| blob | fddbb091a86f858c90f672fe7d5f53a7532152b2 |
1 /*
2 * Copyright (c) 2000-2006 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 */
54 #if defined(DEBUG)
57 #else
58 #define xlog_recover_check_summary(log)
59 #define xlog_recover_check_ail(mp, lip, gen)
60 #endif
63 /*
64 * Sector aligned buffer routines for buffer create/read/write/access
65 */
67 #define XLOG_SECTOR_ROUNDUP_BBCOUNT(log, bbs) \
68 ( ((log)->l_sectbb_mask && (bbs & (log)->l_sectbb_mask)) ? \
69 ((bbs + (log)->l_sectbb_mask + 1) & ~(log)->l_sectbb_mask) : (bbs) )
70 #define XLOG_SECTOR_ROUNDDOWN_BLKNO(log, bno) ((bno) & ~(log)->l_sectbb_mask)
72 xfs_buf_t *
76 {
83 }
85 }
87 void
90 {
92 }
95 /*
96 * nbblks should be uint, but oh well. Just want to catch that 32-bit length.
97 */
98 int
101 xfs_daddr_t blk_no,
104 {
110 }
127 }
129 /*
130 * Write out the buffer at the given block for the given number of blocks.
131 * The buffer is kept locked across the write and is returned locked.
132 * This can only be used for synchronous log writes.
133 */
134 STATIC int
137 xfs_daddr_t blk_no,
140 {
146 }
163 }
165 STATIC xfs_caddr_t
168 xfs_daddr_t blk_no,
171 {
172 xfs_caddr_t ptr;
181 }
183 #ifdef DEBUG
184 /*
185 * dump debug superblock and log record information
186 */
187 STATIC void
191 {
202 }
203 #else
204 #define xlog_header_check_dump(mp, head)
205 #endif
207 /*
208 * check log record header for recovery
209 */
210 STATIC int
214 {
217 /*
218 * IRIX doesn't write the h_fmt field and leaves it zeroed
219 * (XLOG_FMT_UNKNOWN). This stops us from trying to recover
220 * a dirty log created in IRIX.
221 */
236 }
238 }
240 /*
241 * read the head block of the log and check the header
242 */
243 STATIC int
247 {
251 /*
252 * IRIX doesn't write the h_fs_uuid or h_fmt fields. If
253 * h_fs_uuid is nil, we assume this log was last mounted
254 * by IRIX and continue.
255 */
263 }
265 }
267 STATIC void
270 {
276 /*
277 * We're not going to bother about retrying
278 * this during recovery. One strike!
279 */
284 }
288 }
290 /*
291 * This routine finds (to an approximation) the first block in the physical
292 * log which contains the given cycle. It uses a binary search algorithm.
293 * Note that the algorithm can not be perfect because the disk will not
294 * necessarily be perfect.
295 */
296 int
300 xfs_daddr_t first_blk,
302 uint cycle)
303 {
304 xfs_caddr_t offset;
305 xfs_daddr_t mid_blk;
306 uint mid_cycle;
317 /* last_half_cycle == mid_cycle */
320 /* first_half_cycle == mid_cycle */
321 }
323 }
328 }
330 /*
331 * Check that the range of blocks does not contain the cycle number
332 * given. The scan needs to occur from front to back and the ptr into the
333 * region must be updated since a later routine will need to perform another
334 * test. If the region is completely good, we end up returning the same
335 * last block number.
336 *
337 * Set blkno to -1 if we encounter no errors. This is an invalid block number
338 * since we don't ever expect logs to get this large.
339 */
340 STATIC int
343 xfs_daddr_t start_blk,
345 uint stop_on_cycle_no,
347 {
349 uint cycle;
351 xfs_daddr_t bufblks;
358 /* can't get enough memory to do everything in one big buffer */
362 }
378 }
381 }
382 }
386 out:
389 }
391 /*
392 * Potentially backup over partial log record write.
393 *
394 * In the typical case, last_blk is the number of the block directly after
395 * a good log record. Therefore, we subtract one to get the block number
396 * of the last block in the given buffer. extra_bblks contains the number
397 * of blocks we would have read on a previous read. This happens when the
398 * last log record is split over the end of the physical log.
399 *
400 * extra_bblks is the number of blocks potentially verified on a previous
401 * call to this routine.
402 */
403 STATIC int
406 xfs_daddr_t start_blk,
409 {
410 xfs_daddr_t i;
430 }
434 /* valid log record not found */
440 }
446 }
456 }
458 /*
459 * We hit the beginning of the physical log & still no header. Return
460 * to caller. If caller can handle a return of -1, then this routine
461 * will be called again for the end of the physical log.
462 */
466 }
468 /*
469 * We have the final block of the good log (the first block
470 * of the log record _before_ the head. So we check the uuid.
471 */
475 /*
476 * We may have found a log record header before we expected one.
477 * last_blk will be the 1st block # with a given cycle #. We may end
478 * up reading an entire log record. In this case, we don't want to
479 * reset last_blk. Only when last_blk points in the middle of a log
480 * record do we update last_blk.
481 */
487 xhdrs++;
490 }
496 out:
499 }
501 /*
502 * Head is defined to be the point of the log where the next log write
503 * write could go. This means that incomplete LR writes at the end are
504 * eliminated when calculating the head. We aren't guaranteed that previous
505 * LR have complete transactions. We only know that a cycle number of
506 * current cycle number -1 won't be present in the log if we start writing
507 * from our current block number.
508 *
509 * last_blk contains the block number of the first block with a given
510 * cycle number.
511 *
512 * Return: zero if normal, non-zero if error.
513 */
514 STATIC int
518 {
520 xfs_caddr_t offset;
524 uint stop_on_cycle;
527 /* Is the end of the log device zeroed? */
531 /* Is the whole lot zeroed? */
533 /* Linux XFS shouldn't generate totally zeroed logs -
534 * mkfs etc write a dummy unmount record to a fresh
535 * log so we can store the uuid in there
536 */
538 }
544 }
562 /*
563 * If the 1st half cycle number is equal to the last half cycle number,
564 * then the entire log is stamped with the same cycle number. In this
565 * case, head_blk can't be set to zero (which makes sense). The below
566 * math doesn't work out properly with head_blk equal to zero. Instead,
567 * we set it to log_bbnum which is an invalid block number, but this
568 * value makes the math correct. If head_blk doesn't changed through
569 * all the tests below, *head_blk is set to zero at the very end rather
570 * than log_bbnum. In a sense, log_bbnum and zero are the same block
571 * in a circular file.
572 */
574 /*
575 * In this case we believe that the entire log should have
576 * cycle number last_half_cycle. We need to scan backwards
577 * from the end verifying that there are no holes still
578 * containing last_half_cycle - 1. If we find such a hole,
579 * then the start of that hole will be the new head. The
580 * simple case looks like
581 * x | x ... | x - 1 | x
582 * Another case that fits this picture would be
583 * x | x + 1 | x ... | x
584 * In this case the head really is somewhere at the end of the
585 * log, as one of the latest writes at the beginning was
586 * incomplete.
587 * One more case is
588 * x | x + 1 | x ... | x - 1 | x
589 * This is really the combination of the above two cases, and
590 * the head has to end up at the start of the x-1 hole at the
591 * end of the log.
592 *
593 * In the 256k log case, we will read from the beginning to the
594 * end of the log and search for cycle numbers equal to x-1.
595 * We don't worry about the x+1 blocks that we encounter,
596 * because we know that they cannot be the head since the log
597 * started with x.
598 */
602 /*
603 * In this case we want to find the first block with cycle
604 * number matching last_half_cycle. We expect the log to be
605 * some variation on
606 * x + 1 ... | x ...
607 * The first block with cycle number x (last_half_cycle) will
608 * be where the new head belongs. First we do a binary search
609 * for the first occurrence of last_half_cycle. The binary
610 * search may not be totally accurate, so then we scan back
611 * from there looking for occurrences of last_half_cycle before
612 * us. If that backwards scan wraps around the beginning of
613 * the log, then we look for occurrences of last_half_cycle - 1
614 * at the end of the log. The cases we're looking for look
615 * like
616 * x + 1 ... | x | x + 1 | x ...
617 * ^ binary search stopped here
618 * or
619 * x + 1 ... | x ... | x - 1 | x
620 * <---------> less than scan distance
621 */
626 }
628 /*
629 * Now validate the answer. Scan back some number of maximum possible
630 * blocks and make sure each one has the expected cycle number. The
631 * maximum is determined by the total possible amount of buffering
632 * in the in-core log. The following number can be made tighter if
633 * we actually look at the block size of the filesystem.
634 */
637 /*
638 * We are guaranteed that the entire check can be performed
639 * in one buffer.
640 */
649 /*
650 * We are going to scan backwards in the log in two parts.
651 * First we scan the physical end of the log. In this part
652 * of the log, we are looking for blocks with cycle number
653 * last_half_cycle - 1.
654 * If we find one, then we know that the log starts there, as
655 * we've found a hole that didn't get written in going around
656 * the end of the physical log. The simple case for this is
657 * x + 1 ... | x ... | x - 1 | x
658 * <---------> less than scan distance
659 * If all of the blocks at the end of the log have cycle number
660 * last_half_cycle, then we check the blocks at the start of
661 * the log looking for occurrences of last_half_cycle. If we
662 * find one, then our current estimate for the location of the
663 * first occurrence of last_half_cycle is wrong and we move
664 * back to the hole we've found. This case looks like
665 * x + 1 ... | x | x + 1 | x ...
666 * ^ binary search stopped here
667 * Another case we need to handle that only occurs in 256k
668 * logs is
669 * x + 1 ... | x ... | x+1 | x ...
670 * ^ binary search stops here
671 * In a 256k log, the scan at the end of the log will see the
672 * x + 1 blocks. We need to skip past those since that is
673 * certainly not the head of the log. By searching for
674 * last_half_cycle-1 we accomplish that.
675 */
686 }
688 /*
689 * Scan beginning of log now. The last part of the physical
690 * log is good. This scan needs to verify that it doesn't find
691 * the last_half_cycle.
692 */
701 }
703 bad_blk:
704 /*
705 * Now we need to make sure head_blk is not pointing to a block in
706 * the middle of a log record.
707 */
712 /* start ptr at last block ptr before head_blk */
724 /* We hit the beginning of the log during our search */
741 }
746 else
748 /*
749 * When returning here, we have a good block number. Bad block
750 * means that during a previous crash, we didn't have a clean break
751 * from cycle number N to cycle number N-1. In this case, we need
752 * to find the first block with cycle number N-1.
753 */
756 bp_err:
762 }
764 /*
765 * Find the sync block number or the tail of the log.
766 *
767 * This will be the block number of the last record to have its
768 * associated buffers synced to disk. Every log record header has
769 * a sync lsn embedded in it. LSNs hold block numbers, so it is easy
770 * to get a sync block number. The only concern is to figure out which
771 * log record header to believe.
772 *
773 * The following algorithm uses the log record header with the largest
774 * lsn. The entire log record does not need to be valid. We only care
775 * that the header is valid.
776 *
777 * We could speed up search by using current head_blk buffer, but it is not
778 * available.
779 */
780 int
785 {
791 xfs_daddr_t umount_data_blk;
792 xfs_daddr_t after_umount_blk;
793 xfs_lsn_t tail_lsn;
798 /*
799 * Find previous log record
800 */
813 /* leave all other log inited values alone */
815 }
816 }
818 /*
819 * Search backwards looking for log record header block
820 */
830 }
831 }
832 /*
833 * If we haven't found the log record header block, start looking
834 * again from the end of the physical log. XXXmiken: There should be
835 * a check here to make sure we didn't search more than N blocks in
836 * the previous code.
837 */
847 }
848 }
849 }
854 }
856 /* find blk_no of tail of log */
860 /*
861 * Reset log values according to the state of the log when we
862 * crashed. In the case where head_blk == 0, we bump curr_cycle
863 * one because the next write starts a new cycle rather than
864 * continuing the cycle of the last good log record. At this
865 * point we have guaranteed that all partial log records have been
866 * accounted for. Therefore, we know that the last good log record
867 * written was complete and ended exactly on the end boundary
868 * of the physical log.
869 */
882 /*
883 * Look for unmount record. If we find it, then we know there
884 * was a clean unmount. Since 'i' could be the last block in
885 * the physical log, we convert to a log block before comparing
886 * to the head_blk.
887 *
888 * Save the current tail lsn to use to pass to
889 * xlog_clear_stale_blocks() below. We won't want to clear the
890 * unmount record if there is one, so we pass the lsn of the
891 * unmount record rather than the block after it.
892 */
901 hblks++;
904 }
907 }
916 }
920 /*
921 * Set tail and last sync so that newly written
922 * log records will point recovery to after the
923 * current unmount record.
924 */
926 after_umount_blk);
928 after_umount_blk);
931 /*
932 * Note that the unmount was clean. If the unmount
933 * was not clean, we need to know this to rebuild the
934 * superblock counters from the perag headers if we
935 * have a filesystem using non-persistent counters.
936 */
938 }
939 }
941 /*
942 * Make sure that there are no blocks in front of the head
943 * with the same cycle number as the head. This can happen
944 * because we allow multiple outstanding log writes concurrently,
945 * and the later writes might make it out before earlier ones.
946 *
947 * We use the lsn from before modifying it so that we'll never
948 * overwrite the unmount record after a clean unmount.
949 *
950 * Do this only if we are going to recover the filesystem
951 *
952 * NOTE: This used to say "if (!readonly)"
953 * However on Linux, we can & do recover a read-only filesystem.
954 * We only skip recovery if NORECOVERY is specified on mount,
955 * in which case we would not be here.
956 *
957 * But... if the -device- itself is readonly, just skip this.
958 * We can't recover this device anyway, so it won't matter.
959 */
962 }
964 bread_err:
965 exit:
971 }
973 /*
974 * Is the log zeroed at all?
975 *
976 * The last binary search should be changed to perform an X block read
977 * once X becomes small enough. You can then search linearly through
978 * the X blocks. This will cut down on the number of reads we need to do.
979 *
980 * If the log is partially zeroed, this routine will pass back the blkno
981 * of the first block with cycle number 0. It won't have a complete LR
982 * preceding it.
983 *
984 * Return:
985 * 0 => the log is completely written to
986 * -1 => use *blk_no as the first block of the log
987 * >0 => error has occurred
988 */
989 int
993 {
995 xfs_caddr_t offset;
998 xfs_daddr_t num_scan_bblks;
1003 /* check totally zeroed log */
1015 }
1017 /* check partially zeroed log */
1026 /*
1027 * If the cycle of the last block is zero, the cycle of
1028 * the first block must be 1. If it's not, maybe we're
1029 * not looking at a log... Bail out.
1030 */
1033 }
1035 /* we have a partially zeroed log */
1040 /*
1041 * Validate the answer. Because there is no way to guarantee that
1042 * the entire log is made up of log records which are the same size,
1043 * we scan over the defined maximum blocks. At this point, the maximum
1044 * is not chosen to mean anything special. XXXmiken
1045 */
1053 /*
1054 * We search for any instances of cycle number 0 that occur before
1055 * our current estimate of the head. What we're trying to detect is
1056 * 1 ... | 0 | 1 | 0...
1057 * ^ binary search ends here
1058 */
1065 /*
1066 * Potentially backup over partial log record write. We don't need
1067 * to search the end of the log because we know it is zero.
1068 */
1077 bp_err:
1082 }
1084 /*
1085 * These are simple subroutines used by xlog_clear_stale_blocks() below
1086 * to initialize a buffer full of empty log record headers and write
1087 * them into the log.
1088 */
1089 STATIC void
1092 xfs_caddr_t buf,
1097 {
1109 }
1111 STATIC int
1119 {
1120 xfs_caddr_t offset;
1134 }
1136 /* We may need to do a read at the start to fill in part of
1137 * the buffer in the starting sector not covered by the first
1138 * write below.
1139 */
1145 }
1147 }
1155 /* We may need to do a read at the end to fill in part of
1156 * the buffer in the final sector not covered by the write.
1157 * If this is the same sector as the above read, skip it.
1158 */
1167 }
1174 }
1180 }
1183 }
1185 /*
1186 * This routine is called to blow away any incomplete log writes out
1187 * in front of the log head. We do this so that we won't become confused
1188 * if we come up, write only a little bit more, and then crash again.
1189 * If we leave the partial log records out there, this situation could
1190 * cause us to think those partial writes are valid blocks since they
1191 * have the current cycle number. We get rid of them by overwriting them
1192 * with empty log records with the old cycle number rather than the
1193 * current one.
1194 *
1195 * The tail lsn is passed in rather than taken from
1196 * the log so that we will not write over the unmount record after a
1197 * clean unmount in a 512 block log. Doing so would leave the log without
1198 * any valid log records in it until a new one was written. If we crashed
1199 * during that time we would not be able to recover.
1200 */
1201 STATIC int
1204 xfs_lsn_t tail_lsn)
1205 {
1217 /*
1218 * Figure out the distance between the new head of the log
1219 * and the tail. We want to write over any blocks beyond the
1220 * head that we may have written just before the crash, but
1221 * we don't want to overwrite the tail of the log.
1222 */
1224 /*
1225 * The tail is behind the head in the physical log,
1226 * so the distance from the head to the tail is the
1227 * distance from the head to the end of the log plus
1228 * the distance from the beginning of the log to the
1229 * tail.
1230 */
1235 }
1238 /*
1239 * The head is behind the tail in the physical log,
1240 * so the distance from the head to the tail is just
1241 * the tail block minus the head block.
1242 */
1247 }
1249 }
1251 /*
1252 * If the head is right up against the tail, we can't clear
1253 * anything.
1254 */
1258 }
1261 /*
1262 * Take the smaller of the maximum amount of outstanding I/O
1263 * we could have and the distance to the tail to clear out.
1264 * We take the smaller so that we don't overwrite the tail and
1265 * we don't waste all day writing from the head to the tail
1266 * for no reason.
1267 */
1271 /*
1272 * We can stomp all the blocks we need to without
1273 * wrapping around the end of the log. Just do it
1274 * in a single write. Use the cycle number of the
1275 * current cycle minus one so that the log will look like:
1276 * n ... | n - 1 ...
1277 */
1280 tail_block);
1284 /*
1285 * We need to wrap around the end of the physical log in
1286 * order to clear all the blocks. Do it in two separate
1287 * I/Os. The first write should be from the head to the
1288 * end of the physical log, and it should use the current
1289 * cycle number minus one just like above.
1290 */
1294 tail_block);
1299 /*
1300 * Now write the blocks at the start of the physical log.
1301 * This writes the remainder of the blocks we want to clear.
1302 * It uses the current cycle number since we're now on the
1303 * same cycle as the head so that we get:
1304 * n ... n ... | n - 1 ...
1305 * ^^^^^ blocks we're writing
1306 */
1312 }
1315 }
1317 /******************************************************************************
1318 *
1319 * Log recover routines
1320 *
1321 ******************************************************************************
1322 */
1324 STATIC xlog_recover_t *
1327 xlog_tid_t tid)
1328 {
1335 }
1337 }
1339 STATIC void
1343 {
1346 }
1348 STATIC void
1351 {
1356 }
1358 STATIC int
1361 xfs_caddr_t dp,
1363 {
1370 /* finish copying rest of trans header */
1376 }
1387 }
1389 /*
1390 * The next region to add is the start of a new region. It could be
1391 * a whole region or it could be the first part of a new region. Because
1392 * of this, the assumption here is that the type and size fields of all
1393 * format structures fit into the first 32 bits of the structure.
1394 *
1395 * This works because all regions must be 32 bit aligned. Therefore, we
1396 * either have both fields or we have neither field. In the case we have
1397 * neither field, the data part of the region is zero length. We only have
1398 * a log_op_header and can throw away the header since a new one will appear
1399 * later. If we have at least 4 bytes, then we can determine how many regions
1400 * will appear in the current log item.
1401 */
1402 STATIC int
1405 xfs_caddr_t dp,
1407 {
1410 xfs_caddr_t ptr;
1421 }
1430 }
1439 }
1441 /* Description region is ri_buf[0] */
1446 }
1448 STATIC void
1451 xlog_tid_t tid,
1452 xfs_lsn_t lsn)
1453 {
1460 }
1462 STATIC int
1466 {
1479 }
1481 }
1487 }
1489 }
1491 }
1493 STATIC void
1497 {
1506 }
1507 }
1509 STATIC void
1513 {
1516 }
1518 STATIC int
1521 {
1537 itemq);
1539 }
1552 }
1556 }
1558 /*
1559 * Build up the table of buf cancel records so that we don't replay
1560 * cancelled data in the second pass. For buffer records that are
1561 * not cancel records, there is nothing to do here so we just return.
1562 *
1563 * If we get a cancel record which is already in the table, this indicates
1564 * that the buffer was cancelled multiple times. In order to ensure
1565 * that during pass 2 we keep the record in the table until we reach its
1566 * last occurrence in the log, we keep a reference count in the cancel
1567 * record in the table to tell us how many times we expect to see this
1568 * record during the second pass.
1569 */
1570 STATIC void
1574 {
1589 }
1591 /*
1592 * If this isn't a cancel buffer item, then just return.
1593 */
1597 /*
1598 * Insert an xfs_buf_cancel record into the hash table of
1599 * them. If there is already an identical record, bump
1600 * its reference count.
1601 */
1603 XLOG_BC_TABLE_SIZE];
1604 /*
1605 * If the hash bucket is empty then just insert a new record into
1606 * the bucket.
1607 */
1610 KM_SLEEP);
1617 }
1619 /*
1620 * The hash bucket is not empty, so search for duplicates of our
1621 * record. If we find one them just bump its refcount. If not
1622 * then add us at the end of the list.
1623 */
1630 }
1633 }
1636 KM_SLEEP);
1642 }
1644 /*
1645 * Check to see whether the buffer being recovered has a corresponding
1646 * entry in the buffer cancel record table. If it does then return 1
1647 * so that it will be cancelled, otherwise return 0. If the buffer is
1648 * actually a buffer cancel item (XFS_BLI_CANCEL is set), then decrement
1649 * the refcount on the entry in the table and remove it from the table
1650 * if this is the last reference.
1651 *
1652 * We remove the cancel record from the table when we encounter its
1653 * last occurrence in the log so that if the same buffer is re-used
1654 * again after its last cancellation we actually replay the changes
1655 * made at that point.
1656 */
1657 STATIC int
1660 xfs_daddr_t blkno,
1661 uint len,
1662 ushort flags)
1663 {
1669 /*
1670 * There is nothing in the table built in pass one,
1671 * so this buffer must not be cancelled.
1672 */
1675 }
1678 XLOG_BC_TABLE_SIZE];
1681 /*
1682 * There is no corresponding entry in the table built
1683 * in pass one, so this buffer has not been cancelled.
1684 */
1687 }
1689 /*
1690 * Search for an entry in the buffer cancel table that
1691 * matches our buffer.
1692 */
1696 /*
1697 * We've go a match, so return 1 so that the
1698 * recovery of this buffer is cancelled.
1699 * If this buffer is actually a buffer cancel
1700 * log item, then decrement the refcount on the
1701 * one in the table and remove it if this is the
1702 * last reference.
1703 */
1711 }
1714 }
1715 }
1717 }
1720 }
1721 /*
1722 * We didn't find a corresponding entry in the table, so
1723 * return 0 so that the buffer is NOT cancelled.
1724 */
1727 }
1729 STATIC int
1733 {
1744 }
1747 }
1749 /*
1750 * Perform recovery for a buffer full of inodes. In these buffers,
1751 * the only data which should be recovered is that which corresponds
1752 * to the di_next_unlinked pointers in the on disk inode structures.
1753 * The rest of the data for the inodes is always logged through the
1754 * inodes themselves rather than the inode buffer and is recovered
1755 * in xlog_recover_do_inode_trans().
1756 *
1757 * The only time when buffers full of inodes are fully recovered is
1758 * when the buffer is full of newly allocated inodes. In this case
1759 * the buffer will not be marked as an inode buffer and so will be
1760 * sent to xlog_recover_do_reg_buffer() below during recovery.
1761 */
1762 STATIC int
1768 {
1787 }
1788 /*
1789 * Set the variables corresponding to the current region to
1790 * 0 so that we'll initialize them on the first pass through
1791 * the loop.
1792 */
1805 /*
1806 * The next di_next_unlinked field is beyond
1807 * the current logged region. Find the next
1808 * logged region that contains or is beyond
1809 * the current di_next_unlinked field.
1810 */
1814 /*
1815 * If there are no more logged regions in the
1816 * buffer, then we're done.
1817 */
1820 }
1823 bit);
1827 item_index++;
1828 }
1830 /*
1831 * If the current logged region starts after the current
1832 * di_next_unlinked field, then move on to the next
1833 * di_next_unlinked field.
1834 */
1837 }
1843 /*
1844 * The current logged region contains a copy of the
1845 * current di_next_unlinked field. Extract its value
1846 * and copy it to the buffer copy.
1847 */
1853 "bad inode buffer log record (ptr = 0x%p, bp = 0x%p). XFS trying to replay bad (0) inode di_next_unlinked field",
1858 }
1861 next_unlinked_offset);
1863 }
1866 }
1868 /*
1869 * Perform a 'normal' buffer recovery. Each logged region of the
1870 * buffer should be copied over the corresponding region in the
1871 * given buffer. The bitmap in the buf log format structure indicates
1872 * where to place the logged data.
1873 */
1874 /*ARGSUSED*/
1875 STATIC void
1880 {
1893 }
1907 /*
1908 * Do a sanity check if this is a dquot buffer. Just checking
1909 * the first dquot in the buffer should do. XXXThis is
1910 * probably a good thing to do for other buf types also.
1911 */
1919 }
1925 i++;
1927 }
1929 /* Shouldn't be any more regions */
1931 }
1933 /*
1934 * Do some primitive error checking on ondisk dquot data structures.
1935 */
1936 int
1939 xfs_dqid_t id,
1941 uint flags,
1943 {
1947 /*
1948 * We can encounter an uninitialized dquot buffer for 2 reasons:
1949 * 1. If we crash while deleting the quotainode(s), and those blks got
1950 * used for user data. This is because we take the path of regular
1951 * file deletion; however, the size field of quotainodes is never
1952 * updated, so all the tricks that we play in itruncate_finish
1953 * don't quite matter.
1954 *
1955 * 2. We don't play the quota buffers when there's a quotaoff logitem.
1956 * But the allocation will be replayed so we'll end up with an
1957 * uninitialized quota block.
1958 *
1959 * This is all fine; things are still consistent, and we haven't lost
1960 * any quota information. Just don't complain about bad dquot blks.
1961 */
1967 errs++;
1968 }
1974 errs++;
1975 }
1984 errs++;
1985 }
1990 "%s : ondisk-dquot 0x%p, ID mismatch: "
1993 errs++;
1994 }
2003 "%s : Dquot ID 0x%x (0x%p) "
2006 errs++;
2007 }
2008 }
2015 "%s : Dquot ID 0x%x (0x%p) "
2018 errs++;
2019 }
2020 }
2027 "%s : Dquot ID 0x%x (0x%p) "
2030 errs++;
2031 }
2032 }
2033 }
2041 /*
2042 * Typically, a repair is only requested by quotacheck.
2043 */
2054 }
2056 /*
2057 * Perform a dquot buffer recovery.
2058 * Simple algorithm: if we have found a QUOTAOFF logitem of the same type
2059 * (ie. USR or GRP), then just toss this buffer away; don't recover it.
2060 * Else, treat it as a regular buffer and do recovery.
2061 */
2062 STATIC void
2069 {
2070 uint type;
2072 /*
2073 * Filesystems are required to send in quota flags at mount time.
2074 */
2077 }
2086 /*
2087 * This type of quotas was turned off, so ignore this buffer
2088 */
2093 }
2095 /*
2096 * This routine replays a modification made to a buffer at runtime.
2097 * There are actually two types of buffer, regular and inode, which
2098 * are handled differently. Inode buffers are handled differently
2099 * in that we only recover a specific set of data from them, namely
2100 * the inode di_next_unlinked fields. This is because all other inode
2101 * data is actually logged via inode records and any data we replay
2102 * here which overlaps that may be stale.
2103 *
2104 * When meta-data buffers are freed at run time we log a buffer item
2105 * with the XFS_BLI_CANCEL bit set to indicate that previous copies
2106 * of the buffer in the log should not be replayed at recovery time.
2107 * This is so that if the blocks covered by the buffer are reused for
2108 * file data before we crash we don't end up replaying old, freed
2109 * meta-data into a user's file.
2110 *
2111 * To handle the cancellation of buffer log items, we make two passes
2112 * over the log during recovery. During the first we build a table of
2113 * those buffers which have been cancelled, and during the second we
2114 * only replay those buffers which do not have corresponding cancel
2115 * records in the table. See xlog_recover_do_buffer_pass[1,2] above
2116 * for more details on the implementation of the table of cancel records.
2117 */
2118 STATIC int
2123 {
2129 xfs_daddr_t blkno;
2131 ushort flags;
2136 /*
2137 * In this pass we're only looking for buf items
2138 * with the XFS_BLI_CANCEL bit set.
2139 */
2143 /*
2144 * In this pass we want to recover all the buffers
2145 * which have not been cancelled and are not
2146 * cancellation buffers themselves. The routine
2147 * we call here will tell us whether or not to
2148 * continue with the replay of this buffer.
2149 */
2153 }
2154 }
2169 }
2174 XFS_BUF_LOCK);
2177 }
2184 }
2194 }
2198 /*
2199 * Perform delayed write on the buffer. Asynchronous writes will be
2200 * slower when taking into account all the buffers to be flushed.
2201 *
2202 * Also make sure that only inode buffers with good sizes stay in
2203 * the buffer cache. The kernel moves inodes in buffers of 1 block
2204 * or XFS_INODE_CLUSTER_SIZE bytes, whichever is bigger. The inode
2205 * buffers in the log can be a different size if the log was generated
2206 * by an older kernel using unclustered inode buffers or a newer kernel
2207 * running with a different inode cluster size. Regardless, if the
2208 * the inode buffer size isn't MAX(blocksize, XFS_INODE_CLUSTER_SIZE)
2209 * for *our* value of XFS_INODE_CLUSTER_SIZE, then we need to keep
2210 * the buffer out of the buffer cache so that the buffer won't
2211 * overlap with future reads of those inodes.
2212 */
2225 }
2228 }
2230 STATIC int
2235 {
2239 xfs_imap_t imap;
2241 xfs_ino_t ino;
2243 xfs_caddr_t src;
2244 xfs_caddr_t dest;
2247 uint fields;
2253 }
2264 }
2272 /*
2273 * It's an old inode format record. We don't know where
2274 * its cluster is located on disk, and we can't allow
2275 * xfs_imap() to figure it out because the inode btrees
2276 * are not ready to be used. Therefore do not pass the
2277 * XFS_IMAP_LOOKUP flag to xfs_imap(). This will give
2278 * us only the single block in which the inode lives
2279 * rather than its cluster, so we must make sure to
2280 * invalidate the buffer when we write it out below.
2281 */
2284 }
2286 /*
2287 * Inode buffers can be freed, look out for it,
2288 * and do not replay the inode.
2289 */
2293 }
2296 XFS_BUF_LOCK);
2303 }
2308 /*
2309 * Make sure the place we're flushing out to really looks
2310 * like an inode!
2311 */
2321 }
2332 }
2334 /* Skip replay when the on disk inode is newer than the log one */
2337 /*
2338 * Deal with the wrap case, DI_MAX_FLUSH is less
2339 * than smaller numbers
2340 */
2344 /* do nothing */
2349 }
2350 }
2351 /* Take the opportunity to reset the flush iteration count */
2361 "xfs_inode_recover: Bad regular inode log record, rec ptr 0x%p, ino ptr = 0x%p, ino bp = 0x%p, ino %Ld",
2365 }
2374 "xfs_inode_recover: Bad dir inode log record, rec ptr 0x%p, ino ptr = 0x%p, ino bp = 0x%p, ino %Ld",
2378 }
2379 }
2385 "xfs_inode_recover: Bad inode log record, rec ptr 0x%p, dino ptr 0x%p, dino bp 0x%p, ino %Ld, total extents = %d, nblocks = %Ld",
2391 }
2397 "xfs_inode_recover: Bad inode log rec ptr 0x%p, dino ptr 0x%p, dino bp 0x%p, ino %Ld, forkoff 0x%x",
2401 }
2411 }
2413 /* The core is in in-core format */
2417 /* the rest is in on-disk format */
2422 }
2433 }
2457 /*
2458 * There are no data fork flags set.
2459 */
2462 }
2464 /*
2465 * If we logged any attribute data, recover it. There may or
2466 * may not have been any other non-core data logged in this
2467 * transaction.
2468 */
2474 }
2500 }
2501 }
2503 write_inode_buffer:
2513 }
2515 error:
2519 }
2521 /*
2522 * Recover QUOTAOFF records. We simply make a note of it in the xlog_t
2523 * structure, so that we know not to do any dquot item or dquot buffer recovery,
2524 * of that type.
2525 */
2526 STATIC int
2531 {
2536 }
2541 /*
2542 * The logitem format's flag tells us if this was user quotaoff,
2543 * group/project quotaoff or both.
2544 */
2553 }
2555 /*
2556 * Recover a dquot record
2557 */
2558 STATIC int
2563 {
2569 uint type;
2573 }
2576 /*
2577 * Filesystems are required to send in quota flags at mount time.
2578 */
2584 /*
2585 * This type of quotas was turned off, so ignore this record.
2586 */
2593 /*
2594 * At this point we know that quota was _not_ turned off.
2595 * Since the mount flags are not indicating to us otherwise, this
2596 * must mean that quota is on, and the dquot needs to be replayed.
2597 * Remember that we may not have fully recovered the superblock yet,
2598 * so we can't do the usual trick of looking at the SB quota bits.
2599 *
2600 * The other possibility, of course, is that the quota subsystem was
2601 * removed since the last mount - ENOSYS.
2602 */
2610 }
2621 }
2625 /*
2626 * At least the magic num portion should be on disk because this
2627 * was among a chunk of dquots created earlier, and we did some
2628 * minimal initialization then.
2629 */
2634 }
2646 }
2648 /*
2649 * This routine is called to create an in-core extent free intent
2650 * item from the efi format structure which was logged on disk.
2651 * It allocates an in-core efi, copies the extents from the format
2652 * structure into it, and adds the efi to the AIL with the given
2653 * LSN.
2654 */
2655 STATIC int
2659 xfs_lsn_t lsn,
2661 {
2670 }
2680 }
2685 /*
2686 * xfs_trans_update_ail() drops the AIL lock.
2687 */
2690 }
2693 /*
2694 * This routine is called when an efd format structure is found in
2695 * a committed transaction in the log. It's purpose is to cancel
2696 * the corresponding efi if it was still in the log. To do this
2697 * it searches the AIL for the efi with an id equal to that in the
2698 * efd format structure. If we find it, we remove the efi from the
2699 * AIL and free it.
2700 */
2701 STATIC void
2706 {
2712 __uint64_t efi_id;
2717 }
2726 /*
2727 * Search for the efi with the id in the efd format structure
2728 * in the AIL.
2729 */
2737 /*
2738 * xfs_trans_delete_ail() drops the
2739 * AIL lock.
2740 */
2743 }
2744 }
2746 }
2748 /*
2749 * If we found it, then free it up. If it wasn't there, it
2750 * must have been overwritten in the log. Oh well.
2751 */
2756 }
2757 }
2759 /*
2760 * Perform the transaction
2761 *
2762 * If the transaction modifies a buffer or inode, do it now. Otherwise,
2763 * EFIs and EFDs get queued up by adding entries into the AIL for them.
2764 */
2765 STATIC int
2770 {
2778 /*
2779 * we don't need to worry about the block number being
2780 * truncated in > 1 TB buffers because in user-land,
2781 * we're now n32 or 64-bit so xfs_daddr_t is 64-bits so
2782 * the blknos will get through the user-mode buffer
2783 * cache properly. The only bad case is o32 kernels
2784 * where xfs_daddr_t is 32-bits but mount will warn us
2785 * off a > 1 TB filesystem before we get here.
2786 */
2789 pass)))
2793 pass)))
2797 pass)))
2803 pass)))
2807 pass)))
2814 }
2819 }
2821 /*
2822 * Free up any resources allocated by the transaction
2823 *
2824 * Remember that EFIs, EFDs, and IUNLINKs are handled later.
2825 */
2826 STATIC void
2829 {
2837 /* Free the regions in the item. */
2841 }
2842 /* Free the item itself */
2847 /* Free the transaction recover structure */
2849 }
2851 STATIC int
2857 {
2866 }
2868 STATIC int
2871 {
2872 /* Do nothing now */
2875 }
2877 /*
2878 * There are two valid states of the r_state field. 0 indicates that the
2879 * transaction structure is in a normal state. We have either seen the
2880 * start of the transaction or the last operation we added was not a partial
2881 * operation. If the last operation we added to the transaction was a
2882 * partial operation, we need to mark r_state with XLOG_WAS_CONT_TRANS.
2883 *
2884 * NOTE: skip LRs with 0 data length.
2885 */
2886 STATIC int
2891 xfs_caddr_t dp,
2893 {
2894 xfs_caddr_t lp;
2898 xlog_tid_t tid;
2901 uint flags;
2906 /* check the log format matches our own - else we can't recover */
2920 }
2944 ARCH_CONVERT));
2956 ARCH_CONVERT));
2964 }
2967 }
2969 num_logops--;
2970 }
2972 }
2974 /*
2975 * Process an extent free intent item that was recovered from
2976 * the log. We need to free the extents that it describes.
2977 */
2978 STATIC void
2982 {
2987 xfs_fsblock_t startblock_fsb;
2991 /*
2992 * First check the validity of the extents described by the
2993 * EFI. If any are bad, then assume that all are bad and
2994 * just toss the EFI.
2995 */
3004 /*
3005 * This will pull the EFI from the AIL and
3006 * free the memory associated with it.
3007 */
3010 }
3011 }
3022 }
3026 }
3028 /*
3029 * Verify that once we've encountered something other than an EFI
3030 * in the AIL that there are no more EFIs in the AIL.
3031 */
3032 #if defined(DEBUG)
3033 STATIC void
3038 {
3044 /*
3045 * The check will be bogus if we restart from the
3046 * beginning of the AIL, so ASSERT that we don't.
3047 * We never should since we're holding the AIL lock
3048 * the entire time.
3049 */
3052 }
3055 /*
3056 * When this is called, all of the EFIs which did not have
3057 * corresponding EFDs should be in the AIL. What we do now
3058 * is free the extents associated with each one.
3059 *
3060 * Since we process the EFIs in normal transactions, they
3061 * will be removed at some point after the commit. This prevents
3062 * us from just walking down the list processing each one.
3063 * We'll use a flag in the EFI to skip those that we've already
3064 * processed and use the AIL iteration mechanism's generation
3065 * count to try to speed this up at least a bit.
3066 *
3067 * When we start, we know that the EFIs are the only things in
3068 * the AIL. As we process them, however, other items are added
3069 * to the AIL. Since everything added to the AIL must come after
3070 * everything already in the AIL, we stop processing as soon as
3071 * we see something other than an EFI in the AIL.
3072 */
3073 STATIC void
3076 {
3088 /*
3089 * We're done when we see something other than an EFI.
3090 */
3094 }
3096 /*
3097 * Skip EFIs that we've already processed.
3098 */
3103 }
3109 }
3111 }
3113 /*
3114 * This routine performs a transaction to null out a bad inode pointer
3115 * in an agi unlinked inode hash bucket.
3116 */
3117 STATIC void
3120 xfs_agnumber_t agno,
3122 {
3138 }
3144 }
3153 }
3155 /*
3156 * xlog_iunlink_recover
3157 *
3158 * This is called during recovery to process any inodes which
3159 * we unlinked but not freed when the system crashed. These
3160 * inodes will be on the lists in the AGI blocks. What we do
3161 * here is scan all the AGIs and fully truncate and free any
3162 * inodes found on the lists. Each inode is removed from the
3163 * lists when it has been fully truncated and is freed. The
3164 * freeing of the inode and its removal from the list must be
3165 * atomic.
3166 */
3167 void
3170 {
3172 xfs_agnumber_t agno;
3178 xfs_agino_t agino;
3179 xfs_ino_t ino;
3182 uint mp_dmevmask;
3186 /*
3187 * Prevent any DMAPI event from being sent while in this function.
3188 */
3193 /*
3194 * Find the agi for this ag.
3195 */
3203 }
3212 /*
3213 * Release the agi buffer so that it can
3214 * be acquired in the normal course of the
3215 * transaction to truncate and free the inode.
3216 */
3224 /*
3225 * Get the on disk inode to find the
3226 * next inode in the bucket.
3227 */
3231 }
3236 /* setup for the next pass */
3238 ARCH_CONVERT);
3240 /*
3241 * Prevent any DMAPI event from
3242 * being sent when the
3243 * reference on the inode is
3244 * dropped.
3245 */
3248 /*
3249 * If this is a new inode, handle
3250 * it specially. Otherwise,
3251 * just drop our reference to the
3252 * inode. If there are no
3253 * other references, this will
3254 * send the inode to
3255 * xfs_inactive() which will
3256 * truncate the file and free
3257 * the inode.
3258 */
3261 else
3264 /*
3265 * We can't read in the inode
3266 * this bucket points to, or
3267 * this inode is messed up. Just
3268 * ditch this bucket of inodes. We
3269 * will lose some inodes and space,
3270 * but at least we won't hang. Call
3271 * xlog_recover_clear_agi_bucket()
3272 * to perform a transaction to clear
3273 * the inode pointer in the bucket.
3274 */
3276 bucket);
3279 }
3281 /*
3282 * Reacquire the agibuffer and continue around
3283 * the loop.
3284 */
3295 }
3299 }
3300 }
3302 /*
3303 * Release the buffer for the current agi so we can
3304 * go on to the next one.
3305 */
3307 }
3310 }
3313 #ifdef DEBUG
3314 STATIC void
3319 {
3325 /* divide length by 4 to get # words */
3328 up++;
3329 }
3331 }
3332 #else
3333 #define xlog_pack_data_checksum(log, iclog, size)
3334 #endif
3336 /*
3337 * Stamp cycle number in every block
3338 */
3339 void
3344 {
3347 uint cycle_lsn;
3348 xfs_caddr_t dp;
3361 }
3371 }
3375 }
3376 }
3377 }
3379 #if defined(DEBUG) && defined(XFS_LOUD_RECOVERY)
3380 STATIC void
3383 xfs_caddr_t dp,
3385 {
3390 /* divide length by 4 to get # words */
3393 up++;
3394 }
3406 }
3408 }
3409 }
3410 }
3411 #else
3412 #define xlog_unpack_data_checksum(rhead, dp, log)
3413 #endif
3415 STATIC void
3418 xfs_caddr_t dp,
3420 {
3428 }
3437 }
3438 }
3441 }
3443 STATIC int
3447 xfs_daddr_t blkno)
3448 {
3453 XLOG_HEADER_MAGIC_NUM))) {
3457 }
3465 }
3467 /* LR body must have data or it wouldn't have been written */
3473 }
3478 }
3480 }
3482 /*
3483 * Read the log from tail to head and process the log records found.
3484 * Handle the two cases where the tail and head are in the same cycle
3485 * and where the active portion of the log wraps around the end of
3486 * the physical log separately. The pass parameter is passed through
3487 * to the routines called to process the data and is not looked at
3488 * here.
3489 */
3490 STATIC int
3493 xfs_daddr_t head_blk,
3494 xfs_daddr_t tail_blk,
3496 {
3498 xfs_daddr_t blk_no;
3508 /*
3509 * Read the header of the tail block and get the iclog buffer size from
3510 * h_size. Use this to tell how many sectors make up the log header.
3511 */
3513 /*
3514 * When using variable length iclogs, read first sector of
3515 * iclog header and extract the header size from it. Get a
3516 * new hbp that is the correct size.
3517 */
3534 hblks++;
3539 }
3545 }
3553 }
3566 /* blocks in data section */
3577 }
3579 /*
3580 * Perform recovery around the end of the physical log.
3581 * When the head is not on the same cycle number as the tail,
3582 * we can't do a sequential recovery as above.
3583 */
3586 /*
3587 * Check for header wrapping around physical end-of-log
3588 */
3593 /* Read header in one read */
3599 /* This LR is split across physical log end */
3601 /* some data before physical log end */
3610 }
3611 /*
3612 * Note: this black magic still works with
3613 * large sector sizes (non-512) only because:
3614 * - we increased the buffer size originally
3615 * by 1 sector giving us enough extra space
3616 * for the second read;
3617 * - the log start is guaranteed to be sector
3618 * aligned;
3619 * - we read the log end (LR header start)
3620 * _first_, then the log start (LR header end)
3621 * - order is important.
3622 */
3635 }
3645 /* Read in data for log record */
3652 /* This log record is split across the
3653 * physical end of log */
3657 /* some data is before the physical
3658 * end of log */
3661 split_bblks =
3669 }
3670 /*
3671 * Note: this black magic still works with
3672 * large sector sizes (non-512) only because:
3673 * - we increased the buffer size originally
3674 * by 1 sector giving us enough extra space
3675 * for the second read;
3676 * - the log start is guaranteed to be sector
3677 * aligned;
3678 * - we read the log end (LR header start)
3679 * _first_, then the log start (LR header end)
3680 * - order is important.
3681 */
3693 }
3699 }
3704 /* read first part of physical log */
3722 }
3723 }
3725 bread_err2:
3727 bread_err1:
3730 }
3732 /*
3733 * Do the recovery of the log. We actually do this in two phases.
3734 * The two passes are necessary in order to implement the function
3735 * of cancelling a record written into the log. The first pass
3736 * determines those things which have been cancelled, and the
3737 * second pass replays log items normally except for those which
3738 * have been cancelled. The handling of the replay and cancellations
3739 * takes place in the log item type specific routines.
3740 *
3741 * The table of items which have cancel records in the log is allocated
3742 * and freed at this level, since only here do we know when all of
3743 * the log recovery has been completed.
3744 */
3745 STATIC int
3748 xfs_daddr_t head_blk,
3749 xfs_daddr_t tail_blk)
3750 {
3755 /*
3756 * First do a pass to find all of the cancelled buf log items.
3757 * Store them in the buf_cancel_table for use in the second pass.
3758 */
3762 KM_SLEEP);
3764 XLOG_RECOVER_PASS1);
3770 }
3771 /*
3772 * Then do a second pass to actually recover the items in the log.
3773 * When it is complete free the table of buf cancel items.
3774 */
3776 XLOG_RECOVER_PASS2);
3777 #ifdef DEBUG
3783 }
3791 }
3793 /*
3794 * Do the actual recovery
3795 */
3796 STATIC int
3799 xfs_daddr_t head_blk,
3800 xfs_daddr_t tail_blk)
3801 {
3806 /*
3807 * First replay the images in the log.
3808 */
3812 }
3816 /*
3817 * If IO errors happened during recovery, bail out.
3818 */
3821 }
3823 /*
3824 * We now update the tail_lsn since much of the recovery has completed
3825 * and there may be space available to use. If there were no extent
3826 * or iunlinks, we can free up the entire log and set the tail_lsn to
3827 * be the last_sync_lsn. This was set in xlog_find_tail to be the
3828 * lsn of the last known good LR on disk. If there are extent frees
3829 * or iunlinks they will have some entries in the AIL; so we look at
3830 * the AIL to determine how to set the tail_lsn.
3831 */
3834 /*
3835 * Now that we've finished replaying all buffer and inode
3836 * updates, re-read in the superblock.
3837 */
3848 }
3850 /* Convert superblock from on-disk format */
3857 /* We've re-read the superblock so re-initialize per-cpu counters */
3862 /* Normal transactions can now occur */
3865 }
3867 /*
3868 * Perform recovery and re-initialize some log variables in xlog_find_tail.
3869 *
3870 * Return error or zero.
3871 */
3872 int
3875 {
3879 /* find the tail of the log */
3884 /* There used to be a comment here:
3885 *
3886 * disallow recovery on read-only mounts. note -- mount
3887 * checks for ENOSPC and turns it into an intelligent
3888 * error message.
3889 * ...but this is no longer true. Now, unless you specify
3890 * NORECOVERY (in which case this function would never be
3891 * called), we just go ahead and recover. We do this all
3892 * under the vfs layer, so we can get away with it unless
3893 * the device itself is read-only, in which case we fail.
3894 */
3897 }
3906 }
3908 }
3910 /*
3911 * In the first part of recovery we replay inodes and buffers and build
3912 * up the list of extent free items which need to be processed. Here
3913 * we process the extent free items and clean up the on disk unlinked
3914 * inode lists. This is separated from the first part of recovery so
3915 * that the root and real-time bitmap inodes can be read in from disk in
3916 * between the two stages. This is necessary so that we can free space
3917 * in the real-time portion of the file system.
3918 */
3919 int
3923 {
3924 /*
3925 * Now we're ready to do the transactions needed for the
3926 * rest of recovery. Start with completing all the extent
3927 * free intent records and then process the unlinked inode
3928 * lists. At this point, we essentially run in normal mode
3929 * except that we're still performing recovery actions
3930 * rather than accepting new requests.
3931 */
3934 /*
3935 * Sync the log to get all the EFIs out of the AIL.
3936 * This isn't absolutely necessary, but it helps in
3937 * case the unlink transactions would have problems
3938 * pushing the EFIs out of the way.
3939 */
3945 }
3958 }
3960 }
3963 #if defined(DEBUG)
3964 /*
3965 * Read all of the agf and agi counters and check that they
3966 * are consistent with the superblock counters.
3967 */
3968 void
3971 {
3977 xfs_daddr_t agfdaddr;
3978 xfs_daddr_t agidaddr;
3980 #ifdef XFS_LOUD_RECOVERY
3982 #endif
3983 xfs_agnumber_t agno;
3984 __uint64_t freeblks;
3985 __uint64_t itotal;
3986 __uint64_t ifree;
4000 }
4016 }
4025 }
4028 #ifdef XFS_LOUD_RECOVERY
4040 #if 0
4041 /*
4042 * This is turned off until I account for the allocation
4043 * btree blocks which live in free space.
4044 */
4048 #endif
4049 #endif
4051 }