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1 /*
2 * linux/mm/swap.c
3 *
4 * Copyright (C) 1991, 1992, 1993, 1994 Linus Torvalds
5 */
7 /*
8 * This file contains the default values for the operation of the
9 * Linux VM subsystem. Fine-tuning documentation can be found in
10 * Documentation/sysctl/vm.txt.
11 * Started 18.12.91
12 * Swap aging added 23.2.95, Stephen Tweedie.
13 * Buffermem limits added 12.3.98, Rik van Riel.
14 */
16 #include <linux/mm.h>
17 #include <linux/sched.h>
18 #include <linux/kernel_stat.h>
19 #include <linux/swap.h>
20 #include <linux/mman.h>
21 #include <linux/pagemap.h>
22 #include <linux/pagevec.h>
23 #include <linux/init.h>
24 #include <linux/export.h>
25 #include <linux/mm_inline.h>
26 #include <linux/percpu_counter.h>
27 #include <linux/percpu.h>
28 #include <linux/cpu.h>
29 #include <linux/notifier.h>
30 #include <linux/backing-dev.h>
31 #include <linux/memcontrol.h>
32 #include <linux/gfp.h>
33 #include <linux/uio.h>
34 #include <linux/hugetlb.h>
38 #define CREATE_TRACE_POINTS
39 #include <trace/events/pagemap.h>
41 /* How many pages do we try to swap or page in/out together? */
48 /*
49 * This path almost never happens for VM activity - pages are normally
50 * freed via pagevecs. But it gets used by networking.
51 */
53 {
65 }
67 }
70 {
73 }
76 {
79 /*
80 * __page_cache_release() is supposed to be called for thp, not for
81 * hugetlb. This is because hugetlb page does never have PageLRU set
82 * (it's never listed to any LRU lists) and no memcg routines should
83 * be called for hugetlb (it has a separate hugetlb_cgroup.)
84 */
89 }
91 /**
92 * Two special cases here: we could avoid taking compound_lock_irqsave
93 * and could skip the tail refcounting(in _mapcount).
94 *
95 * 1. Hugetlbfs page:
96 *
97 * PageHeadHuge will remain true until the compound page
98 * is released and enters the buddy allocator, and it could
99 * not be split by __split_huge_page_refcount().
100 *
101 * So if we see PageHeadHuge set, and we have the tail page pin,
102 * then we could safely put head page.
103 *
104 * 2. Slab THP page:
105 *
106 * PG_slab is cleared before the slab frees the head page, and
107 * tail pin cannot be the last reference left on the head page,
108 * because the slab code is free to reuse the compound page
109 * after a kfree/kmem_cache_free without having to check if
110 * there's any tail pin left. In turn all tail pinsmust be always
111 * released while the head is still pinned by the slab code
112 * and so we know PG_slab will be still set too.
113 *
114 * So if we see PageSlab set, and we have the tail page pin,
115 * then we could safely put head page.
116 */
117 static __always_inline
119 {
120 /*
121 * If @page is a THP tail, we must read the tail page
122 * flags after the head page flags. The
123 * __split_huge_page_refcount side enforces write memory barriers
124 * between clearing PageTail and before the head page
125 * can be freed and reallocated.
126 */
129 /*
130 * __split_huge_page_refcount cannot race
131 * here, see the comment above this function.
132 */
135 /*
136 * If this is the tail of a slab THP page,
137 * the tail pin must not be the last reference
138 * held on the page, because the PG_slab cannot
139 * be cleared before all tail pins (which skips
140 * the _mapcount tail refcounting) have been
141 * released.
142 *
143 * If this is the tail of a hugetlbfs page,
144 * the tail pin may be the last reference on
145 * the page instead, because PageHeadHuge will
146 * not go away until the compound page enters
147 * the buddy allocator.
148 */
151 }
153 /*
154 * __split_huge_page_refcount run before us,
155 * @page was a THP tail. The split @page_head
156 * has been freed and reallocated as slab or
157 * hugetlbfs page of smaller order (only
158 * possible if reallocated as slab on x86).
159 */
162 }
164 static __always_inline
166 {
170 /*
171 * @page_head wasn't a dangling pointer but it may not
172 * be a head page anymore by the time we obtain the
173 * lock. That is ok as long as it can't be freed from
174 * under us.
175 */
178 /* __split_huge_page_refcount run before us */
181 /*
182 * The @page_head may have been freed
183 * and reallocated as a compound page
184 * of smaller order and then freed
185 * again. All we know is that it
186 * cannot have become: a THP page, a
187 * compound page of higher order, a
188 * tail page. That is because we
189 * still hold the refcount of the
190 * split THP tail and page_head was
191 * the THP head before the split.
192 */
195 else
197 }
198 out_put_single:
202 }
204 /*
205 * We can release the refcount taken by
206 * get_page_unless_zero() now that
207 * __split_huge_page_refcount() is blocked on the
208 * compound_lock.
209 */
212 /* __split_huge_page_refcount will wait now */
222 else
224 }
226 /* @page_head is a dangling pointer */
229 }
230 }
233 {
236 /*
237 * We see the PageCompound set and PageTail not set, so @page maybe:
238 * 1. hugetlbfs head page, or
239 * 2. THP head page.
240 */
243 /*
244 * By the time all refcounts have been released
245 * split_huge_page cannot run anymore from under us.
246 */
249 else
251 }
253 }
255 /*
256 * We see the PageCompound set and PageTail set, so @page maybe:
257 * 1. a tail hugetlbfs page, or
258 * 2. a tail THP page, or
259 * 3. a split THP page.
260 *
261 * Case 3 is possible, as we may race with
262 * __split_huge_page_refcount tearing down a THP page.
263 */
267 else
269 }
272 {
277 }
280 /*
281 * This function is exported but must not be called by anything other
282 * than get_page(). It implements the slow path of get_page().
283 */
285 {
286 /*
287 * This takes care of get_page() if run on a tail page
288 * returned by one of the get_user_pages/follow_page variants.
289 * get_user_pages/follow_page itself doesn't need the compound
290 * lock because it runs __get_page_tail_foll() under the
291 * proper PT lock that already serializes against
292 * split_huge_page().
293 */
298 /* Ref to put_compound_page() comment. */
302 /*
303 * This is a hugetlbfs page or a slab
304 * page. __split_huge_page_refcount
305 * cannot race here.
306 */
311 /*
312 * __split_huge_page_refcount run
313 * before us, "page" was a THP
314 * tail. The split page_head has been
315 * freed and reallocated as slab or
316 * hugetlbfs page of smaller order
317 * (only possible if reallocated as
318 * slab on x86).
319 */
321 }
322 }
326 /*
327 * page_head wasn't a dangling pointer but it
328 * may not be a head page anymore by the time
329 * we obtain the lock. That is ok as long as it
330 * can't be freed from under us.
331 */
333 /* here __split_huge_page_refcount won't run anymore */
337 }
341 }
343 }
346 /**
347 * put_pages_list() - release a list of pages
348 * @pages: list of pages threaded on page->lru
349 *
350 * Release a list of pages which are strung together on page.lru. Currently
351 * used by read_cache_pages() and related error recovery code.
352 */
354 {
361 }
362 }
365 /*
366 * get_kernel_pages() - pin kernel pages in memory
367 * @kiov: An array of struct kvec structures
368 * @nr_segs: number of segments to pin
369 * @write: pinning for read/write, currently ignored
370 * @pages: array that receives pointers to the pages pinned.
371 * Should be at least nr_segs long.
372 *
373 * Returns number of pages pinned. This may be fewer than the number
374 * requested. If nr_pages is 0 or negative, returns 0. If no pages
375 * were pinned, returns -errno. Each page returned must be released
376 * with a put_page() call when it is finished with.
377 */
380 {
389 }
392 }
395 /*
396 * get_kernel_page() - pin a kernel page in memory
397 * @start: starting kernel address
398 * @write: pinning for read/write, currently ignored
399 * @pages: array that receives pointer to the page pinned.
400 * Must be at least nr_segs long.
401 *
402 * Returns 1 if page is pinned. If the page was not pinned, returns
403 * -errno. The page returned must be released with a put_page() call
404 * when it is finished with.
405 */
407 {
411 };
414 }
420 {
435 }
439 }
444 }
448 {
455 }
456 }
458 /*
459 * pagevec_move_tail() must be called with IRQ disabled.
460 * Otherwise this may cause nasty races.
461 */
463 {
468 }
470 /*
471 * Writeback is about to end against a page which has been marked for immediate
472 * reclaim. If it still appears to be reclaimable, move it to the tail of the
473 * inactive list.
474 */
476 {
488 }
489 }
493 {
499 }
503 {
516 }
517 }
519 #ifdef CONFIG_SMP
523 {
528 }
531 {
533 }
536 {
544 }
545 }
547 #else
549 {
550 }
553 {
555 }
558 {
564 }
565 #endif
568 {
572 /*
573 * Search backwards on the optimistic assumption that the page being
574 * activated has just been added to this pagevec. Note that only
575 * the local pagevec is examined as a !PageLRU page could be in the
576 * process of being released, reclaimed, migrated or on a remote
577 * pagevec that is currently being drained. Furthermore, marking
578 * a remote pagevec's page PageActive potentially hits a race where
579 * a page is marked PageActive just after it is added to the inactive
580 * list causing accounting errors and BUG_ON checks to trigger.
581 */
588 }
589 }
592 }
594 /*
595 * Mark a page as having seen activity.
596 *
597 * inactive,unreferenced -> inactive,referenced
598 * inactive,referenced -> active,unreferenced
599 * active,unreferenced -> active,referenced
600 *
601 * When a newly allocated page is not yet visible, so safe for non-atomic ops,
602 * __SetPageReferenced(page) may be substituted for mark_page_accessed(page).
603 */
605 {
609 /*
610 * If the page is on the LRU, queue it for activation via
611 * activate_page_pvecs. Otherwise, assume the page is on a
612 * pagevec, mark it active and it'll be moved to the active
613 * LRU on the next drain.
614 */
617 else
624 }
625 }
629 {
637 }
639 /**
640 * lru_cache_add: add a page to the page lists
641 * @page: the page to add
642 */
644 {
648 }
651 {
655 }
658 /**
659 * lru_cache_add - add a page to a page list
660 * @page: the page to be added to the LRU.
661 *
662 * Queue the page for addition to the LRU via pagevec. The decision on whether
663 * to add the page to the [in]active [file|anon] list is deferred until the
664 * pagevec is drained. This gives a chance for the caller of lru_cache_add()
665 * have the page added to the active list using mark_page_accessed().
666 */
668 {
672 }
674 /**
675 * add_page_to_unevictable_list - add a page to the unevictable list
676 * @page: the page to be added to the unevictable list
677 *
678 * Add page directly to its zone's unevictable list. To avoid races with
679 * tasks that might be making the page evictable, through eg. munlock,
680 * munmap or exit, while it's not on the lru, we want to add the page
681 * while it's locked or otherwise "invisible" to other tasks. This is
682 * difficult to do when using the pagevec cache, so bypass that.
683 */
685 {
696 }
698 /**
699 * lru_cache_add_active_or_unevictable
700 * @page: the page to be added to LRU
701 * @vma: vma in which page is mapped for determining reclaimability
702 *
703 * Place @page on the active or unevictable LRU list, depending on its
704 * evictability. Note that if the page is not evictable, it goes
705 * directly back onto it's zone's unevictable list, it does NOT use a
706 * per cpu pagevec.
707 */
710 {
717 }
720 /*
721 * We use the irq-unsafe __mod_zone_page_stat because this
722 * counter is not modified from interrupt context, and the pte
723 * lock is held(spinlock), which implies preemption disabled.
724 */
728 }
730 }
732 /*
733 * If the page can not be invalidated, it is moved to the
734 * inactive list to speed up its reclaim. It is moved to the
735 * head of the list, rather than the tail, to give the flusher
736 * threads some time to write it out, as this is much more
737 * effective than the single-page writeout from reclaim.
738 *
739 * If the page isn't page_mapped and dirty/writeback, the page
740 * could reclaim asap using PG_reclaim.
741 *
742 * 1. active, mapped page -> none
743 * 2. active, dirty/writeback page -> inactive, head, PG_reclaim
744 * 3. inactive, mapped page -> none
745 * 4. inactive, dirty/writeback page -> inactive, head, PG_reclaim
746 * 5. inactive, clean -> inactive, tail
747 * 6. Others -> none
748 *
749 * In 4, why it moves inactive's head, the VM expects the page would
750 * be write it out by flusher threads as this is much more effective
751 * than the single-page writeout from reclaim.
752 */
755 {
765 /* Some processes are using the page */
779 /*
780 * PG_reclaim could be raced with end_page_writeback
781 * It can make readahead confusing. But race window
782 * is _really_ small and it's non-critical problem.
783 */
786 /*
787 * The page's writeback ends up during pagevec
788 * We moves tha page into tail of inactive.
789 */
792 }
797 }
799 /*
800 * Drain pages out of the cpu's pagevecs.
801 * Either "cpu" is the current CPU, and preemption has already been
802 * disabled; or "cpu" is being hot-unplugged, and is already dead.
803 */
805 {
815 /* No harm done if a racing interrupt already did this */
819 }
826 }
828 /**
829 * deactivate_file_page - forcefully deactivate a file page
830 * @page: page to deactivate
831 *
832 * This function hints the VM that @page is a good reclaim candidate,
833 * for example if its invalidation fails due to the page being dirty
834 * or under writeback.
835 */
837 {
838 /*
839 * In a workload with many unevictable page such as mprotect,
840 * unevictable page deactivation for accelerating reclaim is pointless.
841 */
851 }
852 }
855 {
858 }
861 {
863 }
868 {
887 }
888 }
895 }
897 /**
898 * release_pages - batched page_cache_release()
899 * @pages: array of pages to release
900 * @nr: number of pages
901 * @cold: whether the pages are cache cold
902 *
903 * Decrement the reference count on all the pages in @pages. If it
904 * fell to zero, remove the page from the LRU and free it.
905 */
907 {
922 }
925 }
927 /*
928 * Make sure the IRQ-safe lock-holding time does not get
929 * excessive with a continuous string of pages from the
930 * same zone. The lock is held only if zone != NULL.
931 */
935 }
946 flags);
950 }
956 }
958 /* Clear Active bit in case of parallel mark_page_accessed */
962 }
968 }
971 /*
972 * The pages which we're about to release may be in the deferred lru-addition
973 * queues. That would prevent them from really being freed right now. That's
974 * OK from a correctness point of view but is inefficient - those pages may be
975 * cache-warm and we want to give them back to the page allocator ASAP.
976 *
977 * So __pagevec_release() will drain those queues here. __pagevec_lru_add()
978 * and __pagevec_lru_add_active() call release_pages() directly to avoid
979 * mutual recursion.
980 */
982 {
986 }
989 #ifdef CONFIG_TRANSPARENT_HUGEPAGE
990 /* used by __split_huge_page_refcount() */
993 {
1008 /* page reclaim is reclaiming a huge page */
1013 /*
1014 * Head page has not yet been counted, as an hpage,
1015 * so we must account for each subpage individually.
1016 *
1017 * Use the standard add function to put page_tail on the list,
1018 * but then correct its position so they all end up in order.
1019 */
1023 }
1027 }
1032 {
1043 }
1045 /*
1046 * Add the passed pages to the LRU, then drop the caller's refcount
1047 * on them. Reinitialises the caller's pagevec.
1048 */
1050 {
1052 }
1055 /**
1056 * pagevec_lookup_entries - gang pagecache lookup
1057 * @pvec: Where the resulting entries are placed
1058 * @mapping: The address_space to search
1059 * @start: The starting entry index
1060 * @nr_entries: The maximum number of entries
1061 * @indices: The cache indices corresponding to the entries in @pvec
1062 *
1063 * pagevec_lookup_entries() will search for and return a group of up
1064 * to @nr_entries pages and shadow entries in the mapping. All
1065 * entries are placed in @pvec. pagevec_lookup_entries() takes a
1066 * reference against actual pages in @pvec.
1067 *
1068 * The search returns a group of mapping-contiguous entries with
1069 * ascending indexes. There may be holes in the indices due to
1070 * not-present entries.
1071 *
1072 * pagevec_lookup_entries() returns the number of entries which were
1073 * found.
1074 */
1079 {
1083 }
1085 /**
1086 * pagevec_remove_exceptionals - pagevec exceptionals pruning
1087 * @pvec: The pagevec to prune
1088 *
1089 * pagevec_lookup_entries() fills both pages and exceptional radix
1090 * tree entries into the pagevec. This function prunes all
1091 * exceptionals from @pvec without leaving holes, so that it can be
1092 * passed on to page-only pagevec operations.
1093 */
1095 {
1102 }
1104 }
1106 /**
1107 * pagevec_lookup - gang pagecache lookup
1108 * @pvec: Where the resulting pages are placed
1109 * @mapping: The address_space to search
1110 * @start: The starting page index
1111 * @nr_pages: The maximum number of pages
1112 *
1113 * pagevec_lookup() will search for and return a group of up to @nr_pages pages
1114 * in the mapping. The pages are placed in @pvec. pagevec_lookup() takes a
1115 * reference against the pages in @pvec.
1116 *
1117 * The search returns a group of mapping-contiguous pages with ascending
1118 * indexes. There may be holes in the indices due to not-present pages.
1119 *
1120 * pagevec_lookup() returns the number of pages which were found.
1121 */
1124 {
1127 }
1132 {
1136 }
1139 /*
1140 * Perform any setup for the swap system
1141 */
1143 {
1145 #ifdef CONFIG_SWAP
1150 #endif
1152 /* Use a smaller cluster for small-memory machines */
1155 else
1157 /*
1158 * Right now other parts of the system means that we
1159 * _really_ don't want to cluster much more
1160 */
1161 }