| blob | a4967b27ffb636212ddd21234b1b2fc211a6038b |
1 // SPDX-License-Identifier: GPL-2.0+
2 /*
3 * linux/fs/jbd2/recovery.c
4 *
5 * Written by Stephen C. Tweedie <sct@redhat.com>, 1999
6 *
7 * Copyright 1999-2000 Red Hat Software --- All Rights Reserved
8 *
9 * Journal recovery routines for the generic filesystem journaling code;
10 * part of the ext2fs journaling system.
11 */
13 #ifndef __KERNEL__
15 #else
16 #include <linux/time.h>
17 #include <linux/fs.h>
18 #include <linux/jbd2.h>
19 #include <linux/errno.h>
20 #include <linux/crc32.h>
21 #include <linux/blkdev.h>
22 #endif
24 /*
25 * Maintain information about the progress of the recovery job, so that
26 * the different passes can carry information between them.
27 */
28 struct recovery_info
29 {
30 tid_t start_transaction;
31 tid_t end_transaction;
36 };
44 #ifdef __KERNEL__
46 /* Release readahead buffers after use */
48 {
51 }
54 /*
55 * When reading from the journal, we are going through the block device
56 * layer directly and so there is no readahead being done for us. We
57 * need to implement any readahead ourselves if we want it to happen at
58 * all. Recovery is basically one long sequential read, so make sure we
59 * do the IO in reasonably large chunks.
60 *
61 * This is not so critical that we need to be enormously clever about
62 * the readahead size, though. 128K is a purely arbitrary, good-enough
63 * fixed value.
64 */
66 #define MAXBUF 8
68 {
76 /* Do up to 128K of readahead */
81 /* Do the readahead itself. We'll submit MAXBUF buffer_heads at
82 * a time to the block device IO layer. */
91 next);
93 }
99 }
107 }
110 }
116 failed:
120 }
125 /*
126 * Read a block from the journal
127 */
131 {
141 }
147 offset);
149 }
156 /* If this is a brand new buffer, start readahead.
157 Otherwise, we assume we are already reading it. */
161 }
165 offset);
168 }
172 }
175 {
177 __be32 provided;
178 __u32 calculated;
191 }
193 /*
194 * Count the number of in-use tags in a journal descriptor block.
195 */
198 {
212 nr++;
219 }
222 }
225 /* Make sure we wrap around the log correctly! */
226 #define wrap(journal, var) \
227 do { \
228 if (var >= (journal)->j_last) \
229 var -= ((journal)->j_last - (journal)->j_first); \
230 } while (0)
232 /**
233 * jbd2_journal_recover - recovers a on-disk journal
234 * @journal: the journal to recover
235 *
236 * The primary function for recovering the log contents when mounting a
237 * journaled device.
238 *
239 * Recovery is done in three passes. In the first pass, we look for the
240 * end of the log. In the second, we assemble the list of revoke
241 * blocks. In the third and final pass, we replay any un-revoked blocks
242 * in the log.
243 */
245 {
254 /*
255 * The journal superblock's s_start field (the current log head)
256 * is always zero if, and only if, the journal was cleanly
257 * unmounted.
258 */
265 }
279 /* Restart the log at the next transaction ID, thus invalidating
280 * any existing commit records in the log. */
287 /* Make sure all replayed data is on permanent storage */
292 }
294 }
296 /**
297 * jbd2_journal_skip_recovery - Start journal and wipe exiting records
298 * @journal: journal to startup
299 *
300 * Locate any valid recovery information from the journal and set up the
301 * journal structures in memory to ignore it (presumably because the
302 * caller has evidence that it is out of date).
303 * This function doesn't appear to be exported..
304 *
305 * We perform one pass over the journal to allow us to tell the user how
306 * much recovery information is being erased, and to let us initialise
307 * the journal transaction sequence numbers to the next unused ID.
308 */
310 {
323 #ifdef CONFIG_JBD2_DEBUG
329 #endif
331 }
335 }
339 {
344 }
346 /*
347 * calc_chksums calculates the checksums for the blocks described in the
348 * descriptor block.
349 */
352 {
358 /* Calculate checksum of the descriptor block. */
372 }
374 }
376 }
379 {
381 __be32 provided;
382 __u32 calculated;
394 }
398 {
400 __u32 csum32;
401 __be32 seq;
412 else
414 }
418 {
432 /*
433 * First thing is to establish what we expect to find in the log
434 * (in terms of transaction IDs), and where (in terms of log
435 * block offsets): query the superblock.
436 */
448 /*
449 * Now we walk through the log, transaction by transaction,
450 * making sure that each transaction has a commit block in the
451 * expected place. Each complete transaction gets replayed back
452 * into the main filesystem.
453 */
464 /* If we already know where to stop the log traversal,
465 * check right now that we haven't gone past the end of
466 * the log. */
475 /* Skip over each chunk of the transaction looking
476 * either the next descriptor block or the final commit
477 * record. */
484 next_log_block++;
487 /* What kind of buffer is it?
488 *
489 * If it is a descriptor block, check that it has the
490 * expected sequence number. Otherwise, we're all done
491 * here. */
498 }
508 }
510 /* OK, we have a valid descriptor block which matches
511 * all of the sequence number checks. What are we going
512 * to do with it? That depends on the pass... */
516 /* Verify checksum first */
518 descr_csum_size =
525 next_log_block);
529 }
531 /* If it is a valid descriptor block, replay it
532 * in pass REPLAY; if journal_checksums enabled, then
533 * calculate checksums in PASS_SCAN, otherwise,
534 * just skip over the blocks it describes. */
544 }
547 }
552 }
554 /* A descriptor block: we can now write all of
555 * the data blocks. Yay, useful work is finally
556 * getting done here! */
570 /* Recover what we can, but
571 * report failure at the end. */
574 "JBD2: IO error %d recovering "
582 tag);
584 /* If the block has been
585 * revoked, then we're all done
586 * here. */
589 next_commit_ID)) {
593 }
595 /* Look for block corruption */
602 "checksum recovering "
603 "data block %llu in "
607 }
609 /* Find a buffer for the new
610 * data being restored */
612 blocknr,
616 "JBD2: Out of memory "
622 }
630 }
637 /* ll_rw_block(WRITE, 1, &nbh); */
641 }
643 skip_write:
650 }
656 /* How to differentiate between interrupted commit
657 * and journal corruption ?
658 *
659 * {nth transaction}
660 * Checksum Verification Failed
661 * |
662 * ____________________
663 * | |
664 * async_commit sync_commit
665 * | |
666 * | GO TO NEXT "Journal Corruption"
667 * | TRANSACTION
668 * |
669 * {(n+1)th transanction}
670 * |
671 * _______|______________
672 * | |
673 * Commit block found Commit block not found
674 * | |
675 * "Journal Corruption" |
676 * _____________|_________
677 * | |
678 * nth trans corrupt OR nth trans
679 * and (n+1)th interrupted interrupted
680 * before commit block
681 * could reach the disk.
682 * (Cannot find the difference in above
683 * mentioned conditions. Hence assume
684 * "Interrupted Commit".)
685 */
687 /* Found an expected commit block: if checksums
688 * are present verify them in PASS_SCAN; else not
689 * much to do other than move on to the next sequence
690 * number. */
706 }
711 JBD2_CRC32_CHKSUM_SIZE)
717 /*
718 * If fs is mounted using an old kernel and then
719 * kernel with journal_chksum is used then we
720 * get a situation where the journal flag has
721 * checksum flag set but checksums are not
722 * present i.e chksum = 0, in the individual
723 * commit blocks.
724 * Hence to avoid checksum failures, in this
725 * situation, this extra check is added.
726 */
734 next_commit_ID;
737 }
738 }
740 }
748 next_commit_ID;
751 }
752 }
754 next_commit_ID++;
758 /* If we aren't in the REVOKE pass, then we can
759 * just skip over this block. */
763 }
774 blocktype);
777 }
778 }
780 done:
781 /*
782 * We broke out of the log scan loop: either we came to the
783 * known end of the log or we found an unexpected block in the
784 * log. If the latter happened, then we know that the "current"
785 * transaction marks the end of the valid log.
786 */
792 /* It's really bad news if different passes end up at
793 * different places (but possible due to IO errors). */
800 }
801 }
806 failed:
808 }
810 /* Scan a revoke record, marking all blocks mentioned as revoked. */
814 {
818 __u32 rcount;
843 else
850 }
852 }