| blob | f2d1718c9165f104befa17069c7b48cfd93a4b3a |
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 */
62 #include <linux/namei.h>
63 #include <linux/init.h>
64 #include <linux/slab.h>
65 #include <linux/mount.h>
66 #include <linux/mempool.h>
67 #include <linux/writeback.h>
68 #include <linux/kthread.h>
69 #include <linux/freezer.h>
70 #include <linux/parser.h>
95 * unwritten extent conversion */
103 * in stat(). */
125 /*
126 * Table driven mount option parser.
127 *
128 * Currently only used for remount, but it will be used for mount
129 * in the future, too.
130 */
133 };
139 };
142 STATIC unsigned long
144 {
152 }
156 }
160 }
163 }
165 /*
166 * This function fills in xfs_mount_t fields based on mount args.
167 * Note: the superblock has _not_ yet been read in.
168 *
169 * Note that this function leaks the various device name allocations on
170 * failure. The caller takes care of them.
171 */
172 STATIC int
177 {
186 /*
187 * Copy binary VFS mount flags we are interested in.
188 */
196 /*
197 * Set some default flags that could be cleared by the mount option
198 * parsing.
199 */
204 /*
205 * These can be overridden by the mount option parsing.
206 */
223 this_char);
225 }
231 this_char);
233 }
239 this_char);
241 }
249 this_char);
251 }
259 this_char);
261 }
269 this_char);
271 }
278 this_char);
280 }
303 this_char);
305 }
311 this_char);
313 }
317 #if !XFS_BIG_INUMS
320 this_char);
322 #endif
354 XFS_UQUOTA_ENFD);
362 XFS_OQUOTA_ENFD);
369 XFS_OQUOTA_ENFD);
382 "Enabling EXPERIMENTAL delayed logging feature "
390 /* no-op, this is now the default */
400 }
401 }
403 /*
404 * no recovery flag requires a read-only mount
405 */
410 }
416 }
418 #ifndef CONFIG_XFS_QUOTA
423 }
424 #endif
431 }
435 MNTOPT_DMAPI);
437 }
443 }
450 }
452 /*
453 * Applications using DMI filesystems often expect the
454 * inode generation number to be monotonically increasing.
455 * If we delete inode chunks we break this assumption, so
456 * keep unused inode chunks on disk for DMI filesystems
457 * until we come up with a better solution.
458 * Note that if "ikeep" or "noikeep" mount options are
459 * supplied, then they are honored.
460 */
464 done:
466 /*
467 * At this point the superblock has not been read
468 * in, therefore we do not know the block size.
469 * Before the mount call ends we will convert
470 * these to FSBs.
471 */
475 }
479 }
489 }
499 }
512 XFS_MAX_IO_LOG);
514 }
519 }
522 }
527 };
529 STATIC int
533 {
535 /* the few simple ones we can get from the mount struct */
549 };
551 /* the few simple ones we can get from the mount struct */
556 };
562 }
566 }
594 /* Either project or group quotas can be active, not both */
599 else
604 else
606 }
612 }
613 __uint64_t
616 {
620 /* Figure out maximum filesize, on Linux this can depend on
621 * the filesystem blocksize (on 32 bit platforms).
622 * __block_prepare_write does this in an [unsigned] long...
623 * page->index << (PAGE_CACHE_SHIFT - bbits)
624 * So, for page sized blocks (4K on 32 bit platforms),
625 * this wraps at around 8Tb (hence MAX_LFS_FILESIZE which is
626 * (((u64)PAGE_CACHE_SIZE << (BITS_PER_LONG-1))-1)
627 * but for smaller blocksizes it is less (bbits = log2 bsize).
628 * Note1: get_block_t takes a long (implicit cast from above)
629 * Note2: The Large Block Device (LBD and HAVE_SECTOR_T) patch
630 * can optionally convert the [unsigned] long from above into
631 * an [unsigned] long long.
632 */
634 #if BITS_PER_LONG == 32
635 # if defined(CONFIG_LBDAF)
639 # else
641 # endif
642 #endif
645 }
647 STATIC int
652 {
659 }
662 }
664 STATIC void
667 {
670 }
672 /*
673 * Try to write out the superblock using barriers.
674 */
675 STATIC int
678 {
692 /*
693 * Clear all the flags we set and possible error state in the
694 * buffer. We only did the write to try out whether barriers
695 * worked and shouldn't leave any traces in the superblock
696 * buffer.
697 */
704 }
706 STATIC void
708 {
716 }
723 }
731 }
732 }
734 void
737 {
739 BLKDEV_IFL_WAIT);
740 }
742 STATIC void
745 {
750 }
755 }
757 }
759 /*
760 * The file system configurations are:
761 * (1) device (partition) with data and internal log
762 * (2) logical volume with data and log subvolumes.
763 * (3) logical volume with data, log, and realtime subvolumes.
764 *
765 * We only have to handle opening the log and realtime volumes here if
766 * they are present. The data subvolume has already been opened by
767 * get_sb_bdev() and is stored in sb->s_bdev.
768 */
769 STATIC int
772 {
777 /*
778 * Open real time and log devices - order is important.
779 */
784 }
796 }
797 }
799 /*
800 * Setup xfs_mount buffer target pointers
801 */
811 }
819 }
823 out_free_rtdev_targ:
826 out_free_ddev_targ:
828 out_close_rtdev:
831 out_close_logdev:
834 out:
836 }
838 /*
839 * Setup xfs_mount buffer target pointers based on superblock
840 */
841 STATIC int
844 {
859 log_sector_size);
862 }
869 }
872 }
874 /*
875 * XFS AIL push thread support
876 */
877 void
880 xfs_lsn_t threshold_lsn)
881 {
884 }
886 STATIC int
889 {
898 /* swsusp */
906 }
911 int
914 {
921 }
923 void
926 {
928 }
931 /* Catch misguided souls that try to use this interface on XFS */
935 {
938 }
940 /*
941 * Now that the generic code is guaranteed not to be accessing
942 * the linux inode, we can reclaim the inode.
943 */
944 STATIC void
947 {
954 /* bad inode, get out here ASAP */
962 /*
963 * We should never get here with one of the reclaim flags already set.
964 */
968 /*
969 * We always use background reclaim here because even if the
970 * inode is clean, it still may be under IO and hence we have
971 * to take the flush lock. The background reclaim path handles
972 * this more efficiently than we can here, so simply let background
973 * reclaim tear down all inodes.
974 */
975 out_reclaim:
977 }
979 /*
980 * Slab object creation initialisation for the XFS inode.
981 * This covers only the idempotent fields in the XFS inode;
982 * all other fields need to be initialised on allocation
983 * from the slab. This avoids the need to repeatedly intialise
984 * fields in the xfs inode that left in the initialise state
985 * when freeing the inode.
986 */
987 STATIC void
990 {
995 /* vfs inode */
998 /* xfs inode */
1003 /*
1004 * Because we want to use a counting completion, complete
1005 * the flush completion once to allow a single access to
1006 * the flush completion without blocking.
1007 */
1013 }
1015 /*
1016 * Dirty the XFS inode when mark_inode_dirty_sync() is called so that
1017 * we catch unlogged VFS level updates to the inode. Care must be taken
1018 * here - the transaction code calls mark_inode_dirty_sync() to mark the
1019 * VFS inode dirty in a transaction and clears the i_update_core field;
1020 * it must clear the field after calling mark_inode_dirty_sync() to
1021 * correctly indicate that the dirty state has been propagated into the
1022 * inode log item.
1023 *
1024 * We need the barrier() to maintain correct ordering between unlogged
1025 * updates and the transaction commit code that clears the i_update_core
1026 * field. This requires all updates to be completed before marking the
1027 * inode dirty.
1028 */
1029 STATIC void
1032 {
1035 }
1037 STATIC int
1040 {
1051 /* we need to return with the lock hold shared */
1054 }
1058 /*
1059 * Note - it's possible that we might have pushed ourselves out of the
1060 * way during trans_reserve which would flush the inode. But there's
1061 * no guarantee that the inode buffer has actually gone out yet (it's
1062 * delwri). Plus the buffer could be pinned anyway if it's part of
1063 * an inode in another recent transaction. So we play it safe and
1064 * fire off the transaction anyway.
1065 */
1074 }
1076 STATIC int
1080 {
1091 /*
1092 * Make sure the inode has hit stable storage. By using the
1093 * log and the fsync transactions we reduce the IOs we have
1094 * to do here from two (log and inode) to just the log.
1095 *
1096 * Note: We still need to do a delwri write of the inode after
1097 * this to flush it to the backing buffer so that bulkstat
1098 * works properly if this is the first time the inode has been
1099 * written. Because we hold the ilock atomically over the
1100 * transaction commit and the inode flush we are guaranteed
1101 * that the inode is not pinned when it returns. If the flush
1102 * lock is already held, then the inode has already been
1103 * flushed once and we don't need to flush it again. Hence
1104 * the code will only flush the inode if it isn't already
1105 * being flushed.
1106 */
1113 }
1115 /*
1116 * We make this non-blocking if the inode is contended, return
1117 * EAGAIN to indicate to the caller that they did not succeed.
1118 * This prevents the flush path from blocking on inodes inside
1119 * another operation right now, they get caught later by xfs_sync.
1120 */
1123 }
1128 /*
1129 * Now we have the flush lock and the inode is not pinned, we can check
1130 * if the inode is really clean as we know that there are no pending
1131 * transaction completions, it is not waiting on the delayed write
1132 * queue and there is no IO in progress.
1133 */
1138 }
1141 out_unlock:
1143 out:
1144 /*
1145 * if we failed to write out the inode then mark
1146 * it dirty again so we'll try again later.
1147 */
1151 }
1153 STATIC void
1156 {
1164 /*
1165 * The iolock is used by the file system to coordinate reads,
1166 * writes, and block truncates. Up to this point the lock
1167 * protected concurrent accesses by users of the inode. But
1168 * from here forward we're doing some final processing of the
1169 * inode because we're done with it, and although we reuse the
1170 * iolock for protection it is really a distinct lock class
1171 * (in the lockdep sense) from before. To keep lockdep happy
1172 * (and basically indicate what we are doing), we explicitly
1173 * re-init the iolock here.
1174 */
1179 }
1181 STATIC void
1184 {
1188 }
1190 STATIC void
1193 {
1199 /*
1200 * XXX(hch): this should be SYNC_WAIT.
1201 *
1202 * Or more likely not needed at all because the VFS is already
1203 * calling ->sync_fs after shutting down all filestem
1204 * operations and just before calling ->put_super.
1205 */
1208 }
1212 /*
1213 * Blow away any referenced inode in the filestreams cache.
1214 * This can and will cause log traffic as inodes go inactive
1215 * here.
1216 */
1231 }
1233 STATIC int
1237 {
1241 /*
1242 * Not much we can do for the first async pass. Writing out the
1243 * superblock would be counter-productive as we are going to redirty
1244 * when writing out other data and metadata (and writing out a single
1245 * block is quite fast anyway).
1246 *
1247 * Try to asynchronously kick off quota syncing at least.
1248 */
1252 }
1261 /*
1262 * The disk must be active because we're syncing.
1263 * We schedule xfssyncd now (now that the disk is
1264 * active) instead of later (when it might not be).
1265 */
1267 /*
1268 * We have to wait for the sync iteration to complete.
1269 * If we don't, the disk activity caused by the sync
1270 * will come after the sync is completed, and that
1271 * triggers another sync from laptop mode.
1272 */
1275 }
1278 }
1280 STATIC int
1284 {
1289 xfs_extlen_t lsize;
1321 }
1323 STATIC void
1325 {
1330 }
1332 STATIC void
1334 {
1335 __uint64_t resblks;
1344 }
1346 STATIC int
1351 {
1368 /*
1369 * Test if barriers are actually working if we can,
1370 * else delay this check until the filesystem is
1371 * marked writeable.
1372 */
1380 /*
1381 * Logically we would return an error here to prevent
1382 * users from believing they might have changed
1383 * mount options using remount which can't be changed.
1384 *
1385 * But unfortunately mount(8) adds all options from
1386 * mtab and fstab to the mount arguments in some cases
1387 * so we can't blindly reject options, but have to
1388 * check for each specified option if it actually
1389 * differs from the currently set option and only
1390 * reject it if that's the case.
1391 *
1392 * Until that is implemented we return success for
1393 * every remount request, and silently ignore all
1394 * options that we can't actually change.
1395 */
1396 #if 0
1400 #else
1402 #endif
1403 }
1404 }
1406 /* ro -> rw */
1412 /*
1413 * If this is the first remount to writeable state we
1414 * might have some superblock changes to update.
1415 */
1422 }
1424 }
1426 /*
1427 * Fill out the reserve pool if it is empty. Use the stashed
1428 * value if it is non-zero, otherwise go with the default.
1429 */
1431 }
1433 /* rw -> ro */
1435 /*
1436 * After we have synced the data but before we sync the
1437 * metadata, we need to free up the reserve block pool so that
1438 * the used block count in the superblock on disk is correct at
1439 * the end of the remount. Stash the current reserve pool size
1440 * so that if we get remounted rw, we can return it to the same
1441 * size.
1442 */
1448 }
1451 }
1453 /*
1454 * Second stage of a freeze. The data is already frozen so we only
1455 * need to take care of the metadata. Once that's done write a dummy
1456 * record to dirty the log in case of a crash while frozen.
1457 */
1458 STATIC int
1461 {
1467 }
1469 STATIC int
1472 {
1477 }
1479 STATIC int
1483 {
1485 }
1487 /*
1488 * This function fills in xfs_mount_t fields based on mount args.
1489 * Note: the superblock _has_ now been read in.
1490 */
1491 STATIC int
1494 {
1497 /* Fail a mount where the logbuf is smaller than the log stripe */
1507 }
1509 /* Fail a mount if the logbuf is larger than 32K */
1514 }
1515 }
1517 /*
1518 * mkfs'ed attr2 will turn on attr2 mount unless explicitly
1519 * told by noattr2 to turn it off
1520 */
1525 /*
1526 * prohibit r/w mounts of read-only filesystems
1527 */
1532 }
1535 }
1537 STATIC int
1542 {
1569 #ifdef CONFIG_XFS_QUOTA
1571 #endif
1624 }
1628 }
1633 }
1644 out_filestream_unmount:
1646 out_free_sb:
1648 out_destroy_counters:
1651 out_put_dmops:
1653 out_free_fsname:
1657 out:
1660 fail_vnrele:
1666 }
1668 fail_unmount:
1669 /*
1670 * Blow away any referenced inode in the filestreams cache.
1671 * This can and will cause log traffic as inodes go inactive
1672 * here.
1673 */
1680 }
1682 STATIC int
1689 {
1691 mnt);
1692 }
1707 };
1715 };
1717 STATIC int __init
1719 {
1726 xfs_ioend_zone);
1762 /*
1763 * The size of the zone allocated buf log item is the maximum
1764 * size possible under XFS. This wastes a little bit of memory,
1765 * but it is much faster.
1766 */
1785 xfs_inode_zone =
1788 xfs_fs_inode_init_once);
1792 xfs_ili_zone =
1800 out_destroy_inode_zone:
1802 out_destroy_efi_zone:
1804 out_destroy_efd_zone:
1806 out_destroy_buf_item_zone:
1808 out_destroy_trans_zone:
1810 out_destroy_ifork_zone:
1812 out_destroy_dabuf_zone:
1814 out_destroy_da_state_zone:
1816 out_destroy_btree_cur_zone:
1818 out_destroy_bmap_free_item_zone:
1820 out_destroy_log_ticket_zone:
1822 out_destroy_ioend_pool:
1824 out_destroy_ioend_zone:
1826 out:
1828 }
1830 STATIC void
1832 {
1848 }
1850 STATIC int __init
1852 {
1893 out_sysctl_unregister:
1895 out_cleanup_procfs:
1897 out_buf_terminate:
1899 out_filestream_uninit:
1901 out_mru_cache_uninit:
1903 out_destroy_zones:
1905 out:
1907 }
1909 STATIC void __exit
1911 {
1921 }