| blob | fa608788b93d7c55977b8c64201374ffb6a1a42c |
1 // SPDX-License-Identifier: GPL-2.0+
2 /*
3 * linux/fs/jbd2/revoke.c
4 *
5 * Written by Stephen C. Tweedie <sct@redhat.com>, 2000
6 *
7 * Copyright 2000 Red Hat corp --- All Rights Reserved
8 *
9 * Journal revoke routines for the generic filesystem journaling code;
10 * part of the ext2fs journaling system.
11 *
12 * Revoke is the mechanism used to prevent old log records for deleted
13 * metadata from being replayed on top of newer data using the same
14 * blocks. The revoke mechanism is used in two separate places:
15 *
16 * + Commit: during commit we write the entire list of the current
17 * transaction's revoked blocks to the journal
18 *
19 * + Recovery: during recovery we record the transaction ID of all
20 * revoked blocks. If there are multiple revoke records in the log
21 * for a single block, only the last one counts, and if there is a log
22 * entry for a block beyond the last revoke, then that log entry still
23 * gets replayed.
24 *
25 * We can get interactions between revokes and new log data within a
26 * single transaction:
27 *
28 * Block is revoked and then journaled:
29 * The desired end result is the journaling of the new block, so we
30 * cancel the revoke before the transaction commits.
31 *
32 * Block is journaled and then revoked:
33 * The revoke must take precedence over the write of the block, so we
34 * need either to cancel the journal entry or to write the revoke
35 * later in the log than the log block. In this case, we choose the
36 * latter: journaling a block cancels any revoke record for that block
37 * in the current transaction, so any revoke for that block in the
38 * transaction must have happened after the block was journaled and so
39 * the revoke must take precedence.
40 *
41 * Block is revoked and then written as data:
42 * The data write is allowed to succeed, but the revoke is _not_
43 * cancelled. We still need to prevent old log records from
44 * overwriting the new data. We don't even need to clear the revoke
45 * bit here.
46 *
47 * We cache revoke status of a buffer in the current transaction in b_states
48 * bits. As the name says, revokevalid flag indicates that the cached revoke
49 * status of a buffer is valid and we can rely on the cached status.
50 *
51 * Revoke information on buffers is a tri-state value:
52 *
53 * RevokeValid clear: no cached revoke status, need to look it up
54 * RevokeValid set, Revoked clear:
55 * buffer has not been revoked, and cancel_revoke
56 * need do nothing.
57 * RevokeValid set, Revoked set:
58 * buffer has been revoked.
59 *
60 * Locking rules:
61 * We keep two hash tables of revoke records. One hashtable belongs to the
62 * running transaction (is pointed to by journal->j_revoke), the other one
63 * belongs to the committing transaction. Accesses to the second hash table
64 * happen only from the kjournald and no other thread touches this table. Also
65 * journal_switch_revoke_table() which switches which hashtable belongs to the
66 * running and which to the committing transaction is called only from
67 * kjournald. Therefore we need no locks when accessing the hashtable belonging
68 * to the committing transaction.
69 *
70 * All users operating on the hash table belonging to the running transaction
71 * have a handle to the transaction. Therefore they are safe from kjournald
72 * switching hash tables under them. For operations on the lists of entries in
73 * the hash table j_revoke_lock is used.
74 *
75 * Finally, also replay code uses the hash tables but at this moment no one else
76 * can touch them (filesystem isn't mounted yet) and hence no locking is
77 * needed.
78 */
80 #ifndef __KERNEL__
82 #else
83 #include <linux/time.h>
84 #include <linux/fs.h>
85 #include <linux/jbd2.h>
86 #include <linux/errno.h>
87 #include <linux/slab.h>
88 #include <linux/list.h>
89 #include <linux/init.h>
90 #include <linux/bio.h>
91 #include <linux/log2.h>
92 #include <linux/hash.h>
93 #endif
98 /* Each revoke record represents one single revoked block. During
99 journal replay, this involves recording the transaction ID of the
100 last transaction to revoke this block. */
102 struct jbd2_revoke_record_s
103 {
107 };
110 /* The revoke table is just a simple hash table of revoke records. */
111 struct jbd2_revoke_table_s
112 {
113 /* It is conceivable that we might want a larger hash table
114 * for recovery. Must be a power of two. */
118 };
121 #ifdef __KERNEL__
127 #endif
129 /* Utility functions to maintain the revoke table */
132 {
134 }
137 tid_t seq)
138 {
156 }
158 /* Find a revoke record in the journal's hash table. */
162 {
174 }
176 }
179 }
182 {
185 }
188 {
191 }
194 {
202 }
204 }
207 {
210 SLAB_TEMPORARY);
214 }
216 }
219 {
229 shift++;
239 }
244 out:
246 }
249 {
256 }
260 }
262 /* Initialise the revoke table for a given journal to a given size. */
264 {
282 fail1:
285 fail0:
287 }
289 /* Destroy a journal's revoke table. The table must already be empty! */
291 {
297 }
300 #ifdef __KERNEL__
302 /*
303 * jbd2_journal_revoke: revoke a given buffer_head from the journal. This
304 * prevents the block from being replayed during recovery if we take a
305 * crash after this current transaction commits. Any subsequent
306 * metadata writes of the buffer in this transaction cancel the
307 * revoke.
308 *
309 * Note that this call may block --- it is up to the caller to make
310 * sure that there are no further calls to journal_write_metadata
311 * before the revoke is complete. In ext3, this implies calling the
312 * revoke before clearing the block bitmap when we are deleting
313 * metadata.
314 *
315 * Revoke performs a jbd2_journal_forget on any buffer_head passed in as a
316 * parameter, but does _not_ forget the buffer_head if the bh was only
317 * found implicitly.
318 *
319 * bh_in may not be a journalled buffer - it may have come off
320 * the hash tables without an attached journal_head.
321 *
322 * If bh_in is non-zero, jbd2_journal_revoke() will decrement its b_count
323 * by one.
324 */
328 {
342 }
351 }
352 #ifdef JBD2_EXPENSIVE_CHECKING
356 /* If there is a different buffer_head lying around in
357 * memory anywhere... */
360 /* ... and it has RevokeValid status... */
362 /* ...then it better be revoked too,
363 * since it's illegal to create a revoke
364 * record against a buffer_head which is
365 * not marked revoked --- that would
366 * risk missing a subsequent revoke
367 * cancel. */
370 }
371 }
372 #endif
378 }
379 /* We really ought not ever to revoke twice in a row without
380 first having the revoke cancelled: it's illegal to free a
381 block twice without allocating it in between! */
388 }
397 }
398 }
406 }
408 /*
409 * Cancel an outstanding revoke. For use only internally by the
410 * journaling code (called from jbd2_journal_get_write_access).
411 *
412 * We trust buffer_revoked() on the buffer if the buffer is already
413 * being journaled: if there is no revoke pending on the buffer, then we
414 * don't do anything here.
415 *
416 * This would break if it were possible for a buffer to be revoked and
417 * discarded, and then reallocated within the same transaction. In such
418 * a case we would have lost the revoked bit, but when we arrived here
419 * the second time we would still have a pending revoke to cancel. So,
420 * do not trust the Revoked bit on buffers unless RevokeValid is also
421 * set.
422 */
424 {
433 /* Is the existing Revoke bit valid? If so, we trust it, and
434 * only perform the full cancel if the revoke bit is set. If
435 * not, we can't trust the revoke bit, and we need to do the
436 * full search for a revoke record. */
442 }
454 }
455 }
457 #ifdef JBD2_EXPENSIVE_CHECKING
458 /* There better not be one left behind by now! */
461 #endif
463 /* Finally, have we just cleared revoke on an unhashed
464 * buffer_head? If so, we'd better make sure we clear the
465 * revoked status on any hashed alias too, otherwise the revoke
466 * state machine will get very upset later on. */
474 }
475 }
477 }
479 /*
480 * journal_clear_revoked_flag clears revoked flag of buffers in
481 * revoke table to reflect there is no revoked buffers in the next
482 * transaction which is going to be started.
483 */
485 {
504 }
505 }
506 }
507 }
509 /* journal_switch_revoke table select j_revoke for next transaction
510 * we do not want to suspend any processing until all revokes are
511 * written -bzzz
512 */
514 {
519 else
524 }
526 /*
527 * Write revoke records to the journal for all entries in the current
528 * revoke hash, deleting the entries as we go.
529 */
532 {
544 /* select revoke table for committing transaction */
556 count++;
559 }
560 }
564 }
566 /*
567 * Write out one revoke record. We need to create a new descriptor
568 * block if the old one is full or if we have not already created one.
569 */
576 {
582 /* If we are already aborting, this all becomes a noop. We
583 still need to go round the loop in
584 jbd2_journal_write_revoke_records in order to free all of the
585 revoke records: only the IO to the journal is omitted. */
592 /* Do we need to leave space at the end for a checksum? */
598 else
601 /* Make sure we have a descriptor with space left for the record */
606 }
607 }
611 JBD2_REVOKE_BLOCK);
615 /* Record it so that we can wait for IO completion later */
621 }
626 else
632 }
634 /*
635 * Flush a revoke descriptor out to the journal. If we are aborting,
636 * this is a noop; otherwise we are generating a buffer which needs to
637 * be waited for during commit, so it has to go onto the appropriate
638 * journal buffer list.
639 */
644 {
658 }
659 #endif
661 /*
662 * Revoke support for recovery.
663 *
664 * Recovery needs to be able to:
665 *
666 * record all revoke records, including the tid of the latest instance
667 * of each revoke in the journal
668 *
669 * check whether a given block in a given transaction should be replayed
670 * (ie. has not been revoked by a revoke record in that or a subsequent
671 * transaction)
672 *
673 * empty the revoke table after recovery.
674 */
676 /*
677 * First, setting revoke records. We create a new revoke record for
678 * every block ever revoked in the log as we scan it for recovery, and
679 * we update the existing records if we find multiple revokes for a
680 * single block.
681 */
685 tid_t sequence)
686 {
691 /* If we have multiple occurrences, only record the
692 * latest sequence number in the hashed record */
696 }
698 }
700 /*
701 * Test revoke records. For a given block referenced in the log, has
702 * that block been revoked? A revoke record with a given transaction
703 * sequence number revokes all blocks in that transaction and earlier
704 * ones, but later transactions still need replayed.
705 */
709 tid_t sequence)
710 {
719 }
721 /*
722 * Finally, once recovery is over, we need to clear the revoke table so
723 * that it can be reused by the running filesystem.
724 */
727 {
741 }
742 }
743 }