| blob | d447aef84bc3a552fe44fdd1559bbf05d3f5f17f |
1 /*
2 * Copyright (c) 2000-2005 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 */
50 #ifdef HAVE_PERCPU_SB
56 #else
58 #define xfs_icsb_balance_counter(mp, a, b) do { } while (0)
59 #define xfs_icsb_balance_counter_locked(mp, a, b) do { } while (0)
60 #endif
65 * 1 = binary / string (no translation)
66 */
115 };
121 /*
122 * See if the UUID is unique among mounted XFS filesystems.
123 * Mount fails if UUID is nil or a FS with the same UUID is already mounted.
124 */
125 STATIC int
128 {
140 }
147 }
150 }
156 KM_SLEEP);
158 }
164 out_duplicate:
169 }
171 STATIC void
174 {
189 }
192 }
195 /*
196 * Reference counting access wrappers to the perag structures.
197 * Because we never free per-ag structures, the only thing we
198 * have to protect against changes is the tree structure itself.
199 */
202 {
211 }
215 }
217 /*
218 * search from @first to find the next perag with the given tag set.
219 */
223 xfs_agnumber_t first,
225 {
236 }
241 }
243 void
245 {
251 }
253 STATIC void
256 {
261 }
263 /*
264 * Free up the per-ag resources associated with the mount structure.
265 */
266 STATIC void
269 {
270 xfs_agnumber_t agno;
280 }
281 }
283 /*
284 * Check size of device based on the (data/realtime) block count.
285 * Note: this check is used by the growfs code as well as mount.
286 */
287 int
290 __uint64_t nblocks)
291 {
301 #endif
303 }
305 /*
306 * Check the validity of the SB found.
307 */
308 STATIC int
313 {
314 /*
315 * If the log device and data device have the
316 * same device number, the log is internal.
317 * Consequently, the sb_logstart should be non-zero. If
318 * we have a zero sb_logstart in this case, we may be trying to mount
319 * a volume filesystem in a non-volume manner.
320 */
324 }
329 }
334 "filesystem is marked as having an external log; "
337 }
342 "filesystem is marked as having an internal log; "
345 }
347 /*
348 * More sanity checking. These were stolen directly from
349 * xfs_repair.
350 */
374 }
376 /*
377 * Sanity check AG count, size fields against data size field
378 */
387 }
389 /*
390 * Until this is fixed only page-sized or smaller data blocks work.
391 */
398 PAGE_SIZE);
400 }
402 /*
403 * Currently only very few inode sizes are supported.
404 */
416 }
423 }
428 }
430 /*
431 * Version 1 directory format has never worked on Linux.
432 */
437 }
440 }
442 int
445 xfs_agnumber_t agcount,
447 {
451 xfs_agino_t agino;
452 xfs_ino_t ino;
456 /*
457 * Walk the current per-ag tree so we don't try to initialise AGs
458 * that already exist (growfs case). Allocate and insert all the
459 * AGs we don't find ready for initialisation.
460 */
466 }
491 }
494 }
496 /*
497 * If we mount with the inode64 option, or no inode overflows
498 * the legacy 32-bit address space clear the inode32 option.
499 */
505 else
509 /*
510 * Calculate how much should be reserved for inodes to meet
511 * the max inode percentage.
512 */
514 __uint64_t icount;
523 }
528 index++;
530 }
537 }
543 }
544 }
550 out_unwind:
555 }
557 }
559 void
563 {
610 }
612 /*
613 * Copy in core superblock to ondisk one.
614 *
615 * The fields argument is mask of superblock fields to copy.
616 */
617 void
621 __int64_t fields)
622 {
625 xfs_sb_field_t f;
658 }
659 }
662 }
663 }
665 /*
666 * xfs_readsb
667 *
668 * Does the initial read of the superblock.
669 */
670 int
672 {
680 /*
681 * Allocate a (locked) buffer to hold the superblock.
682 * This will be kept around at all times to optimize
683 * access to the superblock.
684 */
687 reread:
693 }
695 /*
696 * Initialize the mount structure from the superblock.
697 * But first do some basic consistency checking.
698 */
704 }
706 /*
707 * We must be able to do sector-sized and sector-aligned IO.
708 */
715 }
717 /*
718 * If device sector size is smaller than the superblock size,
719 * re-read the superblock so the buffer is correctly sized.
720 */
725 }
727 /* Initialize per-cpu counters */
734 release_buf:
737 }
740 /*
741 * xfs_mount_common
742 *
743 * Mount initialization code establishing various mount
744 * fields from the superblock associated with the given
745 * mount structure
746 */
747 STATIC void
749 {
781 }
783 /*
784 * xfs_initialize_perag_data
785 *
786 * Read in each per-ag structure so we can count up the number of
787 * allocated inodes, free inodes and used filesystem blocks as this
788 * information is no longer persistent in the superblock. Once we have
789 * this information, write it into the in-core superblock structure.
790 */
791 STATIC int
793 {
794 xfs_agnumber_t index;
805 /*
806 * read the agf, then the agi. This gets us
807 * all the information we need and populates the
808 * per-ag structures for us.
809 */
824 }
825 /*
826 * Overwrite incore superblock counters with just-read data
827 */
834 /* Fixup the per-cpu counters as well. */
838 }
840 /*
841 * Update alignment values based on mount options and sb values
842 */
843 STATIC int
845 {
849 /*
850 * If stripe unit and stripe width are not multiples
851 * of the fs blocksize turn off alignment.
852 */
859 }
862 /*
863 * Convert the stripe unit and width to FSBs.
864 */
869 }
886 }
888 }
889 }
891 /*
892 * Update superblock with new values
893 * and log changes
894 */
899 }
903 }
904 }
909 }
912 }
914 /*
915 * Set the maximum inode count for this filesystem
916 */
917 STATIC void
919 {
921 __uint64_t icount;
924 /*
925 * Make sure the maximum inode count is a multiple
926 * of the units we allocate inodes in.
927 */
935 }
936 }
938 /*
939 * Set the default minimum read and write sizes unless
940 * already specified in a mount option.
941 * We use smaller I/O sizes when the file system
942 * is being used for NFS service (wsync mount option).
943 */
944 STATIC void
946 {
957 }
961 }
967 }
973 }
975 }
977 /*
978 * precalculate the low space thresholds for dynamic speculative preallocation.
979 */
980 void
983 {
991 }
992 }
995 /*
996 * Set whether we're using inode alignment.
997 */
998 STATIC void
1000 {
1005 else
1007 /*
1008 * If we are using stripe alignment, check whether
1009 * the stripe unit is a multiple of the inode alignment
1010 */
1014 else
1016 }
1018 /*
1019 * Check that the data (and log if separate) are an ok size.
1020 */
1021 STATIC int
1023 {
1025 xfs_daddr_t d;
1031 }
1038 }
1046 }
1053 }
1055 }
1057 }
1059 /*
1060 * Clear the quotaflags in memory and in the superblock.
1061 */
1062 int
1065 {
1071 /*
1072 * It is OK to look at sb_qflags here in mount path,
1073 * without m_sb_lock.
1074 */
1081 /*
1082 * If the fs is readonly, let the incore superblock run
1083 * with quotas off but don't flush the update out to disk
1084 */
1088 #ifdef QUOTADEBUG
1090 #endif
1094 XFS_DEFAULT_LOG_COUNT);
1100 }
1104 }
1106 __uint64_t
1108 {
1109 __uint64_t resblks;
1111 /*
1112 * We default to 5% or 8192 fsbs of space reserved, whichever is
1113 * smaller. This is intended to cover concurrent allocation
1114 * transactions when we initially hit enospc. These each require a 4
1115 * block reservation. Hence by default we cover roughly 2000 concurrent
1116 * allocation reservations.
1117 */
1122 }
1124 /*
1125 * This function does the following on an initial mount of a file system:
1126 * - reads the superblock from disk and init the mount struct
1127 * - if we're a 32-bit kernel, do a size check on the superblock
1128 * so we don't mount terabyte filesystems
1129 * - init mount struct realtime fields
1130 * - allocate inode hash table for fs
1131 * - init directory manager
1132 * - perform recovery and init the log manager
1133 */
1134 int
1137 {
1140 __uint64_t resblks;
1147 /*
1148 * Check for a mismatched features2 values. Older kernels
1149 * read & wrote into the wrong sb offset for sb_features2
1150 * on some platforms due to xfs_sb_t not being 64bit size aligned
1151 * when sb_features2 was added, which made older superblock
1152 * reading/writing routines swap it as a 64-bit value.
1153 *
1154 * For backwards compatibility, we make both slots equal.
1155 *
1156 * If we detect a mismatched field, we OR the set bits into the
1157 * existing features2 field in case it has already been modified; we
1158 * don't want to lose any features. We then update the bad location
1159 * with the ORed value so that older kernels will see any features2
1160 * flags, and mark the two fields as needing updates once the
1161 * transaction subsystem is online.
1162 */
1170 /*
1171 * Re-check for ATTR2 in case it was found in bad_features2
1172 * slot.
1173 */
1177 }
1184 /* update sb_versionnum for the clearing of the morebits */
1187 }
1189 /*
1190 * Check if sb_agblocks is aligned at stripe boundary
1191 * If sb_agblocks is NOT aligned turn off m_dalign since
1192 * allocator alignment is within an ag, therefore ag has
1193 * to be aligned at stripe boundary.
1194 */
1212 /*
1213 * Set the minimum read and write sizes
1214 */
1217 /* set the low space thresholds for dynamic preallocation */
1220 /*
1221 * Set the inode cluster size.
1222 * This may still be overridden by the file system
1223 * block size if it is larger than the chosen cluster size.
1224 */
1227 /*
1228 * Set inode alignment fields
1229 */
1232 /*
1233 * Check that the data (and log if separate) are an ok size.
1234 */
1239 /*
1240 * Initialize realtime fields in the mount structure
1241 */
1246 }
1248 /*
1249 * Copies the low order bits of the timestamp and the randomly
1250 * set "sequence" number out of a UUID.
1251 */
1258 /*
1259 * Initialize the attribute manager's entries.
1260 */
1263 /*
1264 * Initialize the precomputed transaction reservations values.
1265 */
1268 /*
1269 * Allocate and initialize the per-ag data.
1270 */
1277 }
1284 }
1286 /*
1287 * log's mount-time initialization. Perform 1st part recovery if needed
1288 */
1295 }
1297 /*
1298 * Now the log is mounted, we know if it was an unclean shutdown or
1299 * not. If it was, with the first phase of recovery has completed, we
1300 * have consistent AG blocks on disk. We have not recovered EFIs yet,
1301 * but they are recovered transactionally in the second recovery phase
1302 * later.
1303 *
1304 * Hence we can safely re-initialise incore superblock counters from
1305 * the per-ag data. These may not be correct if the filesystem was not
1306 * cleanly unmounted, so we need to wait for recovery to finish before
1307 * doing this.
1308 *
1309 * If the filesystem was cleanly unmounted, then we can trust the
1310 * values in the superblock to be correct and we don't need to do
1311 * anything here.
1312 *
1313 * If we are currently making the filesystem, the initialisation will
1314 * fail as the perag data is in an undefined state.
1315 */
1322 }
1324 /*
1325 * Get and sanity-check the root inode.
1326 * Save the pointer to it in the mount structure.
1327 */
1332 }
1343 mp);
1346 }
1351 /*
1352 * Initialize realtime inode pointers in the mount structure
1353 */
1356 /*
1357 * Free up the root inode.
1358 */
1361 }
1363 /*
1364 * If this is a read-only mount defer the superblock updates until
1365 * the next remount into writeable mode. Otherwise we would never
1366 * perform the update e.g. for the root filesystem.
1367 */
1373 }
1374 }
1376 /*
1377 * Initialise the XFS quota management subsystem for this mount
1378 */
1386 /*
1387 * If a file system had quotas running earlier, but decided to
1388 * mount without -o uquota/pquota/gquota options, revoke the
1389 * quotachecked license.
1390 */
1399 }
1400 }
1402 /*
1403 * Finish recovering the file system. This part needed to be
1404 * delayed until after the root and real-time bitmap inodes
1405 * were consistently read in.
1406 */
1411 }
1413 /*
1414 * Complete the quota initialisation, post-log-replay component.
1415 */
1421 }
1423 /*
1424 * Now we are mounted, reserve a small amount of unused space for
1425 * privileged transactions. This is needed so that transaction
1426 * space required for critical operations can dip into this pool
1427 * when at ENOSPC. This is needed for operations like create with
1428 * attr, unwritten extent conversion at ENOSPC, etc. Data allocations
1429 * are not allowed to use this reserved space.
1430 *
1431 * This may drive us straight to ENOSPC on mount, but that implies
1432 * we were already there on the last unmount. Warn if this occurs.
1433 */
1440 }
1444 out_rtunmount:
1446 out_rele_rip:
1448 out_log_dealloc:
1450 out_free_perag:
1452 out_remove_uuid:
1454 out:
1456 }
1458 /*
1459 * This flushes out the inodes,dquots and the superblock, unmounts the
1460 * log and makes sure that incore structures are freed.
1461 */
1462 void
1465 {
1466 __uint64_t resblks;
1473 /*
1474 * We can potentially deadlock here if we have an inode cluster
1475 * that has been freed has its buffer still pinned in memory because
1476 * the transaction is still sitting in a iclog. The stale inodes
1477 * on that buffer will have their flush locks held until the
1478 * transaction hits the disk and the callbacks run. the inode
1479 * flush takes the flush lock unconditionally and with nothing to
1480 * push out the iclog we will never get that unlocked. hence we
1481 * need to force the log first.
1482 */
1485 /*
1486 * Do a delwri reclaim pass first so that as many dirty inodes are
1487 * queued up for IO as possible. Then flush the buffers before making
1488 * a synchronous path to catch all the remaining inodes are reclaimed.
1489 * This makes the reclaim process as quick as possible by avoiding
1490 * synchronous writeout and blocking on inodes already in the delwri
1491 * state as much as possible.
1492 */
1499 /*
1500 * Flush out the log synchronously so that we know for sure
1501 * that nothing is pinned. This is important because bflush()
1502 * will skip pinned buffers.
1503 */
1509 }
1511 /*
1512 * Unreserve any blocks we have so that when we unmount we don't account
1513 * the reserved free space as used. This is really only necessary for
1514 * lazy superblock counting because it trusts the incore superblock
1515 * counters to be absolutely correct on clean unmount.
1516 *
1517 * We don't bother correcting this elsewhere for lazy superblock
1518 * counting because on mount of an unclean filesystem we reconstruct the
1519 * correct counter value and this is irrelevant.
1520 *
1521 * For non-lazy counter filesystems, this doesn't matter at all because
1522 * we only every apply deltas to the superblock and hence the incore
1523 * value does not matter....
1524 */
1541 #if defined(DEBUG)
1543 #endif
1545 }
1547 STATIC void
1549 {
1555 }
1557 int
1559 {
1562 }
1564 /*
1565 * xfs_log_sbcount
1566 *
1567 * Called either periodically to keep the on disk superblock values
1568 * roughly up to date or from unmount to make sure the values are
1569 * correct on a clean unmount.
1570 *
1571 * Note this code can be called during the process of freezing, so
1572 * we may need to use the transaction allocator which does not not
1573 * block when the transaction subsystem is in its frozen state.
1574 */
1575 int
1578 uint sync)
1579 {
1588 /*
1589 * we don't need to do this if we are updating the superblock
1590 * counters on every modification.
1591 */
1597 XFS_DEFAULT_LOG_COUNT);
1601 }
1608 }
1610 int
1612 {
1616 /*
1617 * skip superblock write if fs is read-only, or
1618 * if we are doing a forced umount.
1619 */
1637 }
1639 }
1641 /*
1642 * xfs_mod_sb() can be used to copy arbitrary changes to the
1643 * in-core superblock into the superblock buffer to be logged.
1644 * It does not provide the higher level of locking that is
1645 * needed to protect the in-core superblock from concurrent
1646 * access.
1647 */
1648 void
1650 {
1655 xfs_sb_field_t f;
1665 /* translate/copy */
1669 /* find modified range */
1679 }
1682 /*
1683 * xfs_mod_incore_sb_unlocked() is a utility routine common used to apply
1684 * a delta to a specified field in the in-core superblock. Simply
1685 * switch on the field indicated and apply the delta to that field.
1686 * Fields are not allowed to dip below zero, so if the delta would
1687 * do this do not apply it and return EINVAL.
1688 *
1689 * The m_sb_lock must be held when this routine is called.
1690 */
1691 STATIC int
1694 xfs_sb_field_t field,
1697 {
1702 /*
1703 * With the in-core superblock spin lock held, switch
1704 * on the indicated field. Apply the delta to the
1705 * proper field. If the fields value would dip below
1706 * 0, then do not apply the delta and return EINVAL.
1707 */
1715 }
1724 }
1739 }
1746 }
1748 /*
1749 * We are out of blocks, use any available reserved
1750 * blocks if were allowed to.
1751 */
1759 }
1765 }
1774 }
1783 }
1792 }
1801 }
1810 }
1819 }
1828 }
1837 }
1846 }
1852 }
1853 }
1855 /*
1856 * xfs_mod_incore_sb() is used to change a field in the in-core
1857 * superblock structure by the specified delta. This modification
1858 * is protected by the m_sb_lock. Just use the xfs_mod_incore_sb_unlocked()
1859 * routine to do the work.
1860 */
1861 int
1864 xfs_sb_field_t field,
1867 {
1870 #ifdef HAVE_PERCPU_SB
1872 #endif
1878 }
1880 /*
1881 * Change more than one field in the in-core superblock structure at a time.
1882 *
1883 * The fields and changes to those fields are specified in the array of
1884 * xfs_mod_sb structures passed in. Either all of the specified deltas
1885 * will be applied or none of them will. If any modified field dips below 0,
1886 * then all modifications will be backed out and EINVAL will be returned.
1887 *
1888 * Note that this function may not be used for the superblock values that
1889 * are tracked with the in-memory per-cpu counters - a direct call to
1890 * xfs_icsb_modify_counters is required for these.
1891 */
1892 int
1896 uint nmsb,
1898 {
1902 /*
1903 * Loop through the array of mod structures and apply each individually.
1904 * If any fail, then back out all those which have already been applied.
1905 * Do all of this within the scope of the m_sb_lock so that all of the
1906 * changes will be atomic.
1907 */
1917 }
1921 unwind:
1926 }
1929 }
1931 /*
1932 * xfs_getsb() is called to obtain the buffer for the superblock.
1933 * The buffer is returned locked and read in from disk.
1934 * The buffer should be released with a call to xfs_brelse().
1935 *
1936 * If the flags parameter is BUF_TRYLOCK, then we'll only return
1937 * the superblock buffer if it can be locked without sleeping.
1938 * If it can't then we'll return NULL.
1939 */
1940 xfs_buf_t *
1944 {
1952 }
1955 }
1959 }
1961 /*
1962 * Used to free the superblock along various error paths.
1963 */
1964 void
1967 {
1973 }
1975 /*
1976 * Used to log changes to the superblock unit and width fields which could
1977 * be altered by the mount options, as well as any potential sb_features2
1978 * fixup. Only the first superblock is updated.
1979 */
1980 int
1983 __int64_t fields)
1984 {
1990 XFS_SB_VERSIONNUM));
1994 XFS_DEFAULT_LOG_COUNT);
1998 }
2002 }
2004 /*
2005 * If the underlying (data/log/rt) device is readonly, there are some
2006 * operations that cannot proceed.
2007 */
2008 int
2012 {
2021 }
2023 }
2025 #ifdef HAVE_PERCPU_SB
2026 /*
2027 * Per-cpu incore superblock counters
2028 *
2029 * Simple concept, difficult implementation
2030 *
2031 * Basically, replace the incore superblock counters with a distributed per cpu
2032 * counter for contended fields (e.g. free block count).
2033 *
2034 * Difficulties arise in that the incore sb is used for ENOSPC checking, and
2035 * hence needs to be accurately read when we are running low on space. Hence
2036 * there is a method to enable and disable the per-cpu counters based on how
2037 * much "stuff" is available in them.
2038 *
2039 * Basically, a counter is enabled if there is enough free resource to justify
2040 * running a per-cpu fast-path. If the per-cpu counter runs out (i.e. a local
2041 * ENOSPC), then we disable the counters to synchronise all callers and
2042 * re-distribute the available resources.
2043 *
2044 * If, once we redistributed the available resources, we still get a failure,
2045 * we disable the per-cpu counter and go through the slow path.
2046 *
2047 * The slow path is the current xfs_mod_incore_sb() function. This means that
2048 * when we disable a per-cpu counter, we need to drain its resources back to
2049 * the global superblock. We do this after disabling the counter to prevent
2050 * more threads from queueing up on the counter.
2051 *
2052 * Essentially, this means that we still need a lock in the fast path to enable
2053 * synchronisation between the global counters and the per-cpu counters. This
2054 * is not a problem because the lock will be local to a CPU almost all the time
2055 * and have little contention except when we get to ENOSPC conditions.
2056 *
2057 * Basically, this lock becomes a barrier that enables us to lock out the fast
2058 * path while we do things like enabling and disabling counters and
2059 * synchronising the counters.
2060 *
2061 * Locking rules:
2062 *
2063 * 1. m_sb_lock before picking up per-cpu locks
2064 * 2. per-cpu locks always picked up via for_each_online_cpu() order
2065 * 3. accurate counter sync requires m_sb_lock + per cpu locks
2066 * 4. modifying per-cpu counters requires holding per-cpu lock
2067 * 5. modifying global counters requires holding m_sb_lock
2068 * 6. enabling or disabling a counter requires holding the m_sb_lock
2069 * and _none_ of the per-cpu locks.
2070 *
2071 * Disabled counters are only ever re-enabled by a balance operation
2072 * that results in more free resources per CPU than a given threshold.
2073 * To ensure counters don't remain disabled, they are rebalanced when
2074 * the global resource goes above a higher threshold (i.e. some hysteresis
2075 * is present to prevent thrashing).
2076 */
2078 #ifdef CONFIG_HOTPLUG_CPU
2079 /*
2080 * hot-plug CPU notifier support.
2081 *
2082 * We need a notifier per filesystem as we need to be able to identify
2083 * the filesystem to balance the counters out. This is achieved by
2084 * having a notifier block embedded in the xfs_mount_t and doing pointer
2085 * magic to get the mount pointer from the notifier block address.
2086 */
2087 STATIC int
2092 {
2102 /* Easy Case - initialize the area and locks, and
2103 * then rebalance when online does everything else for us. */
2116 /* Disable all the counters, then fold the dead cpu's
2117 * count into the total on the global superblock and
2118 * re-enable the counters. */
2137 }
2140 }
2143 int
2146 {
2154 #ifdef CONFIG_HOTPLUG_CPU
2163 }
2167 /*
2168 * start with all counters disabled so that the
2169 * initial balance kicks us off correctly
2170 */
2173 }
2175 void
2178 {
2180 /*
2181 * start with all counters disabled so that the
2182 * initial balance kicks us off correctly
2183 */
2189 }
2191 void
2194 {
2198 }
2200 }
2202 STATIC void
2205 {
2208 }
2209 }
2211 STATIC void
2214 {
2216 }
2219 STATIC void
2222 {
2229 }
2230 }
2232 STATIC void
2235 {
2242 }
2243 }
2245 STATIC void
2250 {
2264 }
2268 }
2270 STATIC int
2273 xfs_sb_field_t field)
2274 {
2277 }
2279 STATIC void
2282 xfs_sb_field_t field)
2283 {
2284 xfs_icsb_cnts_t cnt;
2288 /*
2289 * If we are already disabled, then there is nothing to do
2290 * here. We check before locking all the counters to avoid
2291 * the expensive lock operation when being called in the
2292 * slow path and the counter is already disabled. This is
2293 * safe because the only time we set or clear this state is under
2294 * the m_icsb_mutex.
2295 */
2301 /* drain back to superblock */
2316 }
2317 }
2320 }
2322 STATIC void
2325 xfs_sb_field_t field,
2328 {
2350 }
2352 }
2355 }
2357 void
2361 {
2362 xfs_icsb_cnts_t cnt;
2372 }
2374 /*
2375 * Accurate update of per-cpu counters to incore superblock
2376 */
2377 void
2381 {
2385 }
2387 /*
2388 * Balance and enable/disable counters as necessary.
2389 *
2390 * Thresholds for re-enabling counters are somewhat magic. inode counts are
2391 * chosen to be the same number as single on disk allocation chunk per CPU, and
2392 * free blocks is something far enough zero that we aren't going thrash when we
2393 * get near ENOSPC. We also need to supply a minimum we require per cpu to
2394 * prevent looping endlessly when xfs_alloc_space asks for more than will
2395 * be distributed to a single CPU but each CPU has enough blocks to be
2396 * reenabled.
2397 *
2398 * Note that we can be called when counters are already disabled.
2399 * xfs_icsb_disable_counter() optimises the counter locking in this case to
2400 * prevent locking every per-cpu counter needlessly.
2401 */
2403 #define XFS_ICSB_INO_CNTR_REENABLE (uint64_t)64
2404 #define XFS_ICSB_FDBLK_CNTR_REENABLE(mp) \
2405 (uint64_t)(512 + XFS_ALLOC_SET_ASIDE(mp))
2406 STATIC void
2409 xfs_sb_field_t field,
2411 {
2416 /* disable counter and sync counter */
2419 /* update counters - first CPU gets residual*/
2443 }
2446 }
2448 STATIC void
2451 xfs_sb_field_t fields,
2453 {
2457 }
2459 int
2462 xfs_sb_field_t field,
2465 {
2471 again:
2475 /*
2476 * if the counter is disabled, go to slow path
2477 */
2484 }
2515 }
2520 slow_path:
2523 /*
2524 * serialise with a mutex so we don't burn lots of cpu on
2525 * the superblock lock. We still need to hold the superblock
2526 * lock, however, when we modify the global structures.
2527 */
2530 /*
2531 * Now running atomically.
2532 *
2533 * If the counter is enabled, someone has beaten us to rebalancing.
2534 * Drop the lock and try again in the fast path....
2535 */
2539 }
2541 /*
2542 * The counter is currently disabled. Because we are
2543 * running atomically here, we know a rebalance cannot
2544 * be in progress. Hence we can go straight to operating
2545 * on the global superblock. We do not call xfs_mod_incore_sb()
2546 * here even though we need to get the m_sb_lock. Doing so
2547 * will cause us to re-enter this function and deadlock.
2548 * Hence we get the m_sb_lock ourselves and then call
2549 * xfs_mod_incore_sb_unlocked() as the unlocked path operates
2550 * directly on the global counters.
2551 */
2556 /*
2557 * Now that we've modified the global superblock, we
2558 * may be able to re-enable the distributed counters
2559 * (e.g. lots of space just got freed). After that
2560 * we are done.
2561 */
2567 balance_counter:
2571 /*
2572 * We may have multiple threads here if multiple per-cpu
2573 * counters run dry at the same time. This will mean we can
2574 * do more balances than strictly necessary but it is not
2575 * the common slowpath case.
2576 */
2579 /*
2580 * running atomically.
2581 *
2582 * This will leave the counter in the correct state for future
2583 * accesses. After the rebalance, we simply try again and our retry
2584 * will either succeed through the fast path or slow path without
2585 * another balance operation being required.
2586 */
2590 }
2592 #endif