| blob | 2219a76e2caf08415b2e207bc23466d4154d35e0 |
1 /*
2 * linux/fs/buffer.c
3 *
4 * Copyright (C) 1991, 1992, 2002 Linus Torvalds
5 */
7 /*
8 * Start bdflush() with kernel_thread not syscall - Paul Gortmaker, 12/95
9 *
10 * Removed a lot of unnecessary code and simplified things now that
11 * the buffer cache isn't our primary cache - Andrew Tridgell 12/96
12 *
13 * Speed up hash, lru, and free list operations. Use gfp() for allocating
14 * hash table, use SLAB cache for buffer heads. SMP threading. -DaveM
15 *
16 * Added 32k buffer block sizes - these are required older ARM systems. - RMK
17 *
18 * async buffer flushing, 1999 Andrea Arcangeli <andrea@suse.de>
19 */
21 #include <linux/kernel.h>
22 #include <linux/syscalls.h>
23 #include <linux/fs.h>
24 #include <linux/mm.h>
25 #include <linux/percpu.h>
26 #include <linux/slab.h>
27 #include <linux/capability.h>
28 #include <linux/blkdev.h>
29 #include <linux/file.h>
30 #include <linux/quotaops.h>
31 #include <linux/highmem.h>
32 #include <linux/module.h>
33 #include <linux/writeback.h>
34 #include <linux/hash.h>
35 #include <linux/suspend.h>
36 #include <linux/buffer_head.h>
37 #include <linux/task_io_accounting_ops.h>
38 #include <linux/bio.h>
39 #include <linux/notifier.h>
40 #include <linux/cpu.h>
41 #include <linux/bitops.h>
42 #include <linux/mpage.h>
43 #include <linux/bit_spinlock.h>
47 #define BH_ENTRY(list) list_entry((list), struct buffer_head, b_assoc_buffers)
51 {
54 }
58 {
69 }
72 {
74 TASK_UNINTERRUPTIBLE);
75 }
79 {
83 }
86 /*
87 * Block until a buffer comes unlocked. This doesn't stop it
88 * from becoming locked again - you have to lock it yourself
89 * if you want to preserve its state.
90 */
92 {
94 }
97 static void
99 {
103 }
107 {
111 }
115 {
120 }
122 /*
123 * End-of-IO handler helper function which does not touch the bh after
124 * unlocking it.
125 * Note: unlock_buffer() sort-of does touch the bh after unlocking it, but
126 * a race there is benign: unlock_buffer() only use the bh's address for
127 * hashing after unlocking the buffer, so it doesn't actually touch the bh
128 * itself.
129 */
131 {
135 /* This happens, due to failed READA attempts. */
137 }
139 }
141 /*
142 * Default synchronous end-of-IO handler.. Just mark it up-to-date and
143 * unlock the buffer. This is what ll_rw_block uses too.
144 */
146 {
149 }
153 {
164 }
167 }
170 }
173 /*
174 * Various filesystems appear to want __find_get_block to be non-blocking.
175 * But it's the page lock which protects the buffers. To get around this,
176 * we get exclusion from try_to_free_buffers with the blockdev mapping's
177 * private_lock.
178 *
179 * Hack idea: for the blockdev mapping, i_bufferlist_lock contention
180 * may be quite high. This code could TryLock the page, and if that
181 * succeeds, there is no need to take private_lock. (But if
182 * private_lock is contended then so is mapping->tree_lock).
183 */
186 {
190 pgoff_t index;
213 }
217 /* we might be here because some of the buffers on this page are
218 * not mapped. This is due to various races between
219 * file io on the block device and getblk. It gets dealt with
220 * elsewhere, don't buffer_error if we had some unmapped buffers
221 */
230 }
231 out_unlock:
234 out:
236 }
238 /* If invalidate_buffers() will trash dirty buffers, it means some kind
239 of fs corruption is going on. Trashing dirty data always imply losing
240 information that was supposed to be just stored on the physical layer
241 by the user.
243 Thus invalidate_buffers in general usage is not allwowed to trash
244 dirty buffers. For example ioctl(FLSBLKBUF) expects dirty data to
245 be preserved. These buffers are simply skipped.
247 We also skip buffers which are still in use. For example this can
248 happen if a userspace program is reading the block device.
250 NOTE: In the case where the user removed a removable-media-disk even if
251 there's still dirty data not synced on disk (due a bug in the device driver
252 or due an error of the user), by not destroying the dirty buffers we could
253 generate corruption also on the next media inserted, thus a parameter is
254 necessary to handle this case in the most safe way possible (trying
255 to not corrupt also the new disk inserted with the data belonging to
256 the old now corrupted disk). Also for the ramdisk the natural thing
257 to do in order to release the ramdisk memory is to destroy dirty buffers.
259 These are two special cases. Normal usage imply the device driver
260 to issue a sync on the device (without waiting I/O completion) and
261 then an invalidate_buffers call that doesn't trash dirty buffers.
263 For handling cache coherency with the blkdev pagecache the 'update' case
264 is been introduced. It is needed to re-read from disk any pinned
265 buffer. NOTE: re-reading from disk is destructive so we can do it only
266 when we assume nobody is changing the buffercache under our I/O and when
267 we think the disk contains more recent information than the buffercache.
268 The update == 1 pass marks the buffers we need to update, the update == 2
269 pass does the actual I/O. */
271 {
280 }
283 /*
284 * Kick the writeback threads then try to free up some ZONE_NORMAL memory.
285 */
287 {
301 }
302 }
304 /*
305 * I/O completion handler for block_read_full_page() - pages
306 * which come unlocked at the end of I/O.
307 */
309 {
326 }
328 /*
329 * Be _very_ careful from here on. Bad things can happen if
330 * two buffer heads end IO at almost the same time and both
331 * decide that the page is now completely done.
332 */
345 }
351 /*
352 * If none of the buffers had errors and they are all
353 * uptodate then we can set the page uptodate.
354 */
360 still_busy:
364 }
366 /*
367 * Completion handler for block_write_full_page() - pages which are unlocked
368 * during I/O, and which have PageWriteback cleared upon I/O completion.
369 */
371 {
389 }
394 }
407 }
409 }
415 still_busy:
419 }
422 /*
423 * If a page's buffers are under async readin (end_buffer_async_read
424 * completion) then there is a possibility that another thread of
425 * control could lock one of the buffers after it has completed
426 * but while some of the other buffers have not completed. This
427 * locked buffer would confuse end_buffer_async_read() into not unlocking
428 * the page. So the absence of BH_Async_Read tells end_buffer_async_read()
429 * that this buffer is not under async I/O.
430 *
431 * The page comes unlocked when it has no locked buffer_async buffers
432 * left.
433 *
434 * PageLocked prevents anyone starting new async I/O reads any of
435 * the buffers.
436 *
437 * PageWriteback is used to prevent simultaneous writeout of the same
438 * page.
439 *
440 * PageLocked prevents anyone from starting writeback of a page which is
441 * under read I/O (PageWriteback is only ever set against a locked page).
442 */
444 {
447 }
451 {
454 }
457 {
459 }
463 /*
464 * fs/buffer.c contains helper functions for buffer-backed address space's
465 * fsync functions. A common requirement for buffer-based filesystems is
466 * that certain data from the backing blockdev needs to be written out for
467 * a successful fsync(). For example, ext2 indirect blocks need to be
468 * written back and waited upon before fsync() returns.
469 *
470 * The functions mark_buffer_inode_dirty(), fsync_inode_buffers(),
471 * inode_has_buffers() and invalidate_inode_buffers() are provided for the
472 * management of a list of dependent buffers at ->i_mapping->private_list.
473 *
474 * Locking is a little subtle: try_to_free_buffers() will remove buffers
475 * from their controlling inode's queue when they are being freed. But
476 * try_to_free_buffers() will be operating against the *blockdev* mapping
477 * at the time, not against the S_ISREG file which depends on those buffers.
478 * So the locking for private_list is via the private_lock in the address_space
479 * which backs the buffers. Which is different from the address_space
480 * against which the buffers are listed. So for a particular address_space,
481 * mapping->private_lock does *not* protect mapping->private_list! In fact,
482 * mapping->private_list will always be protected by the backing blockdev's
483 * ->private_lock.
484 *
485 * Which introduces a requirement: all buffers on an address_space's
486 * ->private_list must be from the same address_space: the blockdev's.
487 *
488 * address_spaces which do not place buffers at ->private_list via these
489 * utility functions are free to use private_lock and private_list for
490 * whatever they want. The only requirement is that list_empty(private_list)
491 * be true at clear_inode() time.
492 *
493 * FIXME: clear_inode should not call invalidate_inode_buffers(). The
494 * filesystems should do that. invalidate_inode_buffers() should just go
495 * BUG_ON(!list_empty).
496 *
497 * FIXME: mark_buffer_dirty_inode() is a data-plane operation. It should
498 * take an address_space, not an inode. And it should be called
499 * mark_buffer_dirty_fsync() to clearly define why those buffers are being
500 * queued up.
501 *
502 * FIXME: mark_buffer_dirty_inode() doesn't need to add the buffer to the
503 * list if it is already on a list. Because if the buffer is on a list,
504 * it *must* already be on the right one. If not, the filesystem is being
505 * silly. This will save a ton of locking. But first we have to ensure
506 * that buffers are taken *off* the old inode's list when they are freed
507 * (presumably in truncate). That requires careful auditing of all
508 * filesystems (do it inside bforget()). It could also be done by bringing
509 * b_inode back.
510 */
512 /*
513 * The buffer's backing address_space's private_lock must be held
514 */
516 {
522 }
525 {
527 }
529 /*
530 * osync is designed to support O_SYNC io. It waits synchronously for
531 * all already-submitted IO to complete, but does not queue any new
532 * writes to the disk.
533 *
534 * To do O_SYNC writes, just queue the buffer writes with ll_rw_block as
535 * you dirty the buffers, and then use osync_inode_buffers to wait for
536 * completion. Any other dirty buffers which are not yet queued for
537 * write will not be flushed to disk by the osync.
538 */
540 {
546 repeat:
558 }
559 }
562 }
565 {
570 }
573 {
577 }
579 /**
580 * emergency_thaw_all -- forcibly thaw every frozen filesystem
581 *
582 * Used for emergency unfreeze of all filesystems via SysRq
583 */
585 {
592 }
593 }
595 /**
596 * sync_mapping_buffers - write out & wait upon a mapping's "associated" buffers
597 * @mapping: the mapping which wants those buffers written
598 *
599 * Starts I/O against the buffers at mapping->private_list, and waits upon
600 * that I/O.
601 *
602 * Basically, this is a convenience function for fsync().
603 * @mapping is a file or directory which needs those buffers to be written for
604 * a successful fsync().
605 */
607 {
615 }
618 /*
619 * Called when we've recently written block `bblock', and it is known that
620 * `bblock' was for a buffer_boundary() buffer. This means that the block at
621 * `bblock + 1' is probably a dirty indirect block. Hunt it down and, if it's
622 * dirty, schedule it for IO. So that indirects merge nicely with their data.
623 */
626 {
632 }
633 }
636 {
645 }
652 }
653 }
656 /*
657 * Mark the page dirty, and set it dirty in the radix tree, and mark the inode
658 * dirty.
659 *
660 * If warn is true, then emit a warning if the page is not uptodate and has
661 * not been truncated.
662 */
665 {
672 }
675 }
677 /*
678 * Add a page to the dirty page list.
679 *
680 * It is a sad fact of life that this function is called from several places
681 * deeply under spinlocking. It may not sleep.
682 *
683 * If the page has buffers, the uptodate buffers are set dirty, to preserve
684 * dirty-state coherency between the page and the buffers. It the page does
685 * not have buffers then when they are later attached they will all be set
686 * dirty.
687 *
688 * The buffers are dirtied before the page is dirtied. There's a small race
689 * window in which a writepage caller may see the page cleanness but not the
690 * buffer dirtiness. That's fine. If this code were to set the page dirty
691 * before the buffers, a concurrent writepage caller could clear the page dirty
692 * bit, see a bunch of clean buffers and we'd end up with dirty buffers/clean
693 * page on the dirty page list.
694 *
695 * We use private_lock to lock against try_to_free_buffers while using the
696 * page's buffer list. Also use this to protect against clean buffers being
697 * added to the page after it was set dirty.
698 *
699 * FIXME: may need to call ->reservepage here as well. That's rather up to the
700 * address_space though.
701 */
703 {
719 }
726 }
729 /*
730 * Write out and wait upon a list of buffers.
731 *
732 * We have conflicting pressures: we want to make sure that all
733 * initially dirty buffers get waited on, but that any subsequently
734 * dirtied buffers don't. After all, we don't want fsync to last
735 * forever if somebody is actively writing to the file.
736 *
737 * Do this in two main stages: first we copy dirty buffers to a
738 * temporary inode list, queueing the writes as we go. Then we clean
739 * up, waiting for those writes to complete.
740 *
741 * During this second stage, any subsequent updates to the file may end
742 * up refiling the buffer on the original inode's dirty list again, so
743 * there is a chance we will end up with a buffer queued for write but
744 * not yet completed on that list. So, as a final cleanup we go through
745 * the osync code to catch these locked, dirty buffers without requeuing
746 * any newly dirty buffers for write.
747 */
749 {
762 /* Avoid race with mark_buffer_dirty_inode() which does
763 * a lockless check and we rely on seeing the dirty bit */
771 /*
772 * Ensure any pending I/O completes so that
773 * write_dirty_buffer() actually writes the
774 * current contents - it is a noop if I/O is
775 * still in flight on potentially older
776 * contents.
777 */
780 /*
781 * Kick off IO for the previous mapping. Note
782 * that we will not run the very last mapping,
783 * wait_on_buffer() will do that for us
784 * through sync_buffer().
785 */
792 }
793 }
794 }
801 /* Avoid race with mark_buffer_dirty_inode() which does
802 * a lockless check and we rely on seeing the dirty bit */
808 }
815 }
821 else
823 }
825 /*
826 * Invalidate any and all dirty buffers on a given inode. We are
827 * probably unmounting the fs, but that doesn't mean we have already
828 * done a sync(). Just drop the buffers from the inode list.
829 *
830 * NOTE: we take the inode's blockdev's mapping's private_lock. Which
831 * assumes that all the buffers are against the blockdev. Not true
832 * for reiserfs.
833 */
835 {
845 }
846 }
849 /*
850 * Remove any clean buffers from the inode's buffer list. This is called
851 * when we're trying to free the inode itself. Those buffers can pin it.
852 *
853 * Returns true if all buffers were removed.
854 */
856 {
870 }
872 }
874 }
876 }
878 /*
879 * Create the appropriate buffers when given a page for data area and
880 * the size of each buffer.. Use the bh->b_this_page linked list to
881 * follow the buffers created. Return NULL if unable to create more
882 * buffers.
883 *
884 * The retry flag is used to differentiate async IO (paging, swapping)
885 * which may not fail from ordinary buffer allocations.
886 */
889 {
893 try_again:
910 /* Link the buffer to its page */
914 }
916 /*
917 * In case anything failed, we just free everything we got.
918 */
919 no_grow:
926 }
928 /*
929 * Return failure for non-async IO requests. Async IO requests
930 * are not allowed to fail, so we have to wait until buffer heads
931 * become available. But we don't want tasks sleeping with
932 * partially complete buffers, so all were released above.
933 */
937 /* We're _really_ low on memory. Now we just
938 * wait for old buffer heads to become free due to
939 * finishing IO. Since this is an async request and
940 * the reserve list is empty, we're sure there are
941 * async buffer heads in use.
942 */
945 }
950 {
960 }
962 /*
963 * Initialise the state of a blockdev page's buffers.
964 */
965 static void
968 {
981 }
982 block++;
985 }
987 /*
988 * Create the page-cache page that contains the requested block.
989 *
990 * This is user purely for blockdev mappings.
991 */
995 {
1012 }
1015 }
1017 /*
1018 * Allocate some buffers for this page
1019 */
1024 /*
1025 * Link the page to the buffers and initialise them. Take the
1026 * lock to be atomic wrt __find_get_block(), which does not
1027 * run under the page lock.
1028 */
1035 failed:
1040 }
1042 /*
1043 * Create buffers for the specified block device block's page. If
1044 * that page was dirty, the buffers are set dirty also.
1045 */
1046 static int
1048 {
1050 pgoff_t index;
1055 sizebits++;
1060 /*
1061 * Check for a block which wants to lie outside our maximum possible
1062 * pagecache index. (this comparison is done using sector_t types).
1063 */
1072 }
1074 /* Create a page with the proper size buffers.. */
1081 }
1085 {
1086 /* Size must be multiple of hard sectorsize */
1090 size);
1096 }
1111 }
1112 }
1114 /*
1115 * The relationship between dirty buffers and dirty pages:
1116 *
1117 * Whenever a page has any dirty buffers, the page's dirty bit is set, and
1118 * the page is tagged dirty in its radix tree.
1119 *
1120 * At all times, the dirtiness of the buffers represents the dirtiness of
1121 * subsections of the page. If the page has buffers, the page dirty bit is
1122 * merely a hint about the true dirty state.
1123 *
1124 * When a page is set dirty in its entirety, all its buffers are marked dirty
1125 * (if the page has buffers).
1126 *
1127 * When a buffer is marked dirty, its page is dirtied, but the page's other
1128 * buffers are not.
1129 *
1130 * Also. When blockdev buffers are explicitly read with bread(), they
1131 * individually become uptodate. But their backing page remains not
1132 * uptodate - even if all of its buffers are uptodate. A subsequent
1133 * block_read_full_page() against that page will discover all the uptodate
1134 * buffers, will set the page uptodate and will perform no I/O.
1135 */
1137 /**
1138 * mark_buffer_dirty - mark a buffer_head as needing writeout
1139 * @bh: the buffer_head to mark dirty
1140 *
1141 * mark_buffer_dirty() will set the dirty bit against the buffer, then set its
1142 * backing page dirty, then tag the page as dirty in its address_space's radix
1143 * tree and then attach the address_space's inode to its superblock's dirty
1144 * inode list.
1145 *
1146 * mark_buffer_dirty() is atomic. It takes bh->b_page->mapping->private_lock,
1147 * mapping->tree_lock and the global inode_lock.
1148 */
1150 {
1153 /*
1154 * Very *carefully* optimize the it-is-already-dirty case.
1155 *
1156 * Don't let the final "is it dirty" escape to before we
1157 * perhaps modified the buffer.
1158 */
1163 }
1171 }
1172 }
1173 }
1176 /*
1177 * Decrement a buffer_head's reference count. If all buffers against a page
1178 * have zero reference count, are clean and unlocked, and if the page is clean
1179 * and unlocked then try_to_free_buffers() may strip the buffers from the page
1180 * in preparation for freeing it (sometimes, rarely, buffers are removed from
1181 * a page but it ends up not being freed, and buffers may later be reattached).
1182 */
1184 {
1188 }
1190 }
1193 /*
1194 * bforget() is like brelse(), except it discards any
1195 * potentially dirty data.
1196 */
1198 {
1207 }
1209 }
1213 {
1225 }
1228 }
1230 /*
1231 * Per-cpu buffer LRU implementation. To reduce the cost of __find_get_block().
1232 * The bhs[] array is sorted - newest buffer is at bhs[0]. Buffers have their
1233 * refcount elevated by one when they're in an LRU. A buffer can only appear
1234 * once in a particular CPU's LRU. A single buffer can be present in multiple
1235 * CPU's LRUs at the same time.
1236 *
1237 * This is a transparent caching front-end to sb_bread(), sb_getblk() and
1238 * sb_find_get_block().
1239 *
1240 * The LRUs themselves only need locking against invalidate_bh_lrus. We use
1241 * a local interrupt disable for that.
1242 */
1244 #define BH_LRU_SIZE 8
1248 };
1252 #ifdef CONFIG_SMP
1253 #define bh_lru_lock() local_irq_disable()
1254 #define bh_lru_unlock() local_irq_enable()
1255 #else
1256 #define bh_lru_lock() preempt_disable()
1257 #define bh_lru_unlock() preempt_enable()
1258 #endif
1261 {
1262 #ifdef irqs_disabled
1264 #endif
1265 }
1267 /*
1268 * The LRU management algorithm is dopey-but-simple. Sorry.
1269 */
1271 {
1295 }
1296 }
1297 }
1301 }
1306 }
1308 /*
1309 * Look up the bh in this cpu's LRU. If it's there, move it to the head.
1310 */
1313 {
1328 i--;
1329 }
1331 }
1335 }
1336 }
1339 }
1341 /*
1342 * Perform a pagecache lookup for the matching buffer. If it's there, refresh
1343 * it in the LRU and mark it as accessed. If it is not present then return
1344 * NULL
1345 */
1348 {
1355 }
1359 }
1362 /*
1363 * __getblk will locate (and, if necessary, create) the buffer_head
1364 * which corresponds to the passed block_device, block and size. The
1365 * returned buffer has its reference count incremented.
1366 *
1367 * __getblk() cannot fail - it just keeps trying. If you pass it an
1368 * illegal block number, __getblk() will happily return a buffer_head
1369 * which represents the non-existent block. Very weird.
1370 *
1371 * __getblk() will lock up the machine if grow_dev_page's try_to_free_buffers()
1372 * attempt is failing. FIXME, perhaps?
1373 */
1376 {
1383 }
1386 /*
1387 * Do async read-ahead on a buffer..
1388 */
1390 {
1395 }
1396 }
1399 /**
1400 * __bread() - reads a specified block and returns the bh
1401 * @bdev: the block_device to read from
1402 * @block: number of block
1403 * @size: size (in bytes) to read
1404 *
1405 * Reads a specified block, and returns buffer head that contains it.
1406 * It returns NULL if the block was unreadable.
1407 */
1410 {
1416 }
1419 /*
1420 * invalidate_bh_lrus() is called rarely - but not only at unmount.
1421 * This doesn't race because it runs in each cpu either in irq
1422 * or with preempt disabled.
1423 */
1425 {
1432 }
1434 }
1437 {
1439 }
1444 {
1448 /*
1449 * This catches illegal uses and preserves the offset:
1450 */
1452 else
1454 }
1457 /*
1458 * Called when truncating a buffer on a page completely.
1459 */
1461 {
1471 }
1473 /**
1474 * block_invalidatepage - invalidate part of all of a buffer-backed page
1475 *
1476 * @page: the page which is affected
1477 * @offset: the index of the truncation point
1478 *
1479 * block_invalidatepage() is called when all or part of the page has become
1480 * invalidatedby a truncate operation.
1481 *
1482 * block_invalidatepage() does not have to release all buffers, but it must
1483 * ensure that no dirty buffer is left outside @offset and that no I/O
1484 * is underway against any of the blocks which are outside the truncation
1485 * point. Because the caller is about to free (and possibly reuse) those
1486 * blocks on-disk.
1487 */
1489 {
1503 /*
1504 * is this block fully invalidated?
1505 */
1512 /*
1513 * We release buffers only if the entire page is being invalidated.
1514 * The get_block cached value has been unconditionally invalidated,
1515 * so real IO is not possible anymore.
1516 */
1519 out:
1521 }
1524 /*
1525 * We attach and possibly dirty the buffers atomically wrt
1526 * __set_page_dirty_buffers() via private_lock. try_to_free_buffers
1527 * is already excluded via the page lock.
1528 */
1531 {
1553 }
1556 }
1559 /*
1560 * We are taking a block for data and we don't want any output from any
1561 * buffer-cache aliases starting from return from that function and
1562 * until the moment when something will explicitly mark the buffer
1563 * dirty (hopefully that will not happen until we will free that block ;-)
1564 * We don't even need to mark it not-uptodate - nobody can expect
1565 * anything from a newly allocated buffer anyway. We used to used
1566 * unmap_buffer() for such invalidation, but that was wrong. We definitely
1567 * don't want to mark the alias unmapped, for example - it would confuse
1568 * anyone who might pick it with bread() afterwards...
1569 *
1570 * Also.. Note that bforget() doesn't lock the buffer. So there can
1571 * be writeout I/O going on against recently-freed buffers. We don't
1572 * wait on that I/O in bforget() - it's more efficient to wait on the I/O
1573 * only if we really need to. That happens here.
1574 */
1576 {
1587 }
1588 }
1591 /*
1592 * NOTE! All mapped/uptodate combinations are valid:
1593 *
1594 * Mapped Uptodate Meaning
1595 *
1596 * No No "unknown" - must do get_block()
1597 * No Yes "hole" - zero-filled
1598 * Yes No "allocated" - allocated on disk, not read in
1599 * Yes Yes "valid" - allocated and up-to-date in memory.
1600 *
1601 * "Dirty" is valid only with the last case (mapped+uptodate).
1602 */
1604 /*
1605 * While block_write_full_page is writing back the dirty buffers under
1606 * the page lock, whoever dirtied the buffers may decide to clean them
1607 * again at any time. We handle that by only looking at the buffer
1608 * state inside lock_buffer().
1609 *
1610 * If block_write_full_page() is called for regular writeback
1611 * (wbc->sync_mode == WB_SYNC_NONE) then it will redirty a page which has a
1612 * locked buffer. This only can happen if someone has written the buffer
1613 * directly, with submit_bh(). At the address_space level PageWriteback
1614 * prevents this contention from occurring.
1615 *
1616 * If block_write_full_page() is called with wbc->sync_mode ==
1617 * WB_SYNC_ALL, the writes are posted using WRITE_SYNC_PLUG; this
1618 * causes the writes to be flagged as synchronous writes, but the
1619 * block device queue will NOT be unplugged, since usually many pages
1620 * will be pushed to the out before the higher-level caller actually
1621 * waits for the writes to be completed. The various wait functions,
1622 * such as wait_on_writeback_range() will ultimately call sync_page()
1623 * which will ultimately call blk_run_backing_dev(), which will end up
1624 * unplugging the device queue.
1625 */
1629 {
1631 sector_t block;
1632 sector_t last_block;
1646 }
1648 /*
1649 * Be very careful. We have no exclusion from __set_page_dirty_buffers
1650 * here, and the (potentially unmapped) buffers may become dirty at
1651 * any time. If a buffer becomes dirty here after we've inspected it
1652 * then we just miss that fact, and the page stays dirty.
1653 *
1654 * Buffers outside i_size may be dirtied by __set_page_dirty_buffers;
1655 * handle that here by just cleaning them.
1656 */
1662 /*
1663 * Get all the dirty buffers mapped to disk addresses and
1664 * handle any aliases from the underlying blockdev's mapping.
1665 */
1668 /*
1669 * mapped buffers outside i_size will occur, because
1670 * this page can be outside i_size when there is a
1671 * truncate in progress.
1672 */
1673 /*
1674 * The buffer was zeroed by block_write_full_page()
1675 */
1686 /* blockdev mappings never come here */
1690 }
1691 }
1693 block++;
1699 /*
1700 * If it's a fully non-blocking write attempt and we cannot
1701 * lock the buffer then redirty the page. Note that this can
1702 * potentially cause a busy-wait loop from writeback threads
1703 * and kswapd activity, but those code paths have their own
1704 * higher-level throttling.
1705 */
1711 }
1716 }
1719 /*
1720 * The page and its buffers are protected by PageWriteback(), so we can
1721 * drop the bh refcounts early.
1722 */
1730 nr_underway++;
1731 }
1737 done:
1739 /*
1740 * The page was marked dirty, but the buffers were
1741 * clean. Someone wrote them back by hand with
1742 * ll_rw_block/submit_bh. A rare case.
1743 */
1746 /*
1747 * The page and buffer_heads can be released at any time from
1748 * here on.
1749 */
1750 }
1753 recover:
1754 /*
1755 * ENOSPC, or some other error. We may already have added some
1756 * blocks to the file, so we need to write these out to avoid
1757 * exposing stale data.
1758 * The page is currently locked and not marked for writeback
1759 */
1761 /* Recovery: lock and submit the mapped buffers */
1768 /*
1769 * The buffer may have been set dirty during
1770 * attachment to a dirty page.
1771 */
1773 }
1784 nr_underway++;
1785 }
1790 }
1792 /*
1793 * If a page has any new buffers, zero them out here, and mark them uptodate
1794 * and dirty so they'll be written out (in order to prevent uninitialised
1795 * block data from leaking). And clear the new bit.
1796 */
1798 {
1821 }
1825 }
1826 }
1831 }
1836 {
1841 sector_t block;
1866 }
1868 }
1884 }
1890 }
1891 }
1896 }
1902 }
1903 }
1904 /*
1905 * If we issued read requests - let them complete.
1906 */
1911 }
1915 }
1917 }
1922 {
1940 }
1942 }
1944 /*
1945 * If this is a partial write which happened to make all buffers
1946 * uptodate then we can optimize away a bogus readpage() for
1947 * the next read(). Here we 'discover' whether the page went
1948 * uptodate as a result of this (potentially partial) write.
1949 */
1953 }
1955 /*
1956 * block_write_begin takes care of the basic task of block allocation and
1957 * bringing partial write blocks uptodate first.
1958 *
1959 * The filesystem needs to handle block truncation upon failure.
1960 */
1963 {
1977 }
1981 }
1987 {
1994 /*
1995 * The buffers that were written will now be uptodate, so we
1996 * don't have to worry about a readpage reading them and
1997 * overwriting a partial write. However if we have encountered
1998 * a short write and only partially written into a buffer, it
1999 * will not be marked uptodate, so a readpage might come in and
2000 * destroy our partial write.
2001 *
2002 * Do the simplest thing, and just treat any short write to a
2003 * non uptodate page as a zero-length write, and force the
2004 * caller to redo the whole thing.
2005 */
2010 }
2013 /* This could be a short (even 0-length) commit */
2017 }
2023 {
2029 /*
2030 * No need to use i_size_read() here, the i_size
2031 * cannot change under us because we hold i_mutex.
2032 *
2033 * But it's important to update i_size while still holding page lock:
2034 * page writeout could otherwise come in and zero beyond i_size.
2035 */
2039 }
2044 /*
2045 * Don't mark the inode dirty under page lock. First, it unnecessarily
2046 * makes the holding time of page lock longer. Second, it forces lock
2047 * ordering of page lock and transaction start for journaling
2048 * filesystems.
2049 */
2054 }
2057 /*
2058 * block_is_partially_uptodate checks whether buffers within a page are
2059 * uptodate or not.
2060 *
2061 * Returns true if all buffers which correspond to a file portion
2062 * we want to read are uptodate.
2063 */
2066 {
2091 }
2094 }
2100 }
2103 /*
2104 * Generic "read page" function for block devices that have the normal
2105 * get_block functionality. This is most of the block device filesystems.
2106 * Reads the page asynchronously --- the unlock_buffer() and
2107 * set/clear_buffer_uptodate() functions propagate buffer state into the
2108 * page struct once IO has completed.
2109 */
2111 {
2144 }
2150 }
2151 /*
2152 * get_block() might have updated the buffer
2153 * synchronously
2154 */
2157 }
2165 /*
2166 * All buffers are uptodate - we can set the page uptodate
2167 * as well. But not if get_block() returned an error.
2168 */
2173 }
2175 /* Stage two: lock the buffers */
2180 }
2182 /*
2183 * Stage 3: start the IO. Check for uptodateness
2184 * inside the buffer lock in case another process reading
2185 * the underlying blockdev brought it uptodate (the sct fix).
2186 */
2191 else
2193 }
2195 }
2198 /* utility function for filesystems that need to do work on expanding
2199 * truncates. Uses filesystem pagecache writes to allow the filesystem to
2200 * deal with the hole.
2201 */
2203 {
2222 out:
2224 }
2229 {
2235 loff_t curpos;
2247 }
2251 AOP_FLAG_UNINTERRUPTIBLE,
2264 }
2266 /* page covers the boundary, find the boundary offset */
2269 /* if we will expand the thing last block will be filled */
2272 }
2276 }
2280 AOP_FLAG_UNINTERRUPTIBLE,
2291 }
2292 out:
2294 }
2296 /*
2297 * For moronic filesystems that do not allow holes in file.
2298 * We may have to extend the file.
2299 */
2304 {
2318 }
2321 }
2325 {
2329 }
2332 /*
2333 * block_page_mkwrite() is not allowed to change the file size as it gets
2334 * called from a page fault handler when a page is first dirtied. Hence we must
2335 * be careful to check for EOF conditions here. We set the page up correctly
2336 * for a written page which means we get ENOSPC checking when writing into
2337 * holes and correct delalloc and unwritten extent mapping on filesystems that
2338 * support these features.
2339 *
2340 * We are not allowed to take the i_mutex here so we have to play games to
2341 * protect against truncate races as the page could now be beyond EOF. Because
2342 * truncate writes the inode size before removing pages, once we have the
2343 * page lock we can determine safely if the page is beyond EOF. If it is not
2344 * beyond EOF, then the page is guaranteed safe against truncation until we
2345 * unlock the page.
2346 */
2347 int
2349 get_block_t get_block)
2350 {
2354 loff_t size;
2361 /* page got truncated out from underneath us */
2364 }
2366 /* page is wholly or partially inside EOF */
2369 else
2385 out:
2387 }
2390 /*
2391 * nobh_write_begin()'s prereads are special: the buffer_heads are freed
2392 * immediately, while under the page lock. So it needs a special end_io
2393 * handler which does not touch the bh after unlocking it.
2394 */
2396 {
2398 }
2400 /*
2401 * Attach the singly-linked list of buffers created by nobh_write_begin, to
2402 * the page (converting it to circular linked list and taking care of page
2403 * dirty races).
2404 */
2406 {
2422 }
2424 /*
2425 * On entry, the page is fully not uptodate.
2426 * On exit the page is fully uptodate in the areas outside (from,to)
2427 * The filesystem needs to handle block truncation upon failure.
2428 */
2433 {
2439 pgoff_t index;
2443 sector_t block_in_file;
2463 }
2468 /*
2469 * Allocate buffers so that we can keep track of state, and potentially
2470 * attach them to the page if an error occurs. In the common case of
2471 * no error, they will just be freed again without ever being attached
2472 * to the page (which is all OK, because we're under the page lock).
2473 *
2474 * Be careful: the buffer linked list is a NULL terminated one, rather
2475 * than the circular one we're used to.
2476 */
2481 }
2485 /*
2486 * We loop across all blocks in the page, whether or not they are
2487 * part of the affected region. This is so we can discover if the
2488 * page is fully mapped-to-disk.
2489 */
2511 }
2516 }
2523 nr_reads++;
2524 }
2525 }
2528 /*
2529 * The page is locked, so these buffers are protected from
2530 * any VM or truncate activity. Hence we don't need to care
2531 * for the buffer_head refcounts.
2532 */
2537 }
2540 }
2549 failed:
2551 /*
2552 * Error recovery is a bit difficult. We need to zero out blocks that
2553 * were newly allocated, and dirty them to ensure they get written out.
2554 * Buffers need to be attached to the page at this point, otherwise
2555 * the handling of potential IO errors during writeout would be hard
2556 * (could try doing synchronous writeout, but what if that fails too?)
2557 */
2561 out_release:
2567 }
2573 {
2590 }
2599 }
2602 }
2605 /*
2606 * nobh_writepage() - based on block_full_write_page() except
2607 * that it tries to operate without attaching bufferheads to
2608 * the page.
2609 */
2612 {
2619 /* Is the page fully inside i_size? */
2623 /* Is the page fully outside i_size? (truncate in progress) */
2626 /*
2627 * The page may have dirty, unmapped buffers. For example,
2628 * they may have been added in ext3_writepage(). Make them
2629 * freeable here, so the page does not leak.
2630 */
2631 #if 0
2632 /* Not really sure about this - do we need this ? */
2635 #endif
2638 }
2640 /*
2641 * The page straddles i_size. It must be zeroed out on each and every
2642 * writepage invocation because it may be mmapped. "A file is mapped
2643 * in multiples of the page size. For a file that is not a multiple of
2644 * the page size, the remaining memory is zeroed when mapped, and
2645 * writes to that region are not written out to the file."
2646 */
2648 out:
2652 end_buffer_async_write);
2654 }
2659 {
2663 sector_t iblock;
2673 /* Block boundary? Nothing to do */
2686 has_buffers:
2690 }
2692 /* Find the buffer that contains "offset" */
2695 iblock++;
2697 }
2704 /* unmapped? It's a hole - nothing to do */
2708 /* Ok, it's mapped. Make sure it's up-to-date */
2714 }
2719 }
2722 }
2727 unlock:
2730 out:
2732 }
2737 {
2741 sector_t iblock;
2751 /* Block boundary? Nothing to do */
2766 /* Find the buffer that contains "offset" */
2771 iblock++;
2773 }
2781 /* unmapped? It's a hole - nothing to do */
2784 }
2786 /* Ok, it's mapped. Make sure it's up-to-date */
2794 /* Uhhuh. Read error. Complain and punt. */
2797 }
2803 unlock:
2806 out:
2808 }
2811 /*
2812 * The generic ->writepage function for buffer-backed address_spaces
2813 * this form passes in the end_io handler used to finish the IO.
2814 */
2817 {
2823 /* Is the page fully inside i_size? */
2826 handler);
2828 /* Is the page fully outside i_size? (truncate in progress) */
2831 /*
2832 * The page may have dirty, unmapped buffers. For example,
2833 * they may have been added in ext3_writepage(). Make them
2834 * freeable here, so the page does not leak.
2835 */
2839 }
2841 /*
2842 * The page straddles i_size. It must be zeroed out on each and every
2843 * writepage invocation because it may be mmapped. "A file is mapped
2844 * in multiples of the page size. For a file that is not a multiple of
2845 * the page size, the remaining memory is zeroed when mapped, and
2846 * writes to that region are not written out to the file."
2847 */
2850 }
2853 /*
2854 * The generic ->writepage function for buffer-backed address_spaces
2855 */
2858 {
2860 end_buffer_async_write);
2861 }
2866 {
2874 }
2878 {
2883 }
2890 }
2893 {
2903 /*
2904 * Only clear out a write error when rewriting
2905 */
2909 /*
2910 * from here on down, it's all bio -- do the initial mapping,
2911 * submit_bio -> generic_make_request may further map this bio around
2912 */
2936 }
2939 /**
2940 * ll_rw_block: low-level access to block devices (DEPRECATED)
2941 * @rw: whether to %READ or %WRITE or maybe %READA (readahead)
2942 * @nr: number of &struct buffer_heads in the array
2943 * @bhs: array of pointers to &struct buffer_head
2944 *
2945 * ll_rw_block() takes an array of pointers to &struct buffer_heads, and
2946 * requests an I/O operation on them, either a %READ or a %WRITE. The third
2947 * %READA option is described in the documentation for generic_make_request()
2948 * which ll_rw_block() calls.
2949 *
2950 * This function drops any buffer that it cannot get a lock on (with the
2951 * BH_Lock state bit), any buffer that appears to be clean when doing a write
2952 * request, and any buffer that appears to be up-to-date when doing read
2953 * request. Further it marks as clean buffers that are processed for
2954 * writing (the buffer cache won't assume that they are actually clean
2955 * until the buffer gets unlocked).
2956 *
2957 * ll_rw_block sets b_end_io to simple completion handler that marks
2958 * the buffer up-to-date (if approriate), unlocks the buffer and wakes
2959 * any waiters.
2960 *
2961 * All of the buffers must be for the same device, and must also be a
2962 * multiple of the current approved size for the device.
2963 */
2965 {
2979 }
2986 }
2987 }
2989 }
2990 }
2994 {
2999 }
3003 }
3006 /*
3007 * For a data-integrity writeout, we need to wait upon any in-progress I/O
3008 * and then start new I/O and then wait upon it. The caller must have a ref on
3009 * the buffer_head.
3010 */
3012 {
3026 }
3028 }
3032 {
3034 }
3037 /*
3038 * try_to_free_buffers() checks if all the buffers on this particular page
3039 * are unused, and releases them if so.
3040 *
3041 * Exclusion against try_to_free_buffers may be obtained by either
3042 * locking the page or by holding its mapping's private_lock.
3043 *
3044 * If the page is dirty but all the buffers are clean then we need to
3045 * be sure to mark the page clean as well. This is because the page
3046 * may be against a block device, and a later reattachment of buffers
3047 * to a dirty page will set *all* buffers dirty. Which would corrupt
3048 * filesystem data on the same device.
3049 *
3050 * The same applies to regular filesystem pages: if all the buffers are
3051 * clean then we set the page clean and proceed. To do that, we require
3052 * total exclusion from __set_page_dirty_buffers(). That is obtained with
3053 * private_lock.
3054 *
3055 * try_to_free_buffers() is non-blocking.
3056 */
3058 {
3061 }
3063 static int
3065 {
3088 failed:
3090 }
3093 {
3105 }
3110 /*
3111 * If the filesystem writes its buffers by hand (eg ext3)
3112 * then we can have clean buffers against a dirty page. We
3113 * clean the page here; otherwise the VM will never notice
3114 * that the filesystem did any IO at all.
3115 *
3116 * Also, during truncate, discard_buffer will have marked all
3117 * the page's buffers clean. We discover that here and clean
3118 * the page also.
3119 *
3120 * private_lock must be held over this entire operation in order
3121 * to synchronise against __set_page_dirty_buffers and prevent the
3122 * dirty bit from being lost.
3123 */
3127 out:
3136 }
3138 }
3142 {
3149 }
3152 /*
3153 * There are no bdflush tunables left. But distributions are
3154 * still running obsolete flush daemons, so we terminate them here.
3155 *
3156 * Use of bdflush() is deprecated and will be removed in a future kernel.
3157 * The `flush-X' kernel threads fully replace bdflush daemons and this call.
3158 */
3160 {
3167 msg_count++;
3169 "warning: process `%s' used the obsolete bdflush"
3172 }
3177 }
3179 /*
3180 * Buffer-head allocation
3181 */
3184 /*
3185 * Once the number of bh's in the machine exceeds this level, we start
3186 * stripping them in writeback.
3187 */
3195 };
3200 {
3210 }
3213 {
3221 }
3223 }
3227 {
3234 }
3238 {
3245 }
3248 }
3252 {
3256 }
3258 /**
3259 * bh_uptodate_or_lock - Test whether the buffer is uptodate
3260 * @bh: struct buffer_head
3261 *
3262 * Return true if the buffer is up-to-date and false,
3263 * with the buffer locked, if not.
3264 */
3266 {
3272 }
3274 }
3277 /**
3278 * bh_submit_read - Submit a locked buffer for reading
3279 * @bh: struct buffer_head
3280 *
3281 * Returns zero on success and -EIO on error.
3282 */
3284 {
3290 }
3299 }
3303 {
3309 SLAB_MEM_SPREAD),
3310 NULL);
3312 /*
3313 * Limit the bh occupancy to 10% of ZONE_NORMAL
3314 */
3318 }