoms() can commit @atom. Locking is up to the ++ * caller */ ++static int atom_is_committable(txn_atom * atom) ++{ ++ return ++ atom->stage < ASTAGE_PRE_COMMIT && ++ atom->txnh_count == atom->nr_waiters && atom_should_commit(atom); ++} ++ ++/* called periodically from ktxnmgrd to commit old atoms. Releases ktxnmgrd spin ++ * lock at exit */ ++int commit_some_atoms(txn_mgr * mgr) ++{ ++ int ret = 0; ++ txn_atom *atom; ++ txn_handle *txnh; ++ reiser4_context *ctx; ++ struct list_head *pos, *tmp; ++ ++ ctx = get_current_context(); ++ assert("nikita-2444", ctx != NULL); ++ ++ txnh = ctx->trans; ++ spin_lock_txnmgr(mgr); ++ ++ /* ++ * this is to avoid gcc complain that atom might be used ++ * uninitialized ++ */ ++ atom = NULL; ++ ++ /* look for atom to commit */ ++ list_for_each_safe(pos, tmp, &mgr->atoms_list) { ++ atom = list_entry(pos, txn_atom, atom_link); ++ /* ++ * first test without taking atom spin lock, whether it is ++ * eligible for committing at all ++ */ ++ if (atom_is_committable(atom)) { ++ /* now, take spin lock and re-check */ ++ spin_lock_atom(atom); ++ if (atom_is_committable(atom)) ++ break; ++ spin_unlock_atom(atom); ++ } ++ } ++ ++ ret = (&mgr->atoms_list == pos); ++ spin_unlock_txnmgr(mgr); ++ ++ if (ret) { ++ /* nothing found */ ++ spin_unlock(&mgr->daemon->guard); ++ return 0; ++ } ++ ++ spin_lock_txnh(txnh); ++ ++ BUG_ON(atom == NULL); ++ /* Set the atom to force committing */ ++ atom->flags |= ATOM_FORCE_COMMIT; ++ ++ /* Add force-context txnh */ ++ capture_assign_txnh_nolock(atom, txnh); ++ ++ spin_unlock_txnh(txnh); ++ spin_unlock_atom(atom); ++ ++ /* we are about to release daemon spin lock, notify daemon it ++ has to rescan atoms */ ++ mgr->daemon->rescan = 1; ++ spin_unlock(&mgr->daemon->guard); ++ reiser4_txn_restart_current(); ++ return 0; ++} ++ ++static int txn_try_to_fuse_small_atom(txn_mgr * tmgr, txn_atom * atom) ++{ ++ int atom_stage; ++ txn_atom *atom_2; ++ int repeat; ++ ++ assert("zam-1051", atom->stage < ASTAGE_PRE_COMMIT); ++ ++ atom_stage = atom->stage; ++ repeat = 0; ++ ++ if (!spin_trylock_txnmgr(tmgr)) { ++ atomic_inc(&atom->refcount); ++ spin_unlock_atom(atom); ++ spin_lock_txnmgr(tmgr); ++ spin_lock_atom(atom); ++ repeat = 1; ++ if (atom->stage != atom_stage) { ++ spin_unlock_txnmgr(tmgr); ++ atom_dec_and_unlock(atom); ++ return -E_REPEAT; ++ } ++ atomic_dec(&atom->refcount); ++ } ++ ++ list_for_each_entry(atom_2, &tmgr->atoms_list, atom_link) { ++ if (atom == atom_2) ++ continue; ++ /* ++ * if trylock does not succeed we just do not fuse with that ++ * atom. ++ */ ++ if (spin_trylock_atom(atom_2)) { ++ if (atom_2->stage < ASTAGE_PRE_COMMIT) { ++ spin_unlock_txnmgr(tmgr); ++ capture_fuse_into(atom_2, atom); ++ /* all locks are lost we can only repeat here */ ++ return -E_REPEAT; ++ } ++ spin_unlock_atom(atom_2); ++ } ++ } ++ atom->flags |= ATOM_CANCEL_FUSION; ++ spin_unlock_txnmgr(tmgr); ++ if (repeat) { ++ spin_unlock_atom(atom); ++ return -E_REPEAT; ++ } ++ return 0; ++} ++ ++/* Calls jnode_flush for current atom if it exists; if not, just take another ++ atom and call jnode_flush() for him. If current transaction handle has ++ already assigned atom (current atom) we have to close current transaction ++ prior to switch to another atom or do something with current atom. This ++ code tries to flush current atom. ++ ++ flush_some_atom() is called as part of memory clearing process. It is ++ invoked from balance_dirty_pages(), pdflushd, and entd. ++ ++ If we can flush no nodes, atom is committed, because this frees memory. ++ ++ If atom is too large or too old it is committed also. ++*/ ++int ++flush_some_atom(jnode * start, long *nr_submitted, const struct writeback_control *wbc, ++ int flags) ++{ ++ reiser4_context *ctx = get_current_context(); ++ txn_mgr *tmgr = &get_super_private(ctx->super)->tmgr; ++ txn_handle *txnh = ctx->trans; ++ txn_atom *atom; ++ int ret; ++ ++ BUG_ON(wbc->nr_to_write == 0); ++ BUG_ON(*nr_submitted != 0); ++ assert("zam-1042", txnh != NULL); ++repeat: ++ if (txnh->atom == NULL) { ++ /* current atom is not available, take first from txnmgr */ ++ spin_lock_txnmgr(tmgr); ++ ++ /* traverse the list of all atoms */ ++ list_for_each_entry(atom, &tmgr->atoms_list, atom_link) { ++ /* lock atom before checking its state */ ++ spin_lock_atom(atom); ++ /* ++ * we need an atom which is not being committed and ++ * which has no flushers (jnode_flush() add one flusher ++ * at the beginning and subtract one at the end). ++ */ ++ if (atom->stage < ASTAGE_PRE_COMMIT && ++ atom->nr_flushers == 0) { ++ spin_lock_txnh(txnh); ++ capture_assign_txnh_nolock(atom, txnh); ++ spin_unlock_txnh(txnh); ++ ++ goto found; ++ } ++ ++ spin_unlock_atom(atom); ++ } ++ ++ /* ++ * Write throttling is case of no one atom can be ++ * flushed/committed. */ ++ if (!ctx->flush_bd_task) { ++ list_for_each_entry(atom, &tmgr->atoms_list, atom_link) { ++ spin_lock_atom(atom); ++ /* Repeat the check from the above. */ ++ if (atom->stage < ASTAGE_PRE_COMMIT ++ && atom->nr_flushers == 0) { ++ spin_lock_txnh(txnh); ++ capture_assign_txnh_nolock(atom, txnh); ++ spin_unlock_txnh(txnh); ++ ++ goto found; ++ } ++ if (atom->stage <= ASTAGE_POST_COMMIT) { ++ spin_unlock_txnmgr(tmgr); ++ /* ++ * we just wait until atom's flusher ++ * makes a progress in flushing or ++ * committing the atom ++ */ ++ reiser4_atom_wait_event(atom); ++ goto repeat; ++ } ++ spin_unlock_atom(atom); ++ } ++ } ++ spin_unlock_txnmgr(tmgr); ++ return 0; ++ found: ++ spin_unlock_txnmgr(tmgr); ++ } else ++ atom = get_current_atom_locked(); ++ ++ BUG_ON(atom->super != ctx->super); ++ assert("vs-35", atom->super == ctx->super); ++ if (start) { ++ spin_lock_jnode(start); ++ ret = (atom == start->atom) ? 1 : 0; ++ spin_unlock_jnode(start); ++ if (ret == 0) ++ start = NULL; ++ } ++ ret = flush_current_atom(flags, wbc->nr_to_write, nr_submitted, &atom, start); ++ if (ret == 0) { ++ /* flush_current_atom returns 0 only if it submitted for write ++ nothing */ ++ BUG_ON(*nr_submitted != 0); ++ if (*nr_submitted == 0 || atom_should_commit_asap(atom)) { ++ if (atom->capture_count < tmgr->atom_min_size && ++ !(atom->flags & ATOM_CANCEL_FUSION)) { ++ ret = txn_try_to_fuse_small_atom(tmgr, atom); ++ if (ret == -E_REPEAT) { ++ reiser4_preempt_point(); ++ goto repeat; ++ } ++ } ++ /* if early flushing could not make more nodes clean, ++ * or atom is too old/large, ++ * we force current atom to commit */ ++ /* wait for commit completion but only if this ++ * wouldn't stall pdflushd and ent thread. */ ++ if (!ctx->entd) ++ txnh->flags |= TXNH_WAIT_COMMIT; ++ atom->flags |= ATOM_FORCE_COMMIT; ++ } ++ spin_unlock_atom(atom); ++ } else if (ret == -E_REPEAT) { ++ if (*nr_submitted == 0) { ++ /* let others who hampers flushing (hold longterm locks, ++ for instance) to free the way for flush */ ++ reiser4_preempt_point(); ++ goto repeat; ++ } ++ ret = 0; ++ } ++/* ++ if (*nr_submitted > wbc->nr_to_write) ++ warning("", "asked for %ld, written %ld\n", wbc->nr_to_write, *nr_submitted); ++*/ ++ reiser4_txn_restart(ctx); ++ ++ return ret; ++} ++ ++/* Remove processed nodes from atom's clean list (thereby remove them from transaction). */ ++void reiser4_invalidate_list(struct list_head *head) ++{ ++ while (!list_empty(head)) { ++ jnode *node; ++ ++ node = list_entry(head->next, jnode, capture_link); ++ spin_lock_jnode(node); ++ reiser4_uncapture_block(node); ++ jput(node); ++ } ++} ++ ++static void init_wlinks(txn_wait_links * wlinks) ++{ ++ wlinks->_lock_stack = get_current_lock_stack(); ++ INIT_LIST_HEAD(&wlinks->_fwaitfor_link); ++ INIT_LIST_HEAD(&wlinks->_fwaiting_link); ++ wlinks->waitfor_cb = NULL; ++ wlinks->waiting_cb = NULL; ++} ++ ++/* Add atom to the atom's waitfor list and wait for somebody to wake us up; */ ++void reiser4_atom_wait_event(txn_atom * atom) ++{ ++ txn_wait_links _wlinks; ++ ++ assert_spin_locked(&(atom->alock)); ++ assert("nikita-3156", ++ lock_stack_isclean(get_current_lock_stack()) || ++ atom->nr_running_queues > 0); ++ ++ init_wlinks(&_wlinks); ++ list_add_tail(&_wlinks._fwaitfor_link, &atom->fwaitfor_list); ++ atomic_inc(&atom->refcount); ++ spin_unlock_atom(atom); ++ ++ reiser4_prepare_to_sleep(_wlinks._lock_stack); ++ reiser4_go_to_sleep(_wlinks._lock_stack); ++ ++ spin_lock_atom(atom); ++ list_del(&_wlinks._fwaitfor_link); ++ atom_dec_and_unlock(atom); ++} ++ ++void reiser4_atom_set_stage(txn_atom * atom, txn_stage stage) ++{ ++ assert("nikita-3535", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ assert("nikita-3536", stage <= ASTAGE_INVALID); ++ /* Excelsior! */ ++ assert("nikita-3537", stage >= atom->stage); ++ if (atom->stage != stage) { ++ atom->stage = stage; ++ reiser4_atom_send_event(atom); ++ } ++} ++ ++/* wake all threads which wait for an event */ ++void reiser4_atom_send_event(txn_atom * atom) ++{ ++ assert_spin_locked(&(atom->alock)); ++ wakeup_atom_waitfor_list(atom); ++} ++ ++/* Informs txn manager code that owner of this txn_handle should wait atom commit completion (for ++ example, because it does fsync(2)) */ ++static int should_wait_commit(txn_handle * h) ++{ ++ return h->flags & TXNH_WAIT_COMMIT; ++} ++ ++typedef struct commit_data { ++ txn_atom *atom; ++ txn_handle *txnh; ++ long nr_written; ++ /* as an optimization we start committing atom by first trying to ++ * flush it few times without switching into ASTAGE_CAPTURE_WAIT. This ++ * allows to reduce stalls due to other threads waiting for atom in ++ * ASTAGE_CAPTURE_WAIT stage. ->preflush is counter of these ++ * preliminary flushes. */ ++ int preflush; ++ /* have we waited on atom. */ ++ int wait; ++ int failed; ++ int wake_ktxnmgrd_up; ++} commit_data; ++ ++/* ++ * Called from commit_txnh() repeatedly, until either error happens, or atom ++ * commits successfully. ++ */ ++static int try_commit_txnh(commit_data * cd) ++{ ++ int result; ++ ++ assert("nikita-2968", lock_stack_isclean(get_current_lock_stack())); ++ ++ /* Get the atom and txnh locked. */ ++ cd->atom = txnh_get_atom(cd->txnh); ++ assert("jmacd-309", cd->atom != NULL); ++ spin_unlock_txnh(cd->txnh); ++ ++ if (cd->wait) { ++ cd->atom->nr_waiters--; ++ cd->wait = 0; ++ } ++ ++ if (cd->atom->stage == ASTAGE_DONE) ++ return 0; ++ ++ if (cd->failed) ++ return 0; ++ ++ if (atom_should_commit(cd->atom)) { ++ /* if atom is _very_ large schedule it for commit as soon as ++ * possible. */ ++ if (atom_should_commit_asap(cd->atom)) { ++ /* ++ * When atom is in PRE_COMMIT or later stage following ++ * invariant (encoded in atom_can_be_committed()) ++ * holds: there is exactly one non-waiter transaction ++ * handle opened on this atom. When thread wants to ++ * wait until atom commits (for example sync()) it ++ * waits on atom event after increasing ++ * atom->nr_waiters (see blow in this function). It ++ * cannot be guaranteed that atom is already committed ++ * after receiving event, so loop has to be ++ * re-started. But if atom switched into PRE_COMMIT ++ * stage and became too large, we cannot change its ++ * state back to CAPTURE_WAIT (atom stage can only ++ * increase monotonically), hence this check. ++ */ ++ if (cd->atom->stage < ASTAGE_CAPTURE_WAIT) ++ reiser4_atom_set_stage(cd->atom, ++ ASTAGE_CAPTURE_WAIT); ++ cd->atom->flags |= ATOM_FORCE_COMMIT; ++ } ++ if (cd->txnh->flags & TXNH_DONT_COMMIT) { ++ /* ++ * this thread (transaction handle that is) doesn't ++ * want to commit atom. Notify waiters that handle is ++ * closed. This can happen, for example, when we are ++ * under VFS directory lock and don't want to commit ++ * atom right now to avoid stalling other threads ++ * working in the same directory. ++ */ ++ ++ /* Wake the ktxnmgrd up if the ktxnmgrd is needed to ++ * commit this atom: no atom waiters and only one ++ * (our) open transaction handle. */ ++ cd->wake_ktxnmgrd_up = ++ cd->atom->txnh_count == 1 && ++ cd->atom->nr_waiters == 0; ++ reiser4_atom_send_event(cd->atom); ++ result = 0; ++ } else if (!atom_can_be_committed(cd->atom)) { ++ if (should_wait_commit(cd->txnh)) { ++ /* sync(): wait for commit */ ++ cd->atom->nr_waiters++; ++ cd->wait = 1; ++ reiser4_atom_wait_event(cd->atom); ++ result = RETERR(-E_REPEAT); ++ } else { ++ result = 0; ++ } ++ } else if (cd->preflush > 0 && !is_current_ktxnmgrd()) { ++ /* ++ * optimization: flush atom without switching it into ++ * ASTAGE_CAPTURE_WAIT. ++ * ++ * But don't do this for ktxnmgrd, because ktxnmgrd ++ * should never block on atom fusion. ++ */ ++ result = flush_current_atom(JNODE_FLUSH_WRITE_BLOCKS, ++ LONG_MAX, &cd->nr_written, ++ &cd->atom, NULL); ++ if (result == 0) { ++ spin_unlock_atom(cd->atom); ++ cd->preflush = 0; ++ result = RETERR(-E_REPEAT); ++ } else /* Atoms wasn't flushed ++ * completely. Rinse. Repeat. */ ++ --cd->preflush; ++ } else { ++ /* We change atom state to ASTAGE_CAPTURE_WAIT to ++ prevent atom fusion and count ourself as an active ++ flusher */ ++ reiser4_atom_set_stage(cd->atom, ASTAGE_CAPTURE_WAIT); ++ cd->atom->flags |= ATOM_FORCE_COMMIT; ++ ++ result = ++ commit_current_atom(&cd->nr_written, &cd->atom); ++ if (result != 0 && result != -E_REPEAT) ++ cd->failed = 1; ++ } ++ } else ++ result = 0; ++ ++#if REISER4_DEBUG ++ if (result == 0) ++ assert_spin_locked(&(cd->atom->alock)); ++#endif ++ ++ /* perfectly valid assertion, except that when atom/txnh is not locked ++ * fusion can take place, and cd->atom points nowhere. */ ++ /* ++ assert("jmacd-1028", ergo(result != 0, spin_atom_is_not_locked(cd->atom))); ++ */ ++ return result; ++} ++ ++/* Called to commit a transaction handle. This decrements the atom's number of open ++ handles and if it is the last handle to commit and the atom should commit, initiates ++ atom commit. if commit does not fail, return number of written blocks */ ++static int commit_txnh(txn_handle * txnh) ++{ ++ commit_data cd; ++ assert("umka-192", txnh != NULL); ++ ++ memset(&cd, 0, sizeof cd); ++ cd.txnh = txnh; ++ cd.preflush = 10; ++ ++ /* calls try_commit_txnh() until either atom commits, or error ++ * happens */ ++ while (try_commit_txnh(&cd) != 0) ++ reiser4_preempt_point(); ++ ++ spin_lock_txnh(txnh); ++ ++ cd.atom->txnh_count -= 1; ++ txnh->atom = NULL; ++ /* remove transaction handle from atom's list of transaction handles */ ++ list_del_init(&txnh->txnh_link); ++ ++ spin_unlock_txnh(txnh); ++ atom_dec_and_unlock(cd.atom); ++ /* if we don't want to do a commit (TXNH_DONT_COMMIT is set, probably ++ * because it takes time) by current thread, we do that work ++ * asynchronously by ktxnmgrd daemon. */ ++ if (cd.wake_ktxnmgrd_up) ++ ktxnmgrd_kick(&get_current_super_private()->tmgr); ++ ++ return 0; ++} ++ ++/* TRY_CAPTURE */ ++ ++/* This routine attempts a single block-capture request. It may return -E_REPEAT if some ++ condition indicates that the request should be retried, and it may block if the ++ txn_capture mode does not include the TXN_CAPTURE_NONBLOCKING request flag. ++ ++ This routine encodes the basic logic of block capturing described by: ++ ++ http://namesys.com/v4/v4.html ++ ++ Our goal here is to ensure that any two blocks that contain dependent modifications ++ should commit at the same time. This function enforces this discipline by initiating ++ fusion whenever a transaction handle belonging to one atom requests to read or write a ++ block belonging to another atom (TXN_CAPTURE_WRITE or TXN_CAPTURE_READ_ATOMIC). ++ ++ In addition, this routine handles the initial assignment of atoms to blocks and ++ transaction handles. These are possible outcomes of this function: ++ ++ 1. The block and handle are already part of the same atom: return immediate success ++ ++ 2. The block is assigned but the handle is not: call capture_assign_txnh to assign ++ the handle to the block's atom. ++ ++ 3. The handle is assigned but the block is not: call capture_assign_block to assign ++ the block to the handle's atom. ++ ++ 4. Both handle and block are assigned, but to different atoms: call capture_init_fusion ++ to fuse atoms. ++ ++ 5. Neither block nor handle are assigned: create a new atom and assign them both. ++ ++ 6. A read request for a non-captured block: return immediate success. ++ ++ This function acquires and releases the handle's spinlock. This function is called ++ under the jnode lock and if the return value is 0, it returns with the jnode lock still ++ held. If the return is -E_REPEAT or some other error condition, the jnode lock is ++ released. The external interface (reiser4_try_capture) manages re-aquiring the jnode ++ lock in the failure case. ++*/ ++int try_capture_block( ++ txn_handle * txnh, jnode * node, txn_capture mode, ++ txn_atom ** atom_alloc) ++{ ++ txn_atom *block_atom; ++ txn_atom *txnh_atom; ++ ++ /* Should not call capture for READ_NONCOM requests, handled in reiser4_try_capture. */ ++ assert("jmacd-567", CAPTURE_TYPE(mode) != TXN_CAPTURE_READ_NONCOM); ++ ++ /* FIXME-ZAM-HANS: FIXME_LATER_JMACD Should assert that atom->tree == ++ * node->tree somewhere. */ ++ assert("umka-194", txnh != NULL); ++ assert("umka-195", node != NULL); ++ ++ /* The jnode is already locked! Being called from reiser4_try_capture(). */ ++ assert_spin_locked(&(node->guard)); ++ block_atom = node->atom; ++ ++ /* Get txnh spinlock, this allows us to compare txn_atom pointers but it doesn't ++ let us touch the atoms themselves. */ ++ spin_lock_txnh(txnh); ++ txnh_atom = txnh->atom; ++ /* Process of capturing continues into one of four branches depends on ++ which atoms from (block atom (node->atom), current atom (txnh->atom)) ++ exist. */ ++ if (txnh_atom == NULL) { ++ if (block_atom == NULL) { ++ spin_unlock_txnh(txnh); ++ spin_unlock_jnode(node); ++ /* assign empty atom to the txnh and repeat */ ++ return atom_begin_and_assign_to_txnh(atom_alloc, txnh); ++ } else { ++ atomic_inc(&block_atom->refcount); ++ /* node spin-lock isn't needed anymore */ ++ spin_unlock_jnode(node); ++ if (!spin_trylock_atom(block_atom)) { ++ spin_unlock_txnh(txnh); ++ spin_lock_atom(block_atom); ++ spin_lock_txnh(txnh); ++ } ++ /* re-check state after getting txnh and the node ++ * atom spin-locked */ ++ if (node->atom != block_atom || txnh->atom != NULL) { ++ spin_unlock_txnh(txnh); ++ atom_dec_and_unlock(block_atom); ++ return RETERR(-E_REPEAT); ++ } ++ atomic_dec(&block_atom->refcount); ++ if (block_atom->stage > ASTAGE_CAPTURE_WAIT || ++ (block_atom->stage == ASTAGE_CAPTURE_WAIT && ++ block_atom->txnh_count != 0)) ++ return capture_fuse_wait(txnh, block_atom, NULL, mode); ++ capture_assign_txnh_nolock(block_atom, txnh); ++ spin_unlock_txnh(txnh); ++ spin_unlock_atom(block_atom); ++ return RETERR(-E_REPEAT); ++ } ++ } else { ++ /* It is time to perform deadlock prevention check over the ++ node we want to capture. It is possible this node was locked ++ for read without capturing it. The optimization which allows ++ to do it helps us in keeping atoms independent as long as ++ possible but it may cause lock/fuse deadlock problems. ++ ++ A number of similar deadlock situations with locked but not ++ captured nodes were found. In each situation there are two ++ or more threads: one of them does flushing while another one ++ does routine balancing or tree lookup. The flushing thread ++ (F) sleeps in long term locking request for node (N), another ++ thread (A) sleeps in trying to capture some node already ++ belonging the atom F, F has a state which prevents ++ immediately fusion . ++ ++ Deadlocks of this kind cannot happen if node N was properly ++ captured by thread A. The F thread fuse atoms before locking ++ therefore current atom of thread F and current atom of thread ++ A became the same atom and thread A may proceed. This does ++ not work if node N was not captured because the fusion of ++ atom does not happens. ++ ++ The following scheme solves the deadlock: If ++ longterm_lock_znode locks and does not capture a znode, that ++ znode is marked as MISSED_IN_CAPTURE. A node marked this way ++ is processed by the code below which restores the missed ++ capture and fuses current atoms of all the node lock owners ++ by calling the fuse_not_fused_lock_owners() function. */ ++ if (JF_ISSET(node, JNODE_MISSED_IN_CAPTURE)) { ++ JF_CLR(node, JNODE_MISSED_IN_CAPTURE); ++ if (jnode_is_znode(node) && znode_is_locked(JZNODE(node))) { ++ spin_unlock_txnh(txnh); ++ spin_unlock_jnode(node); ++ fuse_not_fused_lock_owners(txnh, JZNODE(node)); ++ return RETERR(-E_REPEAT); ++ } ++ } ++ if (block_atom == NULL) { ++ atomic_inc(&txnh_atom->refcount); ++ spin_unlock_txnh(txnh); ++ if (!spin_trylock_atom(txnh_atom)) { ++ spin_unlock_jnode(node); ++ spin_lock_atom(txnh_atom); ++ spin_lock_jnode(node); ++ } ++ if (txnh->atom != txnh_atom || node->atom != NULL ++ || JF_ISSET(node, JNODE_IS_DYING)) { ++ spin_unlock_jnode(node); ++ atom_dec_and_unlock(txnh_atom); ++ return RETERR(-E_REPEAT); ++ } ++ atomic_dec(&txnh_atom->refcount); ++ capture_assign_block_nolock(txnh_atom, node); ++ spin_unlock_atom(txnh_atom); ++ } else { ++ if (txnh_atom != block_atom) { ++ if (mode & TXN_CAPTURE_DONT_FUSE) { ++ spin_unlock_txnh(txnh); ++ spin_unlock_jnode(node); ++ /* we are in a "no-fusion" mode and @node is ++ * already part of transaction. */ ++ return RETERR(-E_NO_NEIGHBOR); ++ } ++ return capture_init_fusion(node, txnh, mode); ++ } ++ spin_unlock_txnh(txnh); ++ } ++ } ++ return 0; ++} ++ ++static txn_capture ++build_capture_mode(jnode * node, znode_lock_mode lock_mode, txn_capture flags) ++{ ++ txn_capture cap_mode; ++ ++ assert_spin_locked(&(node->guard)); ++ ++ /* FIXME_JMACD No way to set TXN_CAPTURE_READ_MODIFY yet. */ ++ ++ if (lock_mode == ZNODE_WRITE_LOCK) { ++ cap_mode = TXN_CAPTURE_WRITE; ++ } else if (node->atom != NULL) { ++ cap_mode = TXN_CAPTURE_WRITE; ++ } else if (0 && /* txnh->mode == TXN_READ_FUSING && */ ++ jnode_get_level(node) == LEAF_LEVEL) { ++ /* NOTE-NIKITA TXN_READ_FUSING is not currently used */ ++ /* We only need a READ_FUSING capture at the leaf level. This ++ is because the internal levels of the tree (twigs included) ++ are redundant from the point of the user that asked for a ++ read-fusing transcrash. The user only wants to read-fuse ++ atoms due to reading uncommitted data that another user has ++ written. It is the file system that reads/writes the ++ internal tree levels, the user only reads/writes leaves. */ ++ cap_mode = TXN_CAPTURE_READ_ATOMIC; ++ } else { ++ /* In this case (read lock at a non-leaf) there's no reason to ++ * capture. */ ++ /* cap_mode = TXN_CAPTURE_READ_NONCOM; */ ++ return 0; ++ } ++ ++ cap_mode |= (flags & (TXN_CAPTURE_NONBLOCKING | TXN_CAPTURE_DONT_FUSE)); ++ assert("nikita-3186", cap_mode != 0); ++ return cap_mode; ++} ++ ++/* This is an external interface to try_capture_block(), it calls ++ try_capture_block() repeatedly as long as -E_REPEAT is returned. ++ ++ @node: node to capture, ++ @lock_mode: read or write lock is used in capture mode calculation, ++ @flags: see txn_capture flags enumeration, ++ @can_coc : can copy-on-capture ++ ++ @return: 0 - node was successfully captured, -E_REPEAT - capture request ++ cannot be processed immediately as it was requested in flags, ++ < 0 - other errors. ++*/ ++int reiser4_try_capture(jnode *node, znode_lock_mode lock_mode, ++ txn_capture flags) ++{ ++ txn_atom *atom_alloc = NULL; ++ txn_capture cap_mode; ++ txn_handle *txnh = get_current_context()->trans; ++ int ret; ++ ++ assert_spin_locked(&(node->guard)); ++ ++ repeat: ++ if (JF_ISSET(node, JNODE_IS_DYING)) ++ return RETERR(-EINVAL); ++ if (node->atom != NULL && txnh->atom == node->atom) ++ return 0; ++ cap_mode = build_capture_mode(node, lock_mode, flags); ++ if (cap_mode == 0 || ++ (!(cap_mode & TXN_CAPTURE_WTYPES) && node->atom == NULL)) { ++ /* Mark this node as "MISSED". It helps in further deadlock ++ * analysis */ ++ if (jnode_is_znode(node)) ++ JF_SET(node, JNODE_MISSED_IN_CAPTURE); ++ return 0; ++ } ++ /* Repeat try_capture as long as -E_REPEAT is returned. */ ++ ret = try_capture_block(txnh, node, cap_mode, &atom_alloc); ++ /* Regardless of non_blocking: ++ ++ If ret == 0 then jnode is still locked. ++ If ret != 0 then jnode is unlocked. ++ */ ++#if REISER4_DEBUG ++ if (ret == 0) ++ assert_spin_locked(&(node->guard)); ++ else ++ assert_spin_not_locked(&(node->guard)); ++#endif ++ assert_spin_not_locked(&(txnh->guard)); ++ ++ if (ret == -E_REPEAT) { ++ /* E_REPEAT implies all locks were released, therefore we need ++ to take the jnode's lock again. */ ++ spin_lock_jnode(node); ++ ++ /* Although this may appear to be a busy loop, it is not. ++ There are several conditions that cause E_REPEAT to be ++ returned by the call to try_capture_block, all cases ++ indicating some kind of state change that means you should ++ retry the request and will get a different result. In some ++ cases this could be avoided with some extra code, but ++ generally it is done because the necessary locks were ++ released as a result of the operation and repeating is the ++ simplest thing to do (less bug potential). The cases are: ++ atom fusion returns E_REPEAT after it completes (jnode and ++ txnh were unlocked); race conditions in assign_block, ++ assign_txnh, and init_fusion return E_REPEAT (trylock ++ failure); after going to sleep in capture_fuse_wait ++ (request was blocked but may now succeed). I'm not quite ++ sure how capture_copy works yet, but it may also return ++ E_REPEAT. When the request is legitimately blocked, the ++ requestor goes to sleep in fuse_wait, so this is not a busy ++ loop. */ ++ /* NOTE-NIKITA: still don't understand: ++ ++ try_capture_block->capture_assign_txnh->spin_trylock_atom->E_REPEAT ++ ++ looks like busy loop? ++ */ ++ goto repeat; ++ } ++ /* ++ * free extra atom object that was possibly allocated by ++ * try_capture_block(). ++ * ++ * Do this before acquiring jnode spin lock to ++ * minimize time spent under lock. --nikita ++ */ ++ if (atom_alloc != NULL) ++ __free_atom(atom_alloc); ++ if (ret != 0) { ++ if (ret == -E_BLOCK) { ++ assert("nikita-3360", ++ cap_mode & TXN_CAPTURE_NONBLOCKING); ++ ret = -E_REPEAT; ++ } ++ ++ /* Failure means jnode is not locked. FIXME_LATER_JMACD May ++ want to fix the above code to avoid releasing the lock and ++ re-acquiring it, but there are cases were failure occurs ++ when the lock is not held, and those cases would need to be ++ modified to re-take the lock. */ ++ spin_lock_jnode(node); ++ } ++ ++ /* Jnode is still locked. */ ++ assert_spin_locked(&(node->guard)); ++ return ret; ++} ++ ++static void release_two_atoms(txn_atom *one, txn_atom *two) ++{ ++ spin_unlock_atom(one); ++ atom_dec_and_unlock(two); ++ spin_lock_atom(one); ++ atom_dec_and_unlock(one); ++} ++ ++/* This function sets up a call to try_capture_block and repeats as long as -E_REPEAT is ++ returned by that routine. The txn_capture request mode is computed here depending on ++ the transaction handle's type and the lock request. This is called from the depths of ++ the lock manager with the jnode lock held and it always returns with the jnode lock ++ held. ++*/ ++ ++/* fuse all 'active' atoms of lock owners of given node. */ ++static void fuse_not_fused_lock_owners(txn_handle * txnh, znode * node) ++{ ++ lock_handle *lh; ++ int repeat; ++ txn_atom *atomh, *atomf; ++ reiser4_context *me = get_current_context(); ++ reiser4_context *ctx = NULL; ++ ++ assert_spin_not_locked(&(ZJNODE(node)->guard)); ++ assert_spin_not_locked(&(txnh->hlock)); ++ ++ repeat: ++ repeat = 0; ++ atomh = txnh_get_atom(txnh); ++ spin_unlock_txnh(txnh); ++ assert("zam-692", atomh != NULL); ++ ++ spin_lock_zlock(&node->lock); ++ /* inspect list of lock owners */ ++ list_for_each_entry(lh, &node->lock.owners, owners_link) { ++ ctx = get_context_by_lock_stack(lh->owner); ++ if (ctx == me) ++ continue; ++ /* below we use two assumptions to avoid addition spin-locks ++ for checking the condition : ++ ++ 1) if the lock stack has lock, the transaction should be ++ opened, i.e. ctx->trans != NULL; ++ ++ 2) reading of well-aligned ctx->trans->atom is atomic, if it ++ equals to the address of spin-locked atomh, we take that ++ the atoms are the same, nothing has to be captured. */ ++ if (atomh != ctx->trans->atom) { ++ reiser4_wake_up(lh->owner); ++ repeat = 1; ++ break; ++ } ++ } ++ if (repeat) { ++ if (!spin_trylock_txnh(ctx->trans)) { ++ spin_unlock_zlock(&node->lock); ++ spin_unlock_atom(atomh); ++ goto repeat; ++ } ++ atomf = ctx->trans->atom; ++ if (atomf == NULL) { ++ capture_assign_txnh_nolock(atomh, ctx->trans); ++ /* release zlock lock _after_ assigning the atom to the ++ * transaction handle, otherwise the lock owner thread ++ * may unlock all znodes, exit kernel context and here ++ * we would access an invalid transaction handle. */ ++ spin_unlock_zlock(&node->lock); ++ spin_unlock_atom(atomh); ++ spin_unlock_txnh(ctx->trans); ++ goto repeat; ++ } ++ assert("zam-1059", atomf != atomh); ++ spin_unlock_zlock(&node->lock); ++ atomic_inc(&atomh->refcount); ++ atomic_inc(&atomf->refcount); ++ spin_unlock_txnh(ctx->trans); ++ if (atomf > atomh) { ++ spin_lock_atom_nested(atomf); ++ } else { ++ spin_unlock_atom(atomh); ++ spin_lock_atom(atomf); ++ spin_lock_atom_nested(atomh); ++ } ++ if (atomh == atomf || !atom_isopen(atomh) || !atom_isopen(atomf)) { ++ release_two_atoms(atomf, atomh); ++ goto repeat; ++ } ++ atomic_dec(&atomh->refcount); ++ atomic_dec(&atomf->refcount); ++ capture_fuse_into(atomf, atomh); ++ goto repeat; ++ } ++ spin_unlock_zlock(&node->lock); ++ spin_unlock_atom(atomh); ++} ++ ++/* This is the interface to capture unformatted nodes via their struct page ++ reference. Currently it is only used in reiser4_invalidatepage */ ++int try_capture_page_to_invalidate(struct page *pg) ++{ ++ int ret; ++ jnode *node; ++ ++ assert("umka-292", pg != NULL); ++ assert("nikita-2597", PageLocked(pg)); ++ ++ node = jnode_by_page(pg); ++ BUG_ON(node == NULL); ++ jref(node); ++ ++ spin_lock_jnode(node); ++ unlock_page(pg); ++ ++ ret = reiser4_try_capture(node, ZNODE_WRITE_LOCK, 0); ++ spin_unlock_jnode(node); ++ jput(node); ++ lock_page(pg); ++ return ret; ++} ++ ++/* This informs the transaction manager when a node is deleted. Add the block to the ++ atom's delete set and uncapture the block. ++ ++VS-FIXME-HANS: this E_REPEAT paradigm clutters the code and creates a need for ++explanations. find all the functions that use it, and unless there is some very ++good reason to use it (I have not noticed one so far and I doubt it exists, but maybe somewhere somehow....), ++move the loop to inside the function. ++ ++VS-FIXME-HANS: can this code be at all streamlined? In particular, can you lock and unlock the jnode fewer times? ++ */ ++void reiser4_uncapture_page(struct page *pg) ++{ ++ jnode *node; ++ txn_atom *atom; ++ ++ assert("umka-199", pg != NULL); ++ assert("nikita-3155", PageLocked(pg)); ++ ++ clear_page_dirty_for_io(pg); ++ ++ reiser4_wait_page_writeback(pg); ++ ++ node = jprivate(pg); ++ BUG_ON(node == NULL); ++ ++ spin_lock_jnode(node); ++ ++ atom = jnode_get_atom(node); ++ if (atom == NULL) { ++ assert("jmacd-7111", !JF_ISSET(node, JNODE_DIRTY)); ++ spin_unlock_jnode(node); ++ return; ++ } ++ ++ /* We can remove jnode from transaction even if it is on flush queue ++ * prepped list, we only need to be sure that flush queue is not being ++ * written by reiser4_write_fq(). reiser4_write_fq() does not use atom ++ * spin lock for protection of the prepped nodes list, instead ++ * write_fq() increments atom's nr_running_queues counters for the time ++ * when prepped list is not protected by spin lock. Here we check this ++ * counter if we want to remove jnode from flush queue and, if the ++ * counter is not zero, wait all reiser4_write_fq() for this atom to ++ * complete. This is not significant overhead. */ ++ while (JF_ISSET(node, JNODE_FLUSH_QUEUED) && atom->nr_running_queues) { ++ spin_unlock_jnode(node); ++ /* ++ * at this moment we want to wait for "atom event", viz. wait ++ * until @node can be removed from flush queue. But ++ * reiser4_atom_wait_event() cannot be called with page locked, ++ * because it deadlocks with jnode_extent_write(). Unlock page, ++ * after making sure (through get_page()) that it cannot ++ * be released from memory. ++ */ ++ get_page(pg); ++ unlock_page(pg); ++ reiser4_atom_wait_event(atom); ++ lock_page(pg); ++ /* ++ * page may has been detached by ->writepage()->releasepage(). ++ */ ++ reiser4_wait_page_writeback(pg); ++ spin_lock_jnode(node); ++ put_page(pg); ++ atom = jnode_get_atom(node); ++/* VS-FIXME-HANS: improve the commenting in this function */ ++ if (atom == NULL) { ++ spin_unlock_jnode(node); ++ return; ++ } ++ } ++ reiser4_uncapture_block(node); ++ spin_unlock_atom(atom); ++ jput(node); ++} ++ ++/** ++ * This is used in extent's kill hook to uncapture and unhash jnodes ++ * attached to inode's tree of jnodes. ++ * Besides, this is used to release resources (except detaching jnode's ++ * page) during data migration caused by operations on logical volumes. ++ */ ++void reiser4_uncapture_jnode(jnode *node) ++{ ++ txn_atom *atom; ++ ++ assert_spin_locked(&(node->guard)); ++ ++ atom = jnode_get_atom(node); ++ if (atom == NULL) { ++ assert("jmacd-7111", !JF_ISSET(node, JNODE_DIRTY)); ++ spin_unlock_jnode(node); ++ return; ++ } ++ ++ reiser4_uncapture_block(node); ++ spin_unlock_atom(atom); ++ jput(node); ++} ++ ++/* No-locking version of assign_txnh. Sets the transaction handle's atom pointer, ++ increases atom refcount and txnh_count, adds to txnh_list. */ ++static void capture_assign_txnh_nolock(txn_atom *atom, txn_handle *txnh) ++{ ++ assert("umka-200", atom != NULL); ++ assert("umka-201", txnh != NULL); ++ ++ assert_spin_locked(&(txnh->hlock)); ++ assert_spin_locked(&(atom->alock)); ++ assert("jmacd-824", txnh->atom == NULL); ++ assert("nikita-3540", atom_isopen(atom)); ++ BUG_ON(txnh->atom != NULL); ++ ++ atomic_inc(&atom->refcount); ++ txnh->atom = atom; ++ reiser4_ctx_gfp_mask_set(); ++ list_add_tail(&txnh->txnh_link, &atom->txnh_list); ++ atom->txnh_count += 1; ++} ++ ++/* No-locking version of assign_block. Sets the block's atom pointer, references the ++ block, adds it to the clean or dirty capture_jnode list, increments capture_count. */ ++static void capture_assign_block_nolock(txn_atom *atom, jnode *node) ++{ ++ assert("umka-202", atom != NULL); ++ assert("umka-203", node != NULL); ++ assert_spin_locked(&(node->guard)); ++ assert_spin_locked(&(atom->alock)); ++ assert("jmacd-323", node->atom == NULL); ++ BUG_ON(!list_empty_careful(&node->capture_link)); ++ assert("nikita-3470", !JF_ISSET(node, JNODE_DIRTY)); ++ ++ /* Pointer from jnode to atom is not counted in atom->refcount. */ ++ node->atom = atom; ++ ++ list_add_tail(&node->capture_link, ATOM_CLEAN_LIST(atom)); ++ atom->capture_count += 1; ++ /* reference to jnode is acquired by atom. */ ++ jref(node); ++ ++ ON_DEBUG(count_jnode(atom, node, NOT_CAPTURED, CLEAN_LIST, 1)); ++ ++ LOCK_CNT_INC(t_refs); ++} ++ ++/** ++ * Common code for dirtying both unformatted jnodes and formatted znodes. ++ * Pre-condition: atom brick header should be already allocated. ++ */ ++static void do_jnode_make_dirty(jnode *node, txn_atom *atom) ++{ ++ assert_spin_locked(&(node->guard)); ++ assert_spin_locked(&(atom->alock)); ++ assert("jmacd-3981", !JF_ISSET(node, JNODE_DIRTY)); ++ assert("edward-2226", node->subvol != NULL); ++ assert("edward-2017", ++ find_atom_brick_info(&atom->bricks_info, ++ jnode_get_subvol(node)->id) != NULL); ++ ++ JF_SET(node, JNODE_DIRTY); ++ ++ if (!JF_ISSET(node, JNODE_CLUSTER_PAGE)) ++ get_current_context()->nr_marked_dirty++; ++ ++ /* We grab2flush_reserve one additional block only if node was ++ not CREATED and jnode_flush did not sort it into neither ++ relocate set nor overwrite one. If node is in overwrite or ++ relocate set we assume that atom's flush reserved counter was ++ already adjusted. */ ++ if (!JF_ISSET(node, JNODE_CREATED) && !JF_ISSET(node, JNODE_RELOC) ++ && !JF_ISSET(node, JNODE_OVRWR) && jnode_is_leaf(node) ++ && !jnode_is_cluster_page(node)) { ++ assert("vs-1093", !reiser4_blocknr_is_fake(&node->blocknr)); ++ assert("vs-1506", *jnode_get_block(node) != 0); ++ /* ++ * this will make a record to the atom brick header ++ */ ++ grabbed2flush_reserved_nolock(atom, (__u64) 1, ++ jnode_get_subvol(node)); ++ JF_SET(node, JNODE_FLUSH_RESERVED); ++ } ++ ++ if (!JF_ISSET(node, JNODE_FLUSH_QUEUED)) { ++ /* If the atom is not set yet, it will be added to the appropriate list in ++ capture_assign_block_nolock. */ ++ /* Sometimes a node is set dirty before being captured -- the case for new ++ jnodes. In that case the jnode will be added to the appropriate list ++ in capture_assign_block_nolock. Another reason not to re-link jnode is ++ that jnode is on a flush queue (see flush.c for details) */ ++ ++ int level = jnode_get_level(node); ++ ++ assert("nikita-3152", !JF_ISSET(node, JNODE_OVRWR)); ++ assert("zam-654", atom->stage < ASTAGE_PRE_COMMIT); ++ assert("nikita-2607", 0 <= level); ++ assert("nikita-2606", level <= REAL_MAX_ZTREE_HEIGHT); ++ ++ /* move node to atom's dirty list */ ++ list_move_tail(&node->capture_link, ATOM_DIRTY_LIST(atom, level)); ++ ON_DEBUG(count_jnode ++ (atom, node, NODE_LIST(node), DIRTY_LIST, 1)); ++ } ++} ++ ++/* Set the dirty status for this (spin locked) jnode. */ ++void jnode_make_dirty_locked(jnode * node) ++{ ++ assert("umka-204", node != NULL); ++ assert("edward-2227", node->subvol != NULL); ++ assert_spin_locked(&(node->guard)); ++ ++ if (REISER4_DEBUG && rofs_jnode(node)) { ++ warning("nikita-3365", "Dirtying jnode on rofs"); ++ dump_stack(); ++ } ++ ++ /* Fast check for already dirty node */ ++ if (!JF_ISSET(node, JNODE_DIRTY)) { ++ txn_atom *atom; ++ ++ atom = jnode_get_atom(node); ++ assert("vs-1094", atom); ++ /* Check jnode dirty status again because node spin lock might ++ * be released inside jnode_get_atom(). */ ++ if (likely(!JF_ISSET(node, JNODE_DIRTY))) ++ do_jnode_make_dirty(node, atom); ++ spin_unlock_atom(atom); ++ } ++} ++ ++/* Set the dirty status for this znode. */ ++void znode_make_dirty(znode * z) ++{ ++ jnode *node; ++ struct page *page; ++ ++ assert("umka-204", z != NULL); ++ assert("nikita-3290", znode_above_root(z) || znode_is_loaded(z)); ++ assert("nikita-3560", znode_is_write_locked(z)); ++ ++ node = ZJNODE(z); ++ /* znode is longterm locked, we can check dirty bit without spinlock */ ++ if (JF_ISSET(node, JNODE_DIRTY)) { ++ /* znode is dirty already. All we have to do is to change znode version */ ++ z->version = znode_build_version(znode_get_tree(z)); ++ return; ++ } ++ ++ spin_lock_jnode(node); ++ jnode_make_dirty_locked(node); ++ page = jnode_page(node); ++ if (page != NULL) { ++ /* this is useful assertion (allows one to check that no ++ * modifications are lost due to update of in-flight page), ++ * but it requires locking on page to check PG_writeback ++ * bit. */ ++ /* assert("nikita-3292", ++ !PageWriteback(page) || ZF_ISSET(z, JNODE_WRITEBACK)); */ ++ get_page(page); ++ ++ /* jnode lock is not needed for the rest of ++ * znode_set_dirty(). */ ++ spin_unlock_jnode(node); ++ /* reiser4 file write code calls set_page_dirty for ++ * unformatted nodes, for formatted nodes we do it here. */ ++ set_page_dirty_notag(page); ++ put_page(page); ++ /* bump version counter in znode */ ++ z->version = znode_build_version(znode_get_tree(z)); ++ } else { ++ assert("zam-596", znode_above_root(JZNODE(node))); ++ spin_unlock_jnode(node); ++ } ++ ++ assert("nikita-1900", znode_is_write_locked(z)); ++ assert("jmacd-9777", node->atom != NULL); ++} ++ ++int reiser4_sync_atom(txn_atom *atom) ++{ ++ int result; ++ txn_handle *txnh; ++ ++ txnh = get_current_context()->trans; ++ ++ result = 0; ++ if (atom != NULL) { ++ if (atom->stage < ASTAGE_PRE_COMMIT) { ++ spin_lock_txnh(txnh); ++ capture_assign_txnh_nolock(atom, txnh); ++ result = force_commit_atom(txnh); ++ } else if (atom->stage < ASTAGE_POST_COMMIT) { ++ /* wait atom commit */ ++ reiser4_atom_wait_event(atom); ++ /* try once more */ ++ result = RETERR(-E_REPEAT); ++ } else ++ spin_unlock_atom(atom); ++ } ++ return result; ++} ++ ++#if REISER4_DEBUG ++ ++/* move jnode form one list to another ++ call this after atom->capture_count is updated */ ++void ++count_jnode(txn_atom * atom, jnode * node, atom_list old_list, ++ atom_list new_list, int check_lists) ++{ ++ struct list_head *pos; ++ ++ assert("zam-1018", atom_is_protected(atom)); ++ assert_spin_locked(&(node->guard)); ++ assert("", NODE_LIST(node) == old_list); ++ ++ switch (NODE_LIST(node)) { ++ case NOT_CAPTURED: ++ break; ++ case DIRTY_LIST: ++ assert("", atom->dirty > 0); ++ atom->dirty--; ++ break; ++ case CLEAN_LIST: ++ assert("", atom->clean > 0); ++ atom->clean--; ++ break; ++ case FQ_LIST: ++ assert("", atom->fq > 0); ++ atom->fq--; ++ break; ++ case WB_LIST: ++ assert("", atom->wb > 0); ++ atom->wb--; ++ break; ++ case OVRWR_LIST: ++ assert("", atom->ovrwr > 0); ++ atom->ovrwr--; ++ break; ++ default: ++ impossible("", ""); ++ } ++ ++ switch (new_list) { ++ case NOT_CAPTURED: ++ break; ++ case DIRTY_LIST: ++ atom->dirty++; ++ break; ++ case CLEAN_LIST: ++ atom->clean++; ++ break; ++ case FQ_LIST: ++ atom->fq++; ++ break; ++ case WB_LIST: ++ atom->wb++; ++ break; ++ case OVRWR_LIST: ++ atom->ovrwr++; ++ break; ++ default: ++ impossible("", ""); ++ } ++ ASSIGN_NODE_LIST(node, new_list); ++ if (0 && check_lists) { ++ int count; ++ tree_level level; ++ ++ count = 0; ++ ++ /* flush queue list */ ++ /* reiser4_check_fq(atom); */ ++ ++ /* dirty list */ ++ count = 0; ++ for (level = 0; level < REAL_MAX_ZTREE_HEIGHT + 1; level += 1) { ++ list_for_each(pos, ATOM_DIRTY_LIST(atom, level)) ++ count++; ++ } ++ if (count != atom->dirty) ++ warning("", "dirty counter %d, real %d\n", atom->dirty, ++ count); ++ ++ /* clean list */ ++ count = 0; ++ list_for_each(pos, ATOM_CLEAN_LIST(atom)) ++ count++; ++ if (count != atom->clean) ++ warning("", "clean counter %d, real %d\n", atom->clean, ++ count); ++ ++ /* wb list */ ++ count = 0; ++ list_for_each(pos, ATOM_WB_LIST(atom)) ++ count++; ++ if (count != atom->wb) ++ warning("", "wb counter %d, real %d\n", atom->wb, ++ count); ++ ++ /* overwrite list */ ++ count = 0; ++ list_for_each(pos, ATOM_OVRWR_LIST(atom)) ++ count++; ++ ++ if (count != atom->ovrwr) ++ warning("", "ovrwr counter %d, real %d\n", atom->ovrwr, ++ count); ++ } ++ assert("vs-1624", atom->num_queued == atom->fq); ++ if (atom->capture_count != ++ atom->dirty + atom->clean + atom->ovrwr + atom->wb + atom->fq) { ++ printk ++ ("count %d, dirty %d clean %d ovrwr %d wb %d fq %d\n", ++ atom->capture_count, atom->dirty, atom->clean, atom->ovrwr, ++ atom->wb, atom->fq); ++ assert("vs-1622", ++ atom->capture_count == ++ atom->dirty + atom->clean + atom->ovrwr + atom->wb + ++ atom->fq); ++ } ++} ++ ++#endif ++ ++int capture_brick_super(reiser4_subvol *subv) ++{ ++ int result; ++ /* ++ * Grab space for a superblock copy update ++ */ ++ result = reiser4_grab_space_force((__u64)1, BA_RESERVED, subv); ++ if (result != 0) ++ return result; ++ { ++ znode *uber; ++ lock_handle lh; ++ struct atom_brick_info *abi; ++ ++ init_lh(&lh); ++ result = get_uber_znode(&subv->tree, ++ ZNODE_WRITE_LOCK, ZNODE_LOCK_LOPRI, ++ &lh); ++ if (result) ++ return result; ++ ++ result = check_insert_atom_brick_info(subv->id, &abi); ++ if (result) { ++ done_lh(&lh); ++ return result; ++ } ++ uber = lh.node; ++ znode_make_dirty(uber); ++ done_lh(&lh); ++ } ++ return 0; ++} ++ ++/** ++ * Wakeup every handle on the atom's WAITFOR list ++ */ ++static void wakeup_atom_waitfor_list(txn_atom * atom) ++{ ++ txn_wait_links *wlinks; ++ ++ assert("umka-210", atom != NULL); ++ ++ /* atom is locked */ ++ list_for_each_entry(wlinks, &atom->fwaitfor_list, _fwaitfor_link) { ++ if (wlinks->waitfor_cb == NULL || ++ wlinks->waitfor_cb(atom, wlinks)) ++ /* Wake up. */ ++ reiser4_wake_up(wlinks->_lock_stack); ++ } ++} ++ ++/* ++ * Wakeup every handle on the atom's WAITING list ++ */ ++static void wakeup_atom_waiting_list(txn_atom * atom) ++{ ++ txn_wait_links *wlinks; ++ ++ assert("umka-211", atom != NULL); ++ ++ /* atom is locked */ ++ list_for_each_entry(wlinks, &atom->fwaiting_list, _fwaiting_link) { ++ if (wlinks->waiting_cb == NULL || ++ wlinks->waiting_cb(atom, wlinks)) ++ /* Wake up. */ ++ reiser4_wake_up(wlinks->_lock_stack); ++ } ++} ++ ++/** ++ * helper function used by capture_fuse_wait() to avoid "spurious wake-ups" ++ */ ++static int wait_for_fusion(txn_atom * atom, txn_wait_links * wlinks) ++{ ++ assert("nikita-3330", atom != NULL); ++ assert_spin_locked(&(atom->alock)); ++ ++ /* atom->txnh_count == 1 is for waking waiters up if we are releasing ++ * last transaction handle. */ ++ return atom->stage != ASTAGE_CAPTURE_WAIT || atom->txnh_count == 1; ++} ++ ++/* The general purpose of this function is to wait on the first of two possible events. ++ The situation is that a handle (and its atom atomh) is blocked trying to capture a ++ block (i.e., node) but the node's atom (atomf) is in the CAPTURE_WAIT state. The ++ handle's atom (atomh) is not in the CAPTURE_WAIT state. However, atomh could fuse with ++ another atom or, due to age, enter the CAPTURE_WAIT state itself, at which point it ++ needs to unblock the handle to avoid deadlock. When the txnh is unblocked it will ++ proceed and fuse the two atoms in the CAPTURE_WAIT state. ++ ++ In other words, if either atomh or atomf change state, the handle will be awakened, ++ thus there are two lists per atom: WAITING and WAITFOR. ++ ++ This is also called by capture_assign_txnh with (atomh == NULL) to wait for atomf to ++ close but it is not assigned to an atom of its own. ++ ++ Lock ordering in this method: all four locks are held: JNODE_LOCK, TXNH_LOCK, ++ BOTH_ATOM_LOCKS. Result: all four locks are released. ++*/ ++static int capture_fuse_wait(txn_handle * txnh, txn_atom * atomf, ++ txn_atom * atomh, txn_capture mode) ++{ ++ int ret; ++ txn_wait_links wlinks; ++ ++ assert("umka-213", txnh != NULL); ++ assert("umka-214", atomf != NULL); ++ ++ if ((mode & TXN_CAPTURE_NONBLOCKING) != 0) { ++ spin_unlock_txnh(txnh); ++ spin_unlock_atom(atomf); ++ ++ if (atomh) { ++ spin_unlock_atom(atomh); ++ } ++ ++ return RETERR(-E_BLOCK); ++ } ++ ++ /* Initialize the waiting list links. */ ++ init_wlinks(&wlinks); ++ ++ /* Add txnh to atomf's waitfor list, unlock atomf. */ ++ list_add_tail(&wlinks._fwaitfor_link, &atomf->fwaitfor_list); ++ wlinks.waitfor_cb = wait_for_fusion; ++ atomic_inc(&atomf->refcount); ++ spin_unlock_atom(atomf); ++ ++ if (atomh) { ++ /* Add txnh to atomh's waiting list, unlock atomh. */ ++ list_add_tail(&wlinks._fwaiting_link, &atomh->fwaiting_list); ++ atomic_inc(&atomh->refcount); ++ spin_unlock_atom(atomh); ++ } ++ ++ /* Go to sleep. */ ++ spin_unlock_txnh(txnh); ++ ++ ret = reiser4_prepare_to_sleep(wlinks._lock_stack); ++ if (ret == 0) { ++ reiser4_go_to_sleep(wlinks._lock_stack); ++ ret = RETERR(-E_REPEAT); ++ } ++ ++ /* Remove from the waitfor list. */ ++ spin_lock_atom(atomf); ++ ++ list_del(&wlinks._fwaitfor_link); ++ atom_dec_and_unlock(atomf); ++ ++ if (atomh) { ++ /* Remove from the waiting list. */ ++ spin_lock_atom(atomh); ++ list_del(&wlinks._fwaiting_link); ++ atom_dec_and_unlock(atomh); ++ } ++ return ret; ++} ++ ++static void lock_two_atoms(txn_atom * one, txn_atom * two) ++{ ++ assert("zam-1067", one != two); ++ ++ /* lock the atom with lesser address first */ ++ if (one < two) { ++ spin_lock_atom(one); ++ spin_lock_atom_nested(two); ++ } else { ++ spin_lock_atom(two); ++ spin_lock_atom_nested(one); ++ } ++} ++ ++/* Perform the necessary work to prepare for fusing two atoms, which involves ++ * acquiring two atom locks in the proper order. If one of the node's atom is ++ * blocking fusion (i.e., it is in the CAPTURE_WAIT stage) and the handle's ++ * atom is not then the handle's request is put to sleep. If the node's atom ++ * is committing, then the node can be copy-on-captured. Otherwise, pick the ++ * atom with fewer pointers to be fused into the atom with more pointer and ++ * call capture_fuse_into. ++ */ ++static int capture_init_fusion(jnode *node, txn_handle *txnh, txn_capture mode) ++{ ++ txn_atom * txnh_atom = txnh->atom; ++ txn_atom * block_atom = node->atom; ++ ++ atomic_inc(&txnh_atom->refcount); ++ atomic_inc(&block_atom->refcount); ++ ++ spin_unlock_txnh(txnh); ++ spin_unlock_jnode(node); ++ ++ lock_two_atoms(txnh_atom, block_atom); ++ ++ if (txnh->atom != txnh_atom || node->atom != block_atom ) { ++ release_two_atoms(txnh_atom, block_atom); ++ return RETERR(-E_REPEAT); ++ } ++ ++ atomic_dec(&txnh_atom->refcount); ++ atomic_dec(&block_atom->refcount); ++ ++ assert ("zam-1066", atom_isopen(txnh_atom)); ++ ++ if (txnh_atom->stage >= block_atom->stage || ++ (block_atom->stage == ASTAGE_CAPTURE_WAIT && block_atom->txnh_count == 0)) { ++ capture_fuse_into(txnh_atom, block_atom); ++ return RETERR(-E_REPEAT); ++ } ++ spin_lock_txnh(txnh); ++ return capture_fuse_wait(txnh, block_atom, txnh_atom, mode); ++} ++ ++/* This function splices together two jnode lists (small and large) and sets all jnodes in ++ the small list to point to the large atom. Returns the length of the list. */ ++static int ++capture_fuse_jnode_lists(txn_atom *large, struct list_head *large_head, ++ struct list_head *small_head) ++{ ++ int count = 0; ++ jnode *node; ++ ++ assert("umka-218", large != NULL); ++ assert("umka-219", large_head != NULL); ++ assert("umka-220", small_head != NULL); ++ /* small atom should be locked also. */ ++ assert_spin_locked(&(large->alock)); ++ ++ /* For every jnode on small's capture list... */ ++ list_for_each_entry(node, small_head, capture_link) { ++ count += 1; ++ ++ /* With the jnode lock held, update atom pointer. */ ++ spin_lock_jnode(node); ++ node->atom = large; ++ spin_unlock_jnode(node); ++ } ++ ++ /* Splice the lists. */ ++ list_splice_init(small_head, large_head->prev); ++ ++ return count; ++} ++ ++/* This function splices together two txnh lists (small and large) and sets all txn handles in ++ the small list to point to the large atom. Returns the length of the list. */ ++static int ++capture_fuse_txnh_lists(txn_atom *large, struct list_head *large_head, ++ struct list_head *small_head) ++{ ++ int count = 0; ++ txn_handle *txnh; ++ ++ assert("umka-221", large != NULL); ++ assert("umka-222", large_head != NULL); ++ assert("umka-223", small_head != NULL); ++ ++ /* Adjust every txnh to the new atom. */ ++ list_for_each_entry(txnh, small_head, txnh_link) { ++ count += 1; ++ ++ /* With the txnh lock held, update atom pointer. */ ++ spin_lock_txnh(txnh); ++ txnh->atom = large; ++ spin_unlock_txnh(txnh); ++ } ++ ++ /* Splice the txn_handle list. */ ++ list_splice_init(small_head, large_head->prev); ++ ++ return count; ++} ++ ++/* This function fuses two atoms. The captured nodes and handles belonging to SMALL are ++ added to LARGE and their ->atom pointers are all updated. The associated counts are ++ updated as well, and any waiting handles belonging to either are awakened. Finally the ++ smaller atom's refcount is decremented. ++*/ ++static void capture_fuse_into(txn_atom * small, txn_atom * large) ++{ ++ int level; ++ unsigned zcount = 0; ++ unsigned tcount = 0; ++ ++ assert("umka-224", small != NULL); ++ assert("umka-225", small != NULL); ++ ++ assert_spin_locked(&(large->alock)); ++ assert_spin_locked(&(small->alock)); ++ ++ assert("jmacd-201", atom_isopen(small)); ++ assert("jmacd-202", atom_isopen(large)); ++ ++ /* Splice and update the per-level dirty jnode lists */ ++ for (level = 0; level < REAL_MAX_ZTREE_HEIGHT + 1; level += 1) { ++ zcount += ++ capture_fuse_jnode_lists(large, ++ ATOM_DIRTY_LIST(large, level), ++ ATOM_DIRTY_LIST(small, level)); ++ } ++ ++ /* Splice and update the [clean,dirty] jnode and txnh lists */ ++ zcount += ++ capture_fuse_jnode_lists(large, ATOM_CLEAN_LIST(large), ++ ATOM_CLEAN_LIST(small)); ++ zcount += ++ capture_fuse_jnode_lists(large, ATOM_OVRWR_LIST(large), ++ ATOM_OVRWR_LIST(small)); ++ zcount += ++ capture_fuse_jnode_lists(large, ATOM_WB_LIST(large), ++ ATOM_WB_LIST(small)); ++ zcount += ++ capture_fuse_jnode_lists(large, &large->inodes, &small->inodes); ++ tcount += ++ capture_fuse_txnh_lists(large, &large->txnh_list, ++ &small->txnh_list); ++ ++ /* Check our accounting. */ ++ assert("jmacd-1063", ++ zcount + small->num_queued == small->capture_count); ++ assert("jmacd-1065", tcount == small->txnh_count); ++ ++ /* sum numbers of waiters threads */ ++ large->nr_waiters += small->nr_waiters; ++ small->nr_waiters = 0; ++ ++ /* splice flush queues */ ++ reiser4_fuse_fq(large, small); ++ ++ /* update counter of jnode on every atom' list */ ++ ON_DEBUG(large->dirty += small->dirty; ++ small->dirty = 0; ++ large->clean += small->clean; ++ small->clean = 0; ++ large->ovrwr += small->ovrwr; ++ small->ovrwr = 0; ++ large->wb += small->wb; ++ small->wb = 0; ++ large->fq += small->fq; ++ small->fq = 0;); ++ ++ /* count flushers in result atom */ ++ large->nr_flushers += small->nr_flushers; ++ small->nr_flushers = 0; ++ ++ /* update counts of flushed nodes */ ++ large->flushed += small->flushed; ++ small->flushed = 0; ++ ++ /* Transfer list counts to large. */ ++ large->txnh_count += small->txnh_count; ++ large->capture_count += small->capture_count; ++ ++ /* Add all txnh references to large. */ ++ atomic_add(small->txnh_count, &large->refcount); ++ atomic_sub(small->txnh_count, &small->refcount); ++ ++ /* Reset small counts */ ++ small->txnh_count = 0; ++ small->capture_count = 0; ++ ++ /* Assign the oldest start_time, merge flags. */ ++ large->start_time = min(large->start_time, small->start_time); ++ large->flags |= small->flags; ++ ++ /* Merge delete sets. */ ++ atom_dset_merge(small, large); ++ ++ /* Merge allocated/deleted file counts */ ++ large->nr_objects_deleted += small->nr_objects_deleted; ++ large->nr_objects_created += small->nr_objects_created; ++ ++ small->nr_objects_deleted = 0; ++ small->nr_objects_created = 0; ++ ++ large->nr_running_queues += small->nr_running_queues; ++ small->nr_running_queues = 0; ++ ++ fuse_abi(small, large); ++ ++ if (large->stage < small->stage) { ++ /* Large only needs to notify if it has changed state. */ ++ reiser4_atom_set_stage(large, small->stage); ++ wakeup_atom_waiting_list(large); ++ } ++ reiser4_atom_set_stage(small, ASTAGE_INVALID); ++ ++ /* Notify any waiters--small needs to unload its wait lists. Waiters ++ actually remove themselves from the list before returning from the ++ fuse_wait function. */ ++ wakeup_atom_waiting_list(small); ++ ++ /* Unlock atoms */ ++ spin_unlock_atom(large); ++ atom_dec_and_unlock(small); ++} ++ ++/* TXNMGR STUFF */ ++ ++/* Release a block from the atom, reversing the effects of being captured, ++ do not release atom's reference to jnode due to holding spin-locks. ++ Currently this is only called when the atom commits. ++ ++ NOTE: this function does not release a (journal) reference to jnode ++ due to locking optimizations, you should call jput() somewhere after ++ calling reiser4_uncapture_block(). */ ++void reiser4_uncapture_block(jnode *node) ++{ ++ txn_atom *atom; ++ ++ assert("umka-226", node != NULL); ++ atom = node->atom; ++ assert("umka-228", atom != NULL); ++ ++ assert("jmacd-1021", node->atom == atom); ++ assert_spin_locked(&(node->guard)); ++ assert("jmacd-1023", atom_is_protected(atom)); ++ ++ JF_CLR(node, JNODE_DIRTY); ++ JF_CLR(node, JNODE_RELOC); ++ JF_CLR(node, JNODE_OVRWR); ++ JF_CLR(node, JNODE_CREATED); ++ JF_CLR(node, JNODE_WRITEBACK); ++ JF_CLR(node, JNODE_REPACK); ++ ++ list_del_init(&node->capture_link); ++ if (JF_ISSET(node, JNODE_FLUSH_QUEUED)) { ++ assert("zam-925", atom_isopen(atom)); ++ assert("vs-1623", NODE_LIST(node) == FQ_LIST); ++ ON_DEBUG(atom->num_queued--); ++ JF_CLR(node, JNODE_FLUSH_QUEUED); ++ } ++ atom->capture_count -= 1; ++ ON_DEBUG(count_jnode(atom, node, NODE_LIST(node), NOT_CAPTURED, 1)); ++ node->atom = NULL; ++ ++ spin_unlock_jnode(node); ++ LOCK_CNT_DEC(t_refs); ++} ++ ++/* ++ * Unconditional insert of jnode into atom's overwrite list. ++ * Currently used in bitmap-based allocator code for adding ++ * modified bitmap blocks the transaction. @atom and @node ++ * are spin locked ++ */ ++void insert_into_atom_ovrwr_list(txn_atom *atom, jnode *node) ++{ ++ assert("zam-538", atom_is_protected(atom)); ++ assert_spin_locked(&(node->guard)); ++ assert("zam-899", JF_ISSET(node, JNODE_OVRWR)); ++ assert("zam-543", node->atom == NULL); ++ assert("vs-1433", !jnode_is_unformatted(node) && !jnode_is_znode(node)); ++ ++ list_add(&node->capture_link, ATOM_OVRWR_LIST(atom)); ++ jref(node); ++ node->atom = atom; ++ atom->capture_count++; ++ ON_DEBUG(count_jnode(atom, node, NODE_LIST(node), OVRWR_LIST, 1)); ++} ++ ++void insert_into_subv_ovrwr_list(reiser4_subvol *subv, jnode *node, ++ txn_atom *atom) ++{ ++ assert("edward-1775", node->subvol == subv); ++ ++ list_add(&node->capture_link, &subv->ch.overwrite_set); ++ jref(node); ++ node->atom = atom; ++ atom->capture_count++; ++ ON_DEBUG(count_jnode(atom, node, NODE_LIST(node), OVRWR_LIST, 1)); ++} ++ ++static int count_deleted_blocks_actor(txn_atom *atom, ++ const reiser4_block_nr *a, ++ const reiser4_block_nr *b, ++ __u32 subvol_id, void *data) ++{ ++ reiser4_block_nr *counter = data; ++ ++ assert("zam-995", data != NULL); ++ assert("zam-996", a != NULL); ++ ++ if (b == NULL) ++ *counter += 1; ++ else ++ *counter += *b; ++ return 0; ++} ++ ++reiser4_block_nr txnmgr_count_deleted_blocks(void) ++{ ++ reiser4_block_nr result; ++ txn_mgr *tmgr = &get_super_private(reiser4_get_current_sb())->tmgr; ++ txn_atom *atom; ++ ++ result = 0; ++ ++ spin_lock_txnmgr(tmgr); ++ list_for_each_entry(atom, &tmgr->atoms_list, atom_link) { ++ spin_lock_atom(atom); ++ if (atom_isopen(atom)) ++ atom_dset_deferred_apply(atom, count_deleted_blocks_actor, &result, 0); ++ spin_unlock_atom(atom); ++ } ++ spin_unlock_txnmgr(tmgr); ++ ++ return result; ++} ++ ++void atom_dset_init(txn_atom *atom) ++{ ++ if (1) { ++ blocknr_list_init(&atom->discard.delete_set); ++ } else { ++ blocknr_set_init(&atom->nodiscard.delete_set); ++ } ++} ++ ++void atom_dset_destroy(txn_atom *atom) ++{ ++ if (1) { ++ blocknr_list_destroy(&atom->discard.delete_set); ++ } else { ++ blocknr_set_destroy(&atom->nodiscard.delete_set); ++ } ++} ++ ++void atom_dset_merge(txn_atom *from, txn_atom *to) ++{ ++ if (1) { ++ blocknr_list_merge(&from->discard.delete_set, &to->discard.delete_set); ++ } else { ++ blocknr_set_merge(&from->nodiscard.delete_set, &to->nodiscard.delete_set); ++ } ++} ++ ++int atom_dset_deferred_apply(txn_atom* atom, ++ blocknr_set_actor_f actor, ++ void *data, ++ int delete) ++{ ++ int ret; ++ ++ if (1) { ++ ret = blocknr_list_iterator(atom, ++ &atom->discard.delete_set, ++ actor, ++ data, ++ delete); ++ } ++#if 0 ++ else { ++ ret = blocknr_set_iterator(atom, ++ &atom->nodiscard.delete_set, ++ actor, ++ data, ++ delete); ++ } ++#endif ++ return ret; ++} ++ ++extern int atom_dset_deferred_add_extent(txn_atom *atom, ++ void **new_entry, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ __u32 subvol_id) ++{ ++ int ret; ++ ++ if (1) { ++ ret = blocknr_list_add_extent(atom, ++ &atom->discard.delete_set, ++ (blocknr_list_entry**)new_entry, ++ start, ++ len, ++ subvol_id); ++ } ++#if 0 ++ else { ++ ret = blocknr_set_add_extent(atom, ++ &atom->nodiscard.delete_set, ++ (blocknr_set_entry**)new_entry, ++ start, ++ len, ++ subvol_id); ++ } ++#endif ++ return ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 79 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/txnmgr.h linux-5.10.2/fs/reiser4/txnmgr.h +--- linux-5.10.2.orig/fs/reiser4/txnmgr.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/txnmgr.h 2020-12-23 16:07:46.136813392 +0100 +@@ -0,0 +1,809 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* data-types and function declarations for transaction manager. See txnmgr.c ++ * for details. */ ++ ++#ifndef __REISER4_TXNMGR_H__ ++#define __REISER4_TXNMGR_H__ ++ ++#include "forward.h" ++#include "dformat.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* TYPE DECLARATIONS */ ++ ++/* This enumeration describes the possible types of a capture request (reiser4_try_capture). ++ A capture request dynamically assigns a block to the calling thread's transaction ++ handle. */ ++typedef enum { ++ /* A READ_ATOMIC request indicates that a block will be read and that the caller's ++ atom should fuse in order to ensure that the block commits atomically with the ++ caller. */ ++ TXN_CAPTURE_READ_ATOMIC = (1 << 0), ++ ++ /* A READ_NONCOM request indicates that a block will be read and that the caller is ++ willing to read a non-committed block without causing atoms to fuse. */ ++ TXN_CAPTURE_READ_NONCOM = (1 << 1), ++ ++ /* A READ_MODIFY request indicates that a block will be read but that the caller ++ wishes for the block to be captured as it will be written. This capture request ++ mode is not currently used, but eventually it will be useful for preventing ++ deadlock in read-modify-write cycles. */ ++ TXN_CAPTURE_READ_MODIFY = (1 << 2), ++ ++ /* A WRITE capture request indicates that a block will be modified and that atoms ++ should fuse to make the commit atomic. */ ++ TXN_CAPTURE_WRITE = (1 << 3), ++ ++ /* CAPTURE_TYPES is a mask of the four above capture types, used to separate the ++ exclusive type designation from extra bits that may be supplied -- see ++ below. */ ++ TXN_CAPTURE_TYPES = (TXN_CAPTURE_READ_ATOMIC | ++ TXN_CAPTURE_READ_NONCOM | TXN_CAPTURE_READ_MODIFY | ++ TXN_CAPTURE_WRITE), ++ ++ /* A subset of CAPTURE_TYPES, CAPTURE_WTYPES is a mask of request types that ++ indicate modification will occur. */ ++ TXN_CAPTURE_WTYPES = (TXN_CAPTURE_READ_MODIFY | TXN_CAPTURE_WRITE), ++ ++ /* An option to reiser4_try_capture, NONBLOCKING indicates that the caller would ++ prefer not to sleep waiting for an aging atom to commit. */ ++ TXN_CAPTURE_NONBLOCKING = (1 << 4), ++ ++ /* An option to reiser4_try_capture to prevent atom fusion, just simple ++ capturing is allowed */ ++ TXN_CAPTURE_DONT_FUSE = (1 << 5) ++ ++ /* This macro selects only the exclusive capture request types, stripping out any ++ options that were supplied (i.e., NONBLOCKING). */ ++#define CAPTURE_TYPE(x) ((x) & TXN_CAPTURE_TYPES) ++} txn_capture; ++ ++/* There are two kinds of transaction handle: WRITE_FUSING and READ_FUSING, the only ++ difference is in the handling of read requests. A WRITE_FUSING transaction handle ++ defaults read capture requests to TXN_CAPTURE_READ_NONCOM whereas a READ_FUSIONG ++ transaction handle defaults to TXN_CAPTURE_READ_ATOMIC. */ ++typedef enum { ++ TXN_WRITE_FUSING = (1 << 0), ++ TXN_READ_FUSING = (1 << 1) | TXN_WRITE_FUSING, /* READ implies WRITE */ ++} txn_mode; ++ ++/* Every atom has a stage, which is one of these exclusive values: */ ++typedef enum { ++ /* Initially an atom is free. */ ++ ASTAGE_FREE = 0, ++ ++ /* An atom begins by entering the CAPTURE_FUSE stage, where it proceeds to capture ++ blocks and fuse with other atoms. */ ++ ASTAGE_CAPTURE_FUSE = 1, ++ ++ /* We need to have a ASTAGE_CAPTURE_SLOW in which an atom fuses with one node for every X nodes it flushes to disk where X > 1. */ ++ ++ /* When an atom reaches a certain age it must do all it can to commit. An atom in ++ the CAPTURE_WAIT stage refuses new transaction handles and prevents fusion from ++ atoms in the CAPTURE_FUSE stage. */ ++ ASTAGE_CAPTURE_WAIT = 2, ++ ++ /* Waiting for I/O before commit. Copy-on-capture (see ++ http://namesys.com/v4/v4.html). */ ++ ASTAGE_PRE_COMMIT = 3, ++ ++ /* Post-commit overwrite I/O. Steal-on-capture. */ ++ ASTAGE_POST_COMMIT = 4, ++ ++ /* Atom which waits for the removal of the last reference to (it? ) to ++ * be deleted from memory */ ++ ASTAGE_DONE = 5, ++ ++ /* invalid atom. */ ++ ASTAGE_INVALID = 6, ++ ++} txn_stage; ++ ++/* Certain flags may be set in the txn_atom->flags field. */ ++typedef enum { ++ /* Indicates that the atom should commit as soon as possible. */ ++ ATOM_FORCE_COMMIT = (1 << 0), ++ /* to avoid endless loop, mark the atom (which was considered as too ++ * small) after failed attempt to fuse it. */ ++ ATOM_CANCEL_FUSION = (1 << 1) ++} txn_flags; ++ ++/* Flags for controlling commit_txnh */ ++typedef enum { ++ /* Wait commit atom completion in commit_txnh */ ++ TXNH_WAIT_COMMIT = 0x2, ++ /* Don't commit atom when this handle is closed */ ++ TXNH_DONT_COMMIT = 0x4 ++} txn_handle_flags_t; ++ ++/* TYPE DEFINITIONS */ ++ ++/* A note on lock ordering: the handle & jnode spinlock protects reading of their ->atom ++ fields, so typically an operation on the atom through either of these objects must (1) ++ lock the object, (2) read the atom pointer, (3) lock the atom. ++ ++ During atom fusion, the process holds locks on both atoms at once. Then, it iterates ++ through the list of handles and pages held by the smaller of the two atoms. For each ++ handle and page referencing the smaller atom, the fusing process must: (1) lock the ++ object, and (2) update the atom pointer. ++ ++ You can see that there is a conflict of lock ordering here, so the more-complex ++ procedure should have priority, i.e., the fusing process has priority so that it is ++ guaranteed to make progress and to avoid restarts. ++ ++ This decision, however, means additional complexity for aquiring the atom lock in the ++ first place. ++ ++ The general original procedure followed in the code was: ++ ++ TXN_OBJECT *obj = ...; ++ TXN_ATOM *atom; ++ ++ spin_lock (& obj->_lock); ++ ++ atom = obj->_atom; ++ ++ if (! spin_trylock_atom (atom)) ++ { ++ spin_unlock (& obj->_lock); ++ RESTART OPERATION, THERE WAS A RACE; ++ } ++ ++ ELSE YOU HAVE BOTH ATOM AND OBJ LOCKED ++ ++ It has however been found that this wastes CPU a lot in a manner that is ++ hard to profile. So, proper refcounting was added to atoms, and new ++ standard locking sequence is like following: ++ ++ TXN_OBJECT *obj = ...; ++ TXN_ATOM *atom; ++ ++ spin_lock (& obj->_lock); ++ ++ atom = obj->_atom; ++ ++ if (! spin_trylock_atom (atom)) ++ { ++ atomic_inc (& atom->refcount); ++ spin_unlock (& obj->_lock); ++ spin_lock (&atom->_lock); ++ atomic_dec (& atom->refcount); ++ // HERE atom is locked ++ spin_unlock (&atom->_lock); ++ RESTART OPERATION, THERE WAS A RACE; ++ } ++ ++ ELSE YOU HAVE BOTH ATOM AND OBJ LOCKED ++ ++ (core of this is implemented in trylock_throttle() function) ++ ++ See the jnode_get_atom() function for a common case. ++ ++ As an additional (and important) optimization allowing to avoid restarts, ++ it is possible to re-check required pre-conditions at the HERE point in ++ code above and proceed without restarting if they are still satisfied. ++*/ ++ ++struct atom_brick_info { ++ struct rb_node node; ++ u32 brick_id; /* key */ ++ reiser4_block_nr nr_blocks_allocated; /* number of blocks allocated ++ during the transaction */ ++ reiser4_block_nr atom_flush_reserved; /* counter of blocks reserved ++ for flush and commit, see ++ reiser4 space reservation ++ scheme at block_alloc.c */ ++}; ++ ++/* An atomic transaction: this is the underlying system representation ++ of a transaction, not the one seen by clients. ++ ++ Invariants involving this data-type: ++ ++ [sb-fake-allocated] ++*/ ++struct txn_atom { ++ /* The spinlock protecting the atom, held during fusion and various other state ++ changes. */ ++ spinlock_t alock; ++ ++ /* The atom's reference counter, increasing (in case of a duplication ++ of an existing reference or when we are sure that some other ++ reference exists) may be done without taking spinlock, decrementing ++ of the ref. counter requires a spinlock to be held. ++ ++ Each transaction handle counts in ->refcount. All jnodes count as ++ one reference acquired in atom_begin_andlock(), released in ++ commit_current_atom(). ++ */ ++ atomic_t refcount; ++ ++ /* The atom_id identifies the atom in persistent records such as the log. */ ++ __u32 atom_id; ++ ++ /* Flags holding any of the txn_flags enumerated values (e.g., ++ ATOM_FORCE_COMMIT). */ ++ __u32 flags; ++ ++ /* Number of open handles. */ ++ __u32 txnh_count; ++ /* The number of znodes captured by this atom. Equal to the sum of lengths of the ++ dirty_nodes[level] and clean_nodes lists. */ ++ __u32 capture_count; ++ ++#if REISER4_DEBUG ++ int clean; ++ int dirty; ++ int ovrwr; ++ int wb; ++ int fq; ++ atom_brick_info *abi; ++ atom_brick_info *abi_found; ++#endif ++ ++ __u32 flushed; ++ ++ /* Current transaction stage. */ ++ txn_stage stage; ++ ++ /* Start time. */ ++ unsigned long start_time; ++ ++ /* The atom's delete sets. ++ "simple" are blocknr_set instances and are used when discard is disabled. ++ "discard" are blocknr_list instances and are used when discard is enabled. */ ++ union { ++ struct { ++ /* The atom's delete set. It collects block numbers of the nodes ++ which were deleted during the transaction. */ ++ struct list_head delete_set; ++ } nodiscard; ++ ++ struct { ++ /* The atom's delete set. It collects all blocks that have been ++ deallocated (both immediate and deferred) during the transaction. ++ These blocks are considered for discarding at commit time. ++ For details see discard.c */ ++ struct list_head delete_set; ++ } discard; ++ }; ++ ++ /* The transaction's list of dirty captured nodes--per level. Index ++ by (level). dirty_nodes[0] is for znode-above-root */ ++ struct list_head dirty_nodes[REAL_MAX_ZTREE_HEIGHT + 1]; ++ ++ /* The transaction's list of clean captured nodes. */ ++ struct list_head clean_nodes; ++ ++ /* The atom's overwrite set */ ++ struct list_head ovrwr_nodes; ++ ++ /* nodes which are being written to disk */ ++ struct list_head writeback_nodes; ++ ++ /* list of inodes */ ++ struct list_head inodes; ++ ++ /* List of handles associated with this atom. */ ++ struct list_head txnh_list; ++ ++ /* Transaction list link: list of atoms in the transaction manager. */ ++ struct list_head atom_link; ++ ++ /* List of handles waiting FOR this atom: see 'capture_fuse_wait' comment. */ ++ struct list_head fwaitfor_list; ++ ++ /* List of this atom's handles that are waiting: see 'capture_fuse_wait' comment. */ ++ struct list_head fwaiting_list; ++ ++ /* Numbers of objects which were deleted/created in this transaction ++ thereby numbers of objects IDs which were released/deallocated. */ ++ int nr_objects_deleted; ++ int nr_objects_created; ++ /* All atom's flush queue objects are on this list */ ++ struct list_head flush_queues; ++#if REISER4_DEBUG ++ /* number of flush queues for this atom. */ ++ int nr_flush_queues; ++ /* Number of jnodes which were removed from atom's lists and put ++ on flush_queue */ ++ int num_queued; ++#endif ++ /* number of threads who wait for this atom to complete commit */ ++ int nr_waiters; ++ /* number of threads which do jnode_flush() over this atom */ ++ int nr_flushers; ++ /* number of flush queues which are IN_USE and jnodes from fq->prepped ++ are submitted to disk by the reiser4_write_fq() routine. */ ++ int nr_running_queues; ++ ++ struct rb_root bricks_info; ++ struct atom_brick_info mabi; /* pre-allocated meta-data brick info */ ++#if REISER4_DEBUG ++ void *committer; ++#endif ++ struct super_block *super; ++}; ++ ++#define ATOM_DIRTY_LIST(atom, level) (&(atom)->dirty_nodes[level]) ++#define ATOM_CLEAN_LIST(atom) (&(atom)->clean_nodes) ++#define ATOM_OVRWR_LIST(atom) (&(atom)->ovrwr_nodes) ++#define ATOM_WB_LIST(atom) (&(atom)->writeback_nodes) ++#define ATOM_FQ_LIST(fq) (&(fq)->prepped) ++ ++#define NODE_LIST(node) (node)->list ++#define ASSIGN_NODE_LIST(node, list) ON_DEBUG(NODE_LIST(node) = list) ++ON_DEBUG(void ++ count_jnode(txn_atom *, jnode *, atom_list old_list, ++ atom_list new_list, int check_lists)); ++ ++/* A transaction handle: the client obtains and commits this handle which is assigned by ++ the system to a txn_atom. */ ++struct txn_handle { ++ /* Spinlock protecting ->atom pointer */ ++ spinlock_t hlock; ++ ++ /* Flags for controlling commit_txnh() behavior */ ++ /* from txn_handle_flags_t */ ++ txn_handle_flags_t flags; ++ ++ /* Whether it is READ_FUSING or WRITE_FUSING. */ ++ txn_mode mode; ++ ++ /* If assigned, the atom it is part of. */ ++ txn_atom *atom; ++ ++ /* Transaction list link. Head is in txn_atom. */ ++ struct list_head txnh_link; ++}; ++ ++/* The transaction manager: one is contained in the reiser4_super_info_data */ ++struct txn_mgr { ++ /* A spinlock protecting the atom list, id_count, flush_control */ ++ spinlock_t tmgr_lock; ++ ++ /* List of atoms. */ ++ struct list_head atoms_list; ++ ++ /* Number of atoms. */ ++ int atom_count; ++ ++ /* A counter used to assign atom->atom_id values. */ ++ __u32 id_count; ++ ++ /* a mutex object for commit serialization */ ++ struct mutex commit_mutex; ++ ++ /* a list of all txnmrgs served by particular daemon. */ ++ struct list_head linkage; ++ ++ /* description of daemon for this txnmgr */ ++ ktxnmgrd_context *daemon; ++ ++ /* parameters. Adjustable through mount options. */ ++ unsigned int atom_max_size; ++ unsigned int atom_max_age; ++ unsigned int atom_min_size; ++ /* max number of concurrent flushers for one atom, 0 - unlimited. */ ++ unsigned int atom_max_flushers; ++ struct dentry *debugfs_atom_count; ++ struct dentry *debugfs_id_count; ++}; ++ ++/* FUNCTION DECLARATIONS */ ++ ++/* These are the externally (within Reiser4) visible transaction functions, therefore they ++ are prefixed with "txn_". For comments, see txnmgr.c. */ ++ ++extern int init_txnmgr_static(void); ++extern void done_txnmgr_static(void); ++ ++extern void reiser4_init_txnmgr(txn_mgr *); ++extern void reiser4_done_txnmgr(txn_mgr *); ++ ++extern int reiser4_txn_reserve(int reserved); ++ ++extern void reiser4_txn_begin(reiser4_context * context); ++extern int reiser4_txn_end(reiser4_context * context); ++ ++extern void reiser4_txn_restart(reiser4_context * context); ++extern void reiser4_txn_restart_current(void); ++ ++extern int txnmgr_force_commit_all(struct super_block *, int); ++extern int current_atom_should_commit(void); ++ ++extern jnode *find_first_dirty_jnode(txn_atom *, int); ++ ++extern int commit_some_atoms(txn_mgr *); ++extern int force_commit_atom(txn_handle *); ++extern int force_commit_current_atom(void); ++ ++extern int flush_current_atom(int, long, long *, txn_atom **, jnode *); ++ ++extern int flush_some_atom(jnode *, long *, const struct writeback_control *, int); ++ ++extern void reiser4_atom_set_stage(txn_atom * atom, txn_stage stage); ++ ++extern int same_slum_check(jnode * base, jnode * check, int alloc_check, ++ int alloc_value); ++extern void atom_dec_and_unlock(txn_atom * atom); ++ ++extern int reiser4_create_atom(void); ++extern int reiser4_try_capture(jnode * node, znode_lock_mode mode, txn_capture flags); ++extern int try_capture_page_to_invalidate(struct page *pg); ++ ++extern void reiser4_uncapture_page(struct page *pg); ++extern void reiser4_uncapture_block(jnode *node); ++extern void reiser4_uncapture_jnode(jnode *node); ++ ++extern int reiser4_capture_inode(struct inode *); ++extern int reiser4_uncapture_inode(struct inode *); ++ ++extern txn_atom *get_current_atom_locked_nocheck(void); ++ ++extern struct atom_brick_info *alloc_atom_brick_info(void); ++extern void free_atom_brick_info(struct atom_brick_info *abi); ++static inline void init_atom_brick_info(struct atom_brick_info *abi, ++ u32 brick_id) ++{ ++ memset(abi, 0, sizeof(*abi)); ++ RB_CLEAR_NODE(&abi->node); ++ abi->brick_id = brick_id; ++} ++ ++static inline struct atom_brick_info *atom_meta_brick_info(txn_atom *atom) ++{ ++ return &atom->mabi; ++} ++ ++extern struct atom_brick_info *find_atom_brick_info(const struct rb_root *root, ++ u32 brick_id); ++extern struct atom_brick_info *insert_atom_brick_info(struct rb_root *root, ++ struct atom_brick_info *abi); ++extern int __check_insert_atom_brick_info(txn_atom **atom, u32 brick_id, ++ struct atom_brick_info **abi); ++extern int check_insert_atom_brick_info(u32 brick_id, ++ struct atom_brick_info **abi); ++ ++#if REISER4_DEBUG ++extern void check_atom_flush_reserved(txn_atom *atom); ++extern void __check_atom_brick_info(struct rb_root *root); ++extern void check_atom_brick_info(txn_atom *atom); ++#else ++#define check_atom_flush_reserved(atom) noop ++#define __check_atom_brick_info(root) noop ++#define check_atom_brick_info(atom) noop ++#endif ++ ++#if REISER4_DEBUG ++ ++/** ++ * atom_is_protected - make sure that nobody but us can do anything with atom ++ * @atom: atom to be checked ++ * ++ * This is used to assert that atom either entered commit stages or is spin ++ * locked. ++ */ ++static inline int atom_is_protected(txn_atom *atom) ++{ ++ if (atom->stage >= ASTAGE_PRE_COMMIT) ++ return 1; ++ assert_spin_locked(&(atom->alock)); ++ return 1; ++} ++ ++#endif ++ ++/* Get the current atom and spinlock it if current atom present. May not return NULL */ ++static inline txn_atom *get_current_atom_locked(void) ++{ ++ txn_atom *atom; ++ ++ atom = get_current_atom_locked_nocheck(); ++ assert("zam-761", atom != NULL); ++ ++ return atom; ++} ++ ++extern txn_atom *jnode_get_atom(jnode *); ++ ++extern void reiser4_atom_wait_event(txn_atom *); ++extern void reiser4_atom_send_event(txn_atom *); ++ ++extern void insert_into_atom_ovrwr_list(txn_atom *atom, jnode *node); ++extern void insert_into_subv_ovrwr_list(reiser4_subvol *subv, jnode *node, ++ txn_atom *atom); ++ ++extern int capture_brick_super(reiser4_subvol *subv); ++int capture_bulk(jnode **, int count); ++ ++/* See the comment on the function blocknrset.c:blocknr_set_add for the ++ calling convention of these three routines. */ ++extern int blocknr_set_init_static(void); ++extern void blocknr_set_done_static(void); ++extern void blocknr_set_init(struct list_head * bset); ++extern void blocknr_set_destroy(struct list_head * bset); ++extern void blocknr_set_merge(struct list_head * from, struct list_head * into); ++extern int blocknr_set_add_extent(txn_atom * atom, ++ struct list_head * bset, ++ blocknr_set_entry ** new_bsep, ++ const reiser4_block_nr * start, ++ const reiser4_block_nr * len, ++ const __u32 subvol_id); ++extern int blocknr_set_add_pair(txn_atom * atom, struct list_head * bset, ++ blocknr_set_entry ** new_bsep, ++ const reiser4_block_nr * a, ++ const reiser4_block_nr * b, ++ __u32 subvol_id); ++ ++typedef int (*blocknr_set_actor_f) (txn_atom *, ++ const reiser4_block_nr *, ++ const reiser4_block_nr *, ++ __u32, ++ void *); ++ ++extern int blocknr_set_iterator(txn_atom * atom, struct list_head * bset, ++ blocknr_set_actor_f actor, void *data, ++ int delete, u32 subv_id); ++ ++/* This is the block list interface (see blocknrlist.c) */ ++extern int blocknr_list_init_static(void); ++extern void blocknr_list_done_static(void); ++extern void blocknr_list_init(struct list_head *blist); ++extern void blocknr_list_destroy(struct list_head *blist); ++extern void blocknr_list_merge(struct list_head *from, struct list_head *to); ++extern void blocknr_list_sort_and_join(struct list_head *blist); ++/** ++ * The @atom should be locked. ++ */ ++extern int blocknr_list_add_extent(txn_atom *atom, ++ struct list_head *blist, ++ blocknr_list_entry **new_entry, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ __u32 subvol_id); ++extern int blocknr_list_iterator(txn_atom *atom, ++ struct list_head *blist, ++ blocknr_set_actor_f actor, ++ void *data, ++ int delete); ++ ++/* These are wrappers for accessing and modifying atom's delete lists, ++ depending on whether discard is enabled or not. ++ If it is enabled, (less memory efficient) blocknr_list is used for delete ++ list storage. Otherwise, blocknr_set is used for this purpose. */ ++extern void atom_dset_init(txn_atom *atom); ++extern void atom_dset_destroy(txn_atom *atom); ++extern void atom_dset_merge(txn_atom *from, txn_atom *to); ++extern int atom_dset_deferred_apply(txn_atom* atom, ++ blocknr_set_actor_f actor, ++ void *data, ++ int delete); ++extern int atom_dset_deferred_add_extent(txn_atom *atom, ++ void **new_entry, ++ const reiser4_block_nr *start, ++ const reiser4_block_nr *len, ++ const __u32 subvol_id); ++ ++/* flush code takes care about how to fuse flush queues */ ++extern void flush_init_atom(txn_atom * atom); ++extern void flush_fuse_queues(txn_atom * large, txn_atom * small); ++ ++static inline void spin_lock_atom(txn_atom *atom) ++{ ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(spin_locked_atom) && ++ LOCK_CNT_NIL(spin_locked_jnode) && ++ LOCK_CNT_NIL(spin_locked_zlock) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(rw_locked_tree))); ++ ++ spin_lock(&(atom->alock)); ++ ++ LOCK_CNT_INC(spin_locked_atom); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline void spin_lock_atom_nested(txn_atom *atom) ++{ ++ assert("", (LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(spin_locked_jnode) && ++ LOCK_CNT_NIL(spin_locked_zlock) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(rw_locked_tree))); ++ ++ spin_lock_nested(&(atom->alock), SINGLE_DEPTH_NESTING); ++ ++ LOCK_CNT_INC(spin_locked_atom); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline int spin_trylock_atom(txn_atom *atom) ++{ ++ if (spin_trylock(&(atom->alock))) { ++ LOCK_CNT_INC(spin_locked_atom); ++ LOCK_CNT_INC(spin_locked); ++ return 1; ++ } ++ return 0; ++} ++ ++static inline void spin_unlock_atom(txn_atom *atom) ++{ ++ assert_spin_locked(&(atom->alock)); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_atom)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(spin_locked_atom); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&(atom->alock)); ++} ++ ++static inline void spin_lock_txnh(txn_handle *txnh) ++{ ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(spin_locked_zlock) && ++ LOCK_CNT_NIL(rw_locked_tree))); ++ ++ spin_lock(&(txnh->hlock)); ++ ++ LOCK_CNT_INC(spin_locked_txnh); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline int spin_trylock_txnh(txn_handle *txnh) ++{ ++ if (spin_trylock(&(txnh->hlock))) { ++ LOCK_CNT_INC(spin_locked_txnh); ++ LOCK_CNT_INC(spin_locked); ++ return 1; ++ } ++ return 0; ++} ++ ++static inline void spin_unlock_txnh(txn_handle *txnh) ++{ ++ assert_spin_locked(&(txnh->hlock)); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_txnh)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(spin_locked_txnh); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&(txnh->hlock)); ++} ++ ++#define spin_ordering_pred_txnmgr(tmgr) \ ++ ( LOCK_CNT_NIL(spin_locked_atom) && \ ++ LOCK_CNT_NIL(spin_locked_txnh) && \ ++ LOCK_CNT_NIL(spin_locked_jnode) && \ ++ LOCK_CNT_NIL(rw_locked_zlock) && \ ++ LOCK_CNT_NIL(rw_locked_dk) && \ ++ LOCK_CNT_NIL(rw_locked_tree) ) ++ ++static inline void spin_lock_txnmgr(txn_mgr *mgr) ++{ ++ /* check that spinlocks of lower priorities are not held */ ++ assert("", (LOCK_CNT_NIL(spin_locked_atom) && ++ LOCK_CNT_NIL(spin_locked_txnh) && ++ LOCK_CNT_NIL(spin_locked_jnode) && ++ LOCK_CNT_NIL(spin_locked_zlock) && ++ LOCK_CNT_NIL(rw_locked_dk) && ++ LOCK_CNT_NIL(rw_locked_tree))); ++ ++ spin_lock(&(mgr->tmgr_lock)); ++ ++ LOCK_CNT_INC(spin_locked_txnmgr); ++ LOCK_CNT_INC(spin_locked); ++} ++ ++static inline int spin_trylock_txnmgr(txn_mgr *mgr) ++{ ++ if (spin_trylock(&(mgr->tmgr_lock))) { ++ LOCK_CNT_INC(spin_locked_txnmgr); ++ LOCK_CNT_INC(spin_locked); ++ return 1; ++ } ++ return 0; ++} ++ ++static inline void spin_unlock_txnmgr(txn_mgr *mgr) ++{ ++ assert_spin_locked(&(mgr->tmgr_lock)); ++ assert("nikita-1375", LOCK_CNT_GTZ(spin_locked_txnmgr)); ++ assert("nikita-1376", LOCK_CNT_GTZ(spin_locked)); ++ ++ LOCK_CNT_DEC(spin_locked_txnmgr); ++ LOCK_CNT_DEC(spin_locked); ++ ++ spin_unlock(&(mgr->tmgr_lock)); ++} ++ ++typedef enum { ++ FQ_IN_USE = 0x1 ++} flush_queue_state_t; ++ ++typedef struct flush_queue flush_queue_t; ++ ++/* This is an accumulator for jnodes prepared for writing to disk. A flush queue ++ is filled by the jnode_flush() routine, and written to disk under memory ++ pressure or at atom commit time. */ ++/* LOCKING: fq state and fq->atom are protected by guard spinlock, fq->nr_queued ++ field and fq->prepped list can be modified if atom is spin-locked and fq ++ object is "in-use" state. For read-only traversal of the fq->prepped list ++ and reading of the fq->nr_queued field it is enough to keep fq "in-use" or ++ only have atom spin-locked. */ ++struct flush_queue { ++ /* linkage element is the first in this structure to make debugging ++ easier. See field in atom struct for description of list. */ ++ struct list_head alink; ++ /* A spinlock to protect changes of fq state and fq->atom pointer */ ++ spinlock_t guard; ++ /* flush_queue state: [in_use | ready] */ ++ flush_queue_state_t state; ++ /* A list which contains queued nodes, queued nodes are removed from any ++ * atom's list and put on this ->prepped one. */ ++ struct list_head prepped; ++ /* number of submitted i/o requests */ ++ atomic_t nr_submitted; ++ /* number of i/o errors */ ++ atomic_t nr_errors; ++ /* An atom this flush queue is attached to */ ++ txn_atom *atom; ++ /* A wait queue head to wait on i/o completion */ ++ wait_queue_head_t wait; ++#if REISER4_DEBUG ++ /* A thread which took this fq in exclusive use, NULL if fq is free, ++ * used for debugging. */ ++ struct task_struct *owner; ++#endif ++}; ++ ++extern int reiser4_fq_by_atom(txn_atom *, flush_queue_t **); ++extern void reiser4_fq_put_nolock(flush_queue_t *); ++extern void reiser4_fq_put(flush_queue_t *); ++extern void reiser4_fuse_fq(txn_atom * to, txn_atom * from); ++extern void queue_jnode(flush_queue_t *, jnode *); ++ ++extern int reiser4_write_fq(flush_queue_t *, long *, int); ++extern int current_atom_finish_all_fq(void); ++extern void init_atom_fq_parts(txn_atom *); ++ ++extern reiser4_block_nr txnmgr_count_deleted_blocks(void); ++ ++extern void znode_make_dirty(znode * node); ++extern void jnode_make_dirty_locked(jnode * node); ++ ++extern int reiser4_sync_atom(txn_atom * atom); ++ ++#if REISER4_DEBUG ++extern int atom_fq_parts_are_clean(txn_atom *); ++#endif ++ ++extern void add_fq_to_bio(flush_queue_t *, struct bio *); ++extern flush_queue_t *get_fq_for_current_atom(void); ++ ++void reiser4_invalidate_list(struct list_head * head); ++ ++# endif /* __REISER4_TXNMGR_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/type_safe_hash.h linux-5.10.2/fs/reiser4/type_safe_hash.h +--- linux-5.10.2.orig/fs/reiser4/type_safe_hash.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/type_safe_hash.h 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,320 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* A hash table class that uses hash chains (singly-linked) and is ++ parametrized to provide type safety. */ ++ ++#ifndef __REISER4_TYPE_SAFE_HASH_H__ ++#define __REISER4_TYPE_SAFE_HASH_H__ ++ ++#include "debug.h" ++ ++#include ++/* Step 1: Use TYPE_SAFE_HASH_DECLARE() to define the TABLE and LINK objects ++ based on the object type. You need to declare the item type before ++ this definition, define it after this definition. */ ++#define TYPE_SAFE_HASH_DECLARE(PREFIX,ITEM_TYPE) \ ++ \ ++typedef struct PREFIX##_hash_table_ PREFIX##_hash_table; \ ++typedef struct PREFIX##_hash_link_ PREFIX##_hash_link; \ ++ \ ++struct PREFIX##_hash_table_ \ ++{ \ ++ ITEM_TYPE **_table; \ ++ __u32 _buckets; \ ++}; \ ++ \ ++struct PREFIX##_hash_link_ \ ++{ \ ++ ITEM_TYPE *_next; \ ++} ++ ++/* Step 2: Define the object type of the hash: give it field of type ++ PREFIX_hash_link. */ ++ ++/* Step 3: Use TYPE_SAFE_HASH_DEFINE to define the hash table interface using ++ the type and field name used in step 3. The arguments are: ++ ++ ITEM_TYPE The item type being hashed ++ KEY_TYPE The type of key being hashed ++ KEY_NAME The name of the key field within the item ++ LINK_NAME The name of the link field within the item, which you must make type PREFIX_hash_link) ++ HASH_FUNC The name of the hash function (or macro, takes const pointer to key) ++ EQ_FUNC The name of the equality function (or macro, takes const pointer to two keys) ++ ++ It implements these functions: ++ ++ prefix_hash_init Initialize the table given its size. ++ prefix_hash_insert Insert an item ++ prefix_hash_insert_index Insert an item w/ precomputed hash_index ++ prefix_hash_find Find an item by key ++ prefix_hash_find_index Find an item w/ precomputed hash_index ++ prefix_hash_remove Remove an item, returns 1 if found, 0 if not found ++ prefix_hash_remove_index Remove an item w/ precomputed hash_index ++ ++ If you'd like something to be done differently, feel free to ask me ++ for modifications. Additional features that could be added but ++ have not been: ++ ++ prefix_hash_remove_key Find and remove an item by key ++ prefix_hash_remove_key_index Find and remove an item by key w/ precomputed hash_index ++ ++ The hash_function currently receives only the key as an argument, ++ meaning it must somehow know the number of buckets. If this is a ++ problem let me know. ++ ++ This hash table uses a single-linked hash chain. This means ++ insertion is fast but deletion requires searching the chain. ++ ++ There is also the doubly-linked hash chain approach, under which ++ deletion requires no search but the code is longer and it takes two ++ pointers per item. ++ ++ The circularly-linked approach has the shortest code but requires ++ two pointers per bucket, doubling the size of the bucket array (in ++ addition to two pointers per item). ++*/ ++#define TYPE_SAFE_HASH_DEFINE(PREFIX,ITEM_TYPE,KEY_TYPE,KEY_NAME,LINK_NAME,HASH_FUNC,EQ_FUNC) \ ++ \ ++static __inline__ void \ ++PREFIX##_check_hash (PREFIX##_hash_table *table UNUSED_ARG, \ ++ __u32 hash UNUSED_ARG) \ ++{ \ ++ assert("nikita-2780", hash < table->_buckets); \ ++} \ ++ \ ++static __inline__ int \ ++PREFIX##_hash_init (PREFIX##_hash_table *hash, \ ++ __u32 buckets) \ ++{ \ ++ hash->_table = (ITEM_TYPE**) KMALLOC (sizeof (ITEM_TYPE*) * buckets); \ ++ hash->_buckets = buckets; \ ++ if (hash->_table == NULL) \ ++ { \ ++ return RETERR(-ENOMEM); \ ++ } \ ++ memset (hash->_table, 0, sizeof (ITEM_TYPE*) * buckets); \ ++ ON_DEBUG(printk(#PREFIX "_hash_table: %i buckets\n", buckets)); \ ++ return 0; \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_done (PREFIX##_hash_table *hash) \ ++{ \ ++ if (REISER4_DEBUG && hash->_table != NULL) { \ ++ __u32 i; \ ++ for (i = 0 ; i < hash->_buckets ; ++ i) \ ++ assert("nikita-2905", hash->_table[i] == NULL); \ ++ } \ ++ if (hash->_table != NULL) \ ++ KFREE (hash->_table, sizeof (ITEM_TYPE*) * hash->_buckets); \ ++ hash->_table = NULL; \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_prefetch_next (ITEM_TYPE *item) \ ++{ \ ++ prefetch(item->LINK_NAME._next); \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_prefetch_bucket (PREFIX##_hash_table *hash, \ ++ __u32 index) \ ++{ \ ++ prefetch(hash->_table[index]); \ ++} \ ++ \ ++static __inline__ ITEM_TYPE* \ ++PREFIX##_hash_find_index (PREFIX##_hash_table *hash, \ ++ __u32 hash_index, \ ++ KEY_TYPE const *find_key) \ ++{ \ ++ ITEM_TYPE *item; \ ++ \ ++ PREFIX##_check_hash(hash, hash_index); \ ++ \ ++ for (item = hash->_table[hash_index]; \ ++ item != NULL; \ ++ item = item->LINK_NAME._next) \ ++ { \ ++ prefetch(item->LINK_NAME._next); \ ++ prefetch(item->LINK_NAME._next + offsetof(ITEM_TYPE, KEY_NAME)); \ ++ if (EQ_FUNC (& item->KEY_NAME, find_key)) \ ++ { \ ++ return item; \ ++ } \ ++ } \ ++ \ ++ return NULL; \ ++} \ ++ \ ++static __inline__ ITEM_TYPE* \ ++PREFIX##_hash_find_index_lru (PREFIX##_hash_table *hash, \ ++ __u32 hash_index, \ ++ KEY_TYPE const *find_key) \ ++{ \ ++ ITEM_TYPE ** item = &hash->_table[hash_index]; \ ++ \ ++ PREFIX##_check_hash(hash, hash_index); \ ++ \ ++ while (*item != NULL) { \ ++ prefetch(&(*item)->LINK_NAME._next); \ ++ if (EQ_FUNC (&(*item)->KEY_NAME, find_key)) { \ ++ ITEM_TYPE *found; \ ++ \ ++ found = *item; \ ++ *item = found->LINK_NAME._next; \ ++ found->LINK_NAME._next = hash->_table[hash_index]; \ ++ hash->_table[hash_index] = found; \ ++ return found; \ ++ } \ ++ item = &(*item)->LINK_NAME._next; \ ++ } \ ++ return NULL; \ ++} \ ++ \ ++static __inline__ int \ ++PREFIX##_hash_remove_index (PREFIX##_hash_table *hash, \ ++ __u32 hash_index, \ ++ ITEM_TYPE *del_item) \ ++{ \ ++ ITEM_TYPE ** hash_item_p = &hash->_table[hash_index]; \ ++ \ ++ PREFIX##_check_hash(hash, hash_index); \ ++ \ ++ while (*hash_item_p != NULL) { \ ++ prefetch(&(*hash_item_p)->LINK_NAME._next); \ ++ if (*hash_item_p == del_item) { \ ++ *hash_item_p = (*hash_item_p)->LINK_NAME._next; \ ++ return 1; \ ++ } \ ++ hash_item_p = &(*hash_item_p)->LINK_NAME._next; \ ++ } \ ++ return 0; \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_insert_index (PREFIX##_hash_table *hash, \ ++ __u32 hash_index, \ ++ ITEM_TYPE *ins_item) \ ++{ \ ++ PREFIX##_check_hash(hash, hash_index); \ ++ \ ++ ins_item->LINK_NAME._next = hash->_table[hash_index]; \ ++ hash->_table[hash_index] = ins_item; \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_insert_index_rcu (PREFIX##_hash_table *hash, \ ++ __u32 hash_index, \ ++ ITEM_TYPE *ins_item) \ ++{ \ ++ PREFIX##_check_hash(hash, hash_index); \ ++ \ ++ ins_item->LINK_NAME._next = hash->_table[hash_index]; \ ++ smp_wmb(); \ ++ hash->_table[hash_index] = ins_item; \ ++} \ ++ \ ++static __inline__ ITEM_TYPE* \ ++PREFIX##_hash_find (PREFIX##_hash_table *hash, \ ++ KEY_TYPE const *find_key) \ ++{ \ ++ return PREFIX##_hash_find_index (hash, HASH_FUNC(hash, find_key), find_key); \ ++} \ ++ \ ++static __inline__ ITEM_TYPE* \ ++PREFIX##_hash_find_lru (PREFIX##_hash_table *hash, \ ++ KEY_TYPE const *find_key) \ ++{ \ ++ return PREFIX##_hash_find_index_lru (hash, HASH_FUNC(hash, find_key), find_key); \ ++} \ ++ \ ++static __inline__ int \ ++PREFIX##_hash_remove (PREFIX##_hash_table *hash, \ ++ ITEM_TYPE *del_item) \ ++{ \ ++ return PREFIX##_hash_remove_index (hash, \ ++ HASH_FUNC(hash, &del_item->KEY_NAME), del_item); \ ++} \ ++ \ ++static __inline__ int \ ++PREFIX##_hash_remove_rcu (PREFIX##_hash_table *hash, \ ++ ITEM_TYPE *del_item) \ ++{ \ ++ return PREFIX##_hash_remove (hash, del_item); \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_insert (PREFIX##_hash_table *hash, \ ++ ITEM_TYPE *ins_item) \ ++{ \ ++ return PREFIX##_hash_insert_index (hash, \ ++ HASH_FUNC(hash, &ins_item->KEY_NAME), ins_item); \ ++} \ ++ \ ++static __inline__ void \ ++PREFIX##_hash_insert_rcu (PREFIX##_hash_table *hash, \ ++ ITEM_TYPE *ins_item) \ ++{ \ ++ return PREFIX##_hash_insert_index_rcu (hash, HASH_FUNC(hash, &ins_item->KEY_NAME), \ ++ ins_item); \ ++} \ ++ \ ++static __inline__ ITEM_TYPE * \ ++PREFIX##_hash_first (PREFIX##_hash_table *hash, __u32 ind) \ ++{ \ ++ ITEM_TYPE *first; \ ++ \ ++ for (first = NULL; ind < hash->_buckets; ++ ind) { \ ++ first = hash->_table[ind]; \ ++ if (first != NULL) \ ++ break; \ ++ } \ ++ return first; \ ++} \ ++ \ ++static __inline__ ITEM_TYPE * \ ++PREFIX##_hash_next (PREFIX##_hash_table *hash, \ ++ ITEM_TYPE *item) \ ++{ \ ++ ITEM_TYPE *next; \ ++ \ ++ if (item == NULL) \ ++ return NULL; \ ++ next = item->LINK_NAME._next; \ ++ if (next == NULL) \ ++ next = PREFIX##_hash_first (hash, HASH_FUNC(hash, &item->KEY_NAME) + 1); \ ++ return next; \ ++} \ ++ \ ++typedef struct {} PREFIX##_hash_dummy ++ ++#define for_all_ht_buckets(table, head) \ ++for ((head) = &(table) -> _table[ 0 ] ; \ ++ (head) != &(table) -> _table[ (table) -> _buckets ] ; ++ (head)) ++ ++#define for_all_in_bucket(bucket, item, next, field) \ ++for ((item) = *(bucket), (next) = (item) ? (item) -> field._next : NULL ; \ ++ (item) != NULL ; \ ++ (item) = (next), (next) = (item) ? (item) -> field._next : NULL ) ++ ++#define for_all_in_htable(table, prefix, item, next) \ ++for ((item) = prefix ## _hash_first ((table), 0), \ ++ (next) = prefix ## _hash_next ((table), (item)) ; \ ++ (item) != NULL ; \ ++ (item) = (next), \ ++ (next) = prefix ## _hash_next ((table), (item))) ++ ++/* __REISER4_TYPE_SAFE_HASH_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/vfs_ops.c linux-5.10.2/fs/reiser4/vfs_ops.c +--- linux-5.10.2.orig/fs/reiser4/vfs_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/vfs_ops.c 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,261 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Interface to VFS. Reiser4 {super|export|dentry}_operations are defined ++ here. */ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "coord.h" ++#include "plugin/item/item.h" ++#include "plugin/file/file.h" ++#include "plugin/security/perm.h" ++#include "plugin/disk_format/disk_format.h" ++#include "plugin/plugin.h" ++#include "plugin/plugin_set.h" ++#include "plugin/object.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "vfs_ops.h" ++#include "inode.h" ++#include "page_cache.h" ++#include "ktxnmgrd.h" ++#include "super.h" ++#include "reiser4.h" ++#include "entd.h" ++#include "status_flags.h" ++#include "flush.h" ++#include "dscale.h" ++ ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++#include ++ ++/* update inode stat-data by calling plugin */ ++int reiser4_update_sd(struct inode *object) ++{ ++ file_plugin *fplug; ++ ++ assert("nikita-2338", object != NULL); ++ ++ /* check for read-only file system. */ ++ if (IS_RDONLY(object)) ++ return 0; ++ ++ fplug = inode_file_plugin(object); ++ assert("nikita-2339", fplug != NULL); ++ return fplug->write_sd_by_inode(object, NULL); ++} ++ ++/* helper function: increase inode nlink count and call plugin method to save ++ updated stat-data. ++ ++ Used by link/create and during creation of dot and dotdot in mkdir ++*/ ++int reiser4_add_nlink(struct inode *object, /* object to which link is added */ ++ struct inode *parent, /* parent where new entry will be */ ++ int write_sd_p /* true if stat-data has to be ++ * updated */ ) ++{ ++ file_plugin *fplug; ++ int result; ++ ++ assert("nikita-1351", object != NULL); ++ ++ fplug = inode_file_plugin(object); ++ assert("nikita-1445", fplug != NULL); ++ ++ /* ask plugin whether it can add yet another link to this ++ object */ ++ if (!fplug->can_add_link(object)) ++ return RETERR(-EMLINK); ++ ++ assert("nikita-2211", fplug->add_link != NULL); ++ /* call plugin to do actual addition of link */ ++ result = fplug->add_link(object, parent); ++ ++ /* optionally update stat data */ ++ if (result == 0 && write_sd_p) ++ result = fplug->write_sd_by_inode(object, NULL); ++ return result; ++} ++ ++/* helper function: decrease inode nlink count and call plugin method to save ++ updated stat-data. ++ ++ Used by unlink/create ++*/ ++int reiser4_del_nlink(struct inode *object /* object from which link is ++ * removed */ , ++ struct inode *parent /* parent where entry was */ , ++ int write_sd_p /* true is stat-data has to be ++ * updated */ ) ++{ ++ file_plugin *fplug; ++ int result; ++ ++ assert("nikita-1349", object != NULL); ++ ++ fplug = inode_file_plugin(object); ++ assert("nikita-1350", fplug != NULL); ++ assert("nikita-1446", object->i_nlink > 0); ++ assert("nikita-2210", fplug->rem_link != NULL); ++ ++ /* call plugin to do actual deletion of link */ ++ result = fplug->rem_link(object, parent); ++ ++ /* optionally update stat data */ ++ if (result == 0 && write_sd_p) ++ result = fplug->write_sd_by_inode(object, NULL); ++ return result; ++} ++ ++/* Release reiser4 dentry. This is d_op->d_release() method. */ ++static void reiser4_d_release(struct dentry *dentry /* dentry released */ ) ++{ ++ reiser4_free_dentry_fsdata(dentry); ++} ++ ++/* ++ * Called by reiser4_sync_inodes(), during speculative write-back (through ++ * pdflush, or balance_dirty_pages()). ++ */ ++void reiser4_writeout(struct super_block *sb, struct writeback_control *wbc) ++{ ++ long written = 0; ++ int repeats = 0; ++ int result; ++ ++ /* ++ * Performs early flushing, trying to free some memory. If there ++ * is nothing to flush, commits some atoms. ++ * ++ * Commit all atoms if reiser4_writepages_dispatch() is called ++ * from sys_sync() or sys_fsync() ++ */ ++ if (wbc->sync_mode != WB_SYNC_NONE) { ++ txnmgr_force_commit_all(sb, 0); ++ return; ++ } ++ ++ BUG_ON(reiser4_get_super_fake(sb) == NULL); ++ do { ++ long nr_submitted = 0; ++ jnode *node = NULL; ++ ++ /* do not put more requests to overload write queue */ ++ if (bdi_write_congested(inode_to_bdi(reiser4_get_super_fake(sb)))) { ++ //blk_flush_plug(current); ++ break; ++ } ++ repeats++; ++ BUG_ON(wbc->nr_to_write <= 0); ++ ++ if (get_current_context()->entd) { ++ entd_context *ent = get_entd_context(sb); ++ ++ if (ent->cur_request->node) ++ /* ++ * this is ent thread and it managed to capture ++ * requested page itself - start flush from ++ * that page ++ */ ++ node = ent->cur_request->node; ++ } ++ ++ result = flush_some_atom(node, &nr_submitted, wbc, ++ JNODE_FLUSH_WRITE_BLOCKS); ++ if (result != 0) ++ warning("nikita-31001", "Flush failed: %i", result); ++ if (node) ++ /* drop the reference aquired ++ in find_or_create_extent() */ ++ jput(node); ++ if (!nr_submitted) ++ break; ++ ++ wbc->nr_to_write -= nr_submitted; ++ written += nr_submitted; ++ } while (wbc->nr_to_write > 0); ++} ++ ++/* tell VM how many pages were dirtied */ ++void reiser4_throttle_write(struct inode *inode) ++{ ++ reiser4_context *ctx; ++ ++ ctx = get_current_context(); ++ reiser4_txn_restart(ctx); ++ current->journal_info = NULL; ++ balance_dirty_pages_ratelimited(inode->i_mapping); ++ current->journal_info = ctx; ++} ++ ++const int REISER4_MAGIC_OFFSET = 16 * 4096; /* offset to magic string from the ++ * beginning of device */ ++ ++/* ++ * Reiser4 initialization/shutdown. ++ * ++ * Code below performs global reiser4 initialization that is done either as ++ * part of kernel initialization (when reiser4 is statically built-in), or ++ * during reiser4 module load (when compiled as module). ++ */ ++ ++void reiser4_handle_error(void) ++{ ++ struct super_block *sb = reiser4_get_current_sb(); ++ ++ if (!sb) ++ return; ++ reiser4_status_write(get_meta_subvol(), ++ REISER4_STATUS_DAMAGED, 0, ++ "Filesystem error occured"); ++ switch (get_super_private(sb)->onerror) { ++ case 1: ++ reiser4_panic("foobar-42", "Filesystem error occured\n"); ++ default: ++ if (sb_rdonly(sb)) ++ return; ++ sb->s_flags |= SB_RDONLY; ++ break; ++ } ++} ++ ++struct dentry_operations reiser4_dentry_operations = { ++ .d_revalidate = NULL, ++ .d_hash = NULL, ++ .d_compare = NULL, ++ .d_delete = NULL, ++ .d_release = reiser4_d_release, ++ .d_iput = NULL, ++}; ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/vfs_ops.h linux-5.10.2/fs/reiser4/vfs_ops.h +--- linux-5.10.2.orig/fs/reiser4/vfs_ops.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/vfs_ops.h 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,60 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* vfs_ops.c's exported symbols */ ++ ++#if !defined( __FS_REISER4_VFS_OPS_H__ ) ++#define __FS_REISER4_VFS_OPS_H__ ++ ++#include "forward.h" ++#include "coord.h" ++#include "seal.h" ++#include "plugin/file/file.h" ++#include "super.h" ++#include "readahead.h" ++ ++#include /* for loff_t */ ++#include /* for struct address_space */ ++#include /* for struct dentry */ ++#include ++#include ++ ++/* address space operations */ ++int reiser4_writepage(struct page *, struct writeback_control *); ++int reiser4_set_page_dirty(struct page *); ++void reiser4_invalidatepage(struct page *, unsigned int offset, unsigned int length); ++int reiser4_releasepage(struct page *, gfp_t); ++ ++#ifdef CONFIG_MIGRATION ++int reiser4_migratepage(struct address_space *, struct page *, ++ struct page *, enum migrate_mode); ++#else ++#define reiser4_migratepage NULL ++#endif /* CONFIG_MIGRATION */ ++ ++extern int reiser4_update_sd(struct inode *); ++extern int reiser4_add_nlink(struct inode *, struct inode *, int); ++extern int reiser4_del_nlink(struct inode *, struct inode *, int); ++ ++extern int reiser4_start_up_io(struct page *page); ++extern void reiser4_throttle_write(struct inode *); ++extern int jnode_is_releasable(jnode *); ++ ++#define CAPTURE_APAGE_BURST (1024l) ++void reiser4_writeout(struct super_block *, struct writeback_control *); ++ ++extern void reiser4_handle_error(void); ++ ++/* __FS_REISER4_VFS_OPS_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/volume_ops.c linux-5.10.2/fs/reiser4/volume_ops.c +--- linux-5.10.2.orig/fs/reiser4/volume_ops.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/volume_ops.c 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,639 @@ ++/* ++ Copyright (c) 2017-2020 Eduard O. Shishkin ++ ++ This file is licensed to you under your choice of the GNU Lesser ++ General Public License, version 3 or any later version (LGPLv3 or ++ later), or the GNU General Public License, version 2 (GPLv2), in all ++ cases as published by the Free Software Foundation. ++*/ ++ ++#include "debug.h" ++#include "super.h" ++#include "inode.h" ++#include "plugin/volume/volume.h" ++ ++static int reiser4_register_brick(struct reiser4_vol_op_args *args) ++{ ++ reiser4_volume *host = NULL; ++ ++ return reiser4_scan_device(args->d.name, FMODE_READ, ++ get_reiser4_fs_type(), NULL, &host); ++} ++ ++static int reiser4_print_volume(struct super_block *sb, ++ struct reiser4_vol_op_args *args) ++{ ++ return super_vol_plug(sb)->print_volume(sb, args); ++} ++ ++static int reiser4_print_brick(struct super_block *sb, ++ struct reiser4_vol_op_args *args) ++{ ++ return super_vol_plug(sb)->print_brick(sb, args); ++} ++ ++/** ++ * find activated brick by @name ++ */ ++static reiser4_subvol *find_active_brick(struct super_block *super, ++ char *name) ++{ ++ u32 subv_id; ++ reiser4_subvol *result = NULL; ++ lv_conf *conf = super_conf(super); ++ ++ for_each_mslot(conf, subv_id) { ++ if (!conf_mslot_at(conf, subv_id)) ++ continue; ++ if (!strcmp(conf_origin(conf, subv_id)->name, name)) { ++ result = conf_origin(conf, subv_id); ++ break; ++ } ++ } ++ return result; ++} ++ ++static int reiser4_resize_brick(struct super_block *sb, ++ struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ reiser4_subvol *this; ++ int need_balance; ++ ++ if (reiser4_volume_has_incomplete_removal(sb)) { ++ warning("edward-2166", ++ "Failed to resize brick (%s has incomplete removal)", ++ sb->s_id); ++ return -EBUSY; ++ } ++ if (args->new_capacity == 0) { ++ warning("edward-2395", "Can not resize brick to zero."); ++ return -EINVAL; ++ } ++ this = find_active_brick(sb, args->d.name); ++ if (!this) { ++ warning("edward-2148", ++ "Brick %s doesn't belong to volume %s. Can not resize.", ++ args->d.name, ++ reiser4_get_current_sb()->s_id); ++ return -EINVAL; ++ } ++ if (args->new_capacity == this->data_capacity) ++ /* nothing to do */ ++ return 0; ++ ret = super_vol_plug(sb)->resize_brick(super_volume(sb), ++ this, ++ args->new_capacity - this->data_capacity, ++ &need_balance); ++ if (ret) ++ /* resize operation should be repeated in regular context */ ++ return ret; ++ ++ if (!(args->flags & COMPLETE_WITH_BALANCE)) ++ return 0; ++ ++ if (!need_balance) ++ return 0; ++ ++ ret = super_vol_plug(sb)->balance_volume(sb, 0); ++ if (ret) ++ return ret; ++ /* ++ * clear unbalanced status on disk ++ */ ++ reiser4_volume_clear_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ return force_commit_current_atom(); ++} ++ ++static int reiser4_add_brick(struct super_block *sb, ++ struct reiser4_vol_op_args *args, int add_proxy) ++{ ++ int ret; ++ reiser4_volume *vol = super_volume(sb); ++ int activated_here = 0; ++ reiser4_subvol *new = NULL; ++ reiser4_volume *host_of_new = NULL; ++ ++ if (reiser4_volume_has_incomplete_removal(sb)) { ++ warning("edward-2167", ++ "Failed to add brick (%s has incomplete removal)", ++ sb->s_id); ++ return -EBUSY; ++ } ++ /* ++ * register new brick ++ */ ++ ret = reiser4_scan_device(args->d.name, FMODE_READ, ++ get_reiser4_fs_type(), &new, &host_of_new); ++ if (ret) ++ return ret; ++ ++ assert("edward-1969", new != NULL); ++ assert("edward-1970", host_of_new != NULL); ++ ++ if (host_of_new != vol) { ++ warning("edward-1971", ++ "Failed to add brick (Inappropriate volume)"); ++ return -EINVAL; ++ } ++ if (!subvol_is_set(new, SUBVOL_ACTIVATED)) { ++ new->flags |= (1 << SUBVOL_IS_ORPHAN); ++ ++ ret = reiser4_activate_subvol(sb, new); ++ if (ret) ++ return ret; ++ activated_here = 1; ++ } ++ if (add_proxy) { ++ if (brick_belongs_volume(vol, new) && is_proxy_brick(new)) { ++ warning("edward-2435", ++ "Can't add second proxy brick to the volume"); ++ return -EINVAL; ++ } ++ assert("edward-2449", ++ ergo(!is_meta_brick(new), ++ subvol_is_set(new, SUBVOL_HAS_DATA_ROOM))); ++ ++ new->flags |= (1 << SUBVOL_IS_PROXY); ++ } ++ ret = vol->vol_plug->add_brick(vol, new); ++ if (ret) { ++ /* ++ * operation of adding a brick should be repeated ++ * in regular context ++ */ ++ if (activated_here) { ++ reiser4_deactivate_subvol(sb, new); ++ reiser4_unregister_subvol(new); ++ } ++ return ret; ++ } ++ /* ++ * new volume configuration has been written to disk, ++ * so release all volinfo jnodes - they are not needed ++ * any more ++ */ ++ release_volinfo_nodes(&vol->volinfo[CUR_VOL_CONF], 0); ++ clear_bit(SUBVOL_IS_ORPHAN, &new->flags); ++ ++ if (!(args->flags & COMPLETE_WITH_BALANCE)) ++ return 0; ++ ++ ret = vol->vol_plug->balance_volume(sb, 0); ++ if (ret) ++ return ret; ++ /* clear unbalanced status on disk */ ++ ++ reiser4_volume_clear_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ return force_commit_current_atom(); ++} ++ ++static void reiser4_detach_brick(reiser4_subvol *victim) ++{ ++ struct ctx_brick_info *cbi; ++ reiser4_context *ctx = get_current_context(); ++ struct rb_root *root = &ctx->bricks_info; ++ reiser4_super_info_data *sbinfo = get_current_super_private(); ++ ++ cbi = find_context_brick_info(ctx, victim->id); ++ ++ assert("edward-2257", cbi != NULL); ++ ++ __grabbed2free(cbi, sbinfo, cbi->grabbed_blocks, victim); ++ ++ rb_erase(&cbi->node, root); ++ RB_CLEAR_NODE(&cbi->node); ++ free_context_brick_info(cbi); ++ ++ victim->id = INVALID_SUBVOL_ID; ++ victim->flags |= (1 << SUBVOL_IS_ORPHAN); ++ reiser4_deactivate_subvol(victim->super, victim); ++ reiser4_unregister_subvol(victim); ++} ++ ++static int reiser4_finish_removal(struct super_block *sb, reiser4_volume *vol); ++ ++static int reiser4_remove_brick(struct super_block *sb, ++ struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ reiser4_volume *vol = super_volume(sb); ++ reiser4_subvol *victim; ++ ++ if (reiser4_volume_has_incomplete_removal(sb)) { ++ warning("edward-2168", ++ "Failed to remove brick (%s has incomplete removal)", ++ sb->s_id); ++ return -EBUSY; ++ } ++ victim = find_active_brick(sb, args->d.name); ++ if (!victim) { ++ warning("edward-2149", ++ "Brick %s doesn't belong to volume %s. Can not remove.", ++ args->d.name, ++ reiser4_get_current_sb()->s_id); ++ return -EINVAL; ++ } ++ ret = vol->vol_plug->remove_brick(vol, victim); ++ if (ret) ++ return ret; ++ printk("reiser4 (%s): Brick %s scheduled for removal.\n", ++ sb->s_id, victim->name); ++ ++ release_volinfo_nodes(&vol->volinfo[CUR_VOL_CONF], 0); ++ ++ return reiser4_finish_removal(sb, vol); ++} ++ ++static int reiser4_scale_volume(struct super_block *sb, ++ struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ reiser4_volume *vol = super_volume(sb); ++ ++ if (reiser4_volume_has_incomplete_removal(sb)) { ++ warning("edward-2168", ++ "Failed to scale volume %s with incomplete removal)", ++ sb->s_id); ++ return -EBUSY; ++ } ++ if (args->s.val == 0) ++ return 0; ++ ret = super_volume(sb)->vol_plug->scale_volume(sb, args->s.val); ++ if (ret) ++ return ret; ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ /* ++ * write unbalanced status to disk ++ */ ++ ret = force_commit_current_atom(); ++ if (ret) ++ return ret; ++ /* ++ * new volume configuration has been written to disk, ++ * so release all volinfo jnodes - they are not needed ++ * any more ++ */ ++ release_volinfo_nodes(&vol->volinfo[CUR_VOL_CONF], 0); ++ ++ printk("reiser4 (%s): Volume has beed scaled in %u times.", ++ sb->s_id, 1 << args->s.val); ++ ++ if (!(args->flags & COMPLETE_WITH_BALANCE)) ++ return 0; ++ ++ ret = vol->vol_plug->balance_volume(sb, 0); ++ if (ret) ++ return ret; ++ /* clear unbalanced status on disk */ ++ ++ reiser4_volume_clear_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ return force_commit_current_atom(); ++} ++ ++/** ++ * We allow more than one balancing threads on the same volume. Note, however, ++ * that it would be inefficient: others will be always going after one leader ++ * without doing useful work. ++ * Pre-condition: volume is read locked ++ */ ++static int reiser4_balance_volume(struct super_block *sb, u32 flags) ++{ ++ reiser4_volume *vol = super_volume(sb); ++ int ret; ++ ++ ret = vol->vol_plug->balance_volume(sb, flags); ++ if (ret) ++ return ret; ++ reiser4_volume_clear_unbalanced(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ return ret; ++ return force_commit_current_atom(); ++} ++ ++/** ++ * Pre-condition: exclusive access to the volume should be held ++ */ ++static int reiser4_finish_removal(struct super_block *sb, reiser4_volume *vol) ++{ ++ int ret; ++ reiser4_subvol *victim; ++ ++ if (!reiser4_volume_has_incomplete_removal(sb)) ++ return 0; ++ ++ victim = vol->victim; ++ if (!victim) ++ goto cleanup; ++ if (reiser4_volume_is_unbalanced(sb)) { ++ /* ++ * Move out all data blocks from @victim to the ++ * remaining bricks. After balancing completion ++ * the @victim shoudn't contain busy data blocks, ++ * so we have to ignore immobile ststus of files ++ */ ++ ret = vol->vol_plug->balance_volume(sb, ++ VBF_MIGRATE_ALL | VBF_CLR_IMMOBILE); ++ if (ret) ++ goto error; ++ reiser4_volume_clear_unbalanced(sb); ++ } ++ /* ++ * at this point volume must have two distribution configs: ++ * old and new ones ++ */ ++ assert("edward-2258", vol->new_conf != NULL); ++ ++ ret = vol->vol_plug->remove_brick_tail(vol, victim); ++ if (ret) ++ goto error; ++ assert("edward-2471", vol->new_conf == NULL); ++ cleanup: ++ assert("edward-2259", vol->victim == NULL); ++ ++ if (victim && !is_meta_brick(victim)) ++ /* Goodbye! */ ++ reiser4_detach_brick(victim); ++ ++ reiser4_volume_clear_incomplete_removal(sb); ++ ret = capture_brick_super(get_meta_subvol()); ++ if (ret) ++ goto error; ++ ret = force_commit_current_atom(); ++ if (ret) ++ goto error; ++ printk("reiser4 (%s): Removal completed.\n", sb->s_id); ++ return 0; ++ error: ++ reiser4_volume_set_incomplete_removal(sb); ++ warning("", "Failed to complete brick removal on %s.", sb->s_id); ++ return ret; ++} ++ ++static int inode_set_immobile(struct inode *inode) ++{ ++ if (reiser4_inode_get_flag(inode, REISER4_FILE_IMMOBILE)) ++ return 0; ++ if (reserve_update_sd_common(inode)) ++ return RETERR(-ENOSPC); ++ ++ reiser4_inode_set_flag(inode, REISER4_FILE_IMMOBILE); ++ return reiser4_update_sd(inode); ++} ++ ++int inode_clr_immobile(struct inode *inode) ++{ ++ if (!reiser4_inode_get_flag(inode, REISER4_FILE_IMMOBILE)) ++ return 0; ++ if (reserve_update_sd_common(inode)) ++ return RETERR(-ENOSPC); ++ ++ reiser4_inode_clr_flag(inode, REISER4_FILE_IMMOBILE); ++ return reiser4_update_sd(inode); ++} ++ ++/** ++ * Pre-condition: brick_removal_sem should be down for read ++ */ ++static int reiser4_migrate_file(struct file *file, u64 dst_idx) ++{ ++ int ret; ++ struct inode *inode = file_inode(file); ++ struct super_block *sb = inode->i_sb; ++ ++ /* ++ * We allow file migration on volumes with incompletely removed brick ++ */ ++ ret = super_vol_plug(sb)->migrate_file(inode, dst_idx); ++ ++ if (ret == 0 && ((file->f_flags & O_SYNC) || IS_SYNC(inode))) { ++ reiser4_txn_restart_current(); ++ grab_space_enable(); ++ ret = reiser4_sync_file_common(file, 0, LONG_MAX, ++ 0 /* data and stat data */); ++ if (ret) ++ warning("edward-2463", "failed to sync file %llu", ++ (unsigned long long)get_inode_oid(inode)); ++ } ++ return ret; ++} ++ ++/** ++ * Reiser4 off-line volume operations (no FS are mounted). ++ * This doesn't spawn transactions and executes not in reiser4 context. ++ */ ++int reiser4_offline_op(struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ ++ switch(args->opcode) { ++ case REISER4_REGISTER_BRICK: ++ ret = reiser4_register_brick(args); ++ break; ++ case REISER4_UNREGISTER_BRICK: ++ ret = reiser4_unregister_brick(args); ++ break; ++ case REISER4_VOLUME_HEADER: ++ ret = reiser4_volume_header(args); ++ break; ++ case REISER4_BRICK_HEADER: ++ ret = reiser4_brick_header(args); ++ break; ++ default: ++ warning("", "Unsupported off-line volume operation %d", ++ args->opcode); ++ ret = -ENOTTY; ++ break; ++ } ++ return ret; ++} ++ ++/** ++ * Reiser4 on-line volume operations (on mounted volumes). ++ * Spawn transactions and performed in reiser4 context. ++ */ ++int reiser4_volume_op_dir(struct file *file, struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ struct super_block *sb = file_inode(file)->i_sb; ++ reiser4_volume *vol = super_volume(sb); ++ ++ switch(args->opcode) { ++ case REISER4_PRINT_VOLUME: ++ if (!down_read_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_print_volume(sb, args); ++ up_read(&vol->volume_sem); ++ break; ++ case REISER4_PRINT_BRICK: ++ if (!down_read_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_print_brick(sb, args); ++ up_read(&vol->volume_sem); ++ break; ++ case REISER4_RESIZE_BRICK: ++ if (!down_write_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_resize_brick(sb, args); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_ADD_BRICK: ++ if (!down_write_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_add_brick(sb, args, 0); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_ADD_PROXY: ++ if (!down_write_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_add_brick(sb, args, 1); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_REMOVE_BRICK: ++ if (!down_write_trylock(&vol->volume_sem)) ++ goto busy; ++ if (!down_write_trylock(&vol->brick_removal_sem)) { ++ up_write(&vol->volume_sem); ++ goto busy; ++ } ++ ret = reiser4_remove_brick(sb, args); ++ up_write(&vol->brick_removal_sem); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_FINISH_REMOVAL: ++ down_write(&vol->volume_sem); ++ down_write(&vol->brick_removal_sem); ++ ret = reiser4_finish_removal(sb, vol); ++ up_write(&vol->brick_removal_sem); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_SCALE_VOLUME: ++ if (!down_write_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_scale_volume(sb, args); ++ up_write(&vol->volume_sem); ++ break; ++ case REISER4_BALANCE_VOLUME: ++ if (!down_read_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_balance_volume(sb, 0); ++ up_read(&vol->volume_sem); ++ break; ++ case REISER4_RESTORE_REGULAR_DST: ++ if (!down_read_trylock(&vol->volume_sem)) ++ goto busy; ++ ret = reiser4_balance_volume(sb, ++ VBF_MIGRATE_ALL | VBF_CLR_IMMOBILE); ++ up_read(&vol->volume_sem); ++ break; ++ default: ++ warning("edward-1950", ++ "%s: volume operation %d is unsupported by directories", ++ sb->s_id, args->opcode); ++ ret = RETERR(-ENOTTY); ++ break; ++ } ++ return ret; ++ busy: ++ warning("", "Operation %d failed: volume %s is busy", ++ args->opcode, sb->s_id); ++ return RETERR(-EBUSY); ++} ++ ++int reiser4_volume_op_file(struct file *file, struct reiser4_vol_op_args *args) ++{ ++ int ret; ++ struct super_block *sb = file_inode(file)->i_sb; ++ reiser4_volume *vol = super_volume(sb); ++ ++ switch(args->opcode) { ++ case REISER4_MIGRATE_FILE: ++ /* ++ * make sure that bricks won't be evicted during file migration ++ */ ++ down_read(&vol->brick_removal_sem); ++ ret = reiser4_migrate_file(file, args->s.brick_idx); ++ up_read(&vol->brick_removal_sem); ++ break; ++ case REISER4_SET_FILE_IMMOBILE: ++ ret = inode_set_immobile(file_inode(file)); ++ break; ++ case REISER4_CLR_FILE_IMMOBILE: ++ ret = inode_clr_immobile(file_inode(file)); ++ break; ++ default: ++ warning("edward-1952", ++ "%s: volume operation %d is unsupported by regular files", ++ sb->s_id, args->opcode); ++ ret = RETERR(-ENOTTY); ++ break; ++ } ++ return ret; ++} ++ ++long reiser4_ioctl_volume(struct file *file, ++ unsigned int cmd, unsigned long arg, ++ int (*volume_op)(struct file *file, ++ struct reiser4_vol_op_args *args)) ++{ ++ int ret; ++ reiser4_context *ctx; ++ ++ ctx = reiser4_init_context(file_inode(file)->i_sb); ++ if (IS_ERR(ctx)) ++ return PTR_ERR(ctx); ++ ++ switch (cmd) { ++ case REISER4_IOC_VOLUME: { ++ struct reiser4_vol_op_args *op_args; ++ ++ if (!capable(CAP_SYS_ADMIN)) ++ return RETERR(-EPERM); ++ ++ op_args = memdup_user((void __user *)arg, sizeof(*op_args)); ++ if (IS_ERR(op_args)) ++ return PTR_ERR(op_args); ++ ++ ret = volume_op(file, op_args); ++ if (ret) { ++ warning("edward-1899", ++ "On-line volume operation failed (%d)", ret); ++ kfree(op_args); ++ break; ++ } ++ if (copy_to_user((struct reiser4_vol_op_args __user *)arg, ++ op_args, sizeof(*op_args))) ++ ret = RETERR(-EFAULT); ++ kfree(op_args); ++ break; ++ } ++ default: ++ ret = RETERR(-ENOTTY); ++ break; ++ } ++ reiser4_exit_context(ctx); ++ return ret; ++} ++ ++/* ++ * Local variables: ++ * c-indentation-style: "K&R" ++ * mode-name: "LC" ++ * c-basic-offset: 8 ++ * tab-width: 8 ++ * fill-column: 80 ++ * scroll-step: 1 ++ * End: ++ */ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/wander.c linux-5.10.2/fs/reiser4/wander.c +--- linux-5.10.2.orig/fs/reiser4/wander.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/wander.c 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,2210 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Reiser4 Wandering Log */ ++ ++/* ++ * Modified by Edward Shishkin to support Heterogeneous Logical Volumes ++ */ ++ ++/* You should read http://www.namesys.com/txn-doc.html ++ ++ That describes how filesystem operations are performed as atomic ++ transactions, and how we try to arrange it so that we can write most of the ++ data only once while performing the operation atomically. ++ ++ For the purposes of this code, it is enough for it to understand that it ++ has been told a given block should be written either once, or twice (if ++ twice then once to the wandered location and once to the real location). ++ ++ This code guarantees that those blocks that are defined to be part of an ++ atom either all take effect or none of them take effect. ++ ++ The "relocate set" of nodes are submitted to write by the jnode_flush() ++ routine, and the "overwrite set" is submitted by reiser4_write_log(). ++ This is because with the overwrite set we seek to optimize writes, and ++ with the relocate set we seek to cause disk order to correlate with the ++ "parent first order" (preorder). ++ ++ reiser4_write_log() allocates and writes wandered blocks and maintains ++ additional on-disk structures of the atom as wander records (each wander ++ record occupies one block) for storing of the "wandered map" (a table which ++ contains a relation between wandered and real block numbers) and other ++ information which might be needed at transaction recovery time. ++ ++ The wander records are unidirectionally linked into a circle: each wander ++ record contains a block number of the next wander record, the last wander ++ record points to the first one. ++ ++ One wander record (named "tx head" in this file) has a format which is ++ different from the other wander records. The "tx head" has a reference to the ++ "tx head" block of the previously committed atom. Also, "tx head" contains ++ fs information (the free blocks counter, and the oid allocator state) which ++ is logged in a special way . ++ ++ There are two journal control blocks, named journal header and journal ++ footer which have fixed on-disk locations. The journal header has a ++ reference to the "tx head" block of the last committed atom. The journal ++ footer points to the "tx head" of the last flushed atom. The atom is ++ "played" when all blocks from its overwrite set are written to disk the ++ second time (i.e. written to their real locations). ++ ++ NOTE: People who know reiserfs internals and its journal structure might be ++ confused with these terms journal footer and journal header. There is a table ++ with terms of similar semantics in reiserfs (reiser3) and reiser4: ++ ++ REISER3 TERM | REISER4 TERM | DESCRIPTION ++ --------------------+-----------------------+---------------------------- ++ commit record | journal header | atomic write of this record ++ | | ends transaction commit ++ --------------------+-----------------------+---------------------------- ++ journal header | journal footer | atomic write of this record ++ | | ends post-commit writes. ++ | | After successful ++ | | writing of this journal ++ | | blocks (in reiser3) or ++ | | wandered blocks/records are ++ | | free for re-use. ++ --------------------+-----------------------+---------------------------- ++ ++ The atom commit process is the following: ++ ++ 1. The overwrite set is taken from atom's clean list, and its size is ++ counted. ++ ++ 2. The number of necessary wander records (including tx head) is calculated, ++ and the wander record blocks are allocated. ++ ++ 3. Allocate wandered blocks and populate wander records by wandered map. ++ ++ 4. submit write requests for wander records and wandered blocks. ++ ++ 5. wait until submitted write requests complete. ++ ++ 6. update journal header: change the pointer to the block number of just ++ written tx head, submit an i/o for modified journal header block and wait ++ for i/o completion. ++ ++ NOTE: The special logging for bitmap blocks and some reiser4 super block ++ fields makes processes of atom commit, flush and recovering a bit more ++ complex (see comments in the source code for details). ++ ++ The atom playing process is the following: ++ ++ 1. Write atom's overwrite set in-place. ++ ++ 2. Wait on i/o. ++ ++ 3. Update journal footer: change the pointer to block number of tx head ++ block of the atom we currently flushing, submit an i/o, wait on i/o ++ completion. ++ ++ 4. Free disk space which was used for wandered blocks and wander records. ++ ++ After the freeing of wandered blocks and wander records we have that journal ++ footer points to the on-disk structure which might be overwritten soon. ++ Neither the log writer nor the journal recovery procedure use that pointer ++ for accessing the data. When the journal recovery procedure finds the oldest ++ transaction it compares the journal footer pointer value with the "prev_tx" ++ pointer value in tx head, if values are equal the oldest not flushed ++ transaction is found. ++ ++ NOTE on disk space leakage: the information about of what blocks and how many ++ blocks are allocated for wandered blocks, wandered records is not written to ++ the disk because of special logging for bitmaps and some super blocks ++ counters. After a system crash we the reiser4 does not remember those ++ objects allocation, thus we have no such a kind of disk space leakage. ++*/ ++ ++/* Special logging of reiser4 super block fields. */ ++ ++/* There are some reiser4 super block fields (free block count and OID allocator ++ state (number of files and next free OID) which are logged separately from ++ super block to avoid unnecessary atom fusion. ++ ++ So, the reiser4 super block can be not captured by a transaction with ++ allocates/deallocates disk blocks or create/delete file objects. Moreover, ++ the reiser4 on-disk super block is not touched when such a transaction is ++ committed and flushed. Those "counters logged specially" are logged in "tx ++ head" blocks and in the journal footer block. ++ ++ A step-by-step description of special logging: ++ ++ 0. The per-atom information about deleted or created files and allocated or ++ freed blocks is collected during the transaction. The atom's ++ ->nr_objects_created and ->nr_objects_deleted are for object ++ deletion/creation tracking, the numbers of allocated and freed blocks are ++ calculated using atom's delete set and atom's capture list -- all new and ++ relocated nodes should be on atom's clean list and should have JNODE_RELOC ++ bit set. ++ ++ 1. The "logged specially" reiser4 super block fields have their "committed" ++ versions in the reiser4 in-memory super block. They get modified only at ++ atom commit time. The atom's commit thread has an exclusive access to those ++ "committed" fields because the log writer implementation supports only one ++ atom commit a time (there is a per-fs "commit" mutex). At ++ that time "committed" counters are modified using per-atom information ++ collected during the transaction. These counters are stored on disk as a ++ part of tx head block when atom is committed. ++ ++ 2. When the atom is flushed the value of the free block counter and the OID ++ allocator state get written to the journal footer block. A special journal ++ procedure (journal_recover_sb_data()) takes those values from the journal ++ footer and updates the reiser4 in-memory super block. ++ ++ NOTE: That means free block count and OID allocator state are logged ++ separately from the reiser4 super block regardless of the fact that the ++ reiser4 super block has fields to store both the free block counter and the ++ OID allocator. ++ ++ Writing the whole super block at commit time requires knowing true values of ++ all its fields without changes made by not yet committed transactions. It is ++ possible by having their "committed" version of the super block like the ++ reiser4 bitmap blocks have "committed" and "working" versions. However, ++ another scheme was implemented which stores special logged values in the ++ unused free space inside transaction head block. In my opinion it has an ++ advantage of not writing whole super block when only part of it was ++ modified. */ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "page_cache.h" ++#include "wander.h" ++#include "reiser4.h" ++#include "super.h" ++#include "vfs_ops.h" ++#include "writeout.h" ++#include "inode.h" ++#include "entd.h" ++#include "plugin/volume/volume.h" ++ ++#include ++#include /* for struct super_block */ ++#include /* for struct page */ ++#include ++#include /* for struct bio */ ++#include ++ ++static int write_jnodes_contig(jnode *, int, const reiser4_block_nr *, ++ flush_queue_t *, int, reiser4_subvol *); ++/* ++ * Per-logical-volume commit_handle. ++ * This contains infrastructure needed at atom commit time. ++ * See also definition of per-suvbolume commit handle (commit_handle_subvol) ++ */ ++struct commit_handle { ++ __u64 nr_files; ++ __u64 next_oid; ++ __u32 total_tx_size; /* total number of wander records */ ++ __u32 total_overwrite_set_size; ++ reiser4_block_nr total_nr_bitmap; ++ txn_atom *atom; /* the atom which is being committed */ ++ struct super_block *super; /* current super block */ ++}; ++ ++static void init_ch_sub(reiser4_subvol *subv) ++{ ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ ++ assert("edward-1700", list_empty(&ch_sub->overwrite_set)); ++ assert("edward-1701", list_empty(&ch_sub->tx_list)); ++ assert("edward-1702", list_empty(&ch_sub->wander_map)); ++ ++ __init_ch_sub(ch_sub); ++ ch_sub->free_blocks = subv->blocks_free_committed; ++} ++ ++static void init_commit_handle(struct commit_handle *ch, txn_atom *atom, ++ reiser4_subvol *subv) ++{ ++ memset(ch, 0, sizeof(struct commit_handle)); ++ ch->atom = atom; ++ ch->super = reiser4_get_current_sb(); ++ ch->nr_files = get_current_super_private()->nr_files_committed; ++ ch->next_oid = oid_next(ch->super); ++ if (subv) ++ /* ++ * init ch of specified subvolume ++ */ ++ init_ch_sub(subv); ++ else { ++ /* ++ * init ch of all subvolumes ++ */ ++ struct rb_node *node; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ++ init_ch_sub(super_origin(ch->super, abi->brick_id)); ++ } ++ } ++} ++ ++#if REISER4_DEBUG ++static void done_ch_sub(reiser4_subvol *subv) ++{ ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ ++ assert("edward-1703", list_empty(&ch_sub->overwrite_set)); ++ assert("edward-1704", list_empty(&ch_sub->tx_list)); ++ assert("edward-1705", list_empty(&ch_sub->wander_map)); ++} ++#endif ++ ++static void done_commit_handle(struct commit_handle *ch, reiser4_subvol *subv) ++{ ++#if REISER4_DEBUG ++ if (subv) ++ done_ch_sub(subv); ++ else { ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ struct atom_brick_info *abi; ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ++ done_ch_sub(super_origin(ch->super, abi->brick_id)); ++ } ++ } ++#endif ++} ++ ++/* fill journal header block data */ ++static void format_journal_header(struct commit_handle *ch, ++ unsigned subv_id) ++{ ++ reiser4_subvol *subv; ++ struct journal_header *header; ++ jnode *txhead; ++ ++ subv = super_origin(ch->super, subv_id); ++ assert("zam-480", subv->journal_header != NULL); ++ ++ txhead = list_entry(subv->ch.tx_list.next, jnode, capture_link); ++ ++ jload(subv->journal_header); ++ ++ header = (struct journal_header *)jdata(subv->journal_header); ++ assert("zam-484", header != NULL); ++ ++ put_unaligned(cpu_to_le64(*jnode_get_block(txhead)), ++ &header->last_committed_tx); ++ ++ jrelse(subv->journal_header); ++} ++ ++/* fill journal footer block data */ ++static void format_journal_footer(struct commit_handle *ch, ++ reiser4_subvol *subv) ++{ ++ struct journal_footer *footer; ++ jnode *tx_head; ++ struct commit_handle_subvol *ch_sub; ++ ++ ch_sub = &subv->ch; ++ ++ tx_head = list_entry(ch_sub->tx_list.next, jnode, capture_link); ++ ++ assert("zam-494", subv->journal_header != NULL); ++ ++ check_me("zam-691", jload(subv->journal_footer) == 0); ++ ++ footer = (struct journal_footer *)jdata(subv->journal_footer); ++ assert("zam-495", footer != NULL); ++ ++ put_unaligned(cpu_to_le64(*jnode_get_block(tx_head)), ++ &footer->last_flushed_tx); ++ put_unaligned(cpu_to_le64(ch_sub->free_blocks), &footer->free_blocks); ++ ++ put_unaligned(cpu_to_le64(ch->nr_files), &footer->nr_files); ++ put_unaligned(cpu_to_le64(ch->next_oid), &footer->next_oid); ++ ++ jrelse(subv->journal_footer); ++} ++ ++/* wander record capacity depends on current block size */ ++static int wander_record_capacity(const struct super_block *super) ++{ ++ return (super->s_blocksize - ++ sizeof(struct wander_record_header)) / ++ sizeof(struct wander_entry); ++} ++ ++/* ++ * Fill first wander record (tx head) in accordance with supplied given data ++ */ ++static void format_tx_head(struct commit_handle *ch, unsigned subv_id) ++{ ++ jnode *tx_head; ++ jnode *next; ++ struct tx_header *header; ++ struct commit_handle_subvol *ch_sub; ++ reiser4_subvol *subv; ++ ++ subv = super_origin(ch->super, subv_id); ++ ch_sub = &subv->ch; ++ ++ tx_head = list_entry(ch_sub->tx_list.next, jnode, capture_link); ++ assert("zam-692", &ch_sub->tx_list != &tx_head->capture_link); ++ ++ next = list_entry(tx_head->capture_link.next, jnode, capture_link); ++ if (&ch_sub->tx_list == &next->capture_link) ++ next = tx_head; ++ ++ header = (struct tx_header *)jdata(tx_head); ++ ++ assert("zam-460", header != NULL); ++ assert("zam-462", ch->super->s_blocksize >= sizeof(struct tx_header)); ++ ++ memset(jdata(tx_head), 0, (size_t) ch->super->s_blocksize); ++ memcpy(jdata(tx_head), TX_HEADER_MAGIC, TX_HEADER_MAGIC_SIZE); ++ ++ put_unaligned(cpu_to_le32(ch_sub->tx_size), &header->total); ++ put_unaligned(cpu_to_le64(subv->last_committed_tx), &header->prev_tx); ++ put_unaligned(cpu_to_le64(*jnode_get_block(next)), &header->next_block); ++ put_unaligned(cpu_to_le64(ch_sub->free_blocks), &header->free_blocks); ++ put_unaligned(cpu_to_le64(ch->nr_files), &header->nr_files); ++ put_unaligned(cpu_to_le64(ch->next_oid), &header->next_oid); ++} ++ ++/* ++ * prepare ordinary wander record block (fill all service fields) ++ */ ++static void format_wander_record(struct commit_handle *ch, unsigned subv_id, ++ jnode *node, __u32 serial) ++{ ++ jnode *next; ++ struct wander_record_header *LRH; ++ struct commit_handle_subvol *ch_sub; ++ ++ assert("zam-464", node != NULL); ++ ++ ch_sub = &super_origin(ch->super, subv_id)->ch; ++ ++ LRH = (struct wander_record_header *)jdata(node); ++ next = list_entry(node->capture_link.next, jnode, capture_link); ++ ++ if (&ch_sub->tx_list == &next->capture_link) ++ next = list_entry(ch_sub->tx_list.next, jnode, capture_link); ++ ++ assert("zam-465", LRH != NULL); ++ assert("zam-463", ++ ch->super->s_blocksize > sizeof(struct wander_record_header)); ++ ++ memset(jdata(node), 0, (size_t) ch->super->s_blocksize); ++ memcpy(jdata(node), WANDER_RECORD_MAGIC, WANDER_RECORD_MAGIC_SIZE); ++ ++ put_unaligned(cpu_to_le32(ch_sub->tx_size), &LRH->total); ++ put_unaligned(cpu_to_le32(serial), &LRH->serial); ++ put_unaligned(cpu_to_le64(*jnode_get_block(next)), &LRH->next_block); ++} ++ ++/** ++ * add one wandered map entry to formatted wander record ++ */ ++static void store_entry(jnode *node, int index, ++ const reiser4_block_nr *a, const reiser4_block_nr *b) ++{ ++ char *data; ++ struct wander_entry *pairs; ++ ++ data = jdata(node); ++ assert("zam-451", data != NULL); ++ ++ pairs = ++ (struct wander_entry *)(data + sizeof(struct wander_record_header)); ++ ++ put_unaligned(cpu_to_le64(*a), &pairs[index].original); ++ put_unaligned(cpu_to_le64(*b), &pairs[index].wandered); ++} ++ ++/* ++ * currently, wander record contains only wandered map, ++ * which depends on overwrite set size ++ */ ++static void get_tx_size(struct commit_handle *ch) ++{ ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = &super_origin(ch->super, abi->brick_id)->ch; ++ ++ assert("zam-695", ch_sub->tx_size == 0); ++ ++ if (ch_sub->overwrite_set_size == 0) ++ continue; ++ /* ++ * count all ordinary wander records ++ * ( - 1) / + 1 ++ * and add one for tx head block ++ */ ++ ch_sub->tx_size = ++ (ch_sub->overwrite_set_size - 1)/ ++ wander_record_capacity(ch->super) + 2; ++ ch->total_tx_size += ch_sub->tx_size; ++ } ++} ++ ++/* ++ * A special structure for using in store_wmap_actor() ++ * for saving its state between calls ++ */ ++struct store_wmap_params { ++ jnode *cur; /* jnode of current wander record to fill */ ++ int idx; /* free element index in wander record */ ++ int capacity; /* capacity */ ++#if REISER4_DEBUG ++ struct list_head *tx_list; ++#endif ++}; ++ ++/* ++ * an actor for use in blocknr_set_iterator routine ++ * which populates the list of pre-formatted wander ++ * records by wandered map info ++ */ ++static int store_wmap_actor(txn_atom *atom UNUSED_ARG, ++ const reiser4_block_nr *a, ++ const reiser4_block_nr *b, ++ __u32 subv_id, void *data) ++{ ++ struct store_wmap_params *params = data; ++ ++ if (params->idx >= params->capacity) { ++ /* ++ * a new wander record should be taken from the tx_list ++ */ ++ params->cur = list_entry(params->cur->capture_link.next, ++ jnode, capture_link); ++ assert("zam-454", ++ params->tx_list != ¶ms->cur->capture_link); ++ ++ params->idx = 0; ++ } ++ store_entry(params->cur, params->idx, a, b); ++ params->idx++; ++ ++ return 0; ++} ++ ++/** ++ * This function is called after Relocate set gets written to disk, Overwrite ++ * set is written to wandered locations and all wander records are written ++ * also. Updated journal header blocks contains a pointer (block number) to ++ * first wander record of the just written transaction ++ */ ++static int update_journal_header(struct commit_handle *ch, u32 subv_id) ++{ ++ int ret; ++ reiser4_subvol *subv = super_origin(ch->super, subv_id); ++ jnode *jh = subv->journal_header; ++ jnode *head = list_entry(subv->ch.tx_list.next, jnode, capture_link); ++ ++ format_journal_header(ch, subv_id); ++ ++ ret = write_jnodes_contig(jh, 1, jnode_get_block(jh), NULL, ++ WRITEOUT_FLUSH_FUA, subv); ++ if (ret) ++ return ret; ++ ++ ret = jwait_io(jh, WRITE); ++ if (ret) ++ return ret; ++ ++ subv->last_committed_tx = *jnode_get_block(head); ++ return 0; ++} ++ ++/** ++ * This function is called after write-back is finished. We update journal ++ * footer block and free blocks which were occupied by wandered blocks and ++ * transaction wander records ++ */ ++static int update_journal_footer(struct commit_handle *ch, reiser4_subvol *subv) ++{ ++ int ret; ++ jnode *jf = subv->journal_footer; ++ ++ format_journal_footer(ch, subv); ++ ++ ret = write_jnodes_contig(jf, 1, jnode_get_block(jf), NULL, ++ WRITEOUT_FLUSH_FUA, subv); ++ if (ret) ++ return ret; ++ ++ ret = jwait_io(jf, WRITE); ++ if (ret) ++ return ret; ++ return 0; ++} ++ ++/* ++ * free block numbers of wander records of already written in place transaction ++ */ ++static void dealloc_tx_list(struct commit_handle *ch) ++{ ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ reiser4_subvol *subv; ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ subv = current_origin(abi->brick_id); ++ ch_sub = &subv->ch; ++ ++ while (!list_empty(&ch_sub->tx_list)) { ++ jnode *cur = list_entry(ch_sub->tx_list.next, ++ jnode, ++ capture_link); ++ ++ list_del(&cur->capture_link); ++ ON_DEBUG(INIT_LIST_HEAD(&cur->capture_link)); ++ reiser4_dealloc_block(jnode_get_block(cur), 0, ++ BA_DEFER | BA_FORMATTED, subv); ++ unpin_jnode_data(cur); ++ reiser4_drop_io_head(cur); ++ } ++ } ++} ++ ++/* ++ * An actor for use in block_nr_iterator() routine which frees wandered blocks ++ * from atom's overwrite set ++ */ ++static int dealloc_wmap_actor(txn_atom *atom UNUSED_ARG, ++ const reiser4_block_nr *a UNUSED_ARG, ++ const reiser4_block_nr *b, __u32 subv_id, ++ void *data UNUSED_ARG) ++{ ++ assert("zam-499", b != NULL); ++ assert("zam-500", *b != 0); ++ assert("zam-501", !reiser4_blocknr_is_fake(b)); ++ ++ reiser4_dealloc_block(b, 0, BA_DEFER | BA_FORMATTED, ++ current_origin(subv_id)); ++ return 0; ++} ++ ++/** ++ * Free wandered block locations. ++ * Pre-condition: Transaction has been played (that is, all blocks ++ * from the OVERWRITE set were overwritten successfully. ++ */ ++static void dealloc_wmap(struct commit_handle *ch) ++{ ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ assert("zam-696", ch->atom != NULL); ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = &super_origin(ch->super, abi->brick_id)->ch; ++ ++ blocknr_set_iterator(atom, ++ &ch_sub->wander_map, ++ dealloc_wmap_actor, NULL, 1, ++ abi->brick_id); ++ } ++} ++ ++static int alloc_wander_blocks(int count, reiser4_block_nr *start, int *len, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ reiser4_blocknr_hint hint; ++ reiser4_block_nr wide_len = count; ++ ++ /* FIXME-ZAM: A special policy needed for allocation of wandered blocks ++ ZAM-FIXME-HANS: yes, what happened to our discussion of using a fixed ++ reserved allocation area so as to get the best qualities of fixed ++ journals? */ ++ reiser4_blocknr_hint_init(&hint); ++ hint.block_stage = BLOCK_GRABBED; ++ ++ ret = reiser4_alloc_blocks(&hint, start, &wide_len, ++ BA_FORMATTED | BA_USE_DEFAULT_SEARCH_START, ++ subv); ++ *len = (int)wide_len; ++ return ret; ++} ++ ++/* ++ * roll back changes made before issuing BIO in the case of IO error. ++ */ ++static void undo_bio(struct bio *bio) ++{ ++ struct bio_vec *bvec; ++ struct bvec_iter_all iter_all; ++ ++ bio_for_each_segment_all(bvec, bio, iter_all) { ++ struct page *pg; ++ jnode *node; ++ ++ pg = bvec->bv_page; ++ end_page_writeback(pg); ++ node = jprivate(pg); ++ spin_lock_jnode(node); ++ JF_CLR(node, JNODE_WRITEBACK); ++ JF_SET(node, JNODE_DIRTY); ++ spin_unlock_jnode(node); ++ } ++ bio_put(bio); ++} ++ ++/** ++ * release resources aquired in get_overwrite_set() ++ */ ++static void put_overwrite_set(struct commit_handle *ch) ++{ ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ jnode *cur; ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = &super_origin(ch->super, abi->brick_id)->ch; ++ ++ list_for_each_entry(cur, &ch_sub->overwrite_set, capture_link) ++ jrelse_tail(cur); ++ reiser4_invalidate_list(&ch_sub->overwrite_set); ++ } ++} ++ ++void check_overwrite_set_subv(reiser4_subvol *subv) ++{ ++ jnode *cur; ++ ++ list_for_each_entry(cur, &subv->ch.overwrite_set, capture_link) ++ assert("edward-1706", cur->subvol == subv); ++} ++ ++void check_overwrite_set(txn_atom *atom) ++{ ++ struct rb_node *node; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ++ check_overwrite_set_subv(current_origin(abi->brick_id)); ++ } ++} ++ ++/* ++ * Scan atom't overwrite set and do the following: ++ * . move every jnode to overwrite set of respective subvolume; ++ * . count total number of nodes in all overwrite sets; ++ * . grab disk space for wandered blocks allocation; ++ * . count bitmap and other not leaf nodes which wandered blocks ++ * allocation we have to grab space for. ++ */ ++int get_overwrite_set(struct commit_handle *ch) ++{ ++ int ret; ++ jnode *cur; ++ struct list_head *overw_set; ++ s64 rest_flush_reserved; ++#if REISER4_DEBUG ++ u64 nr_formatted_leaves = 0; ++ u64 nr_unformatted_leaves = 0; ++#endif ++ overw_set = ATOM_OVRWR_LIST(ch->atom); ++ cur = list_entry(overw_set->next, jnode, capture_link); ++ ++ while (!list_empty(overw_set)) { ++ jnode *next; ++ struct reiser4_subvol *subv; ++ struct commit_handle_subvol *ch_sub; ++ struct list_head *subv_overw_set; ++ ++ next = list_entry(cur->capture_link.next, jnode, capture_link); ++ subv = cur->subvol; ++ ch_sub = &subv->ch; ++ subv_overw_set = &ch_sub->overwrite_set; ++ /* ++ * Count bitmap blocks for getting correct statistics what ++ * number of blocks were cleared by the transaction commit ++ */ ++ if (jnode_get_type(cur) == JNODE_BITMAP) { ++ ch_sub->nr_bitmap++; ++ ch->total_nr_bitmap++; ++ } ++ assert("zam-939", JF_ISSET(cur, JNODE_OVRWR) || ++ jnode_get_type(cur) == JNODE_BITMAP); ++ ++ if (jnode_is_znode(cur) && znode_above_root(JZNODE(cur))) { ++ /* ++ * This is a super-block captured in rare events (like ++ * the final commit at the end of mount session (see ++ * release_format40()->capture_brick_super(), also ++ * see comments at reiser4_journal_recover_sb_data()). ++ * ++ * We replace fake znode by another (real) znode which ++ * is suggested by disk_layout plugin ++ */ ++ struct super_block *s = reiser4_get_current_sb(); ++ ++ if (subv->df_plug->log_super) { ++ jnode *sj; ++ ++ sj = subv->df_plug->log_super(s, subv); ++ assert("zam-593", sj != NULL); ++ ++ if (IS_ERR(sj)) ++ return PTR_ERR(sj); ++ ++ spin_lock_jnode(sj); ++ JF_SET(sj, JNODE_OVRWR); ++ /* ++ * put the new jnode right to overwrite ++ * set of respective subvolume ++ */ ++ insert_into_subv_ovrwr_list(subv, sj, ch->atom); ++ spin_unlock_jnode(sj); ++ jload_gfp(sj, reiser4_ctx_gfp_mask_get(), 0); ++ ++ ch_sub->overwrite_set_size++; ++ ch->total_overwrite_set_size++; ++ } ++ spin_lock_jnode(cur); ++ reiser4_uncapture_block(cur); ++ jput(cur); ++ ++ } else { ++ int ret; ++ ch_sub->overwrite_set_size++; ++ ch->total_overwrite_set_size++; ++ /* ++ * move jnode to the overwrite list of ++ * respective subvolume ++ */ ++ list_move(&cur->capture_link, subv_overw_set); ++ ret = jload_gfp(cur, reiser4_ctx_gfp_mask_get(), 0); ++ if (ret) ++ reiser4_panic("zam-783", ++ "cannot load jnode (ret = %d)\n", ++ ret); ++ } ++ /* ++ * Count not leaves here because we have to grab disk space ++ * for wandered blocks. They were not counted as "flush ++ * reserved". Counting should be done _after_ nodes are pinned ++ * into memory by jload(). ++ */ ++ if (!jnode_is_leaf(cur)) { ++ /* ++ * Grab space for writing (wandered blocks) ++ * of not leaves found in overwrite set ++ */ ++ ret = reiser4_grab_space_force(1, BA_RESERVED, ++ jnode_get_subvol(cur)); ++ if (ret) ++ return ret; ++ } ++ else { ++#if REISER4_DEBUG ++ if (jnode_is_znode(cur)) ++ nr_formatted_leaves++; ++ else ++ nr_unformatted_leaves++; ++#endif ++ JF_CLR(cur, JNODE_FLUSH_RESERVED); ++ } ++ cur = next; ++ } ++ /* ++ * All needed disk space reserved for allocation of wandered ++ * blocks of leaf nodes ("flush reserved") has changed its status ++ * to "used". Return the rest to "grabbed" to be released later. ++ */ ++ rest_flush_reserved = all_flush_reserved2grabbed(ch->atom); ++ if (rest_flush_reserved < 0) ++ return rest_flush_reserved; ++ ++ assert("zam-940", ++ nr_formatted_leaves + nr_unformatted_leaves <= ++ rest_flush_reserved); ++ ++ check_overwrite_set(ch->atom); ++ return ch->total_overwrite_set_size; ++} ++ ++/** ++ * write_jnodes_contig - submit write request. ++ * @head: ++ * @first: first jnode of the list ++ * @nr: number of jnodes on the list ++ * @block_p: ++ * @fq: ++ * @flags: used to decide whether page is to get PG_reclaim flag ++ * ++ * Submits a write request for @nr jnodes beginning from the @first, other ++ * jnodes are after the @first on the double-linked "capture" list. All jnodes ++ * will be written to the disk region of @nr blocks starting with @block_p block ++ * number. If @fq is not NULL it means that waiting for i/o completion will be ++ * done more efficiently by using flush_queue_t objects. ++ * This function is the one which writes list of jnodes in batch mode. It does ++ * all low-level things as bio construction and page states manipulation. ++ * ++ * ZAM-FIXME-HANS: brief me on why this function exists, and why bios are ++ * aggregated in this function instead of being left to the layers below ++ * ++ * FIXME: ZAM->HANS: What layer are you talking about? Can you point me to that? ++ * Why that layer needed? Why BIOs cannot be constructed here? ++ */ ++static int write_jnodes_contig(jnode *first, int nr, ++ const reiser4_block_nr *block_p, ++ flush_queue_t *fq, int flags, ++ reiser4_subvol *subv) ++{ ++ struct super_block *super = reiser4_get_current_sb(); ++ int op_flags = (flags & WRITEOUT_FLUSH_FUA) ? REQ_PREFLUSH | REQ_FUA : 0; ++ jnode *cur = first; ++ reiser4_block_nr block; ++ ++ assert("zam-571", first != NULL); ++ assert("zam-572", block_p != NULL); ++ assert("zam-570", nr > 0); ++ ++ if (subv == NULL) ++ subv = first->subvol; ++ block = *block_p; ++ ++ while (nr > 0) { ++ struct bio *bio; ++ int nr_blocks = min(nr, BIO_MAX_PAGES); ++ int i; ++ int nr_used; ++ ++ bio = bio_alloc(GFP_NOIO, nr_blocks); ++ if (!bio) ++ return RETERR(-ENOMEM); ++ ++ bio_set_dev(bio, subv->bdev); ++ bio->bi_iter.bi_sector = block * (super->s_blocksize >> 9); ++ for (nr_used = 0, i = 0; i < nr_blocks; i++) { ++ struct page *pg; ++ ++ pg = jnode_page(cur); ++ assert("zam-573", pg != NULL); ++ ++ get_page(pg); ++ ++ lock_and_wait_page_writeback(pg); ++ ++ if (!bio_add_page(bio, pg, super->s_blocksize, 0)) { ++ /* ++ * underlying device is satiated. Stop adding ++ * pages to the bio. ++ */ ++ unlock_page(pg); ++ put_page(pg); ++ break; ++ } ++ ++ spin_lock_jnode(cur); ++ assert("nikita-3166", ++ pg->mapping == jnode_get_mapping(cur)); ++ assert("zam-912", !JF_ISSET(cur, JNODE_WRITEBACK)); ++#if REISER4_DEBUG ++ spin_lock(&cur->load); ++ assert("nikita-3165", ++ ergo(is_origin(subv), !jnode_is_releasable(cur))); ++ spin_unlock(&cur->load); ++#endif ++ JF_SET(cur, JNODE_WRITEBACK); ++ JF_CLR(cur, JNODE_DIRTY); ++ ON_DEBUG(cur->written++); ++ ++ assert("edward-1647", ++ ergo(jnode_is_znode(cur), JF_ISSET(cur, JNODE_PARSED))); ++ spin_unlock_jnode(cur); ++ /* ++ * update checksum ++ */ ++ if (jnode_is_znode(cur) && is_origin(subv)) { ++ zload(JZNODE(cur)); ++ if (node_plugin_by_node(JZNODE(cur))->csum) ++ node_plugin_by_node(JZNODE(cur))->csum(JZNODE(cur), 0); ++ zrelse(JZNODE(cur)); ++ } ++ ClearPageError(pg); ++ set_page_writeback(pg); ++ ++ if (get_current_context()->entd) { ++ /* this is ent thread */ ++ entd_context *ent = get_entd_context(super); ++ struct wbq *rq, *next; ++ ++ spin_lock(&ent->guard); ++ ++ if (pg == ent->cur_request->page) { ++ /* ++ * entd is called for this page. This ++ * request is not in th etodo list ++ */ ++ ent->cur_request->written = 1; ++ } else { ++ /* ++ * if we have written a page for which writepage ++ * is called for - move request to another list. ++ */ ++ list_for_each_entry_safe(rq, next, &ent->todo_list, link) { ++ assert("", rq->magic == WBQ_MAGIC); ++ if (pg == rq->page) { ++ /* ++ * remove request from ++ * entd's queue, but do ++ * not wake up a thread ++ * which put this ++ * request ++ */ ++ list_del_init(&rq->link); ++ ent->nr_todo_reqs --; ++ list_add_tail(&rq->link, &ent->done_list); ++ ent->nr_done_reqs ++; ++ rq->written = 1; ++ break; ++ } ++ } ++ } ++ spin_unlock(&ent->guard); ++ } ++ ++ clear_page_dirty_for_io(pg); ++ ++ unlock_page(pg); ++ ++ cur = list_entry(cur->capture_link.next, jnode, capture_link); ++ nr_used++; ++ } ++ if (nr_used > 0) { ++ assert("nikita-3453", ++ bio->bi_iter.bi_size == super->s_blocksize * nr_used); ++ ++ /* Check if we are allowed to write at all */ ++ if (sb_rdonly(super)) ++ undo_bio(bio); ++ else { ++ add_fq_to_bio(fq, bio); ++ bio_get(bio); ++ bio_set_op_attrs(bio, WRITE, op_flags); ++ submit_bio(bio); ++ bio_put(bio); ++ } ++ ++ block += nr_used - 1; ++ if (is_origin(subv)) ++ update_blocknr_hint_default(super, subv, &block); ++ block += 1; ++ } else { ++ bio_put(bio); ++ } ++ nr -= nr_used; ++ } ++ ++ return 0; ++} ++ ++/** ++ * Submit a list of jnodes against specified subvolume @subv (it can be ++ * original subvolume, or replica). ++ * This procedure recovers extents (contiguous sequences of disk block ++ * numbers) in a given list of jnodes and submits write requests on this ++ * per-extent basis. ++ * ++ * @head: the list of jnodes to submit ++ */ ++int write_jnode_list_subv(struct list_head *head, flush_queue_t *fq, ++ long *nr_submitted, int flags, reiser4_subvol *subv) ++{ ++ int ret; ++ struct list_head *beg = head->next; ++ ++ while (head != beg) { ++ int nr = 1; ++ struct list_head *cur = beg->next; ++ ++ while (head != cur) { ++ assert("edward-1707", ++ jnode_by_link(beg)->subvol == ++ jnode_by_link(cur)->subvol); ++ ++ if (*jnode_get_block(jnode_by_link(cur)) != ++ *jnode_get_block(jnode_by_link(beg)) + nr) ++ break; ++ ++nr; ++ cur = cur->next; ++ } ++ ret = write_jnodes_contig(jnode_by_link(beg), nr, ++ jnode_get_block(jnode_by_link(beg)), ++ fq, flags, subv); ++ if (ret) ++ return ret; ++ if (nr_submitted) ++ *nr_submitted += nr; ++ beg = cur; ++ } ++ return 0; ++} ++ ++/** ++ * Submit a list of jnodes. ++ * Every jnode is submitted against an origimal subvolume and all its ++ * replicas. ++ * This procedure recovers extents (contiguous sequences of disk block ++ * numbers) in a given list of jnodes and submits write requests on this ++ * per-extent basis. ++ * ++ * @head: list of jnodes to submit. ++ */ ++int write_jnode_list(struct list_head *head, flush_queue_t *fq, ++ long *nr_submitted, int flags) ++{ ++ int ret; ++ struct list_head *beg = head->next; ++ ++ while (head != beg) { ++ int nr = 1; ++ u32 mirr_id; ++ struct list_head *cur = beg->next; ++ reiser4_subvol *subv = jnode_get_subvol(jnode_by_link(beg)); ++ ++ while (head != cur) { ++ if (jnode_get_subvol(jnode_by_link(cur)) != ++ jnode_get_subvol(jnode_by_link(beg))) ++ break; ++ if (*jnode_get_block(jnode_by_link(cur)) != ++ *jnode_get_block(jnode_by_link(beg)) + nr) ++ break; ++ ++nr; ++ cur = cur->next; ++ } ++ /* ++ * submit recovered extent against original subvolume ++ * and all its replicas ++ */ ++ for_each_mirror(subv->id, mirr_id) { ++ reiser4_subvol *mirror; ++ ++ mirror = current_mirror(subv->id, mirr_id); ++ ++ ret = write_jnodes_contig(jnode_by_link(beg), nr, ++ jnode_get_block(jnode_by_link(beg)), ++ fq, flags, mirror); ++ if (ret) ++ return ret; ++ } ++#if 0 ++ notice("edward-1875", ++ "subvol %llu: written extent (%llu, %llu)", ++ (unsigned long long)subv->id, ++ (unsigned long long)*jnode_get_block(jnode_by_link(beg)), ++ (unsigned long long)nr); ++#endif ++ if (nr_submitted) ++ *nr_submitted += nr; ++ beg = cur; ++ } ++ return 0; ++} ++ ++/* ++ * add given wandered mapping to atom's wandered map ++ */ ++static int add_region_to_wmap(jnode *cur, int len, ++ const reiser4_block_nr *block_p, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ blocknr_set_entry *new_bsep = NULL; ++ reiser4_block_nr block; ++ ++ txn_atom *atom; ++ ++ assert("zam-568", block_p != NULL); ++ block = *block_p; ++ assert("zam-569", len > 0); ++ ++ while ((len--) > 0) { ++ do { ++ atom = get_current_atom_locked(); ++ assert("zam-536", ++ !reiser4_blocknr_is_fake(jnode_get_block(cur))); ++ ++ ret = blocknr_set_add_pair(atom, ++ &subv->ch.wander_map, ++ &new_bsep, ++ jnode_get_block(cur), ++ &block, subv->id); ++ } while (ret == -E_REPEAT); ++ ++ if (ret) { ++ /* ++ * deallocate blocks which were not added ++ * to wandered map ++ */ ++ reiser4_block_nr wide_len = len; ++ ++ reiser4_dealloc_blocks(&block, &wide_len, ++ BLOCK_NOT_COUNTED, ++ BA_FORMATTED, /* formatted, ++ without defer */ ++ subv); ++ return ret; ++ } ++ spin_unlock_atom(atom); ++ ++ cur = list_entry(cur->capture_link.next, jnode, capture_link); ++ ++block; ++ } ++ return 0; ++} ++ ++/** ++ * Allocate temporal ("wandering") disk addresses for specified OVERWRITE set ++ * and immediately submit IOs for them. ++ * We assume that current atom is in a stage when any atom fusion is impossible ++ * and atom is unlocked and it is safe. ++ */ ++static int alloc_submit_wander_blocks(struct commit_handle *ch, ++ unsigned subv_id, flush_queue_t *fq) ++{ ++ reiser4_block_nr block; ++ int rest; ++ int len; ++ int ret; ++ jnode *cur; ++ reiser4_subvol *subv = super_origin(ch->super, subv_id); ++ struct list_head *overw_set = &subv->ch.overwrite_set; ++ ++ rest = subv->ch.overwrite_set_size; ++ ++ assert("zam-534", rest > 0); ++ ++ cur = list_entry(overw_set->next, jnode, capture_link); ++ ++ while (overw_set != &cur->capture_link) { ++ assert("zam-567", JF_ISSET(cur, JNODE_OVRWR)); ++ ++ ret = alloc_wander_blocks(rest, &block, &len, subv); ++ if (ret) ++ return ret; ++ ++ rest -= len; ++ ++ ret = add_region_to_wmap(cur, len, &block, subv); ++ if (ret) ++ return ret; ++ ++ ret = write_jnodes_contig(cur, len, &block, fq, 0, subv); ++ if (ret) ++ return ret; ++ ++ while ((len--) > 0) { ++ assert("zam-604", overw_set != &cur->capture_link); ++ cur = list_entry(cur->capture_link.next, ++ jnode, capture_link); ++ } ++ } ++ return 0; ++} ++ ++/* ++ * Allocate given number of nodes over the journal area and link ++ * them into a list; return pointer to the first jnode in the list ++ */ ++static int alloc_submit_wander_records(struct commit_handle *ch, ++ unsigned subv_id, flush_queue_t *fq) ++{ ++ reiser4_blocknr_hint hint; ++ reiser4_block_nr allocated = 0; ++ reiser4_block_nr first, len; ++ jnode *cur; ++ jnode *txhead; ++ int ret; ++ reiser4_context *ctx; ++ reiser4_subvol *subv = super_origin(ch->super, subv_id); ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ struct list_head *tx_list = &ch_sub->tx_list; ++ int tx_size = ch_sub->tx_size; ++ ++ assert("zam-698", tx_size > 0); ++ assert("zam-699", list_empty_careful(tx_list)); ++ ++ ctx = get_current_context(); ++ ++ while (allocated < (unsigned)tx_size) { ++ len = tx_size - allocated; ++ ++ reiser4_blocknr_hint_init(&hint); ++ ++ hint.block_stage = BLOCK_GRABBED; ++ ++ /* FIXME: there should be some block allocation policy for ++ nodes which contain wander records */ ++ ++ /* We assume that disk space for wandered record blocks can be ++ * taken from reserved area. */ ++ ret = reiser4_alloc_blocks(&hint, &first, &len, ++ BA_FORMATTED | BA_RESERVED | ++ BA_USE_DEFAULT_SEARCH_START, ++ subv); ++ reiser4_blocknr_hint_done(&hint); ++ if (ret) ++ return ret; ++ ++ allocated += len; ++ ++ /* create jnodes for all wander records */ ++ while (len--) { ++ cur = reiser4_alloc_io_head(&first, subv); ++ ++ if (cur == NULL) { ++ ret = RETERR(-ENOMEM); ++ goto free_not_assigned; ++ } ++ ++ ret = jinit_new(cur, reiser4_ctx_gfp_mask_get()); ++ ++ if (ret != 0) { ++ jfree(cur); ++ goto free_not_assigned; ++ } ++ ++ pin_jnode_data(cur); ++ ++ list_add_tail(&cur->capture_link, tx_list); ++ ++ first++; ++ } ++ } ++ ++ { /* format a on-disk linked list of wander records */ ++ int serial = 1; ++ ++ txhead = list_entry(tx_list->next, jnode, capture_link); ++ format_tx_head(ch, subv_id); ++ ++ cur = list_entry(txhead->capture_link.next, jnode, capture_link); ++ while (tx_list != &cur->capture_link) { ++ format_wander_record(ch, subv_id, cur, serial++); ++ cur = list_entry(cur->capture_link.next, jnode, capture_link); ++ } ++ } ++ ++ { /* Fill wander records with Wandered Set */ ++ struct store_wmap_params params; ++ txn_atom *atom; ++ ++ params.cur = list_entry(txhead->capture_link.next, jnode, capture_link); ++ ++ params.idx = 0; ++ params.capacity = ++ wander_record_capacity(reiser4_get_current_sb()); ++ ++ atom = get_current_atom_locked(); ++ blocknr_set_iterator(atom, ++ &ch_sub->wander_map, ++ &store_wmap_actor, ¶ms, 0, subv_id); ++ spin_unlock_atom(atom); ++ } ++ ++ { /* relse all jnodes from tx_list */ ++ cur = list_entry(tx_list->next, jnode, capture_link); ++ while (tx_list != &cur->capture_link) { ++ jrelse(cur); ++ cur = list_entry(cur->capture_link.next, jnode, capture_link); ++ } ++ } ++ /* ++ * submit wander records ++ */ ++ ret = write_jnode_list_subv(tx_list, fq, NULL, 0, subv); ++ ++ return ret; ++ ++ free_not_assigned: ++ /* ++ * We deallocate blocks not yet assigned to jnodes on tx_list. ++ * The caller takes care about invalidating of tx list ++ */ ++ reiser4_dealloc_blocks(&first, &len, ++ BLOCK_NOT_COUNTED, BA_FORMATTED, subv); ++ return ret; ++} ++ ++static int commit_tx_subv(struct commit_handle *ch, u32 subv_id) ++{ ++ int ret; ++ flush_queue_t *fq; ++ reiser4_subvol *subv = super_origin(ch->super, subv_id); ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ /* ++ * Grab more space for wandered records ++ */ ++ ret = reiser4_grab_space_force((__u64)(ch_sub->tx_size), ++ BA_RESERVED, subv); ++ if (ret) ++ return ret; ++ ++ fq = get_fq_for_current_atom(); ++ if (IS_ERR(fq)) ++ return PTR_ERR(fq); ++ ++ spin_unlock_atom(fq->atom); ++ ++ ret = alloc_submit_wander_blocks(ch, subv_id, fq); ++ if (ret) ++ goto exit; ++ ret = alloc_submit_wander_records(ch, subv_id, fq); ++ exit: ++ reiser4_fq_put(fq); ++ return ret; ++} ++ ++static int commit_tx(struct commit_handle *ch) ++{ ++ int ret; ++ ++ txn_atom *atom = ch->atom; ++ struct rb_node *node; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = ¤t_origin(abi->brick_id)->ch; ++ ++ if (ch_sub->overwrite_set_size == 0) ++ continue; ++ ++ ret = commit_tx_subv(ch, abi->brick_id); ++ if (ret) ++ return ret; ++ } ++ ret = current_atom_finish_all_fq(); ++ if (ret) ++ return ret; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = ¤t_origin(abi->brick_id)->ch; ++ ++ if (ch_sub->overwrite_set_size == 0) ++ continue; ++ ++ ret = update_journal_header(ch, abi->brick_id); ++ if (ret) ++ return ret; ++ } ++ return 0; ++} ++ ++/** ++ * Play (checkpoint) transaction on a simplest component of a compound volume. ++ * @mirror can be an original subvolume, or a replica. ++ */ ++static int play_tx_mirror(struct commit_handle *ch, reiser4_subvol *mirror) ++{ ++ int ret; ++ flush_queue_t *fq; ++ struct commit_handle_subvol *ch_sub; ++ /* ++ * replicas don't have their own commit handle, ++ * so borrow it form the original subvolume ++ */ ++ ch_sub = &super_origin(ch->super, mirror->id)->ch; ++ fq = get_fq_for_current_atom(); ++ if (IS_ERR(fq)) ++ return PTR_ERR(fq); ++ spin_unlock_atom(fq->atom); ++ ++ ret = write_jnode_list_subv(&ch_sub->overwrite_set, fq, ++ NULL, WRITEOUT_FOR_PAGE_RECLAIM, mirror); ++ reiser4_fq_put(fq); ++ return ret; ++} ++ ++/** ++ * Play (checkpoint) transaction on a logical (compound) volume. ++ */ ++static int play_tx(struct commit_handle *ch) ++{ ++ int ret; ++ struct rb_node *node; ++ txn_atom *atom = ch->atom; ++ ++ /* ++ * First of all, ++ * we issue per-component portions of IO requests in parallel. ++ */ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ u32 mirr_id; ++ struct atom_brick_info *abi; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ ch_sub = ¤t_origin(abi->brick_id)->ch; ++ ++ if (ch_sub->overwrite_set_size == 0) ++ continue; ++ ++ for_each_mirror(abi->brick_id, mirr_id) { ++ ++ reiser4_subvol *mirror; ++ mirror = current_mirror(abi->brick_id, mirr_id); ++ ret = play_tx_mirror(ch, mirror); ++ if (ret) ++ return ret; ++ } ++ } ++ /* ++ * comply with write barriers ++ */ ++ ret = current_atom_finish_all_fq(); ++ if (ret) ++ return ret; ++ ++ for (node = rb_first(&atom->bricks_info); ++ node; ++ node = rb_next(node)) { ++ ++ struct atom_brick_info *abi; ++ reiser4_subvol *subv; ++ struct commit_handle_subvol *ch_sub; ++ ++ abi = rb_entry(node, struct atom_brick_info, node); ++ subv = current_origin(abi->brick_id); ++ ch_sub = &subv->ch; ++ ++ if (ch_sub->overwrite_set_size == 0) ++ continue; ++ ++ ret = update_journal_footer(ch, subv); ++ if (ret) ++ return ret; ++ } ++ return 0; ++} ++ ++/** ++ * We assume that at this moment all captured blocks are marked as RELOC or ++ * WANDER (belong to Relocate or Overwrite set), all nodes from Relocate set ++ * are submitted to write. ++ */ ++int reiser4_write_logs(long *nr_submitted) ++{ ++ txn_atom *atom; ++ struct super_block *super = reiser4_get_current_sb(); ++ reiser4_super_info_data *sbinfo = get_super_private(super); ++ struct commit_handle ch; ++ int ret; ++ ++ writeout_mode_enable(); ++ /* ++ * block allocator may add jnodes to the clean_list ++ */ ++ ret = reiser4_pre_commit_hook(); ++ if (ret) ++ return ret; ++ /* ++ * No locks are required if we take atom ++ * whose stage >= ASTAGE_PRE_COMMIT ++ */ ++ atom = get_current_context()->trans->atom; ++ assert("zam-965", atom != NULL); ++ /* ++ * relocate set is on the atom->clean_nodes list after ++ * current_atom_complete_writes() finishes. It can be safely ++ * uncaptured after commit_mutex is locked, because any atom that ++ * captures these nodes is guaranteed to commit after current one. ++ * ++ * This can only be done after reiser4_pre_commit_hook(), because ++ * it is where early flushed jnodes with CREATED bit are transferred ++ * to the overwrite list ++ */ ++ reiser4_invalidate_list(ATOM_CLEAN_LIST(atom)); ++ spin_lock_atom(atom); ++ /* There might be waiters for the relocate nodes which we have ++ * released, wake them up. */ ++ reiser4_atom_send_event(atom); ++ spin_unlock_atom(atom); ++ ++ if (REISER4_DEBUG) { ++ int level; ++ ++ for (level = 0; level < REAL_MAX_ZTREE_HEIGHT + 1; ++level) ++ assert("nikita-3352", ++ list_empty_careful(ATOM_DIRTY_LIST(atom, ++ level))); ++ } ++ ++ sbinfo->nr_files_committed += (unsigned)atom->nr_objects_created; ++ sbinfo->nr_files_committed -= (unsigned)atom->nr_objects_deleted; ++ ++ init_commit_handle(&ch, atom, NULL); ++ /* ++ * count overwrite set and distribute it among subvolumes ++ */ ++ ret = get_overwrite_set(&ch); ++ ++ if (ret <= 0) { ++ /* ++ * It is possible that overwrite set is empty here, ++ * which means all captured nodes are clean ++ */ ++ goto up_and_ret; ++ } ++ /* ++ * Inform the caller about what number of dirty pages ++ * will be submitted to disk ++ */ ++ *nr_submitted += ch.total_overwrite_set_size - ch.total_nr_bitmap; ++ /* ++ * count all records needed for storing of the wandered set ++ */ ++ get_tx_size(&ch); ++ ++ ret = commit_tx(&ch); ++ if (ret) ++ goto up_and_ret; ++ ++ spin_lock_atom(atom); ++ reiser4_atom_set_stage(atom, ASTAGE_POST_COMMIT); ++ spin_unlock_atom(atom); ++ reiser4_post_commit_hook(); ++ ++ ret = play_tx(&ch); ++ up_and_ret: ++ if (ret) { ++ /* ++ * there could be fq attached to current atom; ++ * the only way to remove them is: ++ */ ++ current_atom_finish_all_fq(); ++ } ++ /* ++ * free blocks of flushed transaction ++ */ ++ dealloc_tx_list(&ch); ++ dealloc_wmap(&ch); ++ ++ reiser4_post_write_back_hook(); ++ ++ put_overwrite_set(&ch); ++ ++ done_commit_handle(&ch, NULL); ++ ++ writeout_mode_disable(); ++ ++ return ret; ++} ++ ++/** ++ * consistency checks for journal data/control blocks: header, footer, log ++ * records, transactions head blocks. All functions return zero on success ++ */ ++static int check_journal_header(const jnode * node UNUSED_ARG) ++{ ++ /* FIXME: journal header has no magic field yet. */ ++ return 0; ++} ++ ++/** ++ * wait for write completion for all jnodes from given list ++ */ ++static int wait_on_jnode_list(struct list_head *head) ++{ ++ jnode *scan; ++ int ret = 0; ++ ++ list_for_each_entry(scan, head, capture_link) { ++ struct page *pg = jnode_page(scan); ++ ++ if (pg) { ++ if (PageWriteback(pg)) ++ wait_on_page_writeback(pg); ++ ++ if (PageError(pg)) ++ ret++; ++ } ++ } ++ return ret; ++} ++ ++static int check_journal_footer(const jnode * node UNUSED_ARG) ++{ ++ /* FIXME: journal footer has no magic field yet. */ ++ return 0; ++} ++ ++static int check_tx_head(const jnode * node) ++{ ++ struct tx_header *header = (struct tx_header *)jdata(node); ++ ++ if (memcmp(&header->magic, TX_HEADER_MAGIC, TX_HEADER_MAGIC_SIZE) != 0) { ++ warning("zam-627", "tx head at block %s corrupted\n", ++ sprint_address(jnode_get_block(node))); ++ return RETERR(-EIO); ++ } ++ return 0; ++} ++ ++static int check_wander_record(const jnode * node) ++{ ++ struct wander_record_header *RH = ++ (struct wander_record_header *)jdata(node); ++ ++ if (memcmp(&RH->magic, WANDER_RECORD_MAGIC, WANDER_RECORD_MAGIC_SIZE) != ++ 0) { ++ warning("zam-628", "wander record at block %s corrupted\n", ++ sprint_address(jnode_get_block(node))); ++ return RETERR(-EIO); ++ } ++ return 0; ++} ++ ++/** ++ * Fill commit_handler structure by everything what is ++ * needed to update journal footer of specified subvolume ++ */ ++static int restore_commit_handle(struct commit_handle *ch, ++ reiser4_subvol *subv, jnode *tx_head) ++{ ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ struct tx_header *TXH; ++ int ret; ++ ++ ret = jload(tx_head); ++ if (ret) ++ return ret; ++ ++ TXH = (struct tx_header *)jdata(tx_head); ++ ++ ch_sub->free_blocks = le64_to_cpu(get_unaligned(&TXH->free_blocks)); ++ ch->nr_files = le64_to_cpu(get_unaligned(&TXH->nr_files)); ++ ch->next_oid = le64_to_cpu(get_unaligned(&TXH->next_oid)); ++ ++ jrelse(tx_head); ++ ++ list_add(&tx_head->capture_link, &ch_sub->tx_list); ++ ++ return 0; ++} ++ ++/** ++ * Overwrite blocks on permanent location by the wandered set. ++ * and synchronize it with all replicas (if any). ++ * Pre-condition: all replicas of @subv should be already activated. ++ */ ++static int replay_tx_subv(reiser4_subvol *subv) ++{ ++ int ret; ++ u32 repl_id; ++ const u32 orig_id = subv->id; ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ ++ assert("edward-1708", is_origin(subv)); ++ /* ++ * first replay on the original subvolume ++ */ ++ write_jnode_list_subv(&ch_sub->overwrite_set, ++ NULL, NULL, 0, subv); ++ ret = wait_on_jnode_list(&ch_sub->overwrite_set); ++ if (ret) ++ goto error; ++ /* ++ * then replay on its replicas, if any ++ */ ++ __for_each_replica(subv, repl_id) { ++ reiser4_subvol *repl = super_mirror(subv->super, ++ orig_id, repl_id); ++ write_jnode_list_subv(&ch_sub->overwrite_set, ++ NULL, NULL, 0, repl); ++ ret = wait_on_jnode_list(&ch_sub->overwrite_set); ++ if (ret) ++ goto error; ++ } ++ return 0; ++ error: ++ warning("edward-1712", ++ "transaction replay failed on %s (%d)", subv->name, ret); ++ return RETERR(-EIO); ++} ++ ++/** ++ * This is an "offline" version of play_tx(). Called at mount time. ++ * Replay one transaction: restore and write overwrite set in place ++ */ ++static int replay_tx(jnode *tx_head, ++ const reiser4_block_nr *log_rec_block_p, ++ const reiser4_block_nr *end_block, ++ unsigned int nr_wander_records, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ jnode *log; ++ struct commit_handle ch; ++ struct commit_handle_subvol *ch_sub = &subv->ch; ++ reiser4_block_nr log_rec_block = *log_rec_block_p; ++ ++ assert("edward-1713", !is_replica(subv)); ++ ++ init_commit_handle(&ch, NULL, subv); ++ restore_commit_handle(&ch, subv, tx_head); ++ ++ while (log_rec_block != *end_block) { ++ struct wander_record_header *header; ++ struct wander_entry *entry; ++ ++ int i; ++ ++ if (nr_wander_records == 0) { ++ warning("zam-631", ++ "number of wander records in the linked list" ++ " greater than number stored in tx head.\n"); ++ ret = RETERR(-EIO); ++ goto free_ow_set; ++ } ++ ++ log = reiser4_alloc_io_head(&log_rec_block, subv); ++ if (log == NULL) ++ return RETERR(-ENOMEM); ++ ++ ret = jload(log); ++ if (ret < 0) { ++ reiser4_drop_io_head(log); ++ return ret; ++ } ++ ++ ret = check_wander_record(log); ++ if (ret) { ++ jrelse(log); ++ reiser4_drop_io_head(log); ++ return ret; ++ } ++ ++ header = (struct wander_record_header *)jdata(log); ++ log_rec_block = le64_to_cpu(get_unaligned(&header->next_block)); ++ ++ entry = (struct wander_entry *)(header + 1); ++ /* ++ * restore overwrite set from wander record content ++ */ ++ for (i = 0; i < wander_record_capacity(subv->super); i++) { ++ reiser4_block_nr block; ++ jnode *node; ++ ++ block = le64_to_cpu(get_unaligned(&entry->wandered)); ++ if (block == 0) ++ break; ++ ++ node = reiser4_alloc_io_head(&block, subv); ++ if (node == NULL) { ++ ret = RETERR(-ENOMEM); ++ /* ++ * FIXME-VS:??? ++ */ ++ jrelse(log); ++ reiser4_drop_io_head(log); ++ goto free_ow_set; ++ } ++ ++ ret = jload(node); ++ ++ if (ret < 0) { ++ reiser4_drop_io_head(node); ++ /* ++ * FIXME-VS:??? ++ */ ++ jrelse(log); ++ reiser4_drop_io_head(log); ++ goto free_ow_set; ++ } ++ ++ block = le64_to_cpu(get_unaligned(&entry->original)); ++ ++ assert("zam-603", block != 0); ++ ++ jnode_set_block(node, &block); ++ ++ list_add_tail(&node->capture_link, ++ &ch_sub->overwrite_set); ++ ++ ++entry; ++ } ++ ++ jrelse(log); ++ reiser4_drop_io_head(log); ++ ++ --nr_wander_records; ++ } ++ ++ if (nr_wander_records != 0) { ++ warning("zam-632", ++ "number of wander records in the linked list " ++ "is less than number stored in tx head.\n"); ++ ret = RETERR(-EIO); ++ goto free_ow_set; ++ } ++ ret = replay_tx_subv(subv); ++ ret = update_journal_footer(&ch, subv); ++ ++ free_ow_set: ++ ++ while (!list_empty(&ch_sub->overwrite_set)) { ++ jnode *cur = list_entry(ch_sub->overwrite_set.next, ++ jnode, capture_link); ++ list_del_init(&cur->capture_link); ++ jrelse(cur); ++ reiser4_drop_io_head(cur); ++ } ++ ++ list_del_init(&tx_head->capture_link); ++ ++ done_commit_handle(&ch, subv); ++ ++ return ret; ++} ++ ++/** ++ * Find oldest committed and not played transaction and play it. The transaction ++ * was committed and journal header block was updated but the blocks from the ++ * process of writing the atom's overwrite set in-place and updating of journal ++ * footer block were not completed. This function completes the process by ++ * recovering the atom's overwrite set from their wandered locations and writes ++ * them in-place and updating the journal footer. ++ */ ++static int replay_oldest_transaction(reiser4_subvol *subv) ++{ ++ jnode *jf = subv->journal_footer; ++ unsigned int total; ++ struct journal_footer *F; ++ struct tx_header *T; ++ ++ reiser4_block_nr prev_tx; ++ reiser4_block_nr last_flushed_tx; ++ reiser4_block_nr log_rec_block = 0; ++ ++ jnode *tx_head; ++ ++ int ret; ++ ++ if ((ret = jload(jf)) < 0) ++ return ret; ++ ++ F = (struct journal_footer *)jdata(jf); ++ ++ last_flushed_tx = le64_to_cpu(get_unaligned(&F->last_flushed_tx)); ++ ++ jrelse(jf); ++ ++ if (subv->last_committed_tx == last_flushed_tx) { ++ /* all transactions are replayed */ ++ return 0; ++ } ++ ++ prev_tx = subv->last_committed_tx; ++ /* ++ * searching for oldest not flushed transaction ++ */ ++ while (1) { ++ tx_head = reiser4_alloc_io_head(&prev_tx, subv); ++ if (!tx_head) ++ return RETERR(-ENOMEM); ++ ++ ret = jload(tx_head); ++ if (ret < 0) { ++ reiser4_drop_io_head(tx_head); ++ return ret; ++ } ++ ++ ret = check_tx_head(tx_head); ++ if (ret) { ++ jrelse(tx_head); ++ reiser4_drop_io_head(tx_head); ++ return ret; ++ } ++ ++ T = (struct tx_header *)jdata(tx_head); ++ ++ prev_tx = le64_to_cpu(get_unaligned(&T->prev_tx)); ++ ++ if (prev_tx == last_flushed_tx) ++ break; ++ ++ jrelse(tx_head); ++ reiser4_drop_io_head(tx_head); ++ } ++ ++ total = le32_to_cpu(get_unaligned(&T->total)); ++ log_rec_block = le64_to_cpu(get_unaligned(&T->next_block)); ++ ++ pin_jnode_data(tx_head); ++ jrelse(tx_head); ++ ++ ret = replay_tx(tx_head, &log_rec_block, ++ jnode_get_block(tx_head), total - 1, subv); ++ ++ unpin_jnode_data(tx_head); ++ reiser4_drop_io_head(tx_head); ++ ++ if (ret) ++ return ret; ++ return -E_REPEAT; ++} ++ ++/** ++ * The reiser4 journal current implementation was optimized to not to capture ++ * super block if certain super blocks fields are modified. Currently, the set ++ * is (, ). These fields are logged by ++ * special way which includes storing them in each transaction head block at ++ * atom commit time and writing that information to journal footer block at ++ * atom flush time. For getting the info from journal footer block to the ++ * in-memory super block there is a special function ++ * reiser4_journal_recover_sb_data() which should be called after disk format ++ * plugin re-reads super block after journal replaying. ++ * ++ * Get the information from journal footer to in-memory super block ++ */ ++int reiser4_journal_recover_sb_data(struct super_block *s, reiser4_subvol *subv) ++{ ++ struct journal_footer *jf; ++ int ret; ++ ++ assert("zam-673", subv->journal_footer != NULL); ++ ++ ret = jload(subv->journal_footer); ++ if (ret != 0) ++ return ret; ++ ++ ret = check_journal_footer(subv->journal_footer); ++ if (ret != 0) ++ goto out; ++ ++ jf = (struct journal_footer *)jdata(subv->journal_footer); ++ /* ++ * was there at least one flushed transaction? ++ */ ++ if (jf->last_flushed_tx) { ++ /* ++ * restore free block counter logged in this transaction ++ */ ++ reiser4_subvol_set_free_blocks(subv, ++ le64_to_cpu(get_unaligned(&jf->free_blocks))); ++ if (is_meta_brick_id(subv->id)) ++ /* ++ * restore oid allocator state ++ */ ++ oid_init_allocator(s, ++ le64_to_cpu(get_unaligned(&jf->nr_files)), ++ le64_to_cpu(get_unaligned(&jf->next_oid))); ++ } ++ out: ++ jrelse(subv->journal_footer); ++ return ret; ++} ++ ++/** ++ * reiser4 replay journal procedure ++ */ ++int reiser4_journal_replay(reiser4_subvol *subv) ++{ ++ jnode *jh, *jf; ++ struct journal_header *header; ++ int nr_tx_replayed = 0; ++ int ret; ++ ++ assert("edward-1714", subv != NULL); ++ ++ jh = subv->journal_header; ++ jf = subv->journal_footer; ++ ++ if (!jh || !jf) { ++ /* ++ * It is possible that disk layout does not ++ * support journal structures, we just warn about this ++ */ ++ warning("zam-583", ++ "Journal control blocks were not loaded on %s. " ++ "Journal replay is not possible.\n", subv->name); ++ return 0; ++ } ++ /* ++ * Take free block count from journal footer block. The free block ++ * counter value corresponds the last flushed transaction state ++ */ ++ ret = jload(jf); ++ if (ret < 0) ++ return ret; ++ ++ ret = check_journal_footer(jf); ++ if (ret) { ++ jrelse(jf); ++ return ret; ++ } ++ jrelse(jf); ++ /* ++ * store last committed transaction info in ++ * reiser4 in-memory superblock ++ */ ++ ret = jload(jh); ++ if (ret < 0) ++ return ret; ++ ++ ret = check_journal_header(jh); ++ if (ret) { ++ jrelse(jh); ++ return ret; ++ } ++ header = (struct journal_header *)jdata(jh); ++ subv->last_committed_tx = ++ le64_to_cpu(get_unaligned(&header->last_committed_tx)); ++ ++ jrelse(jh); ++ ++ /* replay committed transactions */ ++ while ((ret = replay_oldest_transaction(subv)) == -E_REPEAT) ++ nr_tx_replayed++; ++ ++ return ret; ++} ++ ++/** ++ * Load journal control block (either journal header or journal footer block) ++ */ ++static int load_journal_control_block(jnode **node, ++ const reiser4_block_nr *block, ++ reiser4_subvol *subv) ++{ ++ int ret; ++ ++ *node = reiser4_alloc_io_head(block, subv); ++ if (!(*node)) ++ return RETERR(-ENOMEM); ++ ++ ret = jload(*node); ++ ++ if (ret) { ++ reiser4_drop_io_head(*node); ++ *node = NULL; ++ return ret; ++ } ++ ++ pin_jnode_data(*node); ++ jrelse(*node); ++ ++ return 0; ++} ++ ++/** ++ * Unload journal header or footer and free jnode ++ */ ++static void unload_journal_control_block(jnode ** node) ++{ ++ if (*node) { ++ unpin_jnode_data(*node); ++ reiser4_drop_io_head(*node); ++ *node = NULL; ++ } ++} ++ ++/** ++ * Release journal control blocks ++ */ ++void reiser4_done_journal_info(reiser4_subvol *subv) ++{ ++ unload_journal_control_block(&subv->journal_header); ++ unload_journal_control_block(&subv->journal_footer); ++ rcu_barrier(); ++} ++ ++/** ++ * Load journal control blocks. ++ * Pre-condition: @subv contains valid journal location ++ */ ++int reiser4_init_journal_info(reiser4_subvol *subv) ++{ ++ int ret; ++ journal_location *loc = &subv->jloc; ++ ++ assert("zam-652", loc->header != 0); ++ assert("zam-653", loc->footer != 0); ++ ++ ret = load_journal_control_block(&subv->journal_header, ++ &loc->header, subv); ++ if (ret) ++ return ret; ++ ++ ret = load_journal_control_block(&subv->journal_footer, ++ &loc->footer, subv); ++ if (ret) ++ unload_journal_control_block(&subv->journal_header); ++ return ret; ++} ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/wander.h linux-5.10.2/fs/reiser4/wander.h +--- linux-5.10.2.orig/fs/reiser4/wander.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/wander.h 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,138 @@ ++/* Copyright 2002, 2003 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined (__FS_REISER4_WANDER_H__) ++#define __FS_REISER4_WANDER_H__ ++ ++#include "dformat.h" ++ ++#include /* for struct super_block */ ++ ++/* REISER4 JOURNAL ON-DISK DATA STRUCTURES */ ++ ++#define TX_HEADER_MAGIC "TxMagic4" ++#define WANDER_RECORD_MAGIC "LogMagc4" ++ ++#define TX_HEADER_MAGIC_SIZE (8) ++#define WANDER_RECORD_MAGIC_SIZE (8) ++ ++/* journal header block format */ ++struct journal_header { ++ /* last written transaction head location */ ++ d64 last_committed_tx; ++}; ++ ++typedef struct journal_location { ++ reiser4_block_nr footer; ++ reiser4_block_nr header; ++} journal_location; ++ ++/* The wander.c head comment describes usage and semantic of all these structures */ ++/* journal footer block format */ ++struct journal_footer { ++ /* last flushed transaction location. */ ++ /* This block number is no more valid after the transaction it points ++ to gets flushed, this number is used only at journal replaying time ++ for detection of the end of on-disk list of committed transactions ++ which were not flushed completely */ ++ d64 last_flushed_tx; ++ ++ /* free block counter is written in journal footer at transaction ++ flushing , not in super block because free blocks counter is logged ++ by another way than super block fields (root pointer, for ++ example). */ ++ d64 free_blocks; ++ ++ /* number of used OIDs and maximal used OID are logged separately from ++ super block */ ++ d64 nr_files; ++ d64 next_oid; ++}; ++ ++/* Each wander record (except the first one) has unified format with wander ++ record header followed by an array of log entries */ ++struct wander_record_header { ++ /* when there is no predefined location for wander records, this magic ++ string should help reiser4fsck. */ ++ char magic[WANDER_RECORD_MAGIC_SIZE]; ++ ++ /* transaction id */ ++ d64 id; ++ ++ /* total number of wander records in current transaction */ ++ d32 total; ++ ++ /* this block number in transaction */ ++ d32 serial; ++ ++ /* number of previous block in commit */ ++ d64 next_block; ++}; ++ ++/* The first wander record (transaction head) of written transaction has the ++ special format */ ++struct tx_header { ++ /* magic string makes first block in transaction different from other ++ logged blocks, it should help fsck. */ ++ char magic[TX_HEADER_MAGIC_SIZE]; ++ ++ /* transaction id */ ++ d64 id; ++ ++ /* total number of records (including this first tx head) in the ++ transaction */ ++ d32 total; ++ ++ /* align next field to 8-byte boundary; this field always is zero */ ++ d32 padding; ++ ++ /* block number of previous transaction head */ ++ d64 prev_tx; ++ ++ /* next wander record location */ ++ d64 next_block; ++ ++ /* committed versions of free blocks counter */ ++ d64 free_blocks; ++ ++ /* number of used OIDs (nr_files) and maximal used OID are logged ++ separately from super block */ ++ d64 nr_files; ++ d64 next_oid; ++}; ++ ++/* A transaction gets written to disk as a set of wander records (each wander ++ record size is fs block) */ ++ ++/* As it was told above a wander The rest of wander record is filled by these log entries, unused space filled ++ by zeroes */ ++struct wander_entry { ++ d64 original; /* block original location */ ++ d64 wandered; /* block wandered location */ ++}; ++ ++/* REISER4 JOURNAL WRITER FUNCTIONS */ ++ ++extern int reiser4_write_logs(long *); ++extern int reiser4_journal_replay(reiser4_subvol *); ++extern int reiser4_journal_recover_sb_data(struct super_block *, ++ reiser4_subvol *); ++ ++extern int reiser4_init_journal_info(reiser4_subvol *subv); ++extern void reiser4_done_journal_info(reiser4_subvol *subv); ++ ++extern int write_jnode_list_subv(struct list_head *, flush_queue_t *, ++ long *, int, reiser4_subvol *); ++extern int write_jnode_list(struct list_head *, flush_queue_t *, long *, int); ++ ++#endif /* __FS_REISER4_WANDER_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ scroll-step: 1 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/writeout.h linux-5.10.2/fs/reiser4/writeout.h +--- linux-5.10.2.orig/fs/reiser4/writeout.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/writeout.h 2020-12-23 16:07:46.137813407 +0100 +@@ -0,0 +1,21 @@ ++/* Copyright 2002, 2003, 2004 by Hans Reiser, licensing governed by reiser4/README */ ++ ++#if !defined (__FS_REISER4_WRITEOUT_H__) ++ ++#define WRITEOUT_SINGLE_STREAM (0x1) ++#define WRITEOUT_FOR_PAGE_RECLAIM (0x2) ++#define WRITEOUT_FLUSH_FUA (0x4) ++ ++extern int reiser4_get_writeout_flags(void); ++ ++#endif /* __FS_REISER4_WRITEOUT_H__ */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 80 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/znode.c linux-5.10.2/fs/reiser4/znode.c +--- linux-5.10.2.orig/fs/reiser4/znode.c 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/znode.c 2020-12-23 16:07:46.138813421 +0100 +@@ -0,0 +1,1046 @@ ++/* Copyright 2001, 2002, 2003 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++/* Znode manipulation functions. */ ++/* Znode is the in-memory header for a tree node. It is stored ++ separately from the node itself so that it does not get written to ++ disk. In this respect znode is like buffer head or page head. We ++ also use znodes for additional reiser4 specific purposes: ++ ++ . they are organized into tree structure which is a part of whole ++ reiser4 tree. ++ . they are used to implement node grained locking ++ . they are used to keep additional state associated with a ++ node ++ . they contain links to lists used by the transaction manager ++ ++ Znode is attached to some variable "block number" which is instance of ++ fs/reiser4/tree.h:reiser4_block_nr type. Znode can exist without ++ appropriate node being actually loaded in memory. Existence of znode itself ++ is regulated by reference count (->x_count) in it. Each time thread ++ acquires reference to znode through call to zget(), ->x_count is ++ incremented and decremented on call to zput(). Data (content of node) are ++ brought in memory through call to zload(), which also increments ->d_count ++ reference counter. zload can block waiting on IO. Call to zrelse() ++ decreases this counter. Also, ->c_count keeps track of number of child ++ znodes and prevents parent znode from being recycled until all of its ++ children are. ->c_count is decremented whenever child goes out of existence ++ (being actually recycled in zdestroy()) which can be some time after last ++ reference to this child dies if we support some form of LRU cache for ++ znodes. ++ ++*/ ++/* EVERY ZNODE'S STORY ++ ++ 1. His infancy. ++ ++ Once upon a time, the znode was born deep inside of zget() by call to ++ zalloc(). At the return from zget() znode had: ++ ++ . reference counter (x_count) of 1 ++ . assigned block number, marked as used in bitmap ++ . pointer to parent znode. Root znode parent pointer points ++ to its father: "fake" znode. This, in turn, has NULL parent pointer. ++ . hash table linkage ++ . no data loaded from disk ++ . no node plugin ++ . no sibling linkage ++ ++ 2. His childhood ++ ++ Each node is either brought into memory as a result of tree traversal, or ++ created afresh, creation of the root being a special case of the latter. In ++ either case it's inserted into sibling list. This will typically require ++ some ancillary tree traversing, but ultimately both sibling pointers will ++ exist and JNODE_LEFT_CONNECTED and JNODE_RIGHT_CONNECTED will be true in ++ zjnode.state. ++ ++ 3. His youth. ++ ++ If znode is bound to already existing node in a tree, its content is read ++ from the disk by call to zload(). At that moment, JNODE_LOADED bit is set ++ in zjnode.state and zdata() function starts to return non null for this ++ znode. zload() further calls zparse() that determines which node layout ++ this node is rendered in, and sets ->nplug on success. ++ ++ If znode is for new node just created, memory for it is allocated and ++ zinit_new() function is called to initialise data, according to selected ++ node layout. ++ ++ 4. His maturity. ++ ++ After this point, znode lingers in memory for some time. Threads can ++ acquire references to znode either by blocknr through call to zget(), or by ++ following a pointer to unallocated znode from internal item. Each time ++ reference to znode is obtained, x_count is increased. Thread can read/write ++ lock znode. Znode data can be loaded through calls to zload(), d_count will ++ be increased appropriately. If all references to znode are released ++ (x_count drops to 0), znode is not recycled immediately. Rather, it is ++ still cached in the hash table in the hope that it will be accessed ++ shortly. ++ ++ There are two ways in which znode existence can be terminated: ++ ++ . sudden death: node bound to this znode is removed from the tree ++ . overpopulation: znode is purged out of memory due to memory pressure ++ ++ 5. His death. ++ ++ Death is complex process. ++ ++ When we irrevocably commit ourselves to decision to remove node from the ++ tree, JNODE_HEARD_BANSHEE bit is set in zjnode.state of corresponding ++ znode. This is done either in ->kill_hook() of internal item or in ++ reiser4_kill_root() function when tree root is removed. ++ ++ At this moment znode still has: ++ ++ . locks held on it, necessary write ones ++ . references to it ++ . disk block assigned to it ++ . data loaded from the disk ++ . pending requests for lock ++ ++ But once JNODE_HEARD_BANSHEE bit set, last call to unlock_znode() does node ++ deletion. Node deletion includes two phases. First all ways to get ++ references to that znode (sibling and parent links and hash lookup using ++ block number stored in parent node) should be deleted -- it is done through ++ sibling_list_remove(), also we assume that nobody uses down link from ++ parent node due to its nonexistence or proper parent node locking and ++ nobody uses parent pointers from children due to absence of them. Second we ++ invalidate all pending lock requests which still are on znode's lock ++ request queue, this is done by reiser4_invalidate_lock(). Another ++ JNODE_IS_DYING znode status bit is used to invalidate pending lock requests. ++ Once it set all requesters are forced to return -EINVAL from ++ longterm_lock_znode(). Future locking attempts are not possible because all ++ ways to get references to that znode are removed already. Last, node is ++ uncaptured from transaction. ++ ++ When last reference to the dying znode is just about to be released, ++ block number for this lock is released and znode is removed from the ++ hash table. ++ ++ Now znode can be recycled. ++ ++ [it's possible to free bitmap block and remove znode from the hash ++ table when last lock is released. This will result in having ++ referenced but completely orphaned znode] ++ ++ 6. Limbo ++ ++ As have been mentioned above znodes with reference counter 0 are ++ still cached in a hash table. Once memory pressure increases they are ++ purged out of there [this requires something like LRU list for ++ efficient implementation. LRU list would also greatly simplify ++ implementation of coord cache that would in this case morph to just ++ scanning some initial segment of LRU list]. Data loaded into ++ unreferenced znode are flushed back to the durable storage if ++ necessary and memory is freed. Znodes themselves can be recycled at ++ this point too. ++ ++*/ ++ ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/plugin_header.h" ++#include "plugin/node/node.h" ++#include "plugin/plugin.h" ++#include "txnmgr.h" ++#include "jnode.h" ++#include "znode.h" ++#include "block_alloc.h" ++#include "tree.h" ++#include "tree_walk.h" ++#include "super.h" ++#include "reiser4.h" ++ ++#include ++#include ++#include ++#include ++ ++static z_hash_table *get_htable(reiser4_tree *, ++ const reiser4_block_nr * const blocknr); ++static z_hash_table *znode_get_htable(const znode *); ++static void zdrop(znode *); ++ ++/* hash table support */ ++ ++/* compare two block numbers for equality. Used by hash-table macros */ ++static inline int ++blknreq(const reiser4_block_nr * b1, const reiser4_block_nr * b2) ++{ ++ assert("nikita-534", b1 != NULL); ++ assert("nikita-535", b2 != NULL); ++ ++ return *b1 == *b2; ++} ++ ++/* Hash znode by block number. Used by hash-table macros */ ++/* Audited by: umka (2002.06.11) */ ++static inline __u32 ++blknrhashfn(z_hash_table * table, const reiser4_block_nr * b) ++{ ++ assert("nikita-536", b != NULL); ++ ++ return *b & (REISER4_ZNODE_HASH_TABLE_SIZE - 1); ++} ++ ++/* The hash table definition */ ++#define KMALLOC(size) reiser4_vmalloc(size) ++#define KFREE(ptr, size) vfree(ptr) ++TYPE_SAFE_HASH_DEFINE(z, znode, reiser4_block_nr, zjnode.key.z, zjnode.link.z, ++ blknrhashfn, blknreq); ++#undef KFREE ++#undef KMALLOC ++ ++/* slab for znodes */ ++static struct kmem_cache *znode_cache; ++ ++int znode_shift_order; ++ ++/** ++ * init_znodes - create znode cache ++ * ++ * Initializes slab cache of znodes. It is part of reiser4 module initialization. ++ */ ++int init_znodes(void) ++{ ++ znode_cache = kmem_cache_create("znode", sizeof(znode), 0, ++ SLAB_HWCACHE_ALIGN | ++ SLAB_RECLAIM_ACCOUNT, NULL); ++ if (znode_cache == NULL) ++ return RETERR(-ENOMEM); ++ ++ for (znode_shift_order = 0; (1 << znode_shift_order) < sizeof(znode); ++ ++znode_shift_order); ++ --znode_shift_order; ++ return 0; ++} ++ ++/** ++ * done_znodes - delete znode cache ++ * ++ * This is called on reiser4 module unloading or system shutdown. ++ */ ++void done_znodes(void) ++{ ++ destroy_reiser4_cache(&znode_cache); ++} ++ ++/* call this to initialise tree of znodes */ ++int znodes_tree_init(reiser4_tree * tree /* tree to initialise znodes for */ ) ++{ ++ int result; ++ assert("umka-050", tree != NULL); ++ ++ rwlock_init(&tree->dk_lock); ++ ++ result = z_hash_init(&tree->zhash_table, REISER4_ZNODE_HASH_TABLE_SIZE); ++ if (result != 0) ++ return result; ++ result = z_hash_init(&tree->zfake_table, REISER4_ZNODE_HASH_TABLE_SIZE); ++ return result; ++} ++ ++/* free this znode */ ++void zfree(znode * node /* znode to free */ ) ++{ ++ assert("nikita-465", node != NULL); ++ assert("nikita-2120", znode_page(node) == NULL); ++ assert("nikita-2301", list_empty_careful(&node->lock.owners)); ++ assert("nikita-2302", list_empty_careful(&node->lock.requestors)); ++ assert("nikita-2663", (list_empty_careful(&ZJNODE(node)->capture_link) && ++ NODE_LIST(ZJNODE(node)) == NOT_CAPTURED)); ++ assert("nikita-3220", list_empty(&ZJNODE(node)->jnodes)); ++ assert("nikita-3293", !znode_is_right_connected(node)); ++ assert("nikita-3294", !znode_is_left_connected(node)); ++ assert("nikita-3295", node->left == NULL); ++ assert("nikita-3296", node->right == NULL); ++ ++ /* not yet phash_jnode_destroy(ZJNODE(node)); */ ++ ++ kmem_cache_free(znode_cache, node); ++} ++ ++/* call this to free tree of znodes */ ++void znodes_tree_done(reiser4_tree * tree /* tree to finish with znodes of */ ) ++{ ++ znode *node; ++ znode *next; ++ z_hash_table *ztable; ++ ++ /* scan znode hash-tables and kill all znodes, then free hash tables ++ * themselves. */ ++ ++ assert("nikita-795", tree != NULL); ++ ++ ztable = &tree->zhash_table; ++ ++ if (ztable->_table != NULL) { ++ for_all_in_htable(ztable, z, node, next) { ++ node->c_count = 0; ++ node->in_parent.node = NULL; ++ assert("nikita-2179", atomic_read(&ZJNODE(node)->x_count) == 0); ++ zdrop(node); ++ } ++ ++ z_hash_done(&tree->zhash_table); ++ } ++ ++ ztable = &tree->zfake_table; ++ ++ if (ztable->_table != NULL) { ++ for_all_in_htable(ztable, z, node, next) { ++ node->c_count = 0; ++ node->in_parent.node = NULL; ++ assert("nikita-2179", atomic_read(&ZJNODE(node)->x_count) == 0); ++ zdrop(node); ++ } ++ ++ z_hash_done(&tree->zfake_table); ++ } ++} ++ ++/* ZNODE STRUCTURES */ ++ ++/* allocate fresh znode */ ++znode *zalloc(gfp_t gfp_flag /* allocation flag */ ) ++{ ++ znode *node; ++ ++ node = kmem_cache_alloc(znode_cache, gfp_flag); ++ return node; ++} ++ ++/* ++ * Initialize fields of znode ++ * @node: znode to initialize; ++ * @parent: parent znode; ++ * @subvol: subvolume we are in ++ */ ++void zinit(znode *node, const znode *parent, struct reiser4_subvol *subvol) ++{ ++ assert("nikita-466", node != NULL); ++ assert("edward-1801", subvol != NULL); ++ ++ memset(node, 0, sizeof *node); ++ jnode_init(&node->zjnode, subvol, JNODE_FORMATTED_BLOCK); ++ reiser4_init_lock(&node->lock); ++ init_parent_coord(&node->in_parent, parent); ++} ++ ++/* ++ * remove znode from indices. This is called jput() when last reference on ++ * znode is released. ++ */ ++void znode_remove(znode *node) ++{ ++#if REISER4_DEBUG ++ reiser4_super_info_data *sbinfo; ++ ++ assert("nikita-2108", node != NULL); ++ assert("nikita-470", node->c_count == 0); ++ ++ sbinfo = get_super_private(znode_get_super(node)); ++ assert_rw_write_locked(&(sbinfo->tree_lock)); ++#endif ++ /* remove reference to this znode from cbk cache */ ++ cbk_cache_invalidate(node, znode_get_tree(node)); ++ ++ /* update c_count of parent */ ++ if (znode_parent(node) != NULL) { ++ assert("nikita-472", znode_parent(node)->c_count > 0); ++ /* father, onto your hands I forward my spirit... */ ++ znode_parent(node)->c_count--; ++ node->in_parent.node = NULL; ++ } else { ++ /* orphaned znode?! Root? */ ++ } ++ ++ /* remove znode from hash-table */ ++ z_hash_remove_rcu(znode_get_htable(node), node); ++} ++ ++/* zdrop() -- Remove znode from the tree. ++ ++ This is called when znode is removed from the memory. */ ++static void zdrop(znode * node /* znode to finish with */ ) ++{ ++ jdrop(ZJNODE(node)); ++} ++ ++/* ++ * put znode into right place in the hash table. This is called by relocate ++ * code. ++ */ ++int znode_rehash(znode * node /* node to rehash */ , ++ const reiser4_block_nr * new_block_nr /* new block number */ ) ++{ ++ z_hash_table *oldtable; ++ z_hash_table *newtable; ++ reiser4_tree *tree; ++ ++ assert("nikita-2018", node != NULL); ++ ++ tree = znode_get_tree(node); ++ oldtable = znode_get_htable(node); ++ newtable = get_htable(tree, new_block_nr); ++ ++ write_lock_tree(); ++ /* remove znode from hash-table */ ++ z_hash_remove_rcu(oldtable, node); ++ ++ /* assertion no longer valid due to RCU */ ++ /* assert("nikita-2019", z_hash_find(newtable, new_block_nr) == NULL); */ ++ ++ /* update blocknr */ ++ znode_set_block(node, new_block_nr); ++ node->zjnode.key.z = *new_block_nr; ++ ++ /* insert it into hash */ ++ z_hash_insert_rcu(newtable, node); ++ write_unlock_tree(); ++ return 0; ++} ++ ++/* ZNODE LOOKUP, GET, PUT */ ++ ++/* zlook() - get znode with given block_nr in a hash table or return NULL ++ ++ If result is non-NULL then the znode's x_count is incremented. Internal version ++ accepts pre-computed hash index. The hash table is accessed under caller's ++ tree->hash_lock. ++*/ ++znode *zlook(reiser4_tree *tree, const reiser4_block_nr *const blocknr) ++{ ++ znode *result; ++ __u32 hash; ++ z_hash_table *htable; ++ ++ assert("jmacd-506", tree != NULL); ++ assert("jmacd-507", blocknr != NULL); ++ ++ htable = get_htable(tree, blocknr); ++ hash = blknrhashfn(htable, blocknr); ++ ++ rcu_read_lock(); ++ result = z_hash_find_index(htable, hash, blocknr); ++ ++ if (result != NULL) { ++ add_x_ref(ZJNODE(result)); ++ result = znode_rip_check(result); ++ } ++ rcu_read_unlock(); ++ ++ return result; ++} ++ ++/* return hash table where znode with block @blocknr is (or should be) ++ * stored */ ++static z_hash_table *get_htable(reiser4_tree * tree, ++ const reiser4_block_nr * const blocknr) ++{ ++ z_hash_table *table; ++ if (is_disk_addr_unallocated(blocknr)) ++ table = &tree->zfake_table; ++ else ++ table = &tree->zhash_table; ++ return table; ++} ++ ++/* return hash table where znode @node is (or should be) stored */ ++static z_hash_table *znode_get_htable(const znode * node) ++{ ++ return get_htable(znode_get_tree(node), znode_get_block(node)); ++} ++ ++/* zget() - get znode from hash table, allocating it if necessary. ++ ++ First a call to zlook, locating a x-referenced znode if one ++ exists. If znode is not found, allocate new one and return. Result ++ is returned with x_count reference increased. ++ ++ LOCKS TAKEN: TREE_LOCK, ZNODE_LOCK ++ LOCK ORDERING: NONE ++*/ ++znode *zget(struct reiser4_subvol *subv, ++ const reiser4_block_nr * const blocknr, ++ znode * parent, tree_level level, gfp_t gfp_flag) ++{ ++ znode *result; ++ __u32 hashi; ++ reiser4_tree *tree = &subv->tree; ++ z_hash_table *zth; ++ ++ assert("jmacd-513", blocknr != NULL); ++ assert("jmacd-514", level < REISER4_MAX_ZTREE_HEIGHT); ++ ++ zth = get_htable(tree, blocknr); ++ hashi = blknrhashfn(zth, blocknr); ++ ++ /* NOTE-NIKITA address-as-unallocated-blocknr still is not ++ implemented. */ ++ ++ z_hash_prefetch_bucket(zth, hashi); ++ ++ rcu_read_lock(); ++ /* Find a matching BLOCKNR in the hash table. If the znode is found, ++ we obtain an reference (x_count) but the znode remains unlocked. ++ Have to worry about race conditions later. */ ++ result = z_hash_find_index(zth, hashi, blocknr); ++ /* According to the current design, the hash table lock protects new ++ znode references. */ ++ if (result != NULL) { ++ add_x_ref(ZJNODE(result)); ++ /* NOTE-NIKITA it should be so, but special case during ++ creation of new root makes such assertion highly ++ complicated. */ ++ assert("nikita-2131", 1 || znode_parent(result) == parent || ++ (ZF_ISSET(result, JNODE_ORPHAN) ++ && (znode_parent(result) == NULL))); ++ result = znode_rip_check(result); ++ } ++ ++ rcu_read_unlock(); ++ ++ if (!result) { ++ znode *shadow; ++ ++ result = zalloc(gfp_flag); ++ if (!result) { ++ return ERR_PTR(RETERR(-ENOMEM)); ++ } ++ ++ zinit(result, parent, subv); ++ ZJNODE(result)->blocknr = *blocknr; ++ ZJNODE(result)->key.z = *blocknr; ++ result->level = level; ++ ++ write_lock_tree(); ++ ++ shadow = z_hash_find_index(zth, hashi, blocknr); ++ if (unlikely(shadow != NULL && !ZF_ISSET(shadow, JNODE_RIP))) { ++ jnode_list_remove(ZJNODE(result)); ++ zfree(result); ++ result = shadow; ++ } else { ++ result->version = znode_build_version(tree); ++ z_hash_insert_index_rcu(zth, hashi, result); ++ ++ if (parent != NULL) ++ ++parent->c_count; ++ } ++ ++ add_x_ref(ZJNODE(result)); ++ ++ write_unlock_tree(); ++ } ++ ++ assert("intelfx-6", ++ ergo(!reiser4_blocknr_is_fake(blocknr) && *blocknr != 0, ++ reiser4_check_block(blocknr, 1, subv))); ++ ++ /* Check for invalid tree level, return -EIO */ ++ if (unlikely(znode_get_level(result) != level)) { ++ warning("jmacd-504", ++ "Wrong level for cached block %llu: %i expecting %i", ++ (unsigned long long)(*blocknr), znode_get_level(result), ++ level); ++ zput(result); ++ return ERR_PTR(RETERR(-EIO)); ++ } ++ ++ assert("nikita-1227", znode_invariant(result)); ++ ++ return result; ++} ++ ++/* ZNODE PLUGINS/DATA */ ++ ++/** ++ * Guess plugin for node loaded from the disk. ++ * Id of node plugin is stored at the fixed offset ++ * from the beginning of the node ++ * ++ * @node: znode to guess plugin of ++ */ ++static node_plugin *znode_guess_plugin(const znode *node) ++{ ++ reiser4_subvol *subv; ++ ++ assert("nikita-1053", node != NULL); ++ assert("nikita-1055", zdata(node) != NULL); ++ ++ subv = znode_get_subvol(node); ++ assert("edward-1802", subv != NULL); ++ ++ if (subvol_is_set(subv, SUBVOL_ONE_NODE_PLUGIN)) { ++ return subv->tree.nplug; ++ } else { ++ return node_plugin_by_disk_id ++ (&((common_node_header *) zdata(node))->plugin_id); ++#ifdef GUESS_EXISTS ++ reiser4_plugin *plugin; ++ ++ /* NOTE-NIKITA add locking here when dynamic plugins will be ++ * implemented */ ++ for_all_plugins(REISER4_NODE_PLUGIN_TYPE, plugin) { ++ if ((plugin->u.node.guess != NULL) ++ && plugin->u.node.guess(node)) ++ return plugin; ++ } ++ warning("nikita-1057", "Cannot guess node plugin"); ++ print_znode("node", node); ++ return NULL; ++#endif ++ } ++} ++ ++/* parse node header and install ->node_plugin */ ++int zparse(znode * node /* znode to parse */ ) ++{ ++ int result; ++ ++ assert("nikita-1233", node != NULL); ++ assert("nikita-2370", zdata(node) != NULL); ++ ++ if (node->nplug == NULL) { ++ node_plugin *nplug; ++ ++ nplug = znode_guess_plugin(node); ++ if (likely(nplug != NULL)) { ++ result = nplug->parse(node); ++ if (likely(result == 0)) ++ node->nplug = nplug; ++ } else { ++ result = RETERR(-EIO); ++ } ++ } else ++ result = 0; ++ return result; ++} ++ ++/* zload with readahead */ ++int zload_ra(znode * node /* znode to load */ , ra_info_t * info) ++{ ++ int result; ++ ++ assert("nikita-484", node != NULL); ++ assert("nikita-1377", znode_invariant(node)); ++ assert("jmacd-7771", !znode_above_root(node)); ++ assert("nikita-2125", atomic_read(&ZJNODE(node)->x_count) > 0); ++ assert("nikita-3016", reiser4_schedulable()); ++ ++ if (info) ++ formatted_readahead(node, info); ++ ++ result = jload(ZJNODE(node)); ++ assert("nikita-1378", znode_invariant(node)); ++ return result; ++} ++ ++/* load content of node into memory */ ++int zload(znode *node) ++{ ++#if REISER4_DEBUG ++ int ret; ++ ret = zload_ra(node, NULL); ++ assert("edward-2101", ergo(ret != 0, ret < 0)); ++ return ret; ++#else ++ return zload_ra(node, NULL); ++#endif ++} ++ ++/* call node plugin to initialise newly allocated node. */ ++int zinit_new(znode * node /* znode to initialise */ , gfp_t gfp_flags) ++{ ++ return jinit_new(ZJNODE(node), gfp_flags); ++} ++ ++/* drop reference to node data. When last reference is dropped, data are ++ unloaded. */ ++void zrelse(znode * node /* znode to release references to */ ) ++{ ++ assert("nikita-1381", znode_invariant(node)); ++ jrelse(ZJNODE(node)); ++} ++ ++/* returns free space in node */ ++unsigned znode_free_space(znode * node /* znode to query */ ) ++{ ++ assert("nikita-852", node != NULL); ++ return node_plugin_by_node(node)->free_space(node); ++} ++ ++/* left delimiting key of znode */ ++reiser4_key *znode_get_rd_key(znode * node /* znode to query */ ) ++{ ++ assert("nikita-958", node != NULL); ++ assert_rw_locked(&(znode_get_tree(node)->dk_lock)); ++ assert("nikita-3067", LOCK_CNT_GTZ(rw_locked_dk)); ++ assert("nikita-30671", node->rd_key_version != 0); ++ return &node->rd_key; ++} ++ ++/* right delimiting key of znode */ ++reiser4_key *znode_get_ld_key(znode * node /* znode to query */ ) ++{ ++ assert("nikita-974", node != NULL); ++ assert_rw_locked(&(znode_get_tree(node)->dk_lock)); ++ assert("nikita-3068", LOCK_CNT_GTZ(rw_locked_dk)); ++ assert("nikita-30681", node->ld_key_version != 0); ++ return &node->ld_key; ++} ++ ++ON_DEBUG(atomic_t delim_key_version = ATOMIC_INIT(0); ++ ) ++ ++/* update right-delimiting key of @node */ ++reiser4_key *znode_set_rd_key(znode * node, const reiser4_key * key) ++{ ++ assert("nikita-2937", node != NULL); ++ assert("nikita-2939", key != NULL); ++ assert_rw_write_locked(&(znode_get_tree(node)->dk_lock)); ++ assert("nikita-3069", LOCK_CNT_GTZ(write_locked_dk)); ++ assert("nikita-2944", ++ znode_is_any_locked(node) || ++ znode_get_level(node) != LEAF_LEVEL || ++ keyge(key, &node->rd_key) || ++ keyeq(&node->rd_key, reiser4_min_key()) || ++ ZF_ISSET(node, JNODE_HEARD_BANSHEE)); ++ ++ node->rd_key = *key; ++ ON_DEBUG(node->rd_key_version = atomic_inc_return(&delim_key_version)); ++ return &node->rd_key; ++} ++ ++/* update left-delimiting key of @node */ ++reiser4_key *znode_set_ld_key(znode * node, const reiser4_key * key) ++{ ++ assert("nikita-2940", node != NULL); ++ assert("nikita-2941", key != NULL); ++ assert_rw_write_locked(&(znode_get_tree(node)->dk_lock)); ++ assert("nikita-3070", LOCK_CNT_GTZ(write_locked_dk)); ++ assert("nikita-2943", ++ znode_is_any_locked(node) || keyeq(&node->ld_key, ++ reiser4_min_key())); ++ ++ node->ld_key = *key; ++ ON_DEBUG(node->ld_key_version = atomic_inc_return(&delim_key_version)); ++ return &node->ld_key; ++} ++ ++/* true if @key is inside key range for @node */ ++int znode_contains_key(znode * node /* znode to look in */ , ++ const reiser4_key * key /* key to look for */ ) ++{ ++ assert("nikita-1237", node != NULL); ++ assert("nikita-1238", key != NULL); ++ ++ /* left_delimiting_key <= key <= right_delimiting_key */ ++ return keyle(znode_get_ld_key(node), key) ++ && keyle(key, znode_get_rd_key(node)); ++} ++ ++/* same as znode_contains_key(), but lock dk lock */ ++int znode_contains_key_lock(znode * node /* znode to look in */ , ++ const reiser4_key * key /* key to look for */ ) ++{ ++ int result; ++ ++ assert("umka-056", node != NULL); ++ assert("umka-057", key != NULL); ++ ++ read_lock_dk(znode_get_tree(node)); ++ result = znode_contains_key(node, key); ++ read_unlock_dk(znode_get_tree(node)); ++ return result; ++} ++ ++/* get parent pointer, assuming tree is not locked */ ++znode *znode_parent_nolock(const znode * node /* child znode */ ) ++{ ++ assert("nikita-1444", node != NULL); ++ return node->in_parent.node; ++} ++ ++/* get parent pointer of znode */ ++znode *znode_parent(const znode * node /* child znode */ ) ++{ ++ assert("nikita-1226", node != NULL); ++ assert("nikita-1406", LOCK_CNT_GTZ(rw_locked_tree)); ++ return znode_parent_nolock(node); ++} ++ ++/* detect uber znode used to protect in-superblock tree root pointer */ ++int znode_above_root(const znode * node /* znode to query */ ) ++{ ++ assert("umka-059", node != NULL); ++ ++ return disk_addr_eq(&ZJNODE(node)->blocknr, &UBER_TREE_ADDR); ++} ++ ++/* check that @node is root---that its block number is recorder in the tree as ++ that of root node */ ++#if REISER4_DEBUG ++static int znode_is_true_root(const znode *node) ++{ ++ assert("umka-060", node != NULL); ++ assert("edward-1803", znode_get_subvol(node) != NULL); ++ ++ return disk_addr_eq(znode_get_block(node), ++ &znode_get_tree(node)->root_block); ++} ++#endif ++ ++/* check that @node is root */ ++int znode_is_root(const znode *node) ++{ ++ assert("edward-1804", znode_get_subvol(node) != NULL); ++ ++ return znode_get_level(node) == znode_get_tree(node)->height; ++} ++ ++/* Returns true is @node was just created by zget() and wasn't ever loaded ++ into memory. */ ++/* NIKITA-HANS: yes */ ++int znode_just_created(const znode * node) ++{ ++ assert("nikita-2188", node != NULL); ++ return (znode_page(node) == NULL); ++} ++ ++/* obtain updated ->znode_epoch. See seal.c for description. */ ++__u64 znode_build_version(reiser4_tree * tree) ++{ ++ __u64 result; ++ ++ spin_lock(&tree->epoch_lock); ++ result = ++tree->znode_epoch; ++ spin_unlock(&tree->epoch_lock); ++ return result; ++} ++ ++void init_load_count(load_count * dh) ++{ ++ assert("nikita-2105", dh != NULL); ++ memset(dh, 0, sizeof *dh); ++} ++ ++void done_load_count(load_count * dh) ++{ ++ assert("nikita-2106", dh != NULL); ++ if (dh->node != NULL) { ++ for (; dh->d_ref > 0; --dh->d_ref) ++ zrelse(dh->node); ++ dh->node = NULL; ++ } ++} ++ ++static int incr_load_count(load_count * dh) ++{ ++ int result; ++ ++ assert("nikita-2110", dh != NULL); ++ assert("nikita-2111", dh->node != NULL); ++ ++ result = zload(dh->node); ++ if (result == 0) ++ ++dh->d_ref; ++ return result; ++} ++ ++int incr_load_count_znode(load_count * dh, znode * node) ++{ ++ assert("nikita-2107", dh != NULL); ++ assert("nikita-2158", node != NULL); ++ assert("nikita-2109", ++ ergo(dh->node != NULL, (dh->node == node) || (dh->d_ref == 0))); ++ ++ dh->node = node; ++ return incr_load_count(dh); ++} ++ ++int incr_load_count_jnode(load_count * dh, jnode * node) ++{ ++ if (jnode_is_znode(node)) { ++ return incr_load_count_znode(dh, JZNODE(node)); ++ } ++ return 0; ++} ++ ++void copy_load_count(load_count * new, load_count * old) ++{ ++ int ret = 0; ++ done_load_count(new); ++ new->node = old->node; ++ new->d_ref = 0; ++ ++ while ((new->d_ref < old->d_ref) && (ret = incr_load_count(new)) == 0) { ++ } ++ ++ assert("jmacd-87589", ret == 0); ++} ++ ++void move_load_count(load_count * new, load_count * old) ++{ ++ done_load_count(new); ++ new->node = old->node; ++ new->d_ref = old->d_ref; ++ old->node = NULL; ++ old->d_ref = 0; ++} ++ ++/* convert parent pointer into coord */ ++void parent_coord_to_coord(const parent_coord_t * pcoord, coord_t * coord) ++{ ++ assert("nikita-3204", pcoord != NULL); ++ assert("nikita-3205", coord != NULL); ++ ++ coord_init_first_unit_nocheck(coord, pcoord->node); ++ coord_set_item_pos(coord, pcoord->item_pos); ++ coord->between = AT_UNIT; ++} ++ ++/* pack coord into parent_coord_t */ ++void coord_to_parent_coord(const coord_t * coord, parent_coord_t * pcoord) ++{ ++ assert("nikita-3206", pcoord != NULL); ++ assert("nikita-3207", coord != NULL); ++ ++ pcoord->node = coord->node; ++ pcoord->item_pos = coord->item_pos; ++} ++ ++/* Initialize a parent hint pointer. (parent hint pointer is a field in znode, ++ look for comments there) */ ++void init_parent_coord(parent_coord_t * pcoord, const znode * node) ++{ ++ pcoord->node = (znode *) node; ++ pcoord->item_pos = (unsigned short)~0; ++} ++ ++#if REISER4_DEBUG ++ ++/* debugging aid: znode invariant */ ++static int znode_invariant_f(const znode * node /* znode to check */ , ++ char const **msg /* where to store error ++ * message, if any */ ) ++{ ++#define _ergo(ant, con) \ ++ ((*msg) = "{" #ant "} ergo {" #con "}", ergo((ant), (con))) ++ ++#define _equi(e1, e2) \ ++ ((*msg) = "{" #e1 "} <=> {" #e2 "}", equi((e1), (e2))) ++ ++#define _check(exp) ((*msg) = #exp, (exp)) ++ ++ return jnode_invariant_f(ZJNODE(node), msg) && ++ /* [znode-fake] invariant */ ++ /* fake znode doesn't have a parent, and */ ++ _ergo(znode_get_level(node) == 0, znode_parent(node) == NULL) && ++ /* there is another way to express this very check, and */ ++ _ergo(znode_above_root(node), znode_parent(node) == NULL) && ++ /* it has special block number, and */ ++ _ergo(znode_get_level(node) == 0, ++ disk_addr_eq(znode_get_block(node), &UBER_TREE_ADDR)) && ++ /* it is the only znode with such block number, and */ ++ _ergo(!znode_above_root(node) && znode_is_loaded(node), ++ !disk_addr_eq(znode_get_block(node), &UBER_TREE_ADDR)) && ++ /* it is parent of the tree root node */ ++ _ergo(znode_is_true_root(node), ++ znode_above_root(znode_parent(node))) && ++ /* [znode-level] invariant */ ++ /* level of parent znode is one larger than that of child, ++ except for the fake znode, and */ ++ _ergo(znode_parent(node) && !znode_above_root(znode_parent(node)), ++ znode_get_level(znode_parent(node)) == ++ znode_get_level(node) + 1) && ++ /* left neighbor is at the same level, and */ ++ _ergo(znode_is_left_connected(node) && node->left != NULL, ++ znode_get_level(node) == znode_get_level(node->left)) && ++ /* right neighbor is at the same level */ ++ _ergo(znode_is_right_connected(node) && node->right != NULL, ++ znode_get_level(node) == znode_get_level(node->right)) && ++ /* [znode-connected] invariant */ ++ _ergo(node->left != NULL, znode_is_left_connected(node)) && ++ _ergo(node->right != NULL, znode_is_right_connected(node)) && ++ _ergo(!znode_is_root(node) && node->left != NULL, ++ znode_is_right_connected(node->left) && ++ node->left->right == node) && ++ _ergo(!znode_is_root(node) && node->right != NULL, ++ znode_is_left_connected(node->right) && ++ node->right->left == node) && ++ /* [znode-c_count] invariant */ ++ /* for any znode, c_count of its parent is greater than 0 */ ++ _ergo(znode_parent(node) != NULL && ++ !znode_above_root(znode_parent(node)), ++ znode_parent(node)->c_count > 0) && ++ /* leaves don't have children */ ++ _ergo(znode_get_level(node) == LEAF_LEVEL, ++ node->c_count == 0) && ++ _check(node->zjnode.jnodes.prev != NULL) && ++ _check(node->zjnode.jnodes.next != NULL) && ++ /* orphan doesn't have a parent */ ++ _ergo(ZF_ISSET(node, JNODE_ORPHAN), znode_parent(node) == 0) && ++ /* [znode-modify] invariant */ ++ /* if znode is not write-locked, its checksum remains ++ * invariant */ ++ /* unfortunately, zlock is unordered w.r.t. jnode_lock, so we ++ * cannot check this. */ ++ /* [znode-refs] invariant */ ++ /* only referenced znode can be long-term locked */ ++ _ergo(znode_is_locked(node), ++ atomic_read(&ZJNODE(node)->x_count) != 0); ++} ++ ++/* ++ * debugging aid: check znode invariant and panic if it doesn't hold ++ * @node: znode to check ++ */ ++int znode_invariant(znode *node) ++{ ++ char const *failed_msg; ++ int result; ++ ++ assert("umka-063", node != NULL); ++ assert("edward-1805", znode_get_subvol(node) != NULL); ++ ++ spin_lock_znode(node); ++ read_lock_tree(); ++ result = znode_invariant_f(node, &failed_msg); ++ if (!result) { ++ /* print_znode("corrupted node", node); */ ++ warning("jmacd-555", "Condition %s failed", failed_msg); ++ } ++ read_unlock_tree(); ++ spin_unlock_znode(node); ++ return result; ++} ++ ++/* return non-0 iff data are loaded into znode */ ++int znode_is_loaded(const znode * node /* znode to query */ ) ++{ ++ assert("nikita-497", node != NULL); ++ return jnode_is_loaded(ZJNODE(node)); ++} ++ ++unsigned long znode_times_locked(const znode * z) ++{ ++ return z->times_locked; ++} ++ ++#endif /* REISER4_DEBUG */ ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/fs/reiser4/znode.h linux-5.10.2/fs/reiser4/znode.h +--- linux-5.10.2.orig/fs/reiser4/znode.h 1970-01-01 01:00:00.000000000 +0100 ++++ linux-5.10.2/fs/reiser4/znode.h 2020-12-23 16:07:46.138813421 +0100 +@@ -0,0 +1,441 @@ ++/* Copyright 2001, 2002, 2003, 2004 by Hans Reiser, licensing governed by ++ * reiser4/README */ ++ ++/* Declaration of znode (Zam's node). See znode.c for more details. */ ++ ++#ifndef __ZNODE_H__ ++#define __ZNODE_H__ ++ ++#include "forward.h" ++#include "debug.h" ++#include "dformat.h" ++#include "key.h" ++#include "coord.h" ++#include "plugin/node/node.h" ++#include "jnode.h" ++#include "lock.h" ++#include "readahead.h" ++ ++#include ++#include ++#include /* for PAGE_CACHE_SIZE */ ++#include ++ ++/* znode tracks its position within parent (internal item in a parent node, ++ * that contains znode's block number). */ ++typedef struct parent_coord { ++ znode *node; ++ pos_in_node_t item_pos; ++} parent_coord_t; ++ ++/* &znode - node in a reiser4 tree. ++ ++ NOTE-NIKITA fields in this struct have to be rearranged (later) to reduce ++ cacheline pressure. ++ ++ Locking: ++ ++ Long term: data in a disk node attached to this znode are protected ++ by long term, deadlock aware lock ->lock; ++ ++ Spin lock: the following fields are protected by the spin lock: ++ ++ ->lock ++ ++ Following fields are protected by the global tree lock: ++ ++ ->left ++ ->right ++ ->in_parent ++ ->c_count ++ ++ Following fields are protected by the global delimiting key lock (dk_lock): ++ ++ ->ld_key (to update ->ld_key long-term lock on the node is also required) ++ ->rd_key ++ ++ Following fields are protected by the long term lock: ++ ++ ->nr_items ++ ++ ->node_plugin is never changed once set. This means that after code made ++ itself sure that field is valid it can be accessed without any additional ++ locking. ++ ++ ->level is immutable. ++ ++ Invariants involving this data-type: ++ ++ [znode-fake] ++ [znode-level] ++ [znode-connected] ++ [znode-c_count] ++ [znode-refs] ++ [jnode-refs] ++ [jnode-queued] ++ [znode-modify] ++ ++ For this to be made into a clustering or NUMA filesystem, we would want to eliminate all of the global locks. ++ Suggestions for how to do that are desired.*/ ++struct znode { ++ /* Embedded jnode. */ ++ jnode zjnode; ++ ++ /* contains three subfields, node, pos_in_node, and pos_in_unit. ++ ++ pos_in_node and pos_in_unit are only hints that are cached to ++ speed up lookups during balancing. They are not required to be up to ++ date. Synched in find_child_ptr(). ++ ++ This value allows us to avoid expensive binary searches. ++ ++ in_parent->node points to the parent of this node, and is NOT a ++ hint. ++ */ ++ parent_coord_t in_parent; ++ ++ /* ++ * sibling list pointers ++ */ ++ ++ /* left-neighbor */ ++ znode *left; ++ /* right-neighbor */ ++ znode *right; ++ ++ /* long term lock on node content. This lock supports deadlock ++ detection. See lock.c ++ */ ++ zlock lock; ++ ++ /* You cannot remove from memory a node that has children in ++ memory. This is because we rely on the fact that parent of given ++ node can always be reached without blocking for io. When reading a ++ node into memory you must increase the c_count of its parent, when ++ removing it from memory you must decrease the c_count. This makes ++ the code simpler, and the cases where it is suboptimal are truly ++ obscure. ++ */ ++ int c_count; ++ ++ /* plugin of node attached to this znode. NULL if znode is not ++ loaded. */ ++ node_plugin *nplug; ++ ++ /* version of znode data. This is increased on each modification. This ++ * is necessary to implement seals (see seal.[ch]) efficiently. */ ++ __u64 version; ++ ++ /* left delimiting key. Necessary to efficiently perform ++ balancing with node-level locking. Kept in memory only. */ ++ reiser4_key ld_key; ++ /* right delimiting key. */ ++ reiser4_key rd_key; ++ ++ /* znode's tree level */ ++ __u16 level; ++ /* number of items in this node. This field is modified by node ++ * plugin. */ ++ __u16 nr_items; ++ ++#if REISER4_DEBUG ++ void *creator; ++ reiser4_key first_key; ++ unsigned long times_locked; ++ int left_version; /* when node->left was updated */ ++ int right_version; /* when node->right was updated */ ++ int ld_key_version; /* when node->ld_key was updated */ ++ int rd_key_version; /* when node->rd_key was updated */ ++#endif ++ ++} __attribute__ ((aligned(16))); ++ ++ON_DEBUG(extern atomic_t delim_key_version; ++ ) ++ ++/* In general I think these macros should not be exposed. */ ++#define znode_is_locked(node) (lock_is_locked(&node->lock)) ++#define znode_is_rlocked(node) (lock_is_rlocked(&node->lock)) ++#define znode_is_wlocked(node) (lock_is_wlocked(&node->lock)) ++#define znode_is_wlocked_once(node) (lock_is_wlocked_once(&node->lock)) ++#define znode_can_be_rlocked(node) (lock_can_be_rlocked(&node->lock)) ++#define is_lock_compatible(node, mode) (lock_mode_compatible(&node->lock, mode)) ++/* Macros for accessing the znode state. */ ++#define ZF_CLR(p,f) JF_CLR (ZJNODE(p), (f)) ++#define ZF_ISSET(p,f) JF_ISSET(ZJNODE(p), (f)) ++#define ZF_SET(p,f) JF_SET (ZJNODE(p), (f)) ++extern znode *zget(struct reiser4_subvol *subvol, ++ const reiser4_block_nr * const block, ++ znode * parent, tree_level level, gfp_t gfp_flag); ++extern znode *zlook(reiser4_tree * tree, const reiser4_block_nr * const block); ++extern int zload(znode * node); ++extern int zload_ra(znode * node, ra_info_t * info); ++extern int zinit_new(znode * node, gfp_t gfp_flags); ++extern void zrelse(znode * node); ++extern void znode_change_parent(znode * new_parent, reiser4_block_nr * block); ++extern void znode_update_csum(znode *node); ++ ++/* size of data in znode */ ++static inline unsigned ++znode_size(const znode * node UNUSED_ARG /* znode to query */ ) ++{ ++ assert("nikita-1416", node != NULL); ++ return PAGE_SIZE; ++} ++ ++extern void parent_coord_to_coord(const parent_coord_t * pcoord, ++ coord_t * coord); ++extern void coord_to_parent_coord(const coord_t * coord, ++ parent_coord_t * pcoord); ++extern void init_parent_coord(parent_coord_t * pcoord, const znode * node); ++ ++extern unsigned znode_free_space(znode * node); ++ ++extern reiser4_key *znode_get_rd_key(znode * node); ++extern reiser4_key *znode_get_ld_key(znode * node); ++ ++extern reiser4_key *znode_set_rd_key(znode * node, const reiser4_key * key); ++extern reiser4_key *znode_set_ld_key(znode * node, const reiser4_key * key); ++ ++/* `connected' state checks */ ++static inline int znode_is_right_connected(const znode * node) ++{ ++ return ZF_ISSET(node, JNODE_RIGHT_CONNECTED); ++} ++ ++static inline int znode_is_left_connected(const znode * node) ++{ ++ return ZF_ISSET(node, JNODE_LEFT_CONNECTED); ++} ++ ++static inline int znode_is_connected(const znode * node) ++{ ++ return znode_is_right_connected(node) && znode_is_left_connected(node); ++} ++ ++extern int znode_shift_order; ++extern int znode_rehash(znode * node, const reiser4_block_nr * new_block_nr); ++extern void znode_remove(znode *); ++extern znode *znode_parent(const znode * node); ++extern znode *znode_parent_nolock(const znode * node); ++extern int znode_above_root(const znode * node); ++extern int init_znode(jnode *node); ++extern int init_znodes(void); ++extern void done_znodes(void); ++extern int znodes_tree_init(reiser4_tree * ztree); ++extern void znodes_tree_done(reiser4_tree * ztree); ++extern int znode_contains_key(znode * node, const reiser4_key * key); ++extern int znode_contains_key_lock(znode * node, const reiser4_key * key); ++extern unsigned znode_save_free_space(znode * node); ++extern unsigned znode_recover_free_space(znode * node); ++extern znode *zalloc(gfp_t gfp_flag); ++extern void zinit(znode *, const znode *parent, struct reiser4_subvol *); ++extern int zparse(znode * node); ++ ++extern int znode_just_created(const znode * node); ++ ++extern void zfree(znode * node); ++ ++#if REISER4_DEBUG ++extern void print_znode(const char *prefix, const znode * node); ++#else ++#define print_znode( p, n ) noop ++#endif ++ ++/* Make it look like various znode functions exist instead of treating znodes as ++ jnodes in znode-specific code. */ ++#define znode_page(x) jnode_page ( ZJNODE(x) ) ++#define zdata(x) jdata ( ZJNODE(x) ) ++#define znode_get_block(x) jnode_get_block ( ZJNODE(x) ) ++#define znode_created(x) jnode_created ( ZJNODE(x) ) ++#define znode_set_created(x) jnode_set_created ( ZJNODE(x) ) ++#define znode_convertible(x) jnode_convertible (ZJNODE(x)) ++#define znode_set_convertible(x) jnode_set_convertible (ZJNODE(x)) ++ ++#define znode_is_dirty(x) jnode_is_dirty ( ZJNODE(x) ) ++#define znode_check_dirty(x) jnode_check_dirty ( ZJNODE(x) ) ++#define znode_make_clean(x) jnode_make_clean ( ZJNODE(x) ) ++#define znode_set_block(x, b) jnode_set_block ( ZJNODE(x), (b) ) ++ ++#define spin_lock_znode(x) spin_lock_jnode ( ZJNODE(x) ) ++#define spin_unlock_znode(x) spin_unlock_jnode ( ZJNODE(x) ) ++#define spin_trylock_znode(x) spin_trylock_jnode ( ZJNODE(x) ) ++#define spin_znode_is_locked(x) spin_jnode_is_locked ( ZJNODE(x) ) ++#define spin_znode_is_not_locked(x) spin_jnode_is_not_locked ( ZJNODE(x) ) ++ ++#if REISER4_DEBUG ++extern int znode_x_count_is_protected(const znode * node); ++extern int znode_invariant(znode * node); ++#endif ++ ++/* acquire reference to @node */ ++static inline znode *zref(znode * node) ++{ ++ /* change of x_count from 0 to 1 is protected by tree spin-lock */ ++ return JZNODE(jref(ZJNODE(node))); ++} ++ ++/* release reference to @node */ ++static inline void zput(znode * node) ++{ ++ assert("nikita-3564", znode_invariant(node)); ++ jput(ZJNODE(node)); ++} ++ ++/* get the level field for a znode */ ++static inline tree_level znode_get_level(const znode * node) ++{ ++ return node->level; ++} ++ ++/* get the level field for a jnode */ ++static inline tree_level jnode_get_level(const jnode * node) ++{ ++ if (jnode_is_znode(node)) ++ return znode_get_level(JZNODE(node)); ++ else ++ /* unformatted nodes are all at the LEAF_LEVEL and for ++ "semi-formatted" nodes like bitmaps, level doesn't matter. */ ++ return LEAF_LEVEL; ++} ++ ++/* true if jnode is on leaf level */ ++static inline int jnode_is_leaf(const jnode * node) ++{ ++ if (jnode_is_znode(node)) ++ return (znode_get_level(JZNODE(node)) == LEAF_LEVEL); ++ if (jnode_get_type(node) == JNODE_UNFORMATTED_BLOCK) ++ return 1; ++ return 0; ++} ++ ++static inline struct reiser4_subvol *znode_get_subvol(const znode *node) ++{ ++ return jnode_get_subvol(ZJNODE(node)); ++} ++ ++static inline struct super_block *znode_get_super(const znode *node) ++{ ++ return jnode_get_super(ZJNODE(node)); ++} ++ ++#define znode_get_tree(node) (&znode_get_subvol(node)->tree) ++ ++/* resolve race with zput */ ++static inline znode *znode_rip_check(znode *node) ++{ ++ jnode *j; ++ ++ j = jnode_rip_sync(ZJNODE(node)); ++ if (likely(j != NULL)) ++ node = JZNODE(j); ++ else ++ node = NULL; ++ return node; ++} ++ ++#if defined(REISER4_DEBUG) ++int znode_is_loaded(const znode * node /* znode to query */ ); ++#endif ++ ++extern __u64 znode_build_version(reiser4_tree * tree); ++ ++/* Data-handles. A data handle object manages pairing calls to zload() and zrelse(). We ++ must load the data for a node in many places. We could do this by simply calling ++ zload() everywhere, the difficulty arises when we must release the loaded data by ++ calling zrelse. In a function with many possible error/return paths, it requires extra ++ work to figure out which exit paths must call zrelse and those which do not. The data ++ handle automatically calls zrelse for every zload that it is responsible for. In that ++ sense, it acts much like a lock_handle. ++*/ ++typedef struct load_count { ++ znode *node; ++ int d_ref; ++} load_count; ++ ++extern void init_load_count(load_count * lc); /* Initialize a load_count set the current node to NULL. */ ++extern void done_load_count(load_count * dh); /* Finalize a load_count: call zrelse() if necessary */ ++extern int incr_load_count_znode(load_count * dh, znode * node); /* Set the argument znode to the current node, call zload(). */ ++extern int incr_load_count_jnode(load_count * dh, jnode * node); /* If the argument jnode is formatted, do the same as ++ * incr_load_count_znode, otherwise do nothing (unformatted nodes ++ * don't require zload/zrelse treatment). */ ++extern void move_load_count(load_count * new, load_count * old); /* Move the contents of a load_count. Old handle is released. */ ++extern void copy_load_count(load_count * new, load_count * old); /* Copy the contents of a load_count. Old handle remains held. */ ++ ++/* Variable initializers for load_count. */ ++#define INIT_LOAD_COUNT ( load_count * ){ .node = NULL, .d_ref = 0 } ++#define INIT_LOAD_COUNT_NODE( n ) ( load_count ){ .node = ( n ), .d_ref = 0 } ++/* A convenience macro for use in assertions or debug-only code, where loaded ++ data is only required to perform the debugging check. This macro ++ encapsulates an expression inside a pair of calls to zload()/zrelse(). */ ++#define WITH_DATA( node, exp ) \ ++({ \ ++ long __with_dh_result; \ ++ znode *__with_dh_node; \ ++ \ ++ __with_dh_node = ( node ); \ ++ __with_dh_result = zload( __with_dh_node ); \ ++ if( __with_dh_result == 0 ) { \ ++ __with_dh_result = ( long )( exp ); \ ++ zrelse( __with_dh_node ); \ ++ } \ ++ __with_dh_result; \ ++}) ++ ++/* Same as above, but accepts a return value in case zload fails. */ ++#define WITH_DATA_RET( node, ret, exp ) \ ++({ \ ++ int __with_dh_result; \ ++ znode *__with_dh_node; \ ++ \ ++ __with_dh_node = ( node ); \ ++ __with_dh_result = zload( __with_dh_node ); \ ++ if( __with_dh_result == 0 ) { \ ++ __with_dh_result = ( int )( exp ); \ ++ zrelse( __with_dh_node ); \ ++ } else \ ++ __with_dh_result = ( ret ); \ ++ __with_dh_result; \ ++}) ++ ++#define WITH_COORD(coord, exp) \ ++({ \ ++ coord_t *__coord; \ ++ \ ++ __coord = (coord); \ ++ coord_clear_iplug(__coord); \ ++ WITH_DATA(__coord->node, exp); \ ++}) ++ ++#if REISER4_DEBUG ++#define STORE_COUNTERS \ ++ reiser4_lock_cnt_info __entry_counters = \ ++ *reiser4_lock_counters() ++#define CHECK_COUNTERS \ ++ON_DEBUG_CONTEXT( \ ++({ \ ++ __entry_counters.x_refs = reiser4_lock_counters() -> x_refs; \ ++ __entry_counters.t_refs = reiser4_lock_counters() -> t_refs; \ ++ __entry_counters.d_refs = reiser4_lock_counters() -> d_refs; \ ++ assert("nikita-2159", \ ++ !memcmp(&__entry_counters, reiser4_lock_counters(), \ ++ sizeof __entry_counters)); \ ++}) ) ++ ++#else ++#define STORE_COUNTERS ++#define CHECK_COUNTERS noop ++#endif ++ ++/* __ZNODE_H__ */ ++#endif ++ ++/* Make Linus happy. ++ Local variables: ++ c-indentation-style: "K&R" ++ mode-name: "LC" ++ c-basic-offset: 8 ++ tab-width: 8 ++ fill-column: 120 ++ End: ++*/ +diff -urN --no-dereference linux-5.10.2.orig/include/linux/fs.h linux-5.10.2/include/linux/fs.h +--- linux-5.10.2.orig/include/linux/fs.h 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/include/linux/fs.h 2020-12-23 16:07:46.138813421 +0100 +@@ -245,7 +245,7 @@ + */ + #define FILESYSTEM_MAX_STACK_DEPTH 2 + +-/** ++/** + * enum positive_aop_returns - aop return codes with specific semantics + * + * @AOP_WRITEPAGE_ACTIVATE: Informs the caller that page writeback has +@@ -255,7 +255,7 @@ + * be a candidate for writeback again in the near + * future. Other callers must be careful to unlock + * the page if they get this return. Returned by +- * writepage(); ++ * writepage(); + * + * @AOP_TRUNCATED_PAGE: The AOP method that was handed a locked page has + * unlocked it and the page might have been truncated. +@@ -288,6 +288,8 @@ + struct address_space; + struct writeback_control; + struct readahead_control; ++struct wb_writeback_work; ++struct bdi_writeback; + + /* + * Write life time hint values. +@@ -413,6 +415,7 @@ + int (*swap_activate)(struct swap_info_struct *sis, struct file *file, + sector_t *span); + void (*swap_deactivate)(struct file *file); ++ int batch_lock_tabu; + }; + + extern const struct address_space_operations empty_aops; +@@ -1951,6 +1954,14 @@ + int (*remount_fs) (struct super_block *, int *, char *); + void (*umount_begin) (struct super_block *); + ++ long (*writeback_inodes)(struct super_block *sb, ++ struct bdi_writeback *wb, ++ struct writeback_control *wbc, ++ struct wb_writeback_work *work, ++ bool flush_all); ++ void (*sync_inodes) (struct super_block *sb, ++ struct writeback_control *wbc); ++ + int (*show_options)(struct seq_file *, struct dentry *); + int (*show_devname)(struct seq_file *, struct dentry *); + int (*show_path)(struct seq_file *, struct dentry *); +@@ -2620,6 +2631,13 @@ + extern int invalidate_inode_pages2_range(struct address_space *mapping, + pgoff_t start, pgoff_t end); + extern int write_inode_now(struct inode *, int); ++extern void writeback_skip_sb_inodes(struct super_block *sb, ++ struct bdi_writeback *wb); ++extern long generic_writeback_sb_inodes(struct super_block *sb, ++ struct bdi_writeback *wb, ++ struct writeback_control *wbc, ++ struct wb_writeback_work *work, ++ bool flush_all); + extern int filemap_fdatawrite(struct address_space *); + extern int filemap_flush(struct address_space *); + extern int filemap_fdatawait_keep_errors(struct address_space *mapping); +@@ -2855,7 +2873,7 @@ + extern ssize_t kernel_write(struct file *, const void *, size_t, loff_t *); + extern ssize_t __kernel_write(struct file *, const void *, size_t, loff_t *); + extern struct file * open_exec(const char *); +- ++ + /* fs/dcache.c -- generic fs support functions */ + extern bool is_subdir(struct dentry *, struct dentry *); + extern bool path_is_under(const struct path *, const struct path *); +@@ -2865,6 +2883,8 @@ + #include + + /* needed for stackable file system support */ ++extern loff_t default_llseek_unlocked(struct file *file, loff_t offset, ++ int whence); + extern loff_t default_llseek(struct file *file, loff_t offset, int whence); + + extern loff_t vfs_llseek(struct file *file, loff_t offset, int whence); +@@ -2973,6 +2993,8 @@ + extern ssize_t generic_file_direct_write(struct kiocb *, struct iov_iter *); + extern ssize_t generic_perform_write(struct file *, struct iov_iter *, loff_t); + ++ssize_t new_sync_read(struct file *filp, char __user *buf, size_t len, ++ loff_t *ppos); + ssize_t vfs_iter_read(struct file *file, struct iov_iter *iter, loff_t *ppos, + rwf_t flags); + ssize_t vfs_iter_write(struct file *file, struct iov_iter *iter, loff_t *ppos, +diff -urN --no-dereference linux-5.10.2.orig/include/linux/miscdevice.h linux-5.10.2/include/linux/miscdevice.h +--- linux-5.10.2.orig/include/linux/miscdevice.h 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/include/linux/miscdevice.h 2020-12-23 16:07:46.139813436 +0100 +@@ -71,6 +71,7 @@ + #define USERIO_MINOR 240 + #define VHOST_VSOCK_MINOR 241 + #define RFKILL_MINOR 242 ++#define REISER4_MINOR 243 + #define MISC_DYNAMIC_MINOR 255 + + struct device; +diff -urN --no-dereference linux-5.10.2.orig/include/linux/mm.h linux-5.10.2/include/linux/mm.h +--- linux-5.10.2.orig/include/linux/mm.h 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/include/linux/mm.h 2020-12-23 16:07:46.139813436 +0100 +@@ -1813,6 +1813,7 @@ + struct bdi_writeback *wb); + int set_page_dirty(struct page *page); + int set_page_dirty_lock(struct page *page); ++int set_page_dirty_notag(struct page *page); + void __cancel_dirty_page(struct page *page); + static inline void cancel_dirty_page(struct page *page) + { +diff -urN --no-dereference linux-5.10.2.orig/include/linux/writeback.h linux-5.10.2/include/linux/writeback.h +--- linux-5.10.2.orig/include/linux/writeback.h 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/include/linux/writeback.h 2020-12-23 16:08:55.166816643 +0100 +@@ -185,8 +185,27 @@ + } + + /* ++ * Passed into wb_writeback(), essentially a subset of writeback_control ++ */ ++struct wb_writeback_work { ++ long nr_pages; ++ struct super_block *sb; ++ enum writeback_sync_modes sync_mode; ++ unsigned int tagged_writepages:1; ++ unsigned int for_kupdate:1; ++ unsigned int range_cyclic:1; ++ unsigned int for_background:1; ++ unsigned int for_sync:1; /* sync(2) WB_SYNC_ALL writeback */ ++ unsigned int auto_free:1; /* free on completion */ ++ enum wb_reason reason; /* why was writeback initiated? */ ++ ++ struct list_head list; /* pending work list */ ++ struct wb_completion *done; /* set if the caller waits */ ++}; ++ ++/* + * fs/fs-writeback.c +- */ ++ */ + struct bdi_writeback; + void writeback_inodes_sb(struct super_block *, enum wb_reason reason); + void writeback_inodes_sb_nr(struct super_block *, unsigned long nr, +diff -urN --no-dereference linux-5.10.2.orig/mm/filemap.c linux-5.10.2/mm/filemap.c +--- linux-5.10.2.orig/mm/filemap.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/mm/filemap.c 2020-12-23 16:07:46.140813451 +0100 +@@ -2018,6 +2018,7 @@ + + return ret; + } ++EXPORT_SYMBOL(find_get_pages_range); + + /** + * find_get_pages_contig - gang contiguous pagecache lookup +diff -urN --no-dereference linux-5.10.2.orig/mm/page-writeback.c linux-5.10.2/mm/page-writeback.c +--- linux-5.10.2.orig/mm/page-writeback.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/mm/page-writeback.c 2020-12-23 16:07:46.140813451 +0100 +@@ -2528,6 +2528,35 @@ + EXPORT_SYMBOL(account_page_redirty); + + /* ++ * set_page_dirty_notag() -- similar to __set_page_dirty_nobuffers() ++ * except it doesn't tag the page dirty in the page-cache radix tree. ++ * This means that the address space using this cannot use the regular ++ * filemap ->writepages() helpers and must provide its own means of ++ * tracking and finding non-tagged dirty pages. ++ * ++ * NOTE: furthermore, this version also doesn't handle truncate races. ++ */ ++int set_page_dirty_notag(struct page *page) ++{ ++ struct address_space *mapping = page->mapping; ++ ++ lock_page_memcg(page); ++ if (!TestSetPageDirty(page)) { ++ unsigned long flags; ++ WARN_ON_ONCE(!PagePrivate(page) && !PageUptodate(page)); ++ local_irq_save(flags); ++ account_page_dirtied(page, mapping); ++ local_irq_restore(flags); ++ unlock_page_memcg(page); ++ __mark_inode_dirty(mapping->host, I_DIRTY_PAGES); ++ return 1; ++ } ++ unlock_page_memcg(page); ++ return 0; ++} ++EXPORT_SYMBOL(set_page_dirty_notag); ++ ++/* + * When a writepage implementation decides that it doesn't want to write this + * page for some reason, it should redirty the locked page via + * redirty_page_for_writepage() and it should then unlock the page and return 0 +diff -urN --no-dereference linux-5.10.2.orig/mm/truncate.c linux-5.10.2/mm/truncate.c +--- linux-5.10.2.orig/mm/truncate.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/mm/truncate.c 2020-12-23 16:07:46.140813451 +0100 +@@ -360,6 +360,13 @@ + continue; + } + pagevec_add(&locked_pvec, page); ++ if (mapping->a_ops->batch_lock_tabu) ++ /* ++ * the file system doesn't allow to hold ++ * many pages locked, while calling ++ * ->invalidatepage() for one of them ++ */ ++ break; + } + for (i = 0; i < pagevec_count(&locked_pvec); i++) + truncate_cleanup_page(mapping, locked_pvec.pages[i]); +diff -urN --no-dereference linux-5.10.2.orig/mm/vmscan.c linux-5.10.2/mm/vmscan.c +--- linux-5.10.2.orig/mm/vmscan.c 2020-12-21 13:30:08.000000000 +0100 ++++ linux-5.10.2/mm/vmscan.c 2020-12-23 16:07:46.141813465 +0100 +@@ -3016,7 +3016,11 @@ + pg_data_t *last_pgdat; + struct zoneref *z; + struct zone *zone; ++ void *saved; + retry: ++ saved = current->journal_info; /* save journal info */ ++ current->journal_info = NULL; ++ + delayacct_freepages_start(); + + if (!cgroup_reclaim(sc)) +@@ -3061,6 +3065,8 @@ + } + + delayacct_freepages_end(); ++ /* restore journal info */ ++ current->journal_info = saved; + + if (sc->nr_reclaimed) + return sc->nr_reclaimed;