| blob | e489d7a8446af16a33a2cacbf43897322c6ceee0 |
1 // SPDX-License-Identifier: GPL-2.0+
2 /*
3 * Copyright (C) 2018 Oracle. All Rights Reserved.
4 * Author: Darrick J. Wong <darrick.wong@oracle.com>
5 */
33 /*
34 * Attempt to repair some metadata, if the metadata is corrupt and userspace
35 * told us to fix it. This function returns -EAGAIN to mean "re-run scrub",
36 * and will set *fixed to true if it thinks it repaired anything.
37 */
38 int
42 {
49 /* Repair whatever's broken. */
55 /*
56 * Repair succeeded. Commit the fixes and perform a second
57 * scrub so that we can tell userspace if we fixed the problem.
58 */
64 /* Tell the caller to try again having grabbed all the locks. */
68 }
69 /*
70 * We tried harder but still couldn't grab all the resources
71 * we needed to fix it. The corruption has not been fixed,
72 * so report back to userspace.
73 */
77 }
78 }
80 /*
81 * Complain about unfixable problems in the filesystem. We don't log
82 * corruptions when IFLAG_REPAIR wasn't set on the assumption that the driver
83 * program is xfs_scrub, which will call back with IFLAG_REPAIR set if the
84 * administrator isn't running xfs_scrub in no-repairs mode.
85 *
86 * Use this helper function because _ratelimited silently declares a static
87 * structure to track rate limiting information.
88 */
89 void
92 {
95 }
97 /*
98 * Repair probe -- userspace uses this to probe if we're willing to repair a
99 * given mountpoint.
100 */
101 int
104 {
111 }
113 /*
114 * Roll a transaction, keeping the AG headers locked and reinitializing
115 * the btree cursors.
116 */
117 int
120 {
123 /* Keep the AG header buffers locked so we can keep going. */
131 /*
132 * Roll the transaction. We still own the buffer and the buffer lock
133 * regardless of whether or not the roll succeeds. If the roll fails,
134 * the buffers will be released during teardown on our way out of the
135 * kernel. If it succeeds, we join them to the new transaction and
136 * move on.
137 */
142 /* Join AG headers to the new transaction. */
151 }
153 /*
154 * Does the given AG have enough space to rebuild a btree? Neither AG
155 * reservation can be critical, and we must have enough space (factoring
156 * in AG reservations) to construct a whole btree.
157 */
158 bool
161 xfs_extlen_t nr_blocks,
163 {
167 }
169 /*
170 * Figure out how many blocks to reserve for an AG repair. We calculate the
171 * worst case estimate for the number of blocks we'd need to rebuild one of
172 * any type of per-AG btree.
173 */
174 xfs_extlen_t
177 {
184 xfs_extlen_t usedlen;
185 xfs_extlen_t freelen;
186 xfs_extlen_t bnobt_sz;
187 xfs_extlen_t inobt_sz;
188 xfs_extlen_t rmapbt_sz;
189 xfs_extlen_t refcbt_sz;
197 /* Use in-core icount if possible. */
200 /* Try to get the actual counters from disk. */
205 }
206 }
208 /* Now grab the block counters from the AGF. */
215 }
218 /* If the icount is impossible, make some worst-case assumptions. */
225 }
227 /* If the block counts are impossible, make worst-case assumptions. */
234 }
239 /*
240 * Figure out how many blocks we'd need worst case to rebuild
241 * each type of btree. Note that we can only rebuild the
242 * bnobt/cntbt or inobt/finobt as pairs.
243 */
247 XFS_INODES_PER_HOLEMASK_BIT);
248 else
250 XFS_INODES_PER_CHUNK);
255 else
258 /*
259 * Guess how many blocks we need to rebuild the rmapbt.
260 * For non-reflink filesystems we can't have more records than
261 * used blocks. However, with reflink it's possible to have
262 * more than one rmap record per AG block. We don't know how
263 * many rmaps there could be in the AG, so we start off with
264 * what we hope is an generous over-estimation.
265 */
269 else
273 }
279 }
281 /* Allocate a block in an AG. */
282 int
288 {
290 xfs_agblock_t bno;
309 }
330 }
332 /* Initialize a new AG btree root block with zero entries. */
333 int
336 xfs_fsblock_t fsb,
338 xfs_btnum_t btnum,
340 {
363 }
365 /*
366 * Reconstructing per-AG Btrees
367 *
368 * When a space btree is corrupt, we don't bother trying to fix it. Instead,
369 * we scan secondary space metadata to derive the records that should be in
370 * the damaged btree, initialize a fresh btree root, and insert the records.
371 * Note that for rebuilding the rmapbt we scan all the primary data to
372 * generate the new records.
373 *
374 * However, that leaves the matter of removing all the metadata describing the
375 * old broken structure. For primary metadata we use the rmap data to collect
376 * every extent with a matching rmap owner (bitmap); we then iterate all other
377 * metadata structures with the same rmap owner to collect the extents that
378 * cannot be removed (sublist). We then subtract sublist from bitmap to
379 * derive the blocks that were used by the old btree. These blocks can be
380 * reaped.
381 *
382 * For rmapbt reconstructions we must use different tactics for extent
383 * collection. First we iterate all primary metadata (this excludes the old
384 * rmapbt, obviously) to generate new rmap records. The gaps in the rmap
385 * records are collected as bitmap. The bnobt records are collected as
386 * sublist. As with the other btrees we subtract sublist from bitmap, and the
387 * result (since the rmapbt lives in the free space) are the blocks from the
388 * old rmapbt.
389 *
390 * Disposal of Blocks from Old per-AG Btrees
391 *
392 * Now that we've constructed a new btree to replace the damaged one, we want
393 * to dispose of the blocks that (we think) the old btree was using.
394 * Previously, we used the rmapbt to collect the extents (bitmap) with the
395 * rmap owner corresponding to the tree we rebuilt, collected extents for any
396 * blocks with the same rmap owner that are owned by another data structure
397 * (sublist), and subtracted sublist from bitmap. In theory the extents
398 * remaining in bitmap are the old btree's blocks.
399 *
400 * Unfortunately, it's possible that the btree was crosslinked with other
401 * blocks on disk. The rmap data can tell us if there are multiple owners, so
402 * if the rmapbt says there is an owner of this block other than @oinfo, then
403 * the block is crosslinked. Remove the reverse mapping and continue.
404 *
405 * If there is one rmap record, we can free the block, which removes the
406 * reverse mapping but doesn't add the block to the free space. Our repair
407 * strategy is to hope the other metadata objects crosslinked on this block
408 * will be rebuilt (atop different blocks), thereby removing all the cross
409 * links.
410 *
411 * If there are no rmap records at all, we also free the block. If the btree
412 * being rebuilt lives in the free space (bnobt/cntbt/rmapbt) then there isn't
413 * supposed to be a rmap record and everything is ok. For other btrees there
414 * had to have been an rmap entry for the block to have ended up on @bitmap,
415 * so if it's gone now there's something wrong and the fs will shut down.
416 *
417 * Note: If there are multiple rmap records with only the same rmap owner as
418 * the btree we're trying to rebuild and the block is indeed owned by another
419 * data structure with the same rmap owner, then the block will be in sublist
420 * and therefore doesn't need disposal. If there are multiple rmap records
421 * with only the same rmap owner but the block is not owned by something with
422 * the same rmap owner, the block will be freed.
423 *
424 * The caller is responsible for locking the AG headers for the entire rebuild
425 * operation so that nothing else can sneak in and change the AG state while
426 * we're not looking. We also assume that the caller already invalidated any
427 * buffers associated with @bitmap.
428 */
430 /*
431 * Invalidate buffers for per-AG btree blocks we're dumping. This function
432 * is not intended for use with file data repairs; we have bunmapi for that.
433 */
434 int
438 {
442 xfs_fsblock_t fsbno;
444 /*
445 * For each block in each extent, see if there's an incore buffer for
446 * exactly that block; if so, invalidate it. The buffer cache only
447 * lets us look for one buffer at a time, so we have to look one block
448 * at a time. Avoid invalidating AG headers and post-EOFS blocks
449 * because we never own those; and if we can't TRYLOCK the buffer we
450 * assume it's owned by someone else.
451 */
453 /* Skip AG headers and post-EOFS blocks */
462 }
463 }
466 }
468 /* Ensure the freelist is the correct size. */
469 int
473 {
484 }
486 /*
487 * Put a block back on the AGFL.
488 */
489 STATIC int
492 xfs_agblock_t agbno)
493 {
496 /* Make sure there's space on the freelist. */
501 /*
502 * Since we're "freeing" a lost block onto the AGFL, we have to
503 * create an rmap for the block prior to merging it or else other
504 * parts will break.
505 */
511 /* Put the block on the AGFL. */
517 XFS_EXTENT_BUSY_SKIP_DISCARD);
520 }
522 /* Dispose of a single block. */
523 STATIC int
526 xfs_fsblock_t fsbno,
529 {
532 xfs_agnumber_t agno;
533 xfs_agblock_t agbno;
540 /*
541 * If we are repairing per-inode metadata, we need to read in the AGF
542 * buffer. Otherwise, we're repairing a per-AG structure, so reuse
543 * the AGF buffer that the setup functions already grabbed.
544 */
551 }
554 /* Can we find any other rmappings? */
560 /*
561 * If there are other rmappings, this block is cross linked and must
562 * not be freed. Remove the reverse mapping and move on. Otherwise,
563 * we were the only owner of the block, so free the extent, which will
564 * also remove the rmap.
565 *
566 * XXX: XFS doesn't support detecting the case where a single block
567 * metadata structure is crosslinked with a multi-block structure
568 * because the buffer cache doesn't detect aliasing problems, so we
569 * can't fix 100% of crosslinking problems (yet). The verifiers will
570 * blow on writeout, the filesystem will shut down, and the admin gets
571 * to run xfs_repair.
572 */
577 else
588 out_free:
592 }
594 /* Dispose of every block of every extent in the bitmap. */
595 int
601 {
604 xfs_fsblock_t fsbno;
619 }
621 out:
624 }
626 /*
627 * Finding per-AG Btree Roots for AGF/AGI Reconstruction
628 *
629 * If the AGF or AGI become slightly corrupted, it may be necessary to rebuild
630 * the AG headers by using the rmap data to rummage through the AG looking for
631 * btree roots. This is not guaranteed to work if the AG is heavily damaged
632 * or the rmap data are corrupt.
633 *
634 * Callers of xrep_find_ag_btree_roots must lock the AGF and AGFL
635 * buffers if the AGF is being rebuilt; or the AGF and AGI buffers if the
636 * AGI is being rebuilt. It must maintain these locks until it's safe for
637 * other threads to change the btrees' shapes. The caller provides
638 * information about the btrees to look for by passing in an array of
639 * xrep_find_ag_btree with the (rmap owner, buf_ops, magic) fields set.
640 * The (root, height) fields will be set on return if anything is found. The
641 * last element of the array should have a NULL buf_ops to mark the end of the
642 * array.
643 *
644 * For every rmapbt record matching any of the rmap owners in btree_info,
645 * read each block referenced by the rmap record. If the block is a btree
646 * block from this filesystem matching any of the magic numbers and has a
647 * level higher than what we've already seen, remember the block and the
648 * height of the tree required to have such a block. When the call completes,
649 * we return the highest block we've found for each btree description; those
650 * should be the roots.
651 */
658 };
660 /* See if our block is in the AGFL. */
661 STATIC int
664 xfs_agblock_t bno,
666 {
670 }
672 /* Does this block match the btree information passed in? */
673 STATIC int
678 xfs_agblock_t agbno,
680 {
684 xfs_daddr_t daddr;
690 /*
691 * Blocks in the AGFL have stale contents that might just happen to
692 * have a matching magic and uuid. We don't want to pull these blocks
693 * in as part of a tree root, so we have to filter out the AGFL stuff
694 * here. If the AGFL looks insane we'll just refuse to repair.
695 */
703 }
705 /*
706 * Read the buffer into memory so that we can see if it's a match for
707 * our btree type. We have no clue if it is beforehand, and we want to
708 * avoid xfs_trans_read_buf's behavior of dumping the DONE state (which
709 * will cause needless disk reads in subsequent calls to this function)
710 * and logging metadata verifier failures.
711 *
712 * Therefore, pass in NULL buffer ops. If the buffer was already in
713 * memory from some other caller it will already have b_ops assigned.
714 * If it was in memory from a previous unsuccessful findroot_block
715 * call, the buffer won't have b_ops but it should be clean and ready
716 * for us to try to verify if the read call succeeds. The same applies
717 * if the buffer wasn't in memory at all.
718 *
719 * Note: If we never match a btree type with this buffer, it will be
720 * left in memory with NULL b_ops. This shouldn't be a problem unless
721 * the buffer gets written.
722 */
728 /* Ensure the block magic matches the btree type we're looking for. */
734 /*
735 * If the buffer already has ops applied and they're not the ones for
736 * this btree type, we know this block doesn't match the btree and we
737 * can bail out.
738 *
739 * If the buffer ops match ours, someone else has already validated
740 * the block for us, so we can move on to checking if this is a root
741 * block candidate.
742 *
743 * If the buffer does not have ops, nobody has successfully validated
744 * the contents and the buffer cannot be dirty. If the magic, uuid,
745 * and structure match this btree type then we'll move on to checking
746 * if it's a root block candidate. If there is no match, bail out.
747 */
756 /*
757 * Read verifiers can reference b_ops, so we set the pointer
758 * here. If the verifier fails we'll reset the buffer state
759 * to what it was before we touched the buffer.
760 */
767 }
769 /*
770 * Some read verifiers will (re)set b_ops, so we must be
771 * careful not to change b_ops after running the verifier.
772 */
773 }
775 /*
776 * This block passes the magic/uuid and verifier tests for this btree
777 * type. We don't need the caller to try the other tree types.
778 */
781 /*
782 * Compare this btree block's level to the height of the current
783 * candidate root block.
784 *
785 * If the level matches the root we found previously, throw away both
786 * blocks because there can't be two candidate roots.
787 *
788 * If level is lower in the tree than the root we found previously,
789 * ignore this block.
790 */
797 }
799 /*
800 * This is the highest block in the tree that we've found so far.
801 * Update the btree height to reflect what we've learned from this
802 * block.
803 */
806 /*
807 * If this block doesn't have sibling pointers, then it's the new root
808 * block candidate. Otherwise, the root will be found farther up the
809 * tree.
810 */
814 else
819 out:
822 }
824 /*
825 * Do any of the blocks in this rmap record match one of the btrees we're
826 * looking for?
827 */
828 STATIC int
833 {
836 xfs_agblock_t b;
840 /* Ignore anything that isn't AG metadata. */
844 /* Otherwise scan each block + btree type. */
857 }
858 }
861 }
863 /* Find the roots of the per-AG btrees described in btree_info. */
864 int
870 {
889 }
896 }
898 /* Force a quotacheck the next time we mount. */
899 void
902 uint dqtype)
903 {
904 uint flag;
915 }
917 /*
918 * Attach dquots to this inode, or schedule quotacheck to fix them.
919 *
920 * This function ensures that the appropriate dquots are attached to an inode.
921 * We cannot allow the dquot code to allocate an on-disk dquot block here
922 * because we're already in transaction context with the inode locked. The
923 * on-disk dquot should already exist anyway. If the quota code signals
924 * corruption or missing quota information, schedule quotacheck, which will
925 * repair corruptions in the quota metadata.
926 */
927 int
930 {
947 /* fall through */
953 }
956 }