From patchwork Fri Dec 30 22:10:53 2022 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 8bit X-Patchwork-Submitter: "Darrick J. Wong" X-Patchwork-Id: 13084603 Return-Path: X-Spam-Checker-Version: SpamAssassin 3.4.0 (2014-02-07) on aws-us-west-2-korg-lkml-1.web.codeaurora.org Received: from vger.kernel.org (vger.kernel.org [23.128.96.18]) by smtp.lore.kernel.org (Postfix) with ESMTP id 33CFBC10F1B for ; Fri, 30 Dec 2022 22:32:06 +0000 (UTC) Received: (majordomo@vger.kernel.org) by vger.kernel.org via listexpand id S231256AbiL3WcE (ORCPT ); Fri, 30 Dec 2022 17:32:04 -0500 Received: from lindbergh.monkeyblade.net ([23.128.96.19]:52392 "EHLO lindbergh.monkeyblade.net" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S235634AbiL3Wb5 (ORCPT ); Fri, 30 Dec 2022 17:31:57 -0500 Received: from dfw.source.kernel.org (dfw.source.kernel.org [139.178.84.217]) by lindbergh.monkeyblade.net (Postfix) with ESMTPS id BE3BC1AA0A; Fri, 30 Dec 2022 14:31:54 -0800 (PST) Received: from smtp.kernel.org (relay.kernel.org [52.25.139.140]) (using TLSv1.2 with cipher ECDHE-RSA-AES256-GCM-SHA384 (256/256 bits)) (No client certificate requested) by dfw.source.kernel.org (Postfix) with ESMTPS id 4A18D61C2A; Fri, 30 Dec 2022 22:31:54 +0000 (UTC) Received: by smtp.kernel.org (Postfix) with ESMTPSA id A15F3C433D2; Fri, 30 Dec 2022 22:31:53 +0000 (UTC) DKIM-Signature: v=1; a=rsa-sha256; c=relaxed/simple; d=kernel.org; s=k20201202; t=1672439513; bh=FtvHP3fwzOs/aNRW7mop6R7OqWHDqj2mL+J5i/CCeOU=; h=Subject:From:To:Cc:Date:In-Reply-To:References:From; b=igiCsWrO8a58Z8kwbJYNG7f2MDNDRuc+3Tl4x5xPckgPwelmOKcvr3MyH3IxOk0Em xRduvYZZpvCtcUPL6wx+hK+e7ED1friU4jRQYREnA779BAEGUKQbIeuwRMn6WFPeKE 5zmcRT3H0GT09xiqFEwUHXWgMRTNtEZg/Gb2kF//JOpn+ajPhMjwekf1kf6IDrgMVy GwN/OwjIDjgvxA+nAoYGj8fkkYI280ejwDbP04BQfHc0u8wohkVIRlQKaBgpz+wh3i FQfohO/Vwq7YWsplmVTWw8T49uwL1KdUOwUnWwkcmgcq6cZFADAAEc7Tro4L88o9ig RZfAc2cn7iyqA== Subject: [PATCH 10/14] xfs: document full filesystem scans for online fsck From: "Darrick J. Wong" To: djwong@kernel.org Cc: linux-xfs@vger.kernel.org, willy@infradead.org, chandan.babu@oracle.com, allison.henderson@oracle.com, linux-fsdevel@vger.kernel.org, hch@infradead.org, catherine.hoang@oracle.com, david@fromorbit.com Date: Fri, 30 Dec 2022 14:10:53 -0800 Message-ID: <167243825302.682859.6563684998299886921.stgit@magnolia> In-Reply-To: <167243825144.682859.12802259329489258661.stgit@magnolia> References: <167243825144.682859.12802259329489258661.stgit@magnolia> User-Agent: StGit/0.19 MIME-Version: 1.0 Precedence: bulk List-ID: X-Mailing-List: linux-fsdevel@vger.kernel.org From: Darrick J. Wong Certain parts of the online fsck code need to scan every file in the entire filesystem. It is not acceptable to block the entire filesystem while this happens, which means that we need to be clever in allowing scans to coordinate with ongoing filesystem updates. We also need to hook the filesystem so that regular updates propagate to the staging records. Signed-off-by: Darrick J. Wong --- .../filesystems/xfs-online-fsck-design.rst | 677 ++++++++++++++++++++ 1 file changed, 677 insertions(+) diff --git a/Documentation/filesystems/xfs-online-fsck-design.rst b/Documentation/filesystems/xfs-online-fsck-design.rst index a658da8fe4ae..c0f08a773f08 100644 --- a/Documentation/filesystems/xfs-online-fsck-design.rst +++ b/Documentation/filesystems/xfs-online-fsck-design.rst @@ -3018,3 +3018,680 @@ The proposed patchset is the `summary counter cleanup `_ series. + +Full Filesystem Scans +--------------------- + +Certain types of metadata can only be checked by walking every file in the +entire filesystem to record observations and comparing the observations against +what's recorded on disk. +Like every other type of online repair, repairs are made by writing those +observations to disk in a replacement structure and committing it atomically. +However, it is not practical to shut down the entire filesystem to examine +hundreds of billions of files because the downtime would be excessive. +Therefore, online fsck must build the infrastructure to manage a live scan of +all the files in the filesystem. +There are two questions that need to be solved to perform a live walk: + +- How does scrub manage the scan while it is collecting data? + +- How does the scan keep abreast of changes being made to the system by other + threads? + +.. _iscan: + +Coordinated Inode Scans +``````````````````````` + +In the original Unix filesystems of the 1970s, each directory entry contained +an index number (*inumber*) which was used as an index into on ondisk array +(*itable*) of fixed-size records (*inodes*) describing a file's attributes and +its data block mapping. +This system is described by J. Lions, `"inode (5659)" +`_ in *Lions' Commentary on +UNIX, 6th Edition*, (Dept. of Computer Science, the University of New South +Wales, November 1977), pp. 18-2; and later by D. Ritchie and K. Thompson, +`"Implementation of the File System" +`_, from *The UNIX +Time-Sharing System*, (The Bell System Technical Journal, July 1978), pp. +1913-4. + +XFS retains most of this design, except now inumbers are search keys over all +the space in the data section filesystem. +They form a continuous keyspace that can be expressed as a 64-bit integer, +though the inodes themselves are sparsely distributed within the keyspace. +Scans proceed in a linear fashion across the inumber keyspace, starting from +``0x0`` and ending at ``0xFFFFFFFFFFFFFFFF``. +Naturally, a scan through a keyspace requires a scan cursor object to track the +scan progress. +Because this keyspace is sparse, this cursor contains two parts. +The first part of this scan cursor object tracks the inode that will be +examined next; call this the examination cursor. +Somewhat less obviously, the scan cursor object must also track which parts of +the keyspace have already been visited, which is critical for deciding if a +concurrent filesystem update needs to be incorporated into the scan data. +Call this the visited inode cursor. + +Advancing the scan cursor is a multi-step process encapsulated in +``xchk_iscan_iter``: + +1. Lock the AGI buffer of the AG containing the inode pointed to by the visited + inode cursor. + This guarantee that inodes in this AG cannot be allocated or freed while + advancing the cursor. + +2. Use the per-AG inode btree to look up the next inumber after the one that + was just visited, since it may not be keyspace adjacent. + +3. If there are no more inodes left in this AG: + + a. Move the examination cursor to the point of the inumber keyspace that + corresponds to the start of the next AG. + + b. Adjust the visited inode cursor to indicate that it has "visited" the + last possible inode in the current AG's inode keyspace. + XFS inumbers are segmented, so the cursor needs to be marked as having + visited the entire keyspace up to just before the start of the next AG's + inode keyspace. + + c. Unlock the AGI and return to step 1 if there are unexamined AGs in the + filesystem. + + d. If there are no more AGs to examine, set both cursors to the end of the + inumber keyspace. + The scan is now complete. + +4. Otherwise, there is at least one more inode to scan in this AG: + + a. Move the examination cursor ahead to the next inode marked as allocated + by the inode btree. + + b. Adjust the visited inode cursor to point to the inode just prior to where + the examination cursor is now. + Because the scanner holds the AGI buffer lock, no inodes could have been + created in the part of the inode keyspace that the visited inode cursor + just advanced. + +5. Get the incore inode for the inumber of the examination cursor. + By maintaining the AGI buffer lock until this point, the scanner knows that + it was safe to advance the examination cursor across the entire keyspace, + and that it has stabilized this next inode so that it cannot disappear from + the filesystem until the scan releases the incore inode. + +6. Drop the AGI lock and return the incore inode to the caller. + +Online fsck functions scan all files in the filesystem as follows: + +1. Start a scan by calling ``xchk_iscan_start``. + +2. Advance the scan cursor (``xchk_iscan_iter``) to get the next inode. + If one is provided: + + a. Lock the inode to prevent updates during the scan. + + b. Scan the inode. + + c. While still holding the inode lock, adjust the visited inode cursor + (``xchk_iscan_mark_visited``) to point to this inode. + + d. Unlock and release the inode. + +8. Call ``xchk_iscan_finish`` to complete the scan. + +There are subtleties with the inode cache that complicate grabbing the incore +inode for the caller. +Obviously, it is an absolute requirement that the inode metadata be consistent +enough to load it into the inode cache. +Second, if the incore inode is stuck in some intermediate state, the scan +coordinator must release the AGI and push the main filesystem to get the inode +back into a loadable state. + +The proposed patches are the +`inode scanner +`_ +series. + +Inode Management +```````````````` + +In regular filesystem code, references to allocated XFS incore inodes are +always obtained (``xfs_iget``) outside of transaction context because the +creation of the incore context for ane xisting file does not require metadata +updates. +However, it is important to note that references to incore inodes obtained as +part of file creation must be performed in transaction context because the +filesystem must ensure the atomicity of the ondisk inode btree index updates +and the initialization of the actual ondisk inode. + +References to incore inodes are always released (``xfs_irele``) outside of +transaction context because there are a handful of activities that might +require ondisk updates: + +- The VFS may decide to kick off writeback as part of a ``DONTCACHE`` inode + release. + +- Speculative preallocations need to be unreserved. + +- An unlinked file may have lost its last reference, in which case the entire + file must be inactivated, which involves releasing all of its resources in + the ondisk metadata and freeing the inode. + +These activities are collectively called inode inactivation. +Inactivation has two parts -- the VFS part, which initiates writeback on all +dirty file pages, and the XFS part, which cleans up XFS-specific information +and frees the inode if it was unlinked. +If the inode is unlinked (or unconnected after a file handle operation), the +kernel drops the inode into the inactivation machinery immediately. + +During normal operation, resource acquisition for an update follows this order +to avoid deadlocks: + +1. Inode reference (``iget``). + +2. Filesystem freeze protection, if repairing (``mnt_want_write_file``). + +3. Inode ``IOLOCK`` (VFS ``i_rwsem``) lock to control file IO. + +4. Inode ``MMAPLOCK`` (page cache ``invalidate_lock``) lock for operations that + can update page cache mappings. + +5. Log feature enablement. + +6. Transaction log space grant. + +7. Space on the data and realtime devices for the transaction. + +8. Incore dquot references, if a file is being repaired. + Note that they are not locked, merely acquired. + +9. Inode ``ILOCK`` for file metadata updates. + +10. AG header buffer locks / Realtime metadata inode ILOCK. + +11. Realtime metadata buffer locks, if applicable. + +12. Extent mapping btree blocks, if applicable. + +Resources are often released in the reverse order, though this is not required. +However, online fsck differs from regular XFS operations because it may examine +an object that normally is acquired in a later stage of the locking order, and +then decide to cross-reference the object with an object that is acquired +earlier in the order. +The next few sections detail the specific ways in which online fsck takes care +to avoid deadlocks. + +iget and irele During a Scrub +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +An inode scan performed on behalf of a scrub operation runs in transaction +context, and possibly with resources already locked and bound to it. +This isn't much of a problem for ``iget`` since it can operate in the context +of an existing transaction, as long as all of the bound resources are acquired +before the inode reference in the regular filesystem. + +When the VFS ``iput`` function is given a linked inode with no other +references, it normally puts the inode on an LRU list in the hope that it can +save time if another process re-opens the file before the system runs out +of memory and frees it. +Filesystem callers can short-circuit the LRU process by setting a ``DONTCACHE`` +flag on the inode to cause the kernel to try to drop the inode into the +inactivation machinery immediately. + +In the past, inactivation was always done from the process that dropped the +inode, which was a problem for scrub because scrub may already hold a +transaction, and XFS does not support nesting transactions. +On the other hand, if there is no scrub transaction, it is desirable to drop +otherwise unused inodes immediately to avoid polluting caches. +To capture these nuances, the online fsck code has a separate ``xchk_irele`` +function to set or clear the ``DONTCACHE`` flag to get the required release +behavior. + +Proposed patchsets include fixing +`scrub iget usage +`_ and +`dir iget usage +`_. + +Locking Inodes +^^^^^^^^^^^^^^ + +In regular filesystem code, the VFS and XFS will acquire multiple IOLOCK locks +in a well-known order: parent → child when updating the directory tree, and +``struct inode`` address order otherwise. +For regular files, the MMAPLOCK can be acquired after the IOLOCK to stop page +faults. +If two MMAPLOCKs must be acquired, they are acquired in ``struct +address_space`` order. +Due to the structure of existing filesystem code, IOLOCKs and MMAPLOCKs must be +acquired before transactions are allocated. +If two ILOCKs must be acquired, they are acquired in inumber order. + +Inode lock acquisition must be done carefully during a coordinated inode scan. +Online fsck cannot abide these conventions, because for a directory tree +scanner, the scrub process holds the IOLOCK of the file being scanned and it +needs to take the IOLOCK of the file at the other end of the directory link. +If the directory tree is corrupt because it contains a cycle, ``xfs_scrub`` +cannot use the regular inode locking functions and avoid becoming trapped in an +ABBA deadlock. + +Solving both of these problems is straightforward -- any time online fsck +needs to take a second lock of the same class, it uses trylock to avoid an ABBA +deadlock. +If the trylock fails, scrub drops all inode locks and use trylock loops to +(re)acquire all necessary resources. +Trylock loops enable scrub to check for pending fatal signals, which is how +scrub avoids deadlocking the filesystem or becoming an unresponsive process. +However, trylock loops means that online fsck must be prepared to measure the +resource being scrubbed before and after the lock cycle to detect changes and +react accordingly. + +.. _dirparent: + +Case Study: Finding a Directory Parent +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +Consider the directory parent pointer repair code as an example. +Online fsck must verify that the dotdot dirent of a directory points up to a +parent directory, and that the parent directory contains exactly one dirent +pointing down to the child directory. +Fully validating this relationship (and repairing it if possible) requires a +walk of every directory on the filesystem while holding the child locked, and +while updates to the directory tree are being made. +The coordinated inode scan provides a way to walk the filesystem without the +possibility of missing an inode. +The child directory is kept locked to prevent updates to the dotdot dirent, but +if the scanner fails to lock a parent, it can drop and relock both the child +and the prospective parent. +If the dotdot entry changes while the directory is unlocked, then a move or +rename operation must have changed the child's parentage, and the scan can +exit early. + +The proposed patchset is the +`directory repair +`_ +series. + +.. _fshooks: + +Filesystem Hooks +````````````````` + +The second piece of support that online fsck functions need during a full +filesystem scan is the ability to stay informed about updates being made by +other threads in the filesystem, since comparisons against the past are useless +in a dynamic environment. +Two pieces of Linux kernel infrastructure enable online fsck to monitor regular +filesystem operations: filesystem hooks and :ref:`static keys`. + +Filesystem hooks convey information about an ongoing filesystem operation to +a downstream consumer. +In this case, the downstream consumer is always an online fsck function. +Because multiple fsck functions can run in parallel, online fsck uses the Linux +notifier call chain facility to dispatch updates to any number of interested +fsck processes. +Call chains are a dynamic list, which means that they can be configured at +run time. +Because these hooks are private to the XFS module, the information passed along +contains exactly what the checking function needs to update its observations. + +The current implementation of XFS hooks uses SRCU notifier chains to reduce the +impact to highly threaded workloads. +Regular blocking notifier chains use a rwsem and seem to have a much lower +overhead for single-threaded applications. +However, it may turn out that the combination of blocking chains and static +keys are a more performant combination; more study is needed here. + +The following pieces are necessary to hook a certain point in the filesystem: + +- A ``struct xfs_hooks`` object must be embedded in a convenient place such as + a well-known incore filesystem object. + +- Each hook must define an action code and a structure containing more context + about the action. + +- Hook providers should provide appropriate wrapper functions and structs + around the ``xfs_hooks`` and ``xfs_hook`` objects to take advantage of type + checking to ensure correct usage. + +- A callsite in the regular filesystem code must be chosen to call + ``xfs_hooks_call`` with the action code and data structure. + This place should be adjacent to (and not earlier than) the place where + the filesystem update is committed to the transaction. + In general, when the filesystem calls a hook chain, it should be able to + handle sleeping and should not be vulnerable to memory reclaim or locking + recursion. + However, the exact requirements are very dependent on the context of the hook + caller and the callee. + +- The online fsck function should define a structure to hold scan data, a lock + to coordinate access to the scan data, and a ``struct xfs_hook`` object. + The scanner function and the regular filesystem code must acquire resources + in the same order; see the next section for details. + +- The online fsck code must contain a C function to catch the hook action code + and data structure. + If the object being updated has already been visited by the scan, then the + hook information must be applied to the scan data. + +- Prior to unlocking inodes to start the scan, online fsck must call + ``xfs_hooks_setup`` to initialize the ``struct xfs_hook``, and + ``xfs_hooks_add`` to enable the hook. + +- Online fsck must call ``xfs_hooks_del`` to disable the hook once the scan is + complete. + +The number of hooks should be kept to a minimum to reduce complexity. +Static keys are used to reduce the overhead of filesystem hooks to nearly +zero when online fsck is not running. + +.. _liveupdate: + +Live Updates During a Scan +`````````````````````````` + +The code paths of the online fsck scanning code and the :ref:`hooked` +filesystem code look like this:: + + other program + ↓ + inode lock ←────────────────────┐ + ↓ │ + AG header lock │ + ↓ │ + filesystem function │ + ↓ │ + notifier call chain │ same + ↓ ├─── inode + scrub hook function │ lock + ↓ │ + scan data mutex ←──┐ same │ + ↓ ├─── scan │ + update scan data │ lock │ + ↑ │ │ + scan data mutex ←──┘ │ + ↑ │ + inode lock ←────────────────────┘ + ↑ + scrub function + ↑ + inode scanner + ↑ + xfs_scrub + +These rules must be followed to ensure correct interactions between the +checking code and the code making an update to the filesystem: + +- Prior to invoking the notifier call chain, the filesystem function being + hooked must acquire the same lock that the scrub scanning function acquires + to scan the inode. + +- The scanning function and the scrub hook function must coordinate access to + the scan data by acquiring a lock on the scan data. + +- Scrub hook function must not add the live update information to the scan + observations unless the inode being updated has already been scanned. + The scan coordinator has a helper predicate (``xchk_iscan_want_live_update``) + for this. + +- Scrub hook functions must not change the caller's state, including the + transaction that it is running. + They must not acquire any resources that might conflict with the filesystem + function being hooked. + +- The hook function can abort the inode scan to avoid breaking the other rules. + +The inode scan APIs are pretty simple: + +- ``xchk_iscan_start`` starts a scan + +- ``xchk_iscan_iter`` grabs a reference to the next inode in the scan or + returns zero if there is nothing left to scan + +- ``xchk_iscan_want_live_update`` to decide if an inode has already been + visited in the scan. + This is critical for hook functions to decide if they need to update the + in-memory scan information. + +- ``xchk_iscan_mark_visited`` to mark an inode as having been visited in the + scan + +- ``xchk_iscan_finish`` to finish the scan + +The proposed patches are at the start of the +`online quotacheck +`_ +series. + +.. _quotacheck: + +Case Study: Quota Counter Checking +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +It is useful to compare the mount time quotacheck code to the online repair +quotacheck code. +Mount time quotacheck does not have to contend with concurrent operations, so +it does the following: + +1. Make sure the ondisk dquots are in good enough shape that all the incore + dquots will actually load, and zero the resource usage counters in the + ondisk buffer. + +2. Walk every inode in the filesystem. + Add each file's resource usage to the incore dquot. + +3. Walk each incore dquot. + If the incore dquot is not being flushed, add the ondisk buffer backing the + incore dquot to a delayed write (delwri) list. + +4. Write the buffer list to disk. + +Like most online fsck functions, online quotacheck can't write to regular +filesystem objects until the newly collected metadata reflect all filesystem +state. +Therefore, online quotacheck records file resource usage to a shadow dquot +index implemented with a sparse ``xfarray``, and only writes to the real dquots +once the scan is complete. +Handling transactional updates is tricky because quota resource usage updates +are handled in phases to minimize contention on dquots: + +1. The inodes involved are joined and locked to a transaction. + +2. For each dquot attached to the file: + + a. The dquot is locked. + + b. A quota reservation is added to the dquot's resource usage. + The reservation is recorded in the transaction. + + c. The dquot is unlocked. + +3. Changes in actual quota usage are tracked in the transaction. + +4. At transaction commit time, each dquot is examined again: + + a. The dquot is locked again. + + b. Quota usage changes are logged and unused reservation is given back to + the dquot. + + c. The dquot is unlocked. + +For online quotacheck, hooks are placed in steps 2 and 4. +The step 2 hook creates a shadow version of the transaction dquot context +(``dqtrx``) that operates in a similar manner to the regular code. +The step 4 hook commits the shadow ``dqtrx`` changes to the shadow dquots. +Notice that both hooks are called with the inode locked, which is how the +live update coordinates with the inode scanner. + +The quotacheck scan looks like this: + +1. Set up a coordinated inode scan. + +2. For each inode returned by the inode scan iterator: + + a. Grab and lock the inode. + + b. Determine that inode's resource usage (data blocks, inode counts, + realtime blocks) and add that to the shadow dquots for the user, group, + and project ids associated with the inode. + + c. Unlock and release the inode. + +3. For each dquot in the system: + + a. Grab and lock the dquot. + + b. Check the dquot against the shadow dquots created by the scan and updated + by the live hooks. + +Live updates are key to being able to walk every quota record without +needing to hold any locks for a long duration. +If repairs are desired, the real and shadow dquots are locked and their +resource counts are set to the values in the shadow dquot. + +The proposed patchset is the +`online quotacheck +`_ +series. + +.. _nlinks: + +Case Study: File Link Count Checking +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +File link count checking also uses live update hooks. +The coordinated inode scanner is used to visit all directories on the +filesystem, and per-file link count records are stored in a sparse ``xfarray`` +indexed by inumber. +During the scanning phase, each entry in a directory generates observation +data as follows: + +1. If the entry is a dotdot (``'..'``) entry of the root directory, the + directory's parent link count is bumped because the root directory's dotdot + entry is self referential. + +2. If the entry is a dotdot entry of a subdirectory, the parent's backref + count is bumped. + +3. If the entry is neither a dot nor a dotdot entry, the target file's parent + count is bumped. + +4. If the target is a subdirectory, the parent's child link count is bumped. + +A crucial point to understand about how the link count inode scanner interacts +with the live update hooks is that the scan cursor tracks which *parent* +directories have been scanned. +In other words, the live updates ignore any update about ``A → B`` when A has +not been scanned, even if B has been scanned. +Furthermore, a subdirectory A with a dotdot entry pointing back to B is +accounted as a backref counter in the shadow data for A, since child dotdot +entries affect the parent's link count. +Live update hooks are carefully placed in all parts of the filesystem that +create, change, or remove directory entries, since those operations involve +bumplink and droplink. + +For any file, the correct link count is the number of parents plus the number +of child subdirectories. +Non-directories never have children of any kind. +The backref information is used to detect inconsistencies in the number of +links pointing to child subdirectories and the number of dotdot entries +pointing back. + +After the scan completes, the link count of each file can be checked by locking +both the inode and the shadow data, and comparing the link counts. +A second coordinated inode scan cursor is used for comparisons. +Live updates are key to being able to walk every inode without needing to hold +any locks between inodes. +If repairs are desired, the inode's link count is set to the value in the +shadow information. +If no parents are found, the file must be :ref:`reparented ` to the +orphanage to prevent the file from being lost forever. + +The proposed patchset is the +`file link count repair +`_ +series. + +.. _rmap_repair: + +Case Study: Rebuilding Reverse Mapping Records +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +Most repair functions follow the same pattern: lock filesystem resources, +walk the surviving ondisk metadata looking for replacement metadata records, +and use an :ref:`in-memory array ` to store the gathered observations. +The primary advantage of this approach is the simplicity and modularity of the +repair code -- code and data are entirely contained within the scrub module, +do not require hooks in the main filesystem, and are usually the most efficient +in memory use. +A secondary advantage of this repair approach is atomicity -- once the kernel +decides a structure is corrupt, no other threads can access the metadata until +the kernel finishes repairing and revalidating the metadata. + +For repairs going on within a shard of the filesystem, these advantages +outweigh the delays inherent in locking the shard while repairing parts of the +shard. +Unfortunately, repairs to the reverse mapping btree cannot use the "standard" +btree repair strategy because it must scan every space mapping of every fork of +every file in the filesystem, and the filesystem cannot stop. +Therefore, rmap repair foregoes atomicity between scrub and repair. +It combines a :ref:`coordinated inode scanner `, :ref:`live update hooks +`, and an :ref:`in-memory rmap btree ` to complete the +scan for reverse mapping records. + +1. Set up an xfbtree to stage rmap records. + +2. While holding the locks on the AGI and AGF buffers acquired during the + scrub, generate reverse mappings for all AG metadata: inodes, btrees, CoW + staging extents, and the internal log. + +3. Set up an inode scanner. + +4. Hook into rmap updates for the AG being repaired so that the live scan data + can receive updates to the rmap btree from the rest of the filesystem during + the file scan. + +5. For each space mapping found in either fork of each file scanned, + decide if the mapping matches the AG of interest. + If so: + + a. Create a btree cursor for the in-memory btree. + + b. Use the rmap code to add the record to the in-memory btree. + + c. Use the :ref:`special commit function ` to write the + xfbtree changes to the xfile. + +6. For each live update received via the hook, decide if the owner has already + been scanned. + If so, apply the live update into the scan data: + + a. Create a btree cursor for the in-memory btree. + + b. Replay the operation into the in-memory btree. + + c. Use the :ref:`special commit function ` to write the + xfbtree changes to the xfile. + This is performed with an empty transaction to avoid changing the + caller's state. + +7. When the inode scan finishes, create a new scrub transaction and relock the + two AG headers. + +8. Compute the new btree geometry using the number of rmap records in the + shadow btree, like all other btree rebuilding functions. + +9. Allocate the number of blocks computed in the previous step. + +10. Perform the usual btree bulk loading and commit to install the new rmap + btree. + +11. Reap the old rmap btree blocks as discussed in the case study about how + to :ref:`reap after rmap btree repair `. + +12. Free the xfbtree now that it not needed. + +The proposed patchset is the +`rmap repair +`_ +series.