| blob | 52883ac3cf84c06761afcf0792bbafcf781d509b |
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 */
41 #include <linux/dcache.h>
42 #include <linux/falloc.h>
43 #include <linux/pagevec.h>
44 #include <linux/backing-dev.h>
48 /*
49 * Locking primitives for read and write IO paths to ensure we consistently use
50 * and order the inode->i_mutex, ip->i_lock and ip->i_iolock.
51 */
56 {
60 }
66 {
70 }
76 {
80 }
82 /*
83 * xfs_iozero clears the specified range supplied via the page cache (except in
84 * the DAX case). Writes through the page cache will allocate blocks over holes,
85 * though the callers usually map the holes first and avoid them. If a block is
86 * not completely zeroed, then it will be read from disk before being partially
87 * zeroed.
88 *
89 * In the DAX case, we can just directly write to the underlying pages. This
90 * will not allocate blocks, but will avoid holes and unwritten extents and so
91 * not do unnecessary work.
92 */
93 int
98 {
116 xfs_get_blocks_direct);
121 AOP_FLAG_UNINTERRUPTIBLE,
132 }
138 }
140 int
144 {
153 }
163 }
174 }
176 /*
177 * Fsync operations on directories are much simpler than on regular files,
178 * as there is no file data to flush, and thus also no need for explicit
179 * cache flush operations, and there are no non-transaction metadata updates
180 * on directories either.
181 */
182 STATIC int
185 loff_t start,
186 loff_t end,
188 {
203 }
205 STATIC int
208 loff_t start,
209 loff_t end,
211 {
231 /*
232 * If we have an RT and/or log subvolume we need to make sure
233 * to flush the write cache the device used for file data
234 * first. This is to ensure newly written file data make
235 * it to disk before logging the new inode size in case of
236 * an extending write.
237 */
242 }
244 /*
245 * All metadata updates are logged, which means that we just have to
246 * flush the log up to the latest LSN that touched the inode. If we have
247 * concurrent fsync/fdatasync() calls, we need them to all block on the
248 * log force before we clear the ili_fsync_fields field. This ensures
249 * that we don't get a racing sync operation that does not wait for the
250 * metadata to hit the journal before returning. If we race with
251 * clearing the ili_fsync_fields, then all that will happen is the log
252 * force will do nothing as the lsn will already be on disk. We can't
253 * race with setting ili_fsync_fields because that is done under
254 * XFS_ILOCK_EXCL, and that can't happen because we hold the lock shared
255 * until after the ili_fsync_fields is cleared.
256 */
262 }
267 }
270 /*
271 * If we only have a single device, and the log force about was
272 * a no-op we might have to flush the data device cache here.
273 * This can only happen for fdatasync/O_DSYNC if we were overwriting
274 * an already allocated file and thus do not have any metadata to
275 * commit.
276 */
284 }
286 STATIC ssize_t
290 {
298 xfs_fsize_t n;
312 /* DIO must be aligned to device logical sector size */
317 }
318 }
330 /*
331 * Locking is a bit tricky here. If we take an exclusive lock for direct
332 * IO, we effectively serialise all new concurrent read IO to this file
333 * and block it behind IO that is currently in progress because IO in
334 * progress holds the IO lock shared. We only need to hold the lock
335 * exclusive to blow away the page cache, so only take lock exclusively
336 * if the page cache needs invalidation. This allows the normal direct
337 * IO case of no page cache pages to proceeed concurrently without
338 * serialisation.
339 */
345 /*
346 * The generic dio code only flushes the range of the particular
347 * I/O. Because we take an exclusive lock here, this whole
348 * sequence is considerably more expensive for us. This has a
349 * noticeable performance impact for any file with cached pages,
350 * even when outside of the range of the particular I/O.
351 *
352 * Hence, amortize the cost of the lock against a full file
353 * flush and reduce the chances of repeated iolock cycles going
354 * forward.
355 */
361 }
363 /*
364 * Invalidate whole pages. This can return an error if
365 * we fail to invalidate a page, but this should never
366 * happen on XFS. Warn if it does fail.
367 */
371 }
373 }
383 }
385 STATIC ssize_t
392 {
395 ssize_t ret;
407 /*
408 * DAX inodes cannot ues the page cache for splice, so we have to push
409 * them through the VFS IO path. This means it goes through
410 * ->read_iter, which for us takes the XFS_IOLOCK_SHARED. Hence we
411 * cannot lock the splice operation at this level for DAX inodes.
412 */
415 flags);
417 }
422 out:
426 }
428 /*
429 * This routine is called to handle zeroing any space in the last block of the
430 * file that is beyond the EOF. We do this since the size is being increased
431 * without writing anything to that block and we don't want to read the
432 * garbage on the disk.
433 */
437 xfs_fsize_t offset,
438 xfs_fsize_t isize,
440 {
457 /*
458 * If the block underlying isize is just a hole, then there
459 * is nothing to zero.
460 */
469 }
471 /*
472 * Zero any on disk space between the current EOF and the new, larger EOF.
473 *
474 * This handles the normal case of zeroing the remainder of the last block in
475 * the file and the unusual case of zeroing blocks out beyond the size of the
476 * file. This second case only happens with fixed size extents and when the
477 * system crashes before the inode size was updated but after blocks were
478 * allocated.
479 *
480 * Expects the iolock to be held exclusive, and will take the ilock internally.
481 */
488 {
490 xfs_fileoff_t start_zero_fsb;
491 xfs_fileoff_t end_zero_fsb;
492 xfs_fileoff_t zero_count_fsb;
493 xfs_fileoff_t last_fsb;
494 xfs_fileoff_t zero_off;
495 xfs_fsize_t zero_len;
505 /*
506 * First handle zeroing the block on which isize resides.
507 *
508 * We only zero a part of that block so it is handled specially.
509 */
514 }
516 /*
517 * Calculate the range between the new size and the old where blocks
518 * needing to be zeroed may exist.
519 *
520 * To get the block where the last byte in the file currently resides,
521 * we need to subtract one from the size and truncate back to a block
522 * boundary. We subtract 1 in case the size is exactly on a block
523 * boundary.
524 */
530 /*
531 * The size was only incremented on its last block.
532 * We took care of that above, so just return.
533 */
535 }
556 }
558 /*
559 * There are blocks we need to zero.
560 */
574 }
577 }
579 /*
580 * Common pre-write limit and setup checks.
581 *
582 * Called with the iolocked held either shared and exclusive according to
583 * @iolock, and returns with it held. Might upgrade the iolock to exclusive
584 * if called for a direct write beyond i_size.
585 */
586 STATIC ssize_t
591 {
599 restart:
608 /* For changing security info in file_remove_privs() we need i_mutex */
614 }
615 /*
616 * If the offset is beyond the size of the file, we need to zero any
617 * blocks that fall between the existing EOF and the start of this
618 * write. If zeroing is needed and we are currently holding the
619 * iolock shared, we need to update it to exclusive which implies
620 * having to redo all checks before.
621 *
622 * We need to serialise against EOF updates that occur in IO
623 * completions here. We want to make sure that nobody is changing the
624 * size while we do this check until we have placed an IO barrier (i.e.
625 * hold the XFS_IOLOCK_EXCL) that prevents new IO from being dispatched.
626 * The spinlock effectively forms a memory barrier once we have the
627 * XFS_IOLOCK_EXCL so we are guaranteed to see the latest EOF value
628 * and hence be able to correctly determine if we need to run zeroing.
629 */
641 }
642 /*
643 * We now have an IO submission barrier in place, but
644 * AIO can do EOF updates during IO completion and hence
645 * we now need to wait for all of them to drain. Non-AIO
646 * DIO will have drained before we are given the
647 * XFS_IOLOCK_EXCL, and so for most cases this wait is a
648 * no-op.
649 */
653 }
660 /*
661 * Updating the timestamps will grab the ilock again from
662 * xfs_fs_dirty_inode, so we have to call it after dropping the
663 * lock above. Eventually we should look into a way to avoid
664 * the pointless lock roundtrip.
665 */
670 }
672 /*
673 * If we're writing the file then make sure to clear the setuid and
674 * setgid bits if the process is not being run by root. This keeps
675 * people from modifying setuid and setgid binaries.
676 */
680 }
682 /*
683 * xfs_file_dio_aio_write - handle direct IO writes
684 *
685 * Lock the inode appropriately to prepare for and issue a direct IO write.
686 * By separating it from the buffered write path we remove all the tricky to
687 * follow locking changes and looping.
688 *
689 * If there are cached pages or we're extending the file, we need IOLOCK_EXCL
690 * until we're sure the bytes at the new EOF have been zeroed and/or the cached
691 * pages are flushed out.
692 *
693 * In most cases the direct IO writes will be done holding IOLOCK_SHARED
694 * allowing them to be done in parallel with reads and other direct IO writes.
695 * However, if the IO is not aligned to filesystem blocks, the direct IO layer
696 * needs to do sub-block zeroing and that requires serialisation against other
697 * direct IOs to the same block. In this case we need to serialise the
698 * submission of the unaligned IOs so that we don't get racing block zeroing in
699 * the dio layer. To avoid the problem with aio, we also need to wait for
700 * outstanding IOs to complete so that unwritten extent conversion is completed
701 * before we try to map the overlapping block. This is currently implemented by
702 * hitting it with a big hammer (i.e. inode_dio_wait()).
703 *
704 * Returns with locks held indicated by @iolock and errors indicated by
705 * negative return values.
706 */
707 STATIC ssize_t
711 {
722 loff_t end;
727 /* DIO must be aligned to device logical sector size */
731 /* "unaligned" here means not aligned to a filesystem block */
735 /*
736 * We don't need to take an exclusive lock unless there page cache needs
737 * to be invalidated or unaligned IO is being executed. We don't need to
738 * consider the EOF extension case here because
739 * xfs_file_aio_write_checks() will relock the inode as necessary for
740 * EOF zeroing cases and fill out the new inode size as appropriate.
741 */
744 else
748 /*
749 * Recheck if there are cached pages that need invalidate after we got
750 * the iolock to protect against other threads adding new pages while
751 * we were waiting for the iolock.
752 */
757 }
766 /*
767 * See xfs_file_read_iter() for why we do a full-file flush here.
768 */
773 /*
774 * Invalidate whole pages. This can return an error if we fail
775 * to invalidate a page, but this should never happen on XFS.
776 * Warn if it does fail.
777 */
781 }
783 /*
784 * If we are doing unaligned IO, wait for all other IO to drain,
785 * otherwise demote the lock if we had to flush cached pages
786 */
792 }
799 /* see generic_file_direct_write() for why this is necessary */
804 }
810 }
811 out:
814 /*
815 * No fallback to buffered IO on errors for XFS. DAX can result in
816 * partial writes, but direct IO will either complete fully or fail.
817 */
820 }
822 STATIC ssize_t
826 {
831 ssize_t ret;
841 /* We can write back this queue in page reclaim */
844 write_retry:
851 /*
852 * If we hit a space limit, try to free up some lingering preallocated
853 * space before returning an error. In the case of ENOSPC, first try to
854 * write back all dirty inodes to free up some of the excess reserved
855 * metadata space. This reduces the chances that the eofblocks scan
856 * waits on dirty mappings. Since xfs_flush_inodes() is serialized, this
857 * also behaves as a filter to prevent too many eofblocks scans from
858 * running at the same time.
859 */
873 }
876 out:
879 }
881 STATIC ssize_t
885 {
890 ssize_t ret;
903 else
907 ssize_t err;
911 /* Handle various SYNC-type writes */
915 }
917 }
919 #define XFS_FALLOC_FL_SUPPORTED \
920 (FALLOC_FL_KEEP_SIZE | FALLOC_FL_PUNCH_HOLE | \
921 FALLOC_FL_COLLAPSE_RANGE | FALLOC_FL_ZERO_RANGE | \
922 FALLOC_FL_INSERT_RANGE)
924 STATIC long
928 loff_t offset,
929 loff_t len)
930 {
962 }
964 /*
965 * There is no need to overlap collapse range with EOF,
966 * in which case it is effectively a truncate operation
967 */
971 }
985 }
987 /* check the new inode size does not wrap through zero */
991 }
993 /* Offset should be less than i_size */
997 }
1008 }
1012 else
1014 XFS_BMAPI_PREALLOC);
1017 }
1026 /* Change file size if needed */
1035 }
1037 /*
1038 * Perform hole insertion now that the file size has been
1039 * updated so that if we crash during the operation we don't
1040 * leave shifted extents past EOF and hence losing access to
1041 * the data that is contained within them.
1042 */
1046 out_unlock:
1049 }
1052 STATIC int
1056 {
1062 }
1064 STATIC int
1068 {
1077 /*
1078 * If there are any blocks, read-ahead block 0 as we're almost
1079 * certain to have the next operation be a read there.
1080 */
1086 }
1088 STATIC int
1092 {
1094 }
1096 STATIC int
1100 {
1105 /*
1106 * The Linux API doesn't pass down the total size of the buffer
1107 * we read into down to the filesystem. With the filldir concept
1108 * it's not needed for correct information, but the XFS dir2 leaf
1109 * code wants an estimate of the buffer size to calculate it's
1110 * readahead window and size the buffers used for mapping to
1111 * physical blocks.
1112 *
1113 * Try to give it an estimate that's good enough, maybe at some
1114 * point we can change the ->readdir prototype to include the
1115 * buffer size. For now we use the current glibc buffer size.
1116 */
1120 }
1122 /*
1123 * This type is designed to indicate the type of offset we would like
1124 * to search from page cache for xfs_seek_hole_data().
1125 */
1128 DATA_OFF,
1129 };
1131 /*
1132 * Lookup the desired type of offset from the given page.
1133 *
1134 * On success, return true and the offset argument will point to the
1135 * start of the region that was found. Otherwise this function will
1136 * return false and keep the offset argument unchanged.
1137 */
1138 STATIC bool
1143 {
1150 /*
1151 * Unwritten extents that have data in the page
1152 * cache covering them can be identified by the
1153 * BH_Unwritten state flag. Pages with multiple
1154 * buffers might have a mix of holes, data and
1155 * unwritten extents - any buffer with valid
1156 * data in it should have BH_Uptodate flag set
1157 * on it.
1158 */
1166 }
1171 }
1176 }
1178 /*
1179 * This routine is called to find out and return a data or hole offset
1180 * from the page cache for unwritten extents according to the desired
1181 * type for xfs_seek_hole_data().
1182 *
1183 * The argument offset is used to tell where we start to search from the
1184 * page cache. Map is used to figure out the end points of the range to
1185 * lookup pages.
1186 *
1187 * Return true if the desired type of offset was found, and the argument
1188 * offset is filled with that address. Otherwise, return false and keep
1189 * offset unchanged.
1190 */
1191 STATIC bool
1197 {
1201 pgoff_t index;
1202 pgoff_t end;
1203 loff_t endoff;
1220 want);
1221 /*
1222 * No page mapped into given range. If we are searching holes
1223 * and if this is the first time we got into the loop, it means
1224 * that the given offset is landed in a hole, return it.
1225 *
1226 * If we have already stepped through some block buffers to find
1227 * holes but they all contains data. In this case, the last
1228 * offset is already updated and pointed to the end of the last
1229 * mapped page, if it does not reach the endpoint to search,
1230 * that means there should be a hole between them.
1231 */
1233 /* Data search found nothing */
1241 }
1243 }
1245 /*
1246 * At lease we found one page. If this is the first time we
1247 * step into the loop, and if the first page index offset is
1248 * greater than the given search offset, a hole was found.
1249 */
1254 }
1258 loff_t b_offset;
1260 /*
1261 * At this point, the page may be truncated or
1262 * invalidated (changing page->mapping to NULL),
1263 * or even swizzled back from swapper_space to tmpfs
1264 * file mapping. However, page->index will not change
1265 * because we have a reference on the page.
1266 *
1267 * Searching done if the page index is out of range.
1268 * If the current offset is not reaches the end of
1269 * the specified search range, there should be a hole
1270 * between them.
1271 */
1276 }
1278 }
1281 /*
1282 * Page truncated or invalidated(page->mapping == NULL).
1283 * We can freely skip it and proceed to check the next
1284 * page.
1285 */
1289 }
1294 }
1298 /*
1299 * The found offset may be less than the start
1300 * point to search if this is the first time to
1301 * come here.
1302 */
1306 }
1308 /*
1309 * We either searching data but nothing was found, or
1310 * searching hole but found a data buffer. In either
1311 * case, probably the next page contains the desired
1312 * things, update the last offset to it so.
1313 */
1316 }
1318 /*
1319 * The number of returned pages less than our desired, search
1320 * done. In this case, nothing was found for searching data,
1321 * but we found a hole behind the last offset.
1322 */
1327 }
1329 }
1335 out:
1338 }
1340 STATIC loff_t
1343 loff_t start,
1345 {
1350 xfs_fsize_t isize;
1351 xfs_fileoff_t fsbno;
1352 xfs_filblks_t end;
1353 uint lock;
1365 }
1367 /*
1368 * Try to read extents from the first block indicated
1369 * by fsbno to the end block of the file.
1370 */
1380 XFS_BMAPI_ENTIRE);
1384 /* No extents at given offset, must be beyond EOF */
1388 }
1394 /* Landed in the hole we wanted? */
1399 /* Landed in the data extent we wanted? */
1406 /*
1407 * Landed in an unwritten extent, try to search
1408 * for hole or data from page cache.
1409 */
1415 }
1416 }
1418 /*
1419 * We only received one extent out of the two requested. This
1420 * means we've hit EOF and didn't find what we are looking for.
1421 */
1423 /*
1424 * If we were looking for a hole, set offset to
1425 * the end of the file (i.e., there is an implicit
1426 * hole at the end of any file).
1427 */
1431 }
1432 /*
1433 * If we were looking for data, it's nowhere to be found
1434 */
1438 }
1442 /*
1443 * Nothing was found, proceed to the next round of search
1444 * if the next reading offset is not at or beyond EOF.
1445 */
1452 }
1456 }
1457 }
1459 out:
1460 /*
1461 * If at this point we have found the hole we wanted, the returned
1462 * offset may be bigger than the file size as it may be aligned to
1463 * page boundary for unwritten extents. We need to deal with this
1464 * situation in particular.
1465 */
1470 out_unlock:
1476 }
1478 STATIC loff_t
1481 loff_t offset,
1483 {
1494 }
1495 }
1497 /*
1498 * Locking for serialisation of IO during page faults. This results in a lock
1499 * ordering of:
1500 *
1501 * mmap_sem (MM)
1502 * sb_start_pagefault(vfs, freeze)
1503 * i_mmaplock (XFS - truncate serialisation)
1504 * page_lock (MM)
1505 * i_lock (XFS - extent map serialisation)
1506 */
1508 /*
1509 * mmap()d file has taken write protection fault and is being made writable. We
1510 * can set the page state up correctly for a writable page, which means we can
1511 * do correct delalloc accounting (ENOSPC checking!) and unwritten extent
1512 * mapping.
1513 */
1514 STATIC int
1518 {
1533 }
1539 }
1541 STATIC int
1545 {
1551 /* DAX can shortcut the normal fault path on write faults! */
1557 /*
1558 * we do not want to trigger unwritten extent conversion on read
1559 * faults - that is unnecessary overhead and would also require
1560 * changes to xfs_get_blocks_direct() to map unwritten extent
1561 * ioend for conversion on read-only mappings.
1562 */
1569 }
1571 /*
1572 * Similar to xfs_filemap_fault(), the DAX fault path can call into here on
1573 * both read and write faults. Hence we need to handle both cases. There is no
1574 * ->pmd_mkwrite callout for huge pages, so we have a single function here to
1575 * handle both cases here. @flags carries the information on the type of fault
1576 * occuring.
1577 */
1578 STATIC int
1584 {
1597 }
1601 NULL);
1608 }
1610 /*
1611 * pfn_mkwrite was originally inteneded to ensure we capture time stamp
1612 * updates on write faults. In reality, it's need to serialise against
1613 * truncate similar to page_mkwrite. Hence we cycle the XFS_MMAPLOCK_SHARED
1614 * to ensure we serialise the fault barrier in place.
1615 */
1616 static int
1620 {
1625 loff_t size;
1632 /* check if the faulting page hasn't raced with truncate */
1643 }
1651 };
1653 STATIC int
1657 {
1663 }
1672 #ifdef CONFIG_COMPAT
1674 #endif
1680 };
1688 #ifdef CONFIG_COMPAT
1690 #endif
1692 };