| blob | c8454e06b6c84b424de3952c567fbbcc8264ff75 |
1 /*
2 * mm/rmap.c - physical to virtual reverse mappings
3 *
4 * Copyright 2001, Rik van Riel <riel@conectiva.com.br>
5 * Released under the General Public License (GPL).
6 *
7 * Simple, low overhead reverse mapping scheme.
8 * Please try to keep this thing as modular as possible.
9 *
10 * Provides methods for unmapping each kind of mapped page:
11 * the anon methods track anonymous pages, and
12 * the file methods track pages belonging to an inode.
13 *
14 * Original design by Rik van Riel <riel@conectiva.com.br> 2001
15 * File methods by Dave McCracken <dmccr@us.ibm.com> 2003, 2004
16 * Anonymous methods by Andrea Arcangeli <andrea@suse.de> 2004
17 * Contributions by Hugh Dickins 2003, 2004
18 */
20 /*
21 * Lock ordering in mm:
22 *
23 * inode->i_mutex (while writing or truncating, not reading or faulting)
24 * mm->mmap_sem
25 * page->flags PG_locked (lock_page)
26 * mapping->i_mmap_mutex
27 * anon_vma->mutex
28 * mm->page_table_lock or pte_lock
29 * zone->lru_lock (in mark_page_accessed, isolate_lru_page)
30 * swap_lock (in swap_duplicate, swap_info_get)
31 * mmlist_lock (in mmput, drain_mmlist and others)
32 * mapping->private_lock (in __set_page_dirty_buffers)
33 * inode->i_lock (in set_page_dirty's __mark_inode_dirty)
34 * bdi.wb->list_lock (in set_page_dirty's __mark_inode_dirty)
35 * sb_lock (within inode_lock in fs/fs-writeback.c)
36 * mapping->tree_lock (widely used, in set_page_dirty,
37 * in arch-dependent flush_dcache_mmap_lock,
38 * within bdi.wb->list_lock in __sync_single_inode)
39 *
40 * anon_vma->mutex,mapping->i_mutex (memory_failure, collect_procs_anon)
41 * ->tasklist_lock
42 * pte map lock
43 */
45 #include <linux/mm.h>
46 #include <linux/pagemap.h>
47 #include <linux/swap.h>
48 #include <linux/swapops.h>
49 #include <linux/slab.h>
50 #include <linux/init.h>
51 #include <linux/ksm.h>
52 #include <linux/rmap.h>
53 #include <linux/rcupdate.h>
54 #include <linux/export.h>
55 #include <linux/memcontrol.h>
56 #include <linux/mmu_notifier.h>
57 #include <linux/migrate.h>
58 #include <linux/hugetlb.h>
60 #include <asm/tlbflush.h>
68 {
74 /*
75 * Initialise the anon_vma root to point to itself. If called
76 * from fork, the root will be reset to the parents anon_vma.
77 */
79 }
82 }
85 {
88 /*
89 * Synchronize against page_lock_anon_vma() such that
90 * we can safely hold the lock without the anon_vma getting
91 * freed.
92 *
93 * Relies on the full mb implied by the atomic_dec_and_test() from
94 * put_anon_vma() against the acquire barrier implied by
95 * mutex_trylock() from page_lock_anon_vma(). This orders:
96 *
97 * page_lock_anon_vma() VS put_anon_vma()
98 * mutex_trylock() atomic_dec_and_test()
99 * LOCK MB
100 * atomic_read() mutex_is_locked()
101 *
102 * LOCK should suffice since the actual taking of the lock must
103 * happen _before_ what follows.
104 */
108 }
111 }
114 {
116 }
119 {
121 }
123 /**
124 * anon_vma_prepare - attach an anon_vma to a memory region
125 * @vma: the memory region in question
126 *
127 * This makes sure the memory mapping described by 'vma' has
128 * an 'anon_vma' attached to it, so that we can associate the
129 * anonymous pages mapped into it with that anon_vma.
130 *
131 * The common case will be that we already have one, but if
132 * not we either need to find an adjacent mapping that we
133 * can re-use the anon_vma from (very common when the only
134 * reason for splitting a vma has been mprotect()), or we
135 * allocate a new one.
136 *
137 * Anon-vma allocations are very subtle, because we may have
138 * optimistically looked up an anon_vma in page_lock_anon_vma()
139 * and that may actually touch the spinlock even in the newly
140 * allocated vma (it depends on RCU to make sure that the
141 * anon_vma isn't actually destroyed).
142 *
143 * As a result, we need to do proper anon_vma locking even
144 * for the new allocation. At the same time, we do not want
145 * to do any locking for the common case of already having
146 * an anon_vma.
147 *
148 * This must be called with the mmap_sem held for reading.
149 */
151 {
171 }
174 /* page_table_lock to protect against threads */
184 }
192 }
195 out_enomem_free_avc:
197 out_enomem:
199 }
201 /*
202 * This is a useful helper function for locking the anon_vma root as
203 * we traverse the vma->anon_vma_chain, looping over anon_vma's that
204 * have the same vma.
205 *
206 * Such anon_vma's should have the same root, so you'd expect to see
207 * just a single mutex_lock for the whole traversal.
208 */
209 static inline struct anon_vma *lock_anon_vma_root(struct anon_vma *root, struct anon_vma *anon_vma)
210 {
217 }
219 }
222 {
225 }
230 {
235 /*
236 * It's critical to add new vmas to the tail of the anon_vma,
237 * see comment in huge_memory.c:__split_huge_page().
238 */
240 }
242 /*
243 * Attach the anon_vmas from src to dst.
244 * Returns 0 on success, -ENOMEM on failure.
245 */
247 {
261 }
265 }
269 enomem_failure:
272 }
274 /*
275 * Some rmap walk that needs to find all ptes/hugepmds without false
276 * negatives (like migrate and split_huge_page) running concurrent
277 * with operations that copy or move pagetables (like mremap() and
278 * fork()) to be safe. They depend on the anon_vma "same_anon_vma"
279 * list to be in a certain order: the dst_vma must be placed after the
280 * src_vma in the list. This is always guaranteed by fork() but
281 * mremap() needs to call this function to enforce it in case the
282 * dst_vma isn't newly allocated and chained with the anon_vma_clone()
283 * function but just an extension of a pre-existing vma through
284 * vma_merge.
285 *
286 * NOTE: the same_anon_vma list can still be changed by other
287 * processes while mremap runs because mremap doesn't hold the
288 * anon_vma mutex to prevent modifications to the list while it
289 * runs. All we need to enforce is that the relative order of this
290 * process vmas isn't changing (we don't care about other vmas
291 * order). Each vma corresponds to an anon_vma_chain structure so
292 * there's no risk that other processes calling anon_vma_moveto_tail()
293 * and changing the same_anon_vma list under mremap() will screw with
294 * the relative order of this process vmas in the list, because we
295 * they can't alter the order of any vma that belongs to this
296 * process. And there can't be another anon_vma_moveto_tail() running
297 * concurrently with mremap() coming from this process because we hold
298 * the mmap_sem for the whole mremap(). fork() ordering dependency
299 * also shouldn't be affected because fork() only cares that the
300 * parent vmas are placed in the list before the child vmas and
301 * anon_vma_moveto_tail() won't reorder vmas from either the fork()
302 * parent or child.
303 */
305 {
315 }
317 }
319 /*
320 * Attach vma to its own anon_vma, as well as to the anon_vmas that
321 * the corresponding VMA in the parent process is attached to.
322 * Returns 0 on success, non-zero on failure.
323 */
325 {
329 /* Don't bother if the parent process has no anon_vma here. */
333 /*
334 * First, attach the new VMA to the parent VMA's anon_vmas,
335 * so rmap can find non-COWed pages in child processes.
336 */
340 /* Then add our own anon_vma. */
348 /*
349 * The root anon_vma's spinlock is the lock actually used when we
350 * lock any of the anon_vmas in this anon_vma tree.
351 */
353 /*
354 * With refcounts, an anon_vma can stay around longer than the
355 * process it belongs to. The root anon_vma needs to be pinned until
356 * this anon_vma is freed, because the lock lives in the root.
357 */
359 /* Mark this anon_vma as the one where our new (COWed) pages go. */
367 out_error_free_anon_vma:
369 out_error:
372 }
375 {
379 /*
380 * Unlink each anon_vma chained to the VMA. This list is ordered
381 * from newest to oldest, ensuring the root anon_vma gets freed last.
382 */
389 /*
390 * Leave empty anon_vmas on the list - we'll need
391 * to free them outside the lock.
392 */
398 }
401 /*
402 * Iterate the list once more, it now only contains empty and unlinked
403 * anon_vmas, destroy them. Could not do before due to __put_anon_vma()
404 * needing to acquire the anon_vma->root->mutex.
405 */
413 }
414 }
417 {
423 }
426 {
430 }
432 /*
433 * Getting a lock on a stable anon_vma from a page off the LRU is tricky!
434 *
435 * Since there is no serialization what so ever against page_remove_rmap()
436 * the best this function can do is return a locked anon_vma that might
437 * have been relevant to this page.
438 *
439 * The page might have been remapped to a different anon_vma or the anon_vma
440 * returned may already be freed (and even reused).
441 *
442 * In case it was remapped to a different anon_vma, the new anon_vma will be a
443 * child of the old anon_vma, and the anon_vma lifetime rules will therefore
444 * ensure that any anon_vma obtained from the page will still be valid for as
445 * long as we observe page_mapped() [ hence all those page_mapped() tests ].
446 *
447 * All users of this function must be very careful when walking the anon_vma
448 * chain and verify that the page in question is indeed mapped in it
449 * [ something equivalent to page_mapped_in_vma() ].
450 *
451 * Since anon_vma's slab is DESTROY_BY_RCU and we know from page_remove_rmap()
452 * that the anon_vma pointer from page->mapping is valid if there is a
453 * mapcount, we can dereference the anon_vma after observing those.
454 */
456 {
471 }
473 /*
474 * If this page is still mapped, then its anon_vma cannot have been
475 * freed. But if it has been unmapped, we have no security against the
476 * anon_vma structure being freed and reused (for another anon_vma:
477 * SLAB_DESTROY_BY_RCU guarantees that - so the atomic_inc_not_zero()
478 * above cannot corrupt).
479 */
483 }
484 out:
488 }
490 /*
491 * Similar to page_get_anon_vma() except it locks the anon_vma.
492 *
493 * Its a little more complex as it tries to keep the fast path to a single
494 * atomic op -- the trylock. If we fail the trylock, we fall back to getting a
495 * reference like with page_get_anon_vma() and then block on the mutex.
496 */
498 {
513 /*
514 * If the page is still mapped, then this anon_vma is still
515 * its anon_vma, and holding the mutex ensures that it will
516 * not go away, see anon_vma_free().
517 */
521 }
523 }
525 /* trylock failed, we got to sleep */
529 }
535 }
537 /* we pinned the anon_vma, its safe to sleep */
542 /*
543 * Oops, we held the last refcount, release the lock
544 * and bail -- can't simply use put_anon_vma() because
545 * we'll deadlock on the anon_vma_lock() recursion.
546 */
550 }
554 out:
557 }
560 {
562 }
564 /*
565 * At what user virtual address is page expected in @vma?
566 * Returns virtual address or -EFAULT if page's index/offset is not
567 * within the range mapped the @vma.
568 */
571 {
579 /* page should be within @vma mapping range */
581 }
583 }
585 /*
586 * At what user virtual address is page expected in vma?
587 * Caller should check the page is actually part of the vma.
588 */
590 {
593 /*
594 * Note: swapoff's unuse_vma() is more efficient with this
595 * check, and needs it to match anon_vma when KSM is active.
596 */
607 }
609 /*
610 * Check that @page is mapped at @address into @mm.
611 *
612 * If @sync is false, page_check_address may perform a racy check to avoid
613 * the page table lock when the pte is not present (helpful when reclaiming
614 * highly shared pages).
615 *
616 * On success returns with pte mapped and locked.
617 */
620 {
631 }
648 /* Make a quick check before getting the lock */
652 }
655 check:
660 }
663 }
665 /**
666 * page_mapped_in_vma - check whether a page is really mapped in a VMA
667 * @page: the page to test
668 * @vma: the VMA to test
669 *
670 * Returns 1 if the page is mapped into the page tables of the VMA, 0
671 * if the page is not mapped into the page tables of this VMA. Only
672 * valid for normal file or anonymous VMAs.
673 */
675 {
689 }
691 /*
692 * Subfunctions of page_referenced: page_referenced_one called
693 * repeatedly from either page_referenced_anon or page_referenced_file.
694 */
698 {
706 /*
707 * rmap might return false positives; we must filter
708 * these out using page_check_address_pmd().
709 */
711 PAGE_CHECK_ADDRESS_PMD_FLAG);
715 }
722 }
724 /* go ahead even if the pmd is pmd_trans_splitting() */
726 referenced++;
732 /*
733 * rmap might return false positives; we must filter
734 * these out using page_check_address().
735 */
745 }
748 /*
749 * Don't treat a reference through a sequentially read
750 * mapping as such. If the page has been used in
751 * another mapping, we will catch it; if this other
752 * mapping is already gone, the unmap path will have
753 * set PG_referenced or activated the page.
754 */
756 referenced++;
757 }
759 }
761 /* Pretend the page is referenced if the task has the
762 swap token and is in the middle of a page fault. */
765 referenced++;
771 out:
773 }
778 {
794 /*
795 * If we are reclaiming on behalf of a cgroup, skip
796 * counting on behalf of references from different
797 * cgroups
798 */
805 }
809 }
811 /**
812 * page_referenced_file - referenced check for object-based rmap
813 * @page: the page we're checking references on.
814 * @memcg: target memory control group
815 * @vm_flags: collect encountered vma->vm_flags who actually referenced the page
816 *
817 * For an object-based mapped page, find all the places it is mapped and
818 * check/clear the referenced flag. This is done by following the page->mapping
819 * pointer, then walking the chain of vmas it holds. It returns the number
820 * of references it found.
821 *
822 * This function is only called from page_referenced for object-based pages.
823 */
827 {
835 /*
836 * The caller's checks on page->mapping and !PageAnon have made
837 * sure that this is a file page: the check for page->mapping
838 * excludes the case just before it gets set on an anon page.
839 */
842 /*
843 * The page lock not only makes sure that page->mapping cannot
844 * suddenly be NULLified by truncation, it makes sure that the
845 * structure at mapping cannot be freed and reused yet,
846 * so we can safely take mapping->i_mmap_mutex.
847 */
852 /*
853 * i_mmap_mutex does not stabilize mapcount at all, but mapcount
854 * is more likely to be accurate if we note it after spinning.
855 */
862 /*
863 * If we are reclaiming on behalf of a cgroup, skip
864 * counting on behalf of references from different
865 * cgroups
866 */
873 }
877 }
879 /**
880 * page_referenced - test if the page was referenced
881 * @page: the page to test
882 * @is_locked: caller holds lock on the page
883 * @memcg: target memory cgroup
884 * @vm_flags: collect encountered vma->vm_flags who actually referenced the page
885 *
886 * Quick test_and_clear_referenced for all mappings to a page,
887 * returns the number of ptes which referenced the page.
888 */
893 {
902 referenced++;
904 }
905 }
908 vm_flags);
911 vm_flags);
914 vm_flags);
919 referenced++;
920 }
921 out:
923 }
927 {
938 pte_t entry;
946 }
949 out:
951 }
954 {
969 }
970 }
973 }
976 {
987 }
988 }
991 }
994 /**
995 * page_move_anon_rmap - move a page to our anon_vma
996 * @page: the page to move to our anon_vma
997 * @vma: the vma the page belongs to
998 * @address: the user virtual address mapped
999 *
1000 * When a page belongs exclusively to one process after a COW event,
1001 * that page can be moved into the anon_vma that belongs to just that
1002 * process, so the rmap code will not search the parent or sibling
1003 * processes.
1004 */
1007 {
1016 }
1018 /**
1019 * __page_set_anon_rmap - set up new anonymous rmap
1020 * @page: Page to add to rmap
1021 * @vma: VM area to add page to.
1022 * @address: User virtual address of the mapping
1023 * @exclusive: the page is exclusively owned by the current process
1024 */
1027 {
1035 /*
1036 * If the page isn't exclusively mapped into this vma,
1037 * we must use the _oldest_ possible anon_vma for the
1038 * page mapping!
1039 */
1046 }
1048 /**
1049 * __page_check_anon_rmap - sanity check anonymous rmap addition
1050 * @page: the page to add the mapping to
1051 * @vma: the vm area in which the mapping is added
1052 * @address: the user virtual address mapped
1053 */
1056 {
1057 #ifdef CONFIG_DEBUG_VM
1058 /*
1059 * The page's anon-rmap details (mapping and index) are guaranteed to
1060 * be set up correctly at this point.
1061 *
1062 * We have exclusion against page_add_anon_rmap because the caller
1063 * always holds the page locked, except if called from page_dup_rmap,
1064 * in which case the page is already known to be setup.
1065 *
1066 * We have exclusion against page_add_new_anon_rmap because those pages
1067 * are initially only visible via the pagetables, and the pte is locked
1068 * over the call to page_add_new_anon_rmap.
1069 */
1072 #endif
1073 }
1075 /**
1076 * page_add_anon_rmap - add pte mapping to an anonymous page
1077 * @page: the page to add the mapping to
1078 * @vma: the vm area in which the mapping is added
1079 * @address: the user virtual address mapped
1080 *
1081 * The caller needs to hold the pte lock, and the page must be locked in
1082 * the anon_vma case: to serialize mapping,index checking after setting,
1083 * and to ensure that PageAnon is not being upgraded racily to PageKsm
1084 * (but PageKsm is never downgraded to PageAnon).
1085 */
1088 {
1090 }
1092 /*
1093 * Special version of the above for do_swap_page, which often runs
1094 * into pages that are exclusively owned by the current process.
1095 * Everybody else should continue to use page_add_anon_rmap above.
1096 */
1099 {
1104 else
1106 NR_ANON_TRANSPARENT_HUGEPAGES);
1107 }
1112 /* address might be in next vma when migration races vma_adjust */
1115 else
1117 }
1119 /**
1120 * page_add_new_anon_rmap - add pte mapping to a new anonymous page
1121 * @page: the page to add the mapping to
1122 * @vma: the vm area in which the mapping is added
1123 * @address: the user virtual address mapped
1124 *
1125 * Same as page_add_anon_rmap but must only be called on *new* pages.
1126 * This means the inc-and-test can be bypassed.
1127 * Page does not have to be locked.
1128 */
1131 {
1137 else
1142 else
1144 }
1146 /**
1147 * page_add_file_rmap - add pte mapping to a file page
1148 * @page: the page to add the mapping to
1149 *
1150 * The caller needs to hold the pte lock.
1151 */
1153 {
1157 }
1158 }
1160 /**
1161 * page_remove_rmap - take down pte mapping from a page
1162 * @page: page to remove mapping from
1163 *
1164 * The caller needs to hold the pte lock.
1165 */
1167 {
1168 /* page still mapped by someone else? */
1172 /*
1173 * Now that the last pte has gone, s390 must transfer dirty
1174 * flag from storage key to struct page. We can usually skip
1175 * this if the page is anon, so about to be freed; but perhaps
1176 * not if it's in swapcache - there might be another pte slot
1177 * containing the swap entry, but page not yet written to swap.
1178 */
1182 /*
1183 * Hugepages are not counted in NR_ANON_PAGES nor NR_FILE_MAPPED
1184 * and not charged by memcg for now.
1185 */
1192 else
1194 NR_ANON_TRANSPARENT_HUGEPAGES);
1198 }
1199 /*
1200 * It would be tidy to reset the PageAnon mapping here,
1201 * but that might overwrite a racing page_add_anon_rmap
1202 * which increments mapcount after us but sets mapping
1203 * before us: so leave the reset to free_hot_cold_page,
1204 * and remember that it's only reliable while mapped.
1205 * Leaving it set also helps swapoff to reinstate ptes
1206 * faster for those pages still in swapcache.
1207 */
1208 }
1210 /*
1211 * Subfunctions of try_to_unmap: try_to_unmap_one called
1212 * repeatedly from try_to_unmap_ksm, try_to_unmap_anon or try_to_unmap_file.
1213 */
1216 {
1219 pte_t pteval;
1227 /*
1228 * If the page is mlock()d, we cannot swap it out.
1229 * If it's recently referenced (perhaps page_referenced
1230 * skipped over this mm) then we should reactivate it.
1231 */
1238 }
1243 }
1244 }
1246 /* Nuke the page table entry. */
1250 /* Move the dirty bit to the physical page now the pte is gone. */
1254 /* Update high watermark before we lower rss */
1260 else
1268 /*
1269 * Store the swap location in the pte.
1270 * See handle_pte_fault() ...
1271 */
1276 }
1282 }
1286 /*
1287 * Store the pfn of the page in a special migration
1288 * pte. do_swap_page() will wait until the migration
1289 * pte is removed and then restart fault handling.
1290 */
1293 }
1297 /* Establish migration entry for a file page */
1298 swp_entry_t entry;
1307 out_unmap:
1309 out:
1312 out_mlock:
1316 /*
1317 * We need mmap_sem locking, Otherwise VM_LOCKED check makes
1318 * unstable result and race. Plus, We can't wait here because
1319 * we now hold anon_vma->mutex or mapping->i_mmap_mutex.
1320 * if trylock failed, the page remain in evictable lru and later
1321 * vmscan could retry to move the page to unevictable lru if the
1322 * page is actually mlocked.
1323 */
1328 }
1330 }
1332 }
1334 /*
1335 * objrmap doesn't work for nonlinear VMAs because the assumption that
1336 * offset-into-file correlates with offset-into-virtual-addresses does not hold.
1337 * Consequently, given a particular page and its ->index, we cannot locate the
1338 * ptes which are mapping that page without an exhaustive linear search.
1339 *
1340 * So what this code does is a mini "virtual scan" of each nonlinear VMA which
1341 * maps the file to which the target page belongs. The ->vm_private_data field
1342 * holds the current cursor into that scan. Successive searches will circulate
1343 * around the vma's virtual address space.
1344 *
1345 * So as more replacement pressure is applied to the pages in a nonlinear VMA,
1346 * more scanning pressure is placed against them as well. Eventually pages
1347 * will become fully unmapped and are eligible for eviction.
1348 *
1349 * For very sparsely populated VMAs this is a little inefficient - chances are
1350 * there there won't be many ptes located within the scan cluster. In this case
1351 * maybe we could scan further - to the end of the pte page, perhaps.
1352 *
1353 * Mlocked pages: check VM_LOCKED under mmap_sem held for read, if we can
1354 * acquire it without blocking. If vma locked, mlock the pages in the cluster,
1355 * rather than unmapping them. If we encounter the "check_page" that vmscan is
1356 * trying to unmap, return SWAP_MLOCK, else default SWAP_AGAIN.
1357 */
1358 #define CLUSTER_SIZE min(32*PAGE_SIZE, PMD_SIZE)
1359 #define CLUSTER_MASK (~(CLUSTER_SIZE - 1))
1363 {
1369 pte_t pteval;
1396 /*
1397 * If we can acquire the mmap_sem for read, and vma is VM_LOCKED,
1398 * keep the sem while scanning the cluster for mlocking pages.
1399 */
1404 }
1408 /* Update high watermark before we lower rss */
1422 }
1427 /* Nuke the page table entry. */
1431 /* If nonlinear, store the file page offset in the pte. */
1435 /* Move the dirty bit to the physical page now the pte is gone. */
1443 }
1448 }
1451 {
1458 VM_STACK_INCOMPLETE_SETUP)
1462 }
1464 /**
1465 * try_to_unmap_anon - unmap or unlock anonymous page using the object-based
1466 * rmap method
1467 * @page: the page to unmap/unlock
1468 * @flags: action and flags
1469 *
1470 * Find all the mappings of a page using the mapping pointer and the vma chains
1471 * contained in the anon_vma struct it points to.
1472 *
1473 * This function is only called from try_to_unmap/try_to_munlock for
1474 * anonymous pages.
1475 * When called from try_to_munlock(), the mmap_sem of the mm containing the vma
1476 * where the page was found will be held for write. So, we won't recheck
1477 * vm_flags for that VMA. That should be OK, because that vma shouldn't be
1478 * 'LOCKED.
1479 */
1481 {
1494 /*
1495 * During exec, a temporary VMA is setup and later moved.
1496 * The VMA is moved under the anon_vma lock but not the
1497 * page tables leading to a race where migration cannot
1498 * find the migration ptes. Rather than increasing the
1499 * locking requirements of exec(), migration skips
1500 * temporary VMAs until after exec() completes.
1501 */
1512 }
1516 }
1518 /**
1519 * try_to_unmap_file - unmap/unlock file page using the object-based rmap method
1520 * @page: the page to unmap/unlock
1521 * @flags: action and flags
1522 *
1523 * Find all the mappings of a page using the mapping pointer and the vma chains
1524 * contained in the address_space struct it points to.
1525 *
1526 * This function is only called from try_to_unmap/try_to_munlock for
1527 * object-based pages.
1528 * When called from try_to_munlock(), the mmap_sem of the mm containing the vma
1529 * where the page was found will be held for write. So, we won't recheck
1530 * vm_flags for that VMA. That should be OK, because that vma shouldn't be
1531 * 'LOCKED.
1532 */
1534 {
1553 }
1558 /*
1559 * We don't bother to try to find the munlocked page in nonlinears.
1560 * It's costly. Instead, later, page reclaim logic may call
1561 * try_to_unmap(TTU_MUNLOCK) and recover PG_mlocked lazily.
1562 */
1574 }
1579 }
1581 /*
1582 * We don't try to search for this page in the nonlinear vmas,
1583 * and page_referenced wouldn't have found it anyway. Instead
1584 * just walk the nonlinear vmas trying to age and unmap some.
1585 * The mapcount of the page we came in with is irrelevant,
1586 * but even so use it as a guide to how hard we should try?
1587 */
1610 }
1612 }
1617 /*
1618 * Don't loop forever (perhaps all the remaining pages are
1619 * in locked vmas). Reset cursor on all unreserved nonlinear
1620 * vmas, now forgetting on which ones it had fallen behind.
1621 */
1624 out:
1627 }
1629 /**
1630 * try_to_unmap - try to remove all page table mappings to a page
1631 * @page: the page to get unmapped
1632 * @flags: action and flags
1633 *
1634 * Tries to remove all the page table entries which are mapping this
1635 * page, used in the pageout path. Caller must hold the page lock.
1636 * Return values are:
1637 *
1638 * SWAP_SUCCESS - we succeeded in removing all mappings
1639 * SWAP_AGAIN - we missed a mapping, try again later
1640 * SWAP_FAIL - the page is unswappable
1641 * SWAP_MLOCK - page is mlocked.
1642 */
1644 {
1654 else
1659 }
1661 /**
1662 * try_to_munlock - try to munlock a page
1663 * @page: the page to be munlocked
1664 *
1665 * Called from munlock code. Checks all of the VMAs mapping the page
1666 * to make sure nobody else has this page mlocked. The page will be
1667 * returned with PG_mlocked cleared if no other vmas have it mlocked.
1668 *
1669 * Return values are:
1670 *
1671 * SWAP_AGAIN - no vma is holding page mlocked, or,
1672 * SWAP_AGAIN - page mapped in mlocked vma -- couldn't acquire mmap sem
1673 * SWAP_FAIL - page cannot be located at present
1674 * SWAP_MLOCK - page is now mlocked.
1675 */
1677 {
1684 else
1686 }
1689 {
1696 }
1698 #ifdef CONFIG_MIGRATION
1699 /*
1700 * rmap_walk() and its helpers rmap_walk_anon() and rmap_walk_file():
1701 * Called by migrate.c to remove migration ptes, but might be used more later.
1702 */
1705 {
1710 /*
1711 * Note: remove_migration_ptes() cannot use page_lock_anon_vma()
1712 * because that depends on page_mapped(); but not all its usages
1713 * are holding mmap_sem. Users without mmap_sem are required to
1714 * take a reference count to prevent the anon_vma disappearing
1715 */
1728 }
1731 }
1735 {
1752 }
1753 /*
1754 * No nonlinear handling: being always shared, nonlinear vmas
1755 * never contain migration ptes. Decide what to do about this
1756 * limitation to linear when we need rmap_walk() on nonlinear.
1757 */
1760 }
1764 {
1771 else
1773 }
1776 #ifdef CONFIG_HUGETLB_PAGE
1777 /*
1778 * The following three functions are for anonymous (private mapped) hugepages.
1779 * Unlike common anonymous pages, anonymous hugepages have no accounting code
1780 * and no lru code, because we handle hugepages differently from common pages.
1781 */
1784 {
1797 }
1801 {
1807 /* address might be in next vma when migration races vma_adjust */
1811 }
1815 {
1819 }