| blob | ac8f690d288590c9f1c8603bd37272127c9cecf2 |
1 /*
2 * linux/mm/filemap.c
3 *
4 * Copyright (C) 1994-1999 Linus Torvalds
5 */
7 /*
8 * This file handles the generic file mmap semantics used by
9 * most "normal" filesystems (but you don't /have/ to use this:
10 * the NFS filesystem used to do this differently, for example)
11 */
12 #include <linux/module.h>
13 #include <linux/slab.h>
14 #include <linux/compiler.h>
15 #include <linux/fs.h>
16 #include <linux/uaccess.h>
17 #include <linux/aio.h>
18 #include <linux/capability.h>
19 #include <linux/kernel_stat.h>
20 #include <linux/mm.h>
21 #include <linux/swap.h>
22 #include <linux/mman.h>
23 #include <linux/pagemap.h>
24 #include <linux/file.h>
25 #include <linux/uio.h>
26 #include <linux/hash.h>
27 #include <linux/writeback.h>
28 #include <linux/backing-dev.h>
29 #include <linux/pagevec.h>
30 #include <linux/blkdev.h>
31 #include <linux/backing-dev.h>
32 #include <linux/security.h>
33 #include <linux/syscalls.h>
34 #include <linux/cpuset.h>
38 /*
39 * FIXME: remove all knowledge of the buffer layer from the core VM
40 */
43 #include <asm/mman.h>
45 static ssize_t
49 /*
50 * Shared mappings implemented 30.11.1994. It's not fully working yet,
51 * though.
52 *
53 * Shared mappings now work. 15.8.1995 Bruno.
54 *
55 * finished 'unifying' the page and buffer cache and SMP-threaded the
56 * page-cache, 21.05.1999, Ingo Molnar <mingo@redhat.com>
57 *
58 * SMP-threaded pagemap-LRU 1999, Andrea Arcangeli <andrea@suse.de>
59 */
61 /*
62 * Lock ordering:
63 *
64 * ->i_mmap_lock (vmtruncate)
65 * ->private_lock (__free_pte->__set_page_dirty_buffers)
66 * ->swap_lock (exclusive_swap_page, others)
67 * ->mapping->tree_lock
68 * ->zone.lock
69 *
70 * ->i_mutex
71 * ->i_mmap_lock (truncate->unmap_mapping_range)
72 *
73 * ->mmap_sem
74 * ->i_mmap_lock
75 * ->page_table_lock or pte_lock (various, mainly in memory.c)
76 * ->mapping->tree_lock (arch-dependent flush_dcache_mmap_lock)
77 *
78 * ->mmap_sem
79 * ->lock_page (access_process_vm)
80 *
81 * ->i_mutex (generic_file_buffered_write)
82 * ->mmap_sem (fault_in_pages_readable->do_page_fault)
83 *
84 * ->i_mutex
85 * ->i_alloc_sem (various)
86 *
87 * ->inode_lock
88 * ->sb_lock (fs/fs-writeback.c)
89 * ->mapping->tree_lock (__sync_single_inode)
90 *
91 * ->i_mmap_lock
92 * ->anon_vma.lock (vma_adjust)
93 *
94 * ->anon_vma.lock
95 * ->page_table_lock or pte_lock (anon_vma_prepare and various)
96 *
97 * ->page_table_lock or pte_lock
98 * ->swap_lock (try_to_unmap_one)
99 * ->private_lock (try_to_unmap_one)
100 * ->tree_lock (try_to_unmap_one)
101 * ->zone.lru_lock (follow_page->mark_page_accessed)
102 * ->zone.lru_lock (check_pte_range->isolate_lru_page)
103 * ->private_lock (page_remove_rmap->set_page_dirty)
104 * ->tree_lock (page_remove_rmap->set_page_dirty)
105 * ->inode_lock (page_remove_rmap->set_page_dirty)
106 * ->inode_lock (zap_pte_range->set_page_dirty)
107 * ->private_lock (zap_pte_range->__set_page_dirty_buffers)
108 *
109 * ->task->proc_lock
110 * ->dcache_lock (proc_pid_lookup)
111 */
113 /*
114 * Remove a page from the page cache and free it. Caller has to make
115 * sure the page is locked and that nobody else uses it - or that usage
116 * is safe. The caller must hold a write_lock on the mapping's tree_lock.
117 */
119 {
127 }
130 {
138 }
141 {
147 /*
148 * page_mapping() is being called without PG_locked held.
149 * Some knowledge of the state and use of the page is used to
150 * reduce the requirements down to a memory barrier.
151 * The danger here is of a stale page_mapping() return value
152 * indicating a struct address_space different from the one it's
153 * associated with when it is associated with one.
154 * After smp_mb(), it's either the correct page_mapping() for
155 * the page, or an old page_mapping() and the page's own
156 * page_mapping() has gone NULL.
157 * The ->sync_page() address_space operation must tolerate
158 * page_mapping() going NULL. By an amazing coincidence,
159 * this comes about because none of the users of the page
160 * in the ->sync_page() methods make essential use of the
161 * page_mapping(), merely passing the page down to the backing
162 * device's unplug functions when it's non-NULL, which in turn
163 * ignore it for all cases but swap, where only page_private(page) is
164 * of interest. When page_mapping() does go NULL, the entire
165 * call stack gracefully ignores the page and returns.
166 * -- wli
167 */
174 }
177 {
180 }
182 /**
183 * __filemap_fdatawrite_range - start writeback on mapping dirty pages in range
184 * @mapping: address space structure to write
185 * @start: offset in bytes where the range starts
186 * @end: offset in bytes where the range ends (inclusive)
187 * @sync_mode: enable synchronous operation
188 *
189 * Start writeback against all of a mapping's dirty pages that lie
190 * within the byte offsets <start, end> inclusive.
191 *
192 * If sync_mode is WB_SYNC_ALL then this is a "data integrity" operation, as
193 * opposed to a regular memory cleansing writeback. The difference between
194 * these two operations is that if a dirty page/buffer is encountered, it must
195 * be waited upon, and not just skipped over.
196 */
199 {
206 };
213 }
217 {
219 }
222 {
224 }
228 loff_t end)
229 {
231 }
233 /**
234 * filemap_flush - mostly a non-blocking flush
235 * @mapping: target address_space
236 *
237 * This is a mostly non-blocking flush. Not suitable for data-integrity
238 * purposes - I/O may not be started against all dirty pages.
239 */
241 {
243 }
246 /**
247 * wait_on_page_writeback_range - wait for writeback to complete
248 * @mapping: target address_space
249 * @start: beginning page index
250 * @end: ending page index
251 *
252 * Wait for writeback to complete against pages indexed by start->end
253 * inclusive
254 */
257 {
261 pgoff_t index;
270 PAGECACHE_TAG_WRITEBACK,
277 /* until radix tree lookup accepts end_index */
284 }
287 }
289 /* Check for outstanding write errors */
296 }
298 /**
299 * sync_page_range - write and wait on all pages in the passed range
300 * @inode: target inode
301 * @mapping: target address_space
302 * @pos: beginning offset in pages to write
303 * @count: number of bytes to write
304 *
305 * Write and wait upon all the pages in the passed range. This is a "data
306 * integrity" operation. It waits upon in-flight writeout before starting and
307 * waiting upon new writeout. If there was an IO error, return it.
308 *
309 * We need to re-take i_mutex during the generic_osync_inode list walk because
310 * it is otherwise livelockable.
311 */
314 {
326 }
330 }
333 /**
334 * sync_page_range_nolock
335 * @inode: target inode
336 * @mapping: target address_space
337 * @pos: beginning offset in pages to write
338 * @count: number of bytes to write
339 *
340 * Note: Holding i_mutex across sync_page_range_nolock() is not a good idea
341 * as it forces O_SYNC writers to different parts of the same file
342 * to be serialised right until io completion.
343 */
346 {
359 }
362 /**
363 * filemap_fdatawait - wait for all under-writeback pages to complete
364 * @mapping: address space structure to wait for
365 *
366 * Walk the list of under-writeback pages of the given address space
367 * and wait for all of them.
368 */
370 {
378 }
382 {
387 /*
388 * Even if the above returned error, the pages may be
389 * written partially (e.g. -ENOSPC), so we wait for it.
390 * But the -EIO is special case, it may indicate the worst
391 * thing (e.g. bug) happened, so we avoid waiting for it.
392 */
397 }
398 }
400 }
403 /**
404 * filemap_write_and_wait_range - write out & wait on a file range
405 * @mapping: the address_space for the pages
406 * @lstart: offset in bytes where the range starts
407 * @lend: offset in bytes where the range ends (inclusive)
408 *
409 * Write out and wait upon file offsets lstart->lend, inclusive.
410 *
411 * Note that `lend' is inclusive (describes the last byte to be written) so
412 * that this function can be used to write to the very end-of-file (end = -1).
413 */
416 {
421 WB_SYNC_ALL);
422 /* See comment of filemap_write_and_wait() */
429 }
430 }
432 }
434 /**
435 * add_to_page_cache - add newly allocated pagecache pages
436 * @page: page to add
437 * @mapping: the page's address_space
438 * @offset: page index
439 * @gfp_mask: page allocation mode
440 *
441 * This function is used to add newly allocated pagecache pages;
442 * the page is new, so we can just run SetPageLocked() against it.
443 * The other page state flags were set by rmqueue().
444 *
445 * This function does not add the page to the LRU. The caller must do that.
446 */
449 {
462 }
465 }
467 }
472 {
477 }
479 #ifdef CONFIG_NUMA
481 {
485 }
487 }
489 #endif
492 {
495 }
497 /*
498 * In order to wait for pages to become available there must be
499 * waitqueues associated with pages. By using a hash table of
500 * waitqueues where the bucket discipline is to maintain all
501 * waiters on the same queue and wake all when any of the pages
502 * become available, and for the woken contexts to check to be
503 * sure the appropriate page became available, this saves space
504 * at a cost of "thundering herd" phenomena during rare hash
505 * collisions.
506 */
508 {
512 }
515 {
517 }
520 {
525 TASK_UNINTERRUPTIBLE);
526 }
529 /**
530 * unlock_page - unlock a locked page
531 * @page: the page
532 *
533 * Unlocks the page and wakes up sleepers in ___wait_on_page_locked().
534 * Also wakes sleepers in wait_on_page_writeback() because the wakeup
535 * mechananism between PageLocked pages and PageWriteback pages is shared.
536 * But that's OK - sleepers in wait_on_page_writeback() just go back to sleep.
537 *
538 * The first mb is necessary to safely close the critical section opened by the
539 * TestSetPageLocked(), the second mb is necessary to enforce ordering between
540 * the clear_bit and the read of the waitqueue (to avoid SMP races with a
541 * parallel wait_on_page_locked()).
542 */
544 {
550 }
553 /**
554 * end_page_writeback - end writeback against a page
555 * @page: the page
556 */
558 {
562 }
565 }
568 /**
569 * __lock_page - get a lock on the page, assuming we need to sleep to get it
570 * @page: the page to lock
571 *
572 * Ugly. Running sync_page() in state TASK_UNINTERRUPTIBLE is scary. If some
573 * random driver's requestfn sets TASK_RUNNING, we could busywait. However
574 * chances are that on the second loop, the block layer's plug list is empty,
575 * so sync_page() will then return in state TASK_UNINTERRUPTIBLE.
576 */
578 {
582 TASK_UNINTERRUPTIBLE);
583 }
587 {
592 }
594 /*
595 * Variant of lock_page that does not require the caller to hold a reference
596 * on the page's mapping.
597 */
599 {
602 TASK_UNINTERRUPTIBLE);
603 }
605 /**
606 * find_get_page - find and get a page reference
607 * @mapping: the address_space to search
608 * @offset: the page index
609 *
610 * Is there a pagecache struct page at the given (mapping, offset) tuple?
611 * If yes, increment its refcount and return it; if no, return NULL.
612 */
614 {
623 }
626 /**
627 * find_lock_page - locate, pin and lock a pagecache page
628 * @mapping: the address_space to search
629 * @offset: the page index
630 *
631 * Locates the desired pagecache page, locks it, increments its reference
632 * count and returns its address.
633 *
634 * Returns zero if the page was not present. find_lock_page() may sleep.
635 */
637 pgoff_t offset)
638 {
641 repeat:
650 /* Has the page been truncated while we slept? */
655 }
658 }
659 }
661 out:
663 }
666 /**
667 * find_or_create_page - locate or add a pagecache page
668 * @mapping: the page's address_space
669 * @index: the page's index into the mapping
670 * @gfp_mask: page allocation mode
671 *
672 * Locates a page in the pagecache. If the page is not present, a new page
673 * is allocated using @gfp_mask and is added to the pagecache and to the VM's
674 * LRU list. The returned page is locked and has its reference count
675 * incremented.
676 *
677 * find_or_create_page() may sleep, even if @gfp_flags specifies an atomic
678 * allocation!
679 *
680 * find_or_create_page() returns the desired page's address, or zero on
681 * memory exhaustion.
682 */
685 {
688 repeat:
700 }
701 }
703 }
706 /**
707 * find_get_pages - gang pagecache lookup
708 * @mapping: The address_space to search
709 * @start: The starting page index
710 * @nr_pages: The maximum number of pages
711 * @pages: Where the resulting pages are placed
712 *
713 * find_get_pages() will search for and return a group of up to
714 * @nr_pages pages in the mapping. The pages are placed at @pages.
715 * find_get_pages() takes a reference against the returned pages.
716 *
717 * The search returns a group of mapping-contiguous pages with ascending
718 * indexes. There may be holes in the indices due to not-present pages.
719 *
720 * find_get_pages() returns the number of pages which were found.
721 */
724 {
735 }
737 /**
738 * find_get_pages_contig - gang contiguous pagecache lookup
739 * @mapping: The address_space to search
740 * @index: The starting page index
741 * @nr_pages: The maximum number of pages
742 * @pages: Where the resulting pages are placed
743 *
744 * find_get_pages_contig() works exactly like find_get_pages(), except
745 * that the returned number of pages are guaranteed to be contiguous.
746 *
747 * find_get_pages_contig() returns the number of pages which were found.
748 */
751 {
763 index++;
764 }
767 }
770 /**
771 * find_get_pages_tag - find and return pages that match @tag
772 * @mapping: the address_space to search
773 * @index: the starting page index
774 * @tag: the tag index
775 * @nr_pages: the maximum number of pages
776 * @pages: where the resulting pages are placed
777 *
778 * Like find_get_pages, except we only return pages which are tagged with
779 * @tag. We update @index to index the next page for the traversal.
780 */
783 {
796 }
799 /**
800 * grab_cache_page_nowait - returns locked page at given index in given cache
801 * @mapping: target address_space
802 * @index: the page index
803 *
804 * Same as grab_cache_page(), but do not wait if the page is unavailable.
805 * This is intended for speculative data generators, where the data can
806 * be regenerated if the page couldn't be grabbed. This routine should
807 * be safe to call while holding the lock for another page.
808 *
809 * Clear __GFP_FS when allocating the page to avoid recursion into the fs
810 * and deadlock against the caller's locked page.
811 */
814 {
822 }
827 }
829 }
832 /*
833 * CD/DVDs are error prone. When a medium error occurs, the driver may fail
834 * a _large_ part of the i/o request. Imagine the worst scenario:
835 *
836 * ---R__________________________________________B__________
837 * ^ reading here ^ bad block(assume 4k)
838 *
839 * read(R) => miss => readahead(R...B) => media error => frustrating retries
840 * => failing the whole request => read(R) => read(R+1) =>
841 * readahead(R+1...B+1) => bang => read(R+2) => read(R+3) =>
842 * readahead(R+3...B+2) => bang => read(R+3) => read(R+4) =>
843 * readahead(R+4...B+3) => bang => read(R+4) => read(R+5) => ......
844 *
845 * It is going insane. Fix it by quickly scaling down the readahead size.
846 */
849 {
854 }
856 /**
857 * do_generic_mapping_read - generic file read routine
858 * @mapping: address_space to be read
859 * @ra: file's readahead state
860 * @filp: the file to read
861 * @ppos: current file position
862 * @desc: read_descriptor
863 * @actor: read method
864 *
865 * This is a generic file read routine, and uses the
866 * mapping->a_ops->readpage() function for the actual low-level stuff.
867 *
868 * This is really ugly. But the goto's actually try to clarify some
869 * of the logic when it comes to error handling etc.
870 *
871 * Note the struct file* is only passed for the use of readpage.
872 * It may be NULL.
873 */
879 read_actor_t actor)
880 {
882 pgoff_t index;
883 pgoff_t last_index;
884 pgoff_t prev_index;
897 pgoff_t end_index;
898 loff_t isize;
902 find_page:
911 }
916 }
919 page_ok:
920 /*
921 * i_size must be checked after we know the page is Uptodate.
922 *
923 * Checking i_size after the check allows us to calculate
924 * the correct value for "nr", which means the zero-filled
925 * part of the page is not copied back to userspace (unless
926 * another truncate extends the file - this is desired though).
927 */
934 }
936 /* nr is the maximum number of bytes to copy from this page */
943 }
944 }
947 /* If users can be writing to this page using arbitrary
948 * virtual addresses, take care about potential aliasing
949 * before reading the page on the kernel side.
950 */
954 /*
955 * When a sequential read accesses a page several times,
956 * only mark it as accessed the first time.
957 */
962 /*
963 * Ok, we have the page, and it's up-to-date, so
964 * now we can copy it to user space...
965 *
966 * The actor routine returns how many bytes were actually used..
967 * NOTE! This may not be the same as how much of a user buffer
968 * we filled up (we may be padding etc), so we can only update
969 * "pos" here (the actor routine has to update the user buffer
970 * pointers and the remaining count).
971 */
983 page_not_up_to_date:
984 /* Get exclusive access to the page ... */
987 /* Did it get truncated before we got the lock? */
992 }
994 /* Did somebody else fill it already? */
998 }
1000 readpage:
1001 /* Start the actual read. The read will unlock the page. */
1008 }
1010 }
1016 /*
1017 * invalidate_inode_pages got it
1018 */
1022 }
1027 }
1029 }
1033 readpage_error:
1034 /* UHHUH! A synchronous read error occurred. Report it */
1039 no_cached_page:
1040 /*
1041 * Ok, it wasn't cached, so we need to create a new
1042 * page..
1043 */
1048 }
1057 }
1059 }
1061 out:
1069 }
1074 {
1081 /*
1082 * Faults on the destination of a read are common, so do it before
1083 * taking the kmap.
1084 */
1092 }
1094 /* Do it the slow way */
1102 }
1103 success:
1108 }
1110 /*
1111 * Performs necessary checks before doing a write
1112 * @iov: io vector request
1113 * @nr_segs: number of segments in the iovec
1114 * @count: number of bytes to write
1115 * @access_flags: type of access: %VERIFY_READ or %VERIFY_WRITE
1116 *
1117 * Adjust number of segments and amount of bytes to write (nr_segs should be
1118 * properly initialized first). Returns appropriate error code that caller
1119 * should return or zero in case that write should be allowed.
1120 */
1123 {
1129 /*
1130 * If any segment has a negative length, or the cumulative
1131 * length ever wraps negative then return -EINVAL.
1132 */
1143 }
1146 }
1149 /**
1150 * generic_file_aio_read - generic filesystem read routine
1151 * @iocb: kernel I/O control block
1152 * @iov: io vector request
1153 * @nr_segs: number of segments in the iovec
1154 * @pos: current file position
1155 *
1156 * This is the "read()" routine for all filesystems
1157 * that can use the page cache directly.
1158 */
1159 ssize_t
1162 {
1164 ssize_t retval;
1174 /* coalesce the iovecs and go direct-to-BIO for O_DIRECT */
1176 loff_t size;
1191 }
1195 }
1196 }
1201 read_descriptor_t desc;
1214 }
1217 }
1218 }
1219 out:
1221 }
1224 static ssize_t
1227 {
1234 }
1237 {
1238 ssize_t ret;
1250 }
1252 }
1254 }
1256 #ifdef CONFIG_MMU
1257 /**
1258 * page_cache_read - adds requested page to the page cache if not already there
1259 * @file: file to read
1260 * @offset: page index
1261 *
1262 * This adds the requested page to the page cache if it isn't already there,
1263 * and schedules an I/O to read in its contents from disk.
1264 */
1266 {
1287 }
1289 #define MMAP_LOTSAMISS (100)
1291 /**
1292 * filemap_fault - read in file data for page fault handling
1293 * @vma: vma in which the fault was taken
1294 * @vmf: struct vm_fault containing details of the fault
1295 *
1296 * filemap_fault() is invoked via the vma operations vector for a
1297 * mapped memory region to read in file data during a page fault.
1298 *
1299 * The goto's are kind of ugly, but this streamlines the normal case of having
1300 * it in the page cache, and handles the special cases reasonably without
1301 * having a lot of duplicated code.
1302 */
1304 {
1319 /* If we don't want any read-ahead, don't bother */
1323 /*
1324 * Do we have something in the page cache already?
1325 */
1326 retry_find:
1328 /*
1329 * For sequential accesses, we use the generic readahead logic.
1330 */
1338 }
1342 }
1343 }
1350 /*
1351 * Do we miss much more than hit in this file? If so,
1352 * stop bothering with read-ahead. It will only hurt.
1353 */
1357 /*
1358 * To keep the pgmajfault counter straight, we need to
1359 * check did_readaround, as this is an inner loop.
1360 */
1364 }
1373 }
1377 }
1382 /*
1383 * We have a locked page in the page cache, now we need to check
1384 * that it's up-to-date. If not, it is going to be due to an error.
1385 */
1389 /* Must recheck i_size under page lock */
1395 }
1397 /*
1398 * Found the page and have a reference on it.
1399 */
1405 no_cached_page:
1406 /*
1407 * We're only likely to ever get here if MADV_RANDOM is in
1408 * effect.
1409 */
1412 /*
1413 * The page we want has now been added to the page cache.
1414 * In the unlikely event that someone removed it in the
1415 * meantime, we'll just come back here and read it again.
1416 */
1420 /*
1421 * An error return from page_cache_read can result if the
1422 * system is low on memory, or a problem occurs while trying
1423 * to schedule I/O.
1424 */
1429 page_not_uptodate:
1430 /* IO error path */
1434 }
1436 /*
1437 * Umm, take care of errors if the page isn't up-to-date.
1438 * Try to re-read it _once_. We do this synchronously,
1439 * because there really aren't any performance issues here
1440 * and we need to check for errors.
1441 */
1449 /* Things didn't work out. Return zero to tell the mm layer so. */
1452 }
1457 };
1459 /* This is used for a general mmap of a disk file */
1462 {
1471 }
1473 /*
1474 * This is for filesystems which do not implement ->writepage.
1475 */
1477 {
1481 }
1482 #else
1484 {
1486 }
1488 {
1490 }
1497 pgoff_t index,
1500 {
1503 repeat:
1514 /* Presumably ENOMEM for radix tree node */
1516 }
1521 }
1522 }
1524 }
1526 /*
1527 * Same as read_cache_page, but don't wait for page to become unlocked
1528 * after submitting it to the filler.
1529 */
1531 pgoff_t index,
1534 {
1538 retry:
1550 }
1554 }
1559 }
1560 out:
1563 }
1566 /**
1567 * read_cache_page - read into page cache, fill it if needed
1568 * @mapping: the page's address_space
1569 * @index: the page index
1570 * @filler: function to perform the read
1571 * @data: destination for read data
1572 *
1573 * Read into the page cache. If a page already exists, and PageUptodate() is
1574 * not set, try to fill the page then wait for it to become unlocked.
1575 *
1576 * If the page does not get brought uptodate, return -EIO.
1577 */
1579 pgoff_t index,
1582 {
1592 }
1593 out:
1595 }
1598 /*
1599 * The logic we want is
1600 *
1601 * if suid or (sgid and xgrp)
1602 * remove privs
1603 */
1605 {
1609 /* suid always must be killed */
1613 /*
1614 * sgid without any exec bits is just a mandatory locking mark; leave
1615 * it alone. If some exec bits are set, it's a real sgid; kill it.
1616 */
1624 }
1628 {
1633 }
1636 {
1649 }
1654 {
1666 iov++;
1670 }
1672 }
1674 /*
1675 * Copy as much as we can into the page and return the number of bytes which
1676 * were sucessfully copied. If a fault is encountered then return the number of
1677 * bytes which were copied.
1678 */
1681 {
1696 }
1700 }
1703 /*
1704 * This has the same sideeffects and return value as
1705 * iov_iter_copy_from_user_atomic().
1706 * The difference is that it attempts to resolve faults.
1707 * Page must not be locked.
1708 */
1711 {
1724 }
1727 }
1731 {
1744 iov++;
1746 }
1747 }
1750 }
1751 }
1754 {
1759 }
1762 /*
1763 * Fault in the first iovec of the given iov_iter, to a maximum length
1764 * of bytes. Returns 0 on success, or non-zero if the memory could not be
1765 * accessed (ie. because it is an invalid address).
1766 *
1767 * writev-intensive code may want this to prefault several iovecs -- that
1768 * would be possible (callers must not rely on the fact that _only_ the
1769 * first iovec will be faulted with the current implementation).
1770 */
1772 {
1776 }
1779 /*
1780 * Return the count of just the current iov_iter segment.
1781 */
1783 {
1787 else
1789 }
1792 /*
1793 * Performs necessary checks before doing a write
1794 *
1795 * Can adjust writing position or amount of bytes to write.
1796 * Returns appropriate error code that caller should return or
1797 * zero in case that write should be allowed.
1798 */
1800 {
1808 /* FIXME: this is for backwards compatibility with 2.4 */
1816 }
1819 }
1820 }
1821 }
1823 /*
1824 * LFS rule
1825 */
1830 }
1833 }
1834 }
1836 /*
1837 * Are we about to exceed the fs block limit ?
1838 *
1839 * If we have written data it becomes a short write. If we have
1840 * exceeded without writing data we send a signal and return EFBIG.
1841 * Linus frestrict idea will clean these up nicely..
1842 */
1847 }
1848 /* zero-length writes at ->s_maxbytes are OK */
1849 }
1854 #ifdef CONFIG_BLOCK
1855 loff_t isize;
1862 }
1866 #else
1868 #endif
1869 }
1871 }
1877 {
1889 again:
1896 /*
1897 * There is no way to resolve a short write situation
1898 * for a !Uptodate page (except by double copying in
1899 * the caller done by generic_perform_write_2copy).
1900 *
1901 * Instead, we have to bring it uptodate here.
1902 */
1909 }
1911 }
1919 }
1921 }
1922 }
1928 {
1951 else
1953 }
1956 }
1959 ssize_t
1963 {
1967 ssize_t written;
1978 }
1980 }
1982 /*
1983 * Sync the fs metadata but not the minor inode changes and
1984 * of course not the data as we did direct DMA for the IO.
1985 * i_mutex is held, which protects generic_osync_inode() from
1986 * livelocking. AIO O_DIRECT ops attempt to sync metadata here.
1987 */
1993 }
1995 }
1998 /*
1999 * Find or create a page at the given pagecache position. Return the locked
2000 * page. This function is specifically for buffered writes.
2001 */
2003 {
2006 repeat:
2020 }
2022 }
2027 {
2047 /*
2048 * a non-NULL src_page indicates that we're doing the
2049 * copy via get_user_pages and kmap.
2050 */
2053 /*
2054 * Bring in the user page that we will copy from _first_.
2055 * Otherwise there's a nasty deadlock on copying from the
2056 * same page as we're writing to, without it being marked
2057 * up-to-date.
2058 *
2059 * Not only is this an optimisation, but it is also required
2060 * to check that the address is actually valid, when atomic
2061 * usercopies are used, below.
2062 */
2066 }
2072 }
2074 /*
2075 * non-uptodate pages cannot cope with short copies, and we
2076 * cannot take a pagefault with the destination page locked.
2077 * So pin the source page to copy it.
2078 */
2087 }
2089 /*
2090 * Cannot get_user_pages with a page locked for the
2091 * same reason as we can't take a page fault with a
2092 * page locked (as explained below).
2093 */
2101 }
2105 /*
2106 * Can't handle the page going uptodate here, because
2107 * that means we would use non-atomic usercopies, which
2108 * zero out the tail of the page, which can cause
2109 * zeroes to become transiently visible. We could just
2110 * use a non-zeroing copy, but the APIs aren't too
2111 * consistent.
2112 */
2118 }
2119 }
2126 /*
2127 * Must not enter the pagefault handler here, because
2128 * we hold the page lock, so we might recursively
2129 * deadlock on the same lock, or get an ABBA deadlock
2130 * against a different lock, or against the mmap_sem
2131 * (which nests outside the page lock). So increment
2132 * preempt count, and use _atomic usercopies.
2133 *
2134 * The page is uptodate so we are OK to encounter a
2135 * short copy: if unmodified parts of the page are
2136 * marked dirty and written out to disk, it doesn't
2137 * really matter.
2138 */
2151 }
2174 fs_write_aop_error:
2180 /*
2181 * prepare_write() may have instantiated a few blocks
2182 * outside i_size. Trim these off again. Don't need
2183 * i_size_read because we hold i_mutex.
2184 */
2191 }
2195 {
2202 /*
2203 * Copies from kernel address space cannot fail (NFSD is a big user).
2204 */
2221 again:
2223 /*
2224 * Bring in the user page that we will copy from _first_.
2225 * Otherwise there's a nasty deadlock on copying from the
2226 * same page as we're writing to, without it being marked
2227 * up-to-date.
2228 *
2229 * Not only is this an optimisation, but it is also required
2230 * to check that the address is actually valid, when atomic
2231 * usercopies are used, below.
2232 */
2236 }
2257 /*
2258 * If we were unable to copy any data at all, we must
2259 * fall back to a single segment length write.
2260 *
2261 * If we didn't fallback here, we could livelock
2262 * because not all segments in the iov can be copied at
2263 * once without a pagefault.
2264 */
2268 }
2278 }
2280 ssize_t
2284 {
2289 ssize_t status;
2295 else
2302 /*
2303 * For now, when the user asks for O_SYNC, we'll actually give
2304 * O_DSYNC
2305 */
2310 }
2311 }
2313 /*
2314 * If we get here for O_DIRECT writes then we must have fallen through
2315 * to buffered writes (block instantiation inside i_size). So we sync
2316 * the file data here, to try to honour O_DIRECT expectations.
2317 */
2322 }
2325 static ssize_t
2328 {
2334 loff_t pos;
2335 ssize_t written;
2336 ssize_t err;
2348 /* We can write back this queue in page reclaim */
2365 /* coalesce the iovecs and go direct-to-BIO for O_DIRECT */
2367 loff_t endbyte;
2368 ssize_t written_buffered;
2374 /*
2375 * direct-io write to a hole: fall through to buffered I/O
2376 * for completing the rest of the request.
2377 */
2382 written);
2383 /*
2384 * If generic_file_buffered_write() retuned a synchronous error
2385 * then we want to return the number of bytes which were
2386 * direct-written, or the error code if that was zero. Note
2387 * that this differs from normal direct-io semantics, which
2388 * will return -EFOO even if some bytes were written.
2389 */
2393 }
2395 /*
2396 * We need to ensure that the page cache pages are written to
2397 * disk and invalidated to preserve the expected O_DIRECT
2398 * semantics.
2399 */
2402 SYNC_FILE_RANGE_WAIT_BEFORE|
2403 SYNC_FILE_RANGE_WRITE|
2404 SYNC_FILE_RANGE_WAIT_AFTER);
2411 /*
2412 * We don't know how much we wrote, so just return
2413 * the number of bytes which were direct-written
2414 */
2415 }
2419 }
2420 out:
2423 }
2427 {
2431 ssize_t ret;
2439 ssize_t err;
2444 }
2446 }
2451 {
2455 ssize_t ret;
2465 ssize_t err;
2470 }
2472 }
2475 /*
2476 * Called under i_mutex for writes to S_ISREG files. Returns -EIO if something
2477 * went wrong during pagecache shootdown.
2478 */
2479 static ssize_t
2482 {
2485 ssize_t retval;
2489 /*
2490 * If it's a write, unmap all mmappings of the file up-front. This
2491 * will cause any pte dirty bits to be propagated into the pageframes
2492 * for the subsequent filemap_write_and_wait().
2493 */
2499 }
2505 /*
2506 * After a write we want buffered reads to be sure to go to disk to get
2507 * the new data. We invalidate clean cached page from the region we're
2508 * about to write. We do this *before* the write so that we can return
2509 * -EIO without clobbering -EIOCBQUEUED from ->direct_IO().
2510 */
2516 }
2520 /*
2521 * Finally, try again to invalidate clean pages which might have been
2522 * cached by non-direct readahead, or faulted in by get_user_pages()
2523 * if the source of the write was an mmap'ed region of the file
2524 * we're writing. Either one is a pretty crazy thing to do,
2525 * so we don't support it 100%. If this invalidation
2526 * fails, tough, the write still worked...
2527 */
2530 }
2531 out:
2533 }
2535 /**
2536 * try_to_release_page() - release old fs-specific metadata on a page
2537 *
2538 * @page: the page which the kernel is trying to free
2539 * @gfp_mask: memory allocation flags (and I/O mode)
2540 *
2541 * The address_space is to try to release any data against the page
2542 * (presumably at page->private). If the release was successful, return `1'.
2543 * Otherwise return zero.
2544 *
2545 * The @gfp_mask argument specifies whether I/O may be performed to release
2546 * this page (__GFP_IO), and whether the call may block (__GFP_WAIT).
2547 *
2548 * NOTE: @gfp_mask may go away, and this function may become non-blocking.
2549 */
2551 {
2561 }