| blob | 72c01a1c16e7d16ca0a49e284addf7d884dbfea6 |
1 /*
2 * Copyright (c) 2000-2005 Silicon Graphics, Inc.
3 * All Rights Reserved.
4 *
5 * This program is free software; you can redistribute it and/or
6 * modify it under the terms of the GNU General Public License as
7 * published by the Free Software Foundation.
8 *
9 * This program is distributed in the hope that it would be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, write the Free Software Foundation,
16 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
17 */
40 #include <linux/kthread.h>
41 #include <linux/freezer.h>
45 /*
46 * The inode lookup is done in batches to keep the amount of lock traffic and
47 * radix tree lookups to a minimum. The batch size is a trade off between
48 * lookup reduction and stack usage. This is in the reclaim path, so we can't
49 * be too greedy.
50 */
51 #define XFS_LOOKUP_BATCH 32
53 STATIC int
56 {
61 /*
62 * check for stale RCU freed inode
63 *
64 * If the inode has been reallocated, it doesn't matter if it's not in
65 * the AG we are walking - we are walking for writeback, so if it
66 * passes all the "valid inode" checks and is dirty, then we'll write
67 * it back anyway. If it has been reallocated and still being
68 * initialised, the XFS_INEW check below will catch it.
69 */
74 /* avoid new or reclaimable inodes. Leave for reclaim code to flush */
79 /* nothing to sync during shutdown */
83 /* If we can't grab the inode, it must on it's way to reclaim. */
90 }
92 /* inode is valid */
95 out_unlock_noent:
98 }
100 STATIC int
107 {
114 restart:
127 XFS_LOOKUP_BATCH);
131 }
133 /*
134 * Grab the inodes before we drop the lock. if we found
135 * nothing, nr == 0 and the loop will be skipped.
136 */
143 /*
144 * Update the index for the next lookup. Catch
145 * overflows into the next AG range which can occur if
146 * we have inodes in the last block of the AG and we
147 * are currently pointing to the last inode.
148 *
149 * Because we may see inodes that are from the wrong AG
150 * due to RCU freeing and reallocation, only update the
151 * index if it lies in this AG. It was a race that lead
152 * us to see this inode, so another lookup from the
153 * same index will not find it again.
154 */
160 }
162 /* unlock now we've grabbed the inodes. */
171 skipped++;
173 }
176 }
178 /* bail out if the filesystem is corrupted. */
189 }
191 }
193 int
199 {
203 xfs_agnumber_t ag;
214 }
215 }
217 }
219 STATIC int
224 {
236 }
242 }
244 STATIC int
249 {
259 }
264 }
268 /*
269 * We don't want to try again on non-blocking flushes that can't run
270 * again immediately. If an inode really must be written, then that's
271 * what the SYNC_WAIT flag is for.
272 */
276 }
278 out_unlock:
281 }
283 /*
284 * Write out pagecache data for the whole filesystem.
285 */
286 STATIC int
290 {
301 }
303 /*
304 * Write out inode metadata (attributes) for the whole filesystem.
305 */
306 STATIC int
310 {
314 }
316 STATIC int
319 {
323 /*
324 * If the buffer is pinned then push on the log so we won't get stuck
325 * waiting in the write for someone, maybe ourselves, to flush the log.
326 *
327 * Even though we just pushed the log above, we did not have the
328 * superblock buffer locked at that point so it can become pinned in
329 * between there and here.
330 */
337 }
339 int
344 {
357 }
363 }
365 /*
366 * When remounting a filesystem read-only or freezing the filesystem, we have
367 * two phases to execute. This first phase is syncing the data before we
368 * quiesce the filesystem, and the second is flushing all the inodes out after
369 * we've waited for all the transactions created by the first phase to
370 * complete. The second phase ensures that the inodes are written to their
371 * location on disk rather than just existing in transactions in the log. This
372 * means after a quiesce there is no log replay required to write the inodes to
373 * disk (this is the main difference between a sync and a quiesce).
374 */
375 /*
376 * First stage of freeze - no writers will make progress now we are here,
377 * so we flush delwri and delalloc buffers here, then wait for all I/O to
378 * complete. Data is frozen at that point. Metadata is not frozen,
379 * transactions can still occur here so don't bother flushing the buftarg
380 * because it'll just get dirty again.
381 */
382 int
385 {
388 /*
389 * Log all pending size and timestamp updates. The vfs writeback
390 * code is supposed to do this, but due to its overagressive
391 * livelock detection it will skip inodes where appending writes
392 * were written out in the first non-blocking sync phase if their
393 * completion took long enough that it happened after taking the
394 * timestamp for the cut-off in the blocking phase.
395 */
398 /* force out the log */
401 /* write superblock and hoover up shutdown errors */
404 /* make sure all delwri buffers are written out */
407 /* mark the log as covered if needed */
411 /* flush data-only devices */
416 }
418 STATIC void
421 {
427 /*
428 * This loop must run at least twice. The first instance of the loop
429 * will flush most meta data but that will generate more meta data
430 * (typically directory updates). Which then must be flushed and
431 * logged before we can write the unmount record. We also so sync
432 * reclaim of inodes to catch any that the above delwri flush skipped.
433 */
440 count++;
441 }
443 }
445 /*
446 * Second stage of a quiesce. The data is already synced, now we have to take
447 * care of the metadata. New transactions are already blocked, so we need to
448 * wait for any remaining transactions to drain out before proceeding.
449 */
450 void
453 {
456 /* wait for all modifications to complete */
460 /* flush inodes and push all remaining buffers out to disk */
463 /*
464 * Just warn here till VFS can correctly support
465 * read-only remount without racing.
466 */
469 /* Push the superblock and write an unmount record */
476 }
478 static void
481 {
484 }
486 /*
487 * Every sync period we need to unpin all items, reclaim inodes and sync
488 * disk quotas. We might need to cover the log to indicate that the
489 * filesystem is idle and not frozen.
490 */
491 STATIC void
494 {
500 /* dgc: errors ignored here */
504 else
507 /* start pushing all the metadata that is currently dirty */
509 }
511 /* queue us up again */
513 }
515 /*
516 * Queue a new inode reclaim pass if there are reclaimable inodes and there
517 * isn't a reclaim pass already in progress. By default it runs every 5s based
518 * on the xfs syncd work default of 30s. Perhaps this should have it's own
519 * tunable, but that can be done if this method proves to be ineffective or too
520 * aggressive.
521 */
522 static void
525 {
527 /*
528 * We can have inodes enter reclaim after we've shut down the syncd
529 * workqueue during unmount, so don't allow reclaim work to be queued
530 * during unmount.
531 */
539 }
541 }
543 /*
544 * This is a fast pass over the inode cache to try to get reclaim moving on as
545 * many inodes as possible in a short period of time. It kicks itself every few
546 * seconds, as well as being kicked by the inode cache shrinker when memory
547 * goes low. It scans as quickly as possible avoiding locked inodes or those
548 * already being flushed, and once done schedules a future pass.
549 */
550 STATIC void
553 {
559 }
561 /*
562 * Flush delayed allocate data, attempting to free up reserved space
563 * from existing allocations. At this point a new allocation attempt
564 * has failed with ENOSPC and we are in the process of scratching our
565 * heads, looking about for more room.
566 *
567 * Queue a new data flush if there isn't one already in progress and
568 * wait for completion of the flush. This means that we only ever have one
569 * inode flush in progress no matter how many ENOSPC events are occurring and
570 * so will prevent the system from bogging down due to every concurrent
571 * ENOSPC event scanning all the active inodes in the system for writeback.
572 */
573 void
576 {
581 }
583 STATIC void
586 {
592 }
594 int
597 {
606 }
608 void
611 {
615 }
617 void
621 {
624 XFS_ICI_RECLAIM_TAG);
627 /* propagate the reclaim tag up into the perag radix tree */
631 XFS_ICI_RECLAIM_TAG);
634 /* schedule periodic background inode reclaim */
639 }
641 }
643 /*
644 * We set the inode flag atomically with the radix tree tag.
645 * Once we get tag lookups on the radix tree, this inode flag
646 * can go away.
647 */
648 void
651 {
663 }
665 STATIC void
669 {
672 /* clear the reclaim tag from the perag radix tree */
676 XFS_ICI_RECLAIM_TAG);
680 }
681 }
683 void
688 {
692 }
694 /*
695 * Grab the inode for reclaim exclusively.
696 * Return 0 if we grabbed it, non-zero otherwise.
697 */
698 STATIC int
702 {
705 /* quick check for stale RCU freed inode */
709 /*
710 * do some unlocked checks first to avoid unnecessary lock traffic.
711 * The first is a flush lock check, the second is a already in reclaim
712 * check. Only do these checks if we are not going to block on locks.
713 */
717 }
719 /*
720 * The radix tree lock here protects a thread in xfs_iget from racing
721 * with us starting reclaim on the inode. Once we have the
722 * XFS_IRECLAIM flag set it will not touch us.
723 *
724 * Due to RCU lookup, we may find inodes that have been freed and only
725 * have XFS_IRECLAIM set. Indeed, we may see reallocated inodes that
726 * aren't candidates for reclaim at all, so we must check the
727 * XFS_IRECLAIMABLE is set first before proceeding to reclaim.
728 */
732 /* not a reclaim candidate. */
735 }
739 }
741 /*
742 * Inodes in different states need to be treated differently, and the return
743 * value of xfs_iflush is not sufficient to get this right. The following table
744 * lists the inode states and the reclaim actions necessary for non-blocking
745 * reclaim:
746 *
747 *
748 * inode state iflush ret required action
749 * --------------- ---------- ---------------
750 * bad - reclaim
751 * shutdown EIO unpin and reclaim
752 * clean, unpinned 0 reclaim
753 * stale, unpinned 0 reclaim
754 * clean, pinned(*) 0 requeue
755 * stale, pinned EAGAIN requeue
756 * dirty, delwri ok 0 requeue
757 * dirty, delwri blocked EAGAIN requeue
758 * dirty, sync flush 0 reclaim
759 *
760 * (*) dgc: I don't think the clean, pinned state is possible but it gets
761 * handled anyway given the order of checks implemented.
762 *
763 * As can be seen from the table, the return value of xfs_iflush() is not
764 * sufficient to correctly decide the reclaim action here. The checks in
765 * xfs_iflush() might look like duplicates, but they are not.
766 *
767 * Also, because we get the flush lock first, we know that any inode that has
768 * been flushed delwri has had the flush completed by the time we check that
769 * the inode is clean. The clean inode check needs to be done before flushing
770 * the inode delwri otherwise we would loop forever requeuing clean inodes as
771 * we cannot tell apart a successful delwri flush and a clean inode from the
772 * return value of xfs_iflush().
773 *
774 * Note that because the inode is flushed delayed write by background
775 * writeback, the flush lock may already be held here and waiting on it can
776 * result in very long latencies. Hence for sync reclaims, where we wait on the
777 * flush lock, the caller should push out delayed write inodes first before
778 * trying to reclaim them to minimise the amount of time spent waiting. For
779 * background relaim, we just requeue the inode for the next pass.
780 *
781 * Hence the order of actions after gaining the locks should be:
782 * bad => reclaim
783 * shutdown => unpin and reclaim
784 * pinned, delwri => requeue
785 * pinned, sync => unpin
786 * stale => reclaim
787 * clean => reclaim
788 * dirty, delwri => flush and requeue
789 * dirty, sync => flush, wait and reclaim
790 */
791 STATIC int
796 {
799 restart:
806 /*
807 * If we only have a single dirty inode in a cluster there is
808 * a fair chance that the AIL push may have pushed it into
809 * the buffer, but xfsbufd won't touch it until 30 seconds
810 * from now, and thus we will lock up here.
811 *
812 * Promote the inode buffer to the front of the delwri list
813 * and wake up xfsbufd now.
814 */
817 }
824 }
829 }
831 }
837 /*
838 * Now we have an inode that needs flushing.
839 *
840 * We do a nonblocking flush here even if we are doing a SYNC_WAIT
841 * reclaim as we can deadlock with inode cluster removal.
842 * xfs_ifree_cluster() can lock the inode buffer before it locks the
843 * ip->i_lock, and we are doing the exact opposite here. As a result,
844 * doing a blocking xfs_itobp() to get the cluster buffer will result
845 * in an ABBA deadlock with xfs_ifree_cluster().
846 *
847 * As xfs_ifree_cluser() must gather all inodes that are active in the
848 * cache to mark them stale, if we hit this case we don't actually want
849 * to do IO here - we want the inode marked stale so we can simply
850 * reclaim it. Hence if we get an EAGAIN error on a SYNC_WAIT flush,
851 * just unlock the inode, back off and try again. Hopefully the next
852 * pass through will see the stale flag set on the inode.
853 */
858 /* backoff longer than in xfs_ifree_cluster */
861 }
864 }
866 /*
867 * When we have to flush an inode but don't have SYNC_WAIT set, we
868 * flush the inode out using a delwri buffer and wait for the next
869 * call into reclaim to find it in a clean state instead of waiting for
870 * it now. We also don't return errors here - if the error is transient
871 * then the next reclaim pass will flush the inode, and if the error
872 * is permanent then the next sync reclaim will reclaim the inode and
873 * pass on the error.
874 */
879 }
880 out:
883 /*
884 * We could return EAGAIN here to make reclaim rescan the inode tree in
885 * a short while. However, this just burns CPU time scanning the tree
886 * waiting for IO to complete and xfssyncd never goes back to the idle
887 * state. Instead, return 0 to let the next scheduled background reclaim
888 * attempt to reclaim the inode again.
889 */
892 reclaim:
897 /*
898 * Remove the inode from the per-AG radix tree.
899 *
900 * Because radix_tree_delete won't complain even if the item was never
901 * added to the tree assert that it's been there before to catch
902 * problems with the inode life time early on.
903 */
911 /*
912 * Here we do an (almost) spurious inode lock in order to coordinate
913 * with inode cache radix tree lookups. This is because the lookup
914 * can reference the inodes in the cache without taking references.
915 *
916 * We make that OK here by ensuring that we wait until the inode is
917 * unlocked after the lookup before we go ahead and free it. We get
918 * both the ilock and the iolock because the code may need to drop the
919 * ilock one but will still hold the iolock.
920 */
928 }
930 /*
931 * Walk the AGs and reclaim the inodes in them. Even if the filesystem is
932 * corrupted, we still want to try to reclaim all the inodes. If we don't,
933 * then a shut down during filesystem unmount reclaim walk leak all the
934 * unreclaimed inodes.
935 */
936 int
941 {
945 xfs_agnumber_t ag;
949 restart:
961 skipped++;
964 }
977 XFS_LOOKUP_BATCH,
978 XFS_ICI_RECLAIM_TAG);
983 }
985 /*
986 * Grab the inodes before we drop the lock. if we found
987 * nothing, nr == 0 and the loop will be skipped.
988 */
995 /*
996 * Update the index for the next lookup. Catch
997 * overflows into the next AG range which can
998 * occur if we have inodes in the last block of
999 * the AG and we are currently pointing to the
1000 * last inode.
1001 *
1002 * Because we may see inodes that are from the
1003 * wrong AG due to RCU freeing and
1004 * reallocation, only update the index if it
1005 * lies in this AG. It was a race that lead us
1006 * to see this inode, so another lookup from
1007 * the same index will not find it again.
1008 */
1015 }
1017 /* unlock now we've grabbed the inodes. */
1026 }
1036 else
1040 }
1042 /*
1043 * if we skipped any AG, and we still have scan count remaining, do
1044 * another pass this time using blocking reclaim semantics (i.e
1045 * waiting on the reclaim locks and ignoring the reclaim cursors). This
1046 * ensure that when we get more reclaimers than AGs we block rather
1047 * than spin trying to execute reclaim.
1048 */
1052 }
1054 }
1056 int
1060 {
1064 }
1066 /*
1067 * Scan a certain number of inodes for reclaim.
1068 *
1069 * When called we make sure that there is a background (fast) inode reclaim in
1070 * progress, while we will throttle the speed of reclaim via doing synchronous
1071 * reclaim of inodes. That means if we come across dirty inodes, we wait for
1072 * them to be cleaned, which we hope will not be very long due to the
1073 * background walker having already kicked the IO off on those dirty inodes.
1074 */
1075 void
1079 {
1080 /* kick background reclaimer and push the AIL */
1085 }
1087 /*
1088 * Return the number of reclaimable inodes in the filesystem for
1089 * the shrinker to determine how much to reclaim.
1090 */
1091 int
1094 {
1103 }
1105 }