| blob | 196709f5ee5862753f5f3731bdeab58c2c45c323 |
1 /*
2 * linux/mm/vmscan.c
3 *
4 * Copyright (C) 1991, 1992, 1993, 1994 Linus Torvalds
5 *
6 * Swap reorganised 29.12.95, Stephen Tweedie.
7 * kswapd added: 7.1.96 sct
8 * Removed kswapd_ctl limits, and swap out as many pages as needed
9 * to bring the system back to freepages.high: 2.4.97, Rik van Riel.
10 * Zone aware kswapd started 02/00, Kanoj Sarcar (kanoj@sgi.com).
11 * Multiqueue VM started 5.8.00, Rik van Riel.
12 */
14 #include <linux/mm.h>
15 #include <linux/module.h>
16 #include <linux/gfp.h>
17 #include <linux/kernel_stat.h>
18 #include <linux/swap.h>
19 #include <linux/pagemap.h>
20 #include <linux/init.h>
21 #include <linux/highmem.h>
22 #include <linux/vmstat.h>
23 #include <linux/file.h>
24 #include <linux/writeback.h>
25 #include <linux/blkdev.h>
27 buffer_heads_over_limit */
28 #include <linux/mm_inline.h>
29 #include <linux/backing-dev.h>
30 #include <linux/rmap.h>
31 #include <linux/topology.h>
32 #include <linux/cpu.h>
33 #include <linux/cpuset.h>
34 #include <linux/compaction.h>
35 #include <linux/notifier.h>
36 #include <linux/rwsem.h>
37 #include <linux/delay.h>
38 #include <linux/kthread.h>
39 #include <linux/freezer.h>
40 #include <linux/memcontrol.h>
41 #include <linux/delayacct.h>
42 #include <linux/sysctl.h>
43 #include <linux/oom.h>
44 #include <linux/prefetch.h>
46 #include <asm/tlbflush.h>
47 #include <asm/div64.h>
49 #include <linux/swapops.h>
53 #define CREATE_TRACE_POINTS
54 #include <trace/events/vmscan.h>
57 /* Incremented by the number of inactive pages that were scanned */
60 /* Number of pages freed so far during a call to shrink_zones() */
63 /* How many pages shrink_list() should reclaim */
68 /* This context's GFP mask */
69 gfp_t gfp_mask;
73 /* Can mapped pages be reclaimed? */
76 /* Can pages be swapped as part of reclaim? */
81 /* Scan (total_size >> priority) pages at once */
84 /*
85 * The memory cgroup that hit its limit and as a result is the
86 * primary target of this reclaim invocation.
87 */
90 /*
91 * Nodemask of nodes allowed by the caller. If NULL, all nodes
92 * are scanned.
93 */
95 };
97 #define lru_to_page(_head) (list_entry((_head)->prev, struct page, lru))
99 #ifdef ARCH_HAS_PREFETCH
100 #define prefetch_prev_lru_page(_page, _base, _field) \
101 do { \
102 if ((_page)->lru.prev != _base) { \
103 struct page *prev; \
104 \
105 prev = lru_to_page(&(_page->lru)); \
106 prefetch(&prev->_field); \
107 } \
108 } while (0)
109 #else
110 #define prefetch_prev_lru_page(_page, _base, _field) do { } while (0)
111 #endif
113 #ifdef ARCH_HAS_PREFETCHW
114 #define prefetchw_prev_lru_page(_page, _base, _field) \
115 do { \
116 if ((_page)->lru.prev != _base) { \
117 struct page *prev; \
118 \
119 prev = lru_to_page(&(_page->lru)); \
120 prefetchw(&prev->_field); \
121 } \
122 } while (0)
123 #else
124 #define prefetchw_prev_lru_page(_page, _base, _field) do { } while (0)
125 #endif
127 /*
128 * From 0 .. 100. Higher means more swappy.
129 */
136 #ifdef CONFIG_MEMCG
138 {
140 }
141 #else
143 {
145 }
146 #endif
149 {
154 }
156 /*
157 * Add a shrinker callback to be called from the vm
158 */
160 {
165 }
168 /*
169 * Remove one
170 */
172 {
176 }
182 {
185 }
187 #define SHRINK_BATCH 128
188 /*
189 * Call the shrink functions to age shrinkable caches
190 *
191 * Here we assume it costs one seek to replace a lru page and that it also
192 * takes a seek to recreate a cache object. With this in mind we age equal
193 * percentages of the lru and ageable caches. This should balance the seeks
194 * generated by these structures.
195 *
196 * If the vm encountered mapped pages on the LRU it increase the pressure on
197 * slab to avoid swapping.
198 *
199 * We do weird things to avoid (scanned*seeks*entries) overflowing 32 bits.
200 *
201 * `lru_pages' represents the number of on-LRU pages in all the zones which
202 * are eligible for the caller's allocation attempt. It is used for balancing
203 * slab reclaim versus page reclaim.
204 *
205 * Returns the number of slab objects which we shrunk.
206 */
210 {
218 /* Assume we'll be able to shrink next time */
221 }
237 /*
238 * copy the current shrinker scan count into a local variable
239 * and zero it so that other concurrent shrinker invocations
240 * don't also do this scanning work.
241 */
254 }
256 /*
257 * We need to avoid excessive windup on filesystem shrinkers
258 * due to large numbers of GFP_NOFS allocations causing the
259 * shrinkers to return -1 all the time. This results in a large
260 * nr being built up so when a shrink that can do some work
261 * comes along it empties the entire cache due to nr >>>
262 * max_pass. This is bad for sustaining a working set in
263 * memory.
264 *
265 * Hence only allow the shrinker to scan the entire cache when
266 * a large delta change is calculated directly.
267 */
271 /*
272 * Avoid risking looping forever due to too large nr value:
273 * never try to free more than twice the estimate number of
274 * freeable entries.
275 */
288 batch_size);
297 }
299 /*
300 * move the unused scan count back into the shrinker in a
301 * manner that handles concurrent updates. If we exhausted the
302 * scan, there is no need to do an update.
303 */
307 else
311 }
313 out:
316 }
319 {
320 /*
321 * A freeable page cache page is referenced only by the caller
322 * that isolated the page, the page cache radix tree and
323 * optional buffer heads at page->private.
324 */
326 }
330 {
338 }
340 /*
341 * We detected a synchronous write error writing a page out. Probably
342 * -ENOSPC. We need to propagate that into the address_space for a subsequent
343 * fsync(), msync() or close().
344 *
345 * The tricky part is that after writepage we cannot touch the mapping: nothing
346 * prevents it from being freed up. But we have a ref on the page and once
347 * that page is locked, the mapping is pinned.
348 *
349 * We're allowed to run sleeping lock_page() here because we know the caller has
350 * __GFP_FS.
351 */
354 {
359 }
361 /* possible outcome of pageout() */
363 /* failed to write page out, page is locked */
364 PAGE_KEEP,
365 /* move page to the active list, page is locked */
366 PAGE_ACTIVATE,
367 /* page has been sent to the disk successfully, page is unlocked */
368 PAGE_SUCCESS,
369 /* page is clean and locked */
370 PAGE_CLEAN,
373 /*
374 * pageout is called by shrink_page_list() for each dirty page.
375 * Calls ->writepage().
376 */
379 {
380 /*
381 * If the page is dirty, only perform writeback if that write
382 * will be non-blocking. To prevent this allocation from being
383 * stalled by pagecache activity. But note that there may be
384 * stalls if we need to run get_block(). We could test
385 * PagePrivate for that.
386 *
387 * If this process is currently in __generic_file_aio_write() against
388 * this page's queue, we can perform writeback even if that
389 * will block.
390 *
391 * If the page is swapcache, write it back even if that would
392 * block, for some throttling. This happens by accident, because
393 * swap_backing_dev_info is bust: it doesn't reflect the
394 * congestion state of the swapdevs. Easy to fix, if needed.
395 */
399 /*
400 * Some data journaling orphaned pages can have
401 * page->mapping == NULL while being dirty with clean buffers.
402 */
408 }
409 }
411 }
425 };
434 }
437 /* synchronous write or broken a_ops? */
439 }
443 }
446 }
448 /*
449 * Same as remove_mapping, but if the page is removed from the mapping, it
450 * gets returned with a refcount of 0.
451 */
453 {
458 /*
459 * The non racy check for a busy page.
460 *
461 * Must be careful with the order of the tests. When someone has
462 * a ref to the page, it may be possible that they dirty it then
463 * drop the reference. So if PageDirty is tested before page_count
464 * here, then the following race may occur:
465 *
466 * get_user_pages(&page);
467 * [user mapping goes away]
468 * write_to(page);
469 * !PageDirty(page) [good]
470 * SetPageDirty(page);
471 * put_page(page);
472 * !page_count(page) [good, discard it]
473 *
474 * [oops, our write_to data is lost]
475 *
476 * Reversing the order of the tests ensures such a situation cannot
477 * escape unnoticed. The smp_rmb is needed to ensure the page->flags
478 * load is not satisfied before that of page->_count.
479 *
480 * Note that if SetPageDirty is always performed via set_page_dirty,
481 * and thus under tree_lock, then this ordering is not required.
482 */
485 /* note: atomic_cmpxchg in page_freeze_refs provides the smp_rmb */
489 }
507 }
511 cannot_free:
514 }
516 /*
517 * Attempt to detach a locked page from its ->mapping. If it is dirty or if
518 * someone else has a ref on the page, abort and return 0. If it was
519 * successfully detached, return 1. Assumes the caller has a single ref on
520 * this page.
521 */
523 {
525 /*
526 * Unfreezing the refcount with 1 rather than 2 effectively
527 * drops the pagecache ref for us without requiring another
528 * atomic operation.
529 */
532 }
534 }
536 /**
537 * putback_lru_page - put previously isolated page onto appropriate LRU list
538 * @page: page to be put back to appropriate lru list
539 *
540 * Add previously isolated @page to appropriate LRU list.
541 * Page may still be unevictable for other reasons.
542 *
543 * lru_lock must not be held, interrupts must be enabled.
544 */
546 {
553 redo:
557 /*
558 * For evictable pages, we can use the cache.
559 * In event of a race, worst case is we end up with an
560 * unevictable page on [in]active list.
561 * We know how to handle that.
562 */
566 /*
567 * Put unevictable pages directly on zone's unevictable
568 * list.
569 */
572 /*
573 * When racing with an mlock or AS_UNEVICTABLE clearing
574 * (page is unlocked) make sure that if the other thread
575 * does not observe our setting of PG_lru and fails
576 * isolation/check_move_unevictable_pages,
577 * we see PG_mlocked/AS_UNEVICTABLE cleared below and move
578 * the page back to the evictable list.
579 *
580 * The other side is TestClearPageMlocked() or shmem_lock().
581 */
583 }
585 /*
586 * page's status can change while we move it among lru. If an evictable
587 * page is on unevictable list, it never be freed. To avoid that,
588 * check after we added it to the list, again.
589 */
594 }
595 /* This means someone else dropped this page from LRU
596 * So, it will be freed or putback to LRU again. There is
597 * nothing to do here.
598 */
599 }
607 }
610 PAGEREF_RECLAIM,
611 PAGEREF_RECLAIM_CLEAN,
612 PAGEREF_KEEP,
613 PAGEREF_ACTIVATE,
614 };
618 {
626 /*
627 * Mlock lost the isolation race with us. Let try_to_unmap()
628 * move the page to the unevictable list.
629 */
636 /*
637 * All mapped pages start out with page table
638 * references from the instantiating fault, so we need
639 * to look twice if a mapped file page is used more
640 * than once.
641 *
642 * Mark it and spare it for another trip around the
643 * inactive list. Another page table reference will
644 * lead to its activation.
645 *
646 * Note: the mark is set for activated pages as well
647 * so that recently deactivated but used pages are
648 * quickly recovered.
649 */
655 /*
656 * Activate file-backed executable pages after first usage.
657 */
662 }
664 /* Reclaim if clean, defer dirty pages to writeback */
669 }
671 /*
672 * shrink_page_list() returns the number of reclaimed pages
673 */
681 {
718 /* Double the slab pressure for mapped and swapcache pages */
726 /*
727 * memcg doesn't have any dirty pages throttling so we
728 * could easily OOM just because too many pages are in
729 * writeback and there is nothing else to reclaim.
730 *
731 * Check __GFP_IO, certainly because a loop driver
732 * thread might enter reclaim, and deadlock if it waits
733 * on a page for which it is needed to do the write
734 * (loop masks off __GFP_IO|__GFP_FS for this reason);
735 * but more thought would probably show more reasons.
736 *
737 * Don't require __GFP_FS, since we're not going into
738 * the FS, just waiting on its writeback completion.
739 * Worryingly, ext4 gfs2 and xfs allocate pages with
740 * grab_cache_page_write_begin(,,AOP_FLAG_NOFS), so
741 * testing may_enter_fs here is liable to OOM on them.
742 */
745 /*
746 * This is slightly racy - end_page_writeback()
747 * might have just cleared PageReclaim, then
748 * setting PageReclaim here end up interpreted
749 * as PageReadahead - but that does not matter
750 * enough to care. What we do want is for this
751 * page to have PageReclaim set next time memcg
752 * reclaim reaches the tests above, so it will
753 * then wait_on_page_writeback() to avoid OOM;
754 * and it's also appropriate in global reclaim.
755 */
757 nr_writeback++;
759 }
761 }
774 }
776 /*
777 * Anonymous process memory has backing store?
778 * Try to allocate it some swap space here.
779 */
786 }
790 /*
791 * The page is mapped into the page tables of one or more
792 * processes. Try to unmap it here.
793 */
804 }
805 }
808 nr_dirty++;
810 /*
811 * Only kswapd can writeback filesystem pages to
812 * avoid risk of stack overflow but do not writeback
813 * unless under significant pressure.
814 */
818 /*
819 * Immediately reclaim when written back.
820 * Similar in principal to deactivate_page()
821 * except we already have the page isolated
822 * and know it's dirty
823 */
828 }
837 /* Page is dirty, try to write it out here */
840 nr_congested++;
850 /*
851 * A synchronous write - probably a ramdisk. Go
852 * ahead and try to reclaim the page.
853 */
861 }
862 }
864 /*
865 * If the page has buffers, try to free the buffer mappings
866 * associated with this page. If we succeed we try to free
867 * the page as well.
868 *
869 * We do this even if the page is PageDirty().
870 * try_to_release_page() does not perform I/O, but it is
871 * possible for a page to have PageDirty set, but it is actually
872 * clean (all its buffers are clean). This happens if the
873 * buffers were written out directly, with submit_bh(). ext3
874 * will do this, as well as the blockdev mapping.
875 * try_to_release_page() will discover that cleanness and will
876 * drop the buffers and mark the page clean - it can be freed.
877 *
878 * Rarely, pages can have buffers and no ->mapping. These are
879 * the pages which were not successfully invalidated in
880 * truncate_complete_page(). We try to drop those buffers here
881 * and if that worked, and the page is no longer mapped into
882 * process address space (page_count == 1) it can be freed.
883 * Otherwise, leave the page on the LRU so it is swappable.
884 */
893 /*
894 * rare race with speculative reference.
895 * the speculative reference will free
896 * this page shortly, so we may
897 * increment nr_reclaimed here (and
898 * leave it off the LRU).
899 */
900 nr_reclaimed++;
902 }
903 }
904 }
909 /*
910 * At this point, we have no other references and there is
911 * no way to pick any more up (removed from LRU, removed
912 * from pagecache). Can use non-atomic bitops now (and
913 * we obviously don't have to worry about waking up a process
914 * waiting on the page lock, because there are no references.
915 */
917 free_it:
918 nr_reclaimed++;
920 /*
921 * Is there need to periodically free_page_list? It would
922 * appear not as the counts should be low
923 */
927 cull_mlocked:
934 activate_locked:
935 /* Not a candidate for swapping, so reclaim swap space. */
940 pgactivate++;
941 keep_locked:
943 keep:
946 }
948 /*
949 * Tag a zone as congested if all the dirty pages encountered were
950 * backed by a congested BDI. In this case, reclaimers should just
951 * back off and wait for congestion to clear because further reclaim
952 * will encounter the same problem
953 */
965 }
969 {
974 };
983 }
984 }
992 }
994 /*
995 * Attempt to remove the specified page from its LRU. Only take this page
996 * if it is of the appropriate PageActive status. Pages which are being
997 * freed elsewhere are also ignored.
998 *
999 * page: page to consider
1000 * mode: one of the LRU isolation modes defined above
1001 *
1002 * returns 0 on success, -ve errno on failure.
1003 */
1005 {
1008 /* Only take pages on the LRU. */
1012 /* Compaction should not handle unevictable pages but CMA can do so */
1018 /*
1019 * To minimise LRU disruption, the caller can indicate that it only
1020 * wants to isolate pages it will be able to operate on without
1021 * blocking - clean pages for the most part.
1022 *
1023 * ISOLATE_CLEAN means that only clean pages should be isolated. This
1024 * is used by reclaim when it is cannot write to backing storage
1025 *
1026 * ISOLATE_ASYNC_MIGRATE is used to indicate that it only wants to pages
1027 * that it is possible to migrate without blocking
1028 */
1030 /* All the caller can do on PageWriteback is block */
1037 /* ISOLATE_CLEAN means only clean pages */
1041 /*
1042 * Only pages without mappings or that have a
1043 * ->migratepage callback are possible to migrate
1044 * without blocking
1045 */
1049 }
1050 }
1056 /*
1057 * Be careful not to clear PageLRU until after we're
1058 * sure the page is not being freed elsewhere -- the
1059 * page release code relies on it.
1060 */
1063 }
1066 }
1068 /*
1069 * zone->lru_lock is heavily contended. Some of the functions that
1070 * shrink the lists perform better by taking out a batch of pages
1071 * and working on them outside the LRU lock.
1072 *
1073 * For pagecache intensive workloads, this function is the hottest
1074 * spot in the kernel (apart from copy_*_user functions).
1075 *
1076 * Appropriate locks must be held before calling this function.
1077 *
1078 * @nr_to_scan: The number of pages to look through on the list.
1079 * @lruvec: The LRU vector to pull pages from.
1080 * @dst: The temp list to put pages on to.
1081 * @nr_scanned: The number of pages that were scanned.
1082 * @sc: The scan_control struct for this reclaim session
1083 * @mode: One of the LRU isolation modes
1084 * @lru: LRU list id for isolating
1085 *
1086 * returns how many pages were moved onto *@dst.
1087 */
1092 {
1115 /* else it is being freed elsewhere */
1121 }
1122 }
1128 }
1130 /**
1131 * isolate_lru_page - tries to isolate a page from its LRU list
1132 * @page: page to isolate from its LRU list
1133 *
1134 * Isolates a @page from an LRU list, clears PageLRU and adjusts the
1135 * vmstat statistic corresponding to whatever LRU list the page was on.
1136 *
1137 * Returns 0 if the page was removed from an LRU list.
1138 * Returns -EBUSY if the page was not on an LRU list.
1139 *
1140 * The returned page will have PageLRU() cleared. If it was found on
1141 * the active list, it will have PageActive set. If it was found on
1142 * the unevictable list, it will have the PageUnevictable bit set. That flag
1143 * may need to be cleared by the caller before letting the page go.
1144 *
1145 * The vmstat statistic corresponding to the list on which the page was
1146 * found will be decremented.
1147 *
1148 * Restrictions:
1149 * (1) Must be called with an elevated refcount on the page. This is a
1150 * fundamentnal difference from isolate_lru_pages (which is called
1151 * without a stable reference).
1152 * (2) the lru_lock must not be held.
1153 * (3) interrupts must be enabled.
1154 */
1156 {
1173 }
1175 }
1177 }
1179 /*
1180 * A direct reclaimer may isolate SWAP_CLUSTER_MAX pages from the LRU list and
1181 * then get resheduled. When there are massive number of tasks doing page
1182 * allocation, such sleeping direct reclaimers may keep piling up on each CPU,
1183 * the LRU list will go small and be scanned faster than necessary, leading to
1184 * unnecessary swapping, thrashing and OOM.
1185 */
1188 {
1203 }
1205 /*
1206 * GFP_NOIO/GFP_NOFS callers are allowed to isolate more pages, so they
1207 * won't get blocked by normal direct-reclaimers, forming a circular
1208 * deadlock.
1209 */
1214 }
1218 {
1223 /*
1224 * Put back any unfreeable pages.
1225 */
1237 }
1249 }
1261 }
1262 }
1264 /*
1265 * To save our caller's stack, now use input list for pages to free.
1266 */
1268 }
1270 /*
1271 * shrink_inactive_list() is a helper for shrink_zone(). It returns the number
1272 * of reclaimed pages
1273 */
1277 {
1292 /* We are about to die and free our memory. Return now. */
1295 }
1316 else
1318 }
1334 nr_reclaimed);
1335 else
1337 nr_reclaimed);
1338 }
1348 /*
1349 * If reclaim is isolating dirty pages under writeback, it implies
1350 * that the long-lived page allocation rate is exceeding the page
1351 * laundering rate. Either the global limits are not being effective
1352 * at throttling processes due to the page distribution throughout
1353 * zones or there is heavy usage of a slow backing device. The
1354 * only option is to throttle from reclaim context which is not ideal
1355 * as there is no guarantee the dirtying process is throttled in the
1356 * same way balance_dirty_pages() manages.
1357 *
1358 * This scales the number of dirty pages that must be under writeback
1359 * before throttling depending on priority. It is a simple backoff
1360 * function that has the most effect in the range DEF_PRIORITY to
1361 * DEF_PRIORITY-2 which is the priority reclaim is considered to be
1362 * in trouble and reclaim is considered to be in trouble.
1363 *
1364 * DEF_PRIORITY 100% isolated pages must be PageWriteback to throttle
1365 * DEF_PRIORITY-1 50% must be PageWriteback
1366 * DEF_PRIORITY-2 25% must be PageWriteback, kswapd in trouble
1367 * ...
1368 * DEF_PRIORITY-6 For SWAP_CLUSTER_MAX isolated pages, throttle if any
1369 * isolated page is PageWriteback
1370 */
1381 }
1383 /*
1384 * This moves pages from the active list to the inactive list.
1385 *
1386 * We move them the other way if the page is referenced by one or more
1387 * processes, from rmap.
1388 *
1389 * If the pages are mostly unmapped, the processing is fast and it is
1390 * appropriate to hold zone->lru_lock across the whole operation. But if
1391 * the pages are mapped, the processing is slow (page_referenced()) so we
1392 * should drop zone->lru_lock around each page. It's impossible to balance
1393 * this, so instead we remove the pages from the LRU while processing them.
1394 * It is safe to rely on PG_active against the non-LRU pages in here because
1395 * nobody will play with that bit on a non-LRU page.
1396 *
1397 * The downside is that we have to touch page->_count against each page.
1398 * But we had to alter page->flags anyway.
1399 */
1405 {
1434 }
1435 }
1439 }
1445 {
1488 }
1495 }
1496 }
1501 /*
1502 * Identify referenced, file-backed active pages and
1503 * give them one more trip around the active list. So
1504 * that executable code get better chances to stay in
1505 * memory under moderate memory pressure. Anon pages
1506 * are not likely to be evicted by use-once streaming
1507 * IO, plus JVM can create lots of anon VM_EXEC pages,
1508 * so we ignore them here.
1509 */
1513 }
1514 }
1518 }
1520 /*
1521 * Move pages back to the lru list.
1522 */
1524 /*
1525 * Count referenced pages from currently used mappings as rotated,
1526 * even though only some of them are actually re-activated. This
1527 * helps balance scan pressure between file and anonymous pages in
1528 * get_scan_ratio.
1529 */
1538 }
1540 #ifdef CONFIG_SWAP
1542 {
1552 }
1554 /**
1555 * inactive_anon_is_low - check if anonymous pages need to be deactivated
1556 * @lruvec: LRU vector to check
1557 *
1558 * Returns true if the zone does not have enough inactive anon pages,
1559 * meaning some active anon pages need to be deactivated.
1560 */
1562 {
1563 /*
1564 * If we don't have swap space, anonymous page deactivation
1565 * is pointless.
1566 */
1574 }
1575 #else
1577 {
1579 }
1580 #endif
1583 {
1590 }
1592 /**
1593 * inactive_file_is_low - check if file pages need to be deactivated
1594 * @lruvec: LRU vector to check
1595 *
1596 * When the system is doing streaming IO, memory pressure here
1597 * ensures that active file pages get deactivated, until more
1598 * than half of the file pages are on the inactive list.
1599 *
1600 * Once we get to that situation, protect the system's working
1601 * set from being evicted by disabling active file page aging.
1602 *
1603 * This uses a different ratio than the anonymous pages, because
1604 * the page cache uses a use-once replacement algorithm.
1605 */
1607 {
1612 }
1615 {
1618 else
1620 }
1624 {
1629 }
1632 }
1635 {
1639 }
1641 /*
1642 * Determine how aggressively the anon and file LRU lists should be
1643 * scanned. The relative value of each set of LRU lists is determined
1644 * by looking at the fraction of the pages scanned we did rotate back
1645 * onto the active list instead of evict.
1646 *
1647 * nr[0] = anon inactive pages to scan; nr[1] = anon active pages to scan
1648 * nr[2] = file inactive pages to scan; nr[3] = file active pages to scan
1649 */
1652 {
1663 /*
1664 * If the zone or memcg is small, nr[l] can be 0. This
1665 * results in no scanning on this priority and a potential
1666 * priority drop. Global direct reclaim can go to the next
1667 * zone and tends to have no problems. Global kswapd is for
1668 * zone balancing and it needs to scan a minimum amount. When
1669 * reclaiming for a memcg, a priority drop can cause high
1670 * latencies, so it's better to scan a minimum amount there as
1671 * well.
1672 */
1678 /* If we have no swap space, do not bother scanning anon pages. */
1685 }
1695 /*
1696 * If we have very few page cache pages, force-scan
1697 * anon pages.
1698 */
1704 /*
1705 * There is enough inactive page cache, do not
1706 * reclaim anything from the working set right now.
1707 */
1712 }
1713 }
1715 /*
1716 * With swappiness at 100, anonymous and file have the same priority.
1717 * This scanning priority is essentially the inverse of IO cost.
1718 */
1722 /*
1723 * OK, so we have swap space and a fair amount of page cache
1724 * pages. We use the recently rotated / recently scanned
1725 * ratios to determine how valuable each cache is.
1726 *
1727 * Because workloads change over time (and to avoid overflow)
1728 * we keep these statistics as a floating average, which ends
1729 * up weighing recent references more than old ones.
1730 *
1731 * anon in [0], file in [1]
1732 */
1737 }
1742 }
1744 /*
1745 * The amount of pressure on anon vs file pages is inversely
1746 * proportional to the fraction of recently scanned pages on
1747 * each list that were recently referenced and in active use.
1748 */
1759 out:
1770 }
1772 }
1773 }
1775 /* Use reclaim/compaction for costly allocs or under memory pressure */
1777 {
1784 }
1786 /*
1787 * Reclaim/compaction is used for high-order allocation requests. It reclaims
1788 * order-0 pages before compacting the zone. should_continue_reclaim() returns
1789 * true if more pages should be reclaimed such that when the page allocator
1790 * calls try_to_compact_zone() that it will have enough free pages to succeed.
1791 * It will give up earlier than that if there is difficulty reclaiming pages.
1792 */
1797 {
1801 /* If not in reclaim/compaction mode, stop */
1805 /* Consider stopping depending on scan and reclaim activity */
1807 /*
1808 * For __GFP_REPEAT allocations, stop reclaiming if the
1809 * full LRU list has been scanned and we are still failing
1810 * to reclaim pages. This full LRU scan is potentially
1811 * expensive but a __GFP_REPEAT caller really wants to succeed
1812 */
1816 /*
1817 * For non-__GFP_REPEAT allocations which can presumably
1818 * fail without consequence, stop if we failed to reclaim
1819 * any pages from the last SWAP_CLUSTER_MAX number of
1820 * pages that were scanned. This will return to the
1821 * caller faster at the risk reclaim/compaction and
1822 * the resulting allocation attempt fails
1823 */
1826 }
1828 /*
1829 * If we have not reclaimed enough pages for compaction and the
1830 * inactive lists are large enough, continue reclaiming
1831 */
1840 /* If compaction would go ahead or the allocation would succeed, stop */
1847 }
1848 }
1850 /*
1851 * This is a basic per-zone page freer. Used by both kswapd and direct reclaim.
1852 */
1854 {
1862 restart:
1878 }
1879 }
1880 /*
1881 * On large memory systems, scan >> priority can become
1882 * really large. This is fine for the starting priority;
1883 * we want to put equal scanning pressure on each zone.
1884 * However, if the VM has a harder time of freeing pages,
1885 * with multiple processes reclaiming pages, the total
1886 * freeing target can get unreasonably large.
1887 */
1891 }
1895 /*
1896 * Even if we did not try to evict anon pages at all, we want to
1897 * rebalance the anon lru active/inactive ratio.
1898 */
1903 /* reclaim/compaction might need reclaim to continue */
1909 }
1912 {
1917 };
1926 /*
1927 * Limit reclaim has historically picked one memcg and
1928 * scanned it with decreasing priority levels until
1929 * nr_to_reclaim had been reclaimed. This priority
1930 * cycle is thus over after a single memcg.
1931 *
1932 * Direct reclaim and kswapd, on the other hand, have
1933 * to scan all memory cgroups to fulfill the overall
1934 * scan target for the zone.
1935 */
1939 }
1942 }
1944 /* Returns true if compaction should go ahead for a high-order request */
1946 {
1950 /* Do not consider compaction for orders reclaim is meant to satisfy */
1954 /*
1955 * Compaction takes time to run and there are potentially other
1956 * callers using the pages just freed. Continue reclaiming until
1957 * there is a buffer of free pages available to give compaction
1958 * a reasonable chance of completing and allocating the page
1959 */
1962 KSWAPD_ZONE_BALANCE_GAP_RATIO);
1966 /*
1967 * If compaction is deferred, reclaim up to a point where
1968 * compaction will have a chance of success when re-enabled
1969 */
1973 /* If compaction is not ready to start, keep reclaiming */
1978 }
1980 /*
1981 * This is the direct reclaim path, for page-allocating processes. We only
1982 * try to reclaim pages from zones which will satisfy the caller's allocation
1983 * request.
1984 *
1985 * We reclaim from a zone even if that zone is over high_wmark_pages(zone).
1986 * Because:
1987 * a) The caller may be trying to free *extra* pages to satisfy a higher-order
1988 * allocation or
1989 * b) The target zone may be at high_wmark_pages(zone) but the lower zones
1990 * must go *over* high_wmark_pages(zone) to satisfy the `incremental min'
1991 * zone defense algorithm.
1992 *
1993 * If a zone is deemed to be full of pinned pages then just give it a light
1994 * scan then give up on it.
1995 *
1996 * This function returns true if a zone is being reclaimed for a costly
1997 * high-order allocation and compaction is ready to begin. This indicates to
1998 * the caller that it should consider retrying the allocation instead of
1999 * further reclaim.
2000 */
2002 {
2009 /*
2010 * If the number of buffer_heads in the machine exceeds the maximum
2011 * allowed level, force direct reclaim to scan the highmem zone as
2012 * highmem pages could be pinning lowmem pages storing buffer_heads
2013 */
2021 /*
2022 * Take care memory controller reclaiming has small influence
2023 * to global LRU.
2024 */
2032 /*
2033 * If we already have plenty of memory free for
2034 * compaction in this zone, don't free any more.
2035 * Even though compaction is invoked for any
2036 * non-zero order, only frequent costly order
2037 * reclamation is disruptive enough to become a
2038 * noticeable problem, like transparent huge
2039 * page allocations.
2040 */
2044 }
2045 }
2046 /*
2047 * This steals pages from memory cgroups over softlimit
2048 * and returns the number of reclaimed pages and
2049 * scanned pages. This works for global memory pressure
2050 * and balancing, not for a memcg's limit.
2051 */
2058 /* need some check for avoid more shrink_zone() */
2059 }
2062 }
2065 }
2068 {
2070 }
2072 /* All zones in zonelist are unreclaimable? */
2075 {
2087 }
2090 }
2092 /*
2093 * This is the main entry point to direct page reclaim.
2094 *
2095 * If a full scan of the inactive list fails to free enough memory then we
2096 * are "out of memory" and something needs to be killed.
2097 *
2098 * If the caller is !__GFP_FS then the probability of a failure is reasonably
2099 * high - the zone may be full of dirty or under-writeback pages, which this
2100 * caller can't do much about. We kick the writeback threads and take explicit
2101 * naps in the hope that some of these pages can be written. But if the
2102 * allocating task holds filesystem locks which prevent writeout this might not
2103 * work, and the allocation attempt will fail.
2104 *
2105 * returns: 0, if no pages reclaimed
2106 * else, the number of pages reclaimed
2107 */
2111 {
2128 /*
2129 * Don't shrink slabs when reclaiming memory from
2130 * over limit cgroups
2131 */
2140 }
2146 }
2147 }
2152 /*
2153 * Try to write back as many pages as we just scanned. This
2154 * tends to cause slow streaming writers to write data to the
2155 * disk smoothly, at the dirtying rate, which is nice. But
2156 * that's undesirable in laptop mode, where we *want* lumpy
2157 * writeout. So in laptop mode, write out the whole world.
2158 */
2162 WB_REASON_TRY_TO_FREE_PAGES);
2164 }
2166 /* Take a nap, wait for some writeback to complete */
2175 }
2178 out:
2184 /*
2185 * As hibernation is going on, kswapd is freezed so that it can't mark
2186 * the zone into all_unreclaimable. Thus bypassing all_unreclaimable
2187 * check.
2188 */
2192 /* Aborted reclaim to try compaction? don't OOM, then */
2196 /* top priority shrink_zones still had more to do? don't OOM, then */
2201 }
2204 {
2215 }
2219 /* kswapd must be awake if processes are being throttled */
2224 }
2227 }
2229 /*
2230 * Throttle direct reclaimers if backing storage is backed by the network
2231 * and the PFMEMALLOC reserve for the preferred node is getting dangerously
2232 * depleted. kswapd will continue to make progress and wake the processes
2233 * when the low watermark is reached.
2234 *
2235 * Returns true if a fatal signal was delivered during throttling. If this
2236 * happens, the page allocator should not consider triggering the OOM killer.
2237 */
2240 {
2245 /*
2246 * Kernel threads should not be throttled as they may be indirectly
2247 * responsible for cleaning pages necessary for reclaim to make forward
2248 * progress. kjournald for example may enter direct reclaim while
2249 * committing a transaction where throttling it could forcing other
2250 * processes to block on log_wait_commit().
2251 */
2255 /*
2256 * If a fatal signal is pending, this process should not throttle.
2257 * It should return quickly so it can exit and free its memory
2258 */
2262 /* Check if the pfmemalloc reserves are ok */
2268 /* Account for the throttling */
2271 /*
2272 * If the caller cannot enter the filesystem, it's possible that it
2273 * is due to the caller holding an FS lock or performing a journal
2274 * transaction in the case of a filesystem like ext[3|4]. In this case,
2275 * it is not safe to block on pfmemalloc_wait as kswapd could be
2276 * blocked waiting on the same lock. Instead, throttle for up to a
2277 * second before continuing.
2278 */
2284 }
2286 /* Throttle until kswapd wakes the process */
2290 check_pending:
2294 out:
2296 }
2300 {
2312 };
2315 };
2317 /*
2318 * Do not enter reclaim if fatal signal was delivered while throttled.
2319 * 1 is returned so that the page allocator does not OOM kill at this
2320 * point.
2321 */
2327 gfp_mask);
2334 }
2336 #ifdef CONFIG_MEMCG
2342 {
2352 };
2362 /*
2363 * NOTE: Although we can get the priority field, using it
2364 * here is not a good idea, since it limits the pages we can scan.
2365 * if we don't reclaim here, the shrink_zone from balance_pgdat
2366 * will pick up pages from other mem cgroup's as well. We hack
2367 * the priority and make it zero.
2368 */
2375 }
2378 gfp_t gfp_mask,
2380 {
2395 };
2398 };
2400 /*
2401 * Unlike direct reclaim via alloc_pages(), memcg's reclaim doesn't
2402 * take care of from where we get pages. So the node where we start the
2403 * scan does not need to be the current node.
2404 */
2418 }
2419 #endif
2422 {
2438 }
2442 {
2452 }
2454 /*
2455 * pgdat_balanced() is used when checking if a node is balanced.
2456 *
2457 * For order-0, all zones must be balanced!
2458 *
2459 * For high-order allocations only zones that meet watermarks and are in a
2460 * zone allowed by the callers classzone_idx are added to balanced_pages. The
2461 * total of balanced pages must be at least 25% of the zones allowed by
2462 * classzone_idx for the node to be considered balanced. Forcing all zones to
2463 * be balanced for high orders can cause excessive reclaim when there are
2464 * imbalanced zones.
2465 * The choice of 25% is due to
2466 * o a 16M DMA zone that is balanced will not balance a zone on any
2467 * reasonable sized machine
2468 * o On all other machines, the top zone must be at least a reasonable
2469 * percentage of the middle zones. For example, on 32-bit x86, highmem
2470 * would need to be at least 256M for it to be balance a whole node.
2471 * Similarly, on x86-64 the Normal zone would need to be at least 1G
2472 * to balance a node on its own. These seemed like reasonable ratios.
2473 */
2475 {
2480 /* Check the watermark levels */
2489 /*
2490 * A special case here:
2491 *
2492 * balance_pgdat() skips over all_unreclaimable after
2493 * DEF_PRIORITY. Effectively, it considers them balanced so
2494 * they must be considered balanced here as well!
2495 */
2499 }
2505 }
2509 else
2511 }
2513 /*
2514 * Prepare kswapd for sleeping. This verifies that there are no processes
2515 * waiting in throttle_direct_reclaim() and that watermarks have been met.
2516 *
2517 * Returns true if kswapd is ready to sleep
2518 */
2521 {
2522 /* If a direct reclaimer woke kswapd within HZ/10, it's premature */
2526 /*
2527 * There is a potential race between when kswapd checks its watermarks
2528 * and a process gets throttled. There is also a potential race if
2529 * processes get throttled, kswapd wakes, a large process exits therby
2530 * balancing the zones that causes kswapd to miss a wakeup. If kswapd
2531 * is going to sleep, no process should be sleeping on pfmemalloc_wait
2532 * so wake them now if necessary. If necessary, processes will wake
2533 * kswapd and get throttled again
2534 */
2538 }
2541 }
2543 /*
2544 * For kswapd, balance_pgdat() will work across all this node's zones until
2545 * they are all at high_wmark_pages(zone).
2546 *
2547 * Returns the final order kswapd was reclaiming at
2548 *
2549 * There is special handling here for zones which are full of pinned pages.
2550 * This can happen if the pages are all mlocked, or if they are all used by
2551 * device drivers (say, ZONE_DMA). Or if they are all in use by hugetlb.
2552 * What we do is to detect the case where all pages in the zone have been
2553 * scanned twice and there has been zero successful reclaim. Mark the zone as
2554 * dead and from now on, only perform a short scan. Basically we're polling
2555 * the zone for when the problem goes away.
2556 *
2557 * kswapd scans the zones in the highmem->normal->dma direction. It skips
2558 * zones which have free_pages > high_wmark_pages(zone), but once a zone is
2559 * found to have free_pages <= high_wmark_pages(zone), we scan that zone and the
2560 * lower zones regardless of the number of free pages in the lower zones. This
2561 * interoperates with the page allocator fallback scheme to ensure that aging
2562 * of pages is balanced across the zones.
2563 */
2566 {
2578 /*
2579 * kswapd doesn't want to be bailed out while reclaim. because
2580 * we want to put equal scanning pressure on each zone.
2581 */
2585 };
2588 };
2589 loop_again:
2602 /*
2603 * Scan in the highmem->dma direction for the highest
2604 * zone which needs scanning
2605 */
2616 /*
2617 * Do some background aging of the anon list, to give
2618 * pages a chance to be referenced before reclaiming.
2619 */
2622 /*
2623 * If the number of buffer_heads in the machine
2624 * exceeds the maximum allowed level and this node
2625 * has a highmem zone, force kswapd to reclaim from
2626 * it to relieve lowmem pressure.
2627 */
2631 }
2637 /* If balanced, clear the congested flag */
2639 }
2640 }
2648 }
2650 /*
2651 * Now scan the zone in the dma->highmem direction, stopping
2652 * at the last zone which needs scanning.
2653 *
2654 * We do this because the page allocator works in the opposite
2655 * direction. This prevents the page allocator from allocating
2656 * pages behind kswapd's direction of progress, which would
2657 * cause too much scanning of the lower zones.
2658 */
2674 /*
2675 * Call soft limit reclaim before calling shrink_zone.
2676 */
2683 /*
2684 * We put equal pressure on every zone, unless
2685 * one zone has way too many pages free
2686 * already. The "too many pages" is defined
2687 * as the high wmark plus a "gap" where the
2688 * gap is either the low watermark or 1%
2689 * of the zone, whichever is smaller.
2690 */
2694 KSWAPD_ZONE_BALANCE_GAP_RATIO);
2695 /*
2696 * Kswapd reclaims only single pages with compaction
2697 * enabled. Trying too hard to reclaim until contiguous
2698 * free pages have become available can hurt performance
2699 * by evicting too much useful data from memory.
2700 * Do not reclaim more than needed for compaction.
2701 */
2705 COMPACT_SKIPPED)
2720 }
2722 /*
2723 * If we've done a decent amount of scanning and
2724 * the reclaim ratio is low, start doing writepage
2725 * even in laptop mode
2726 */
2733 end_zone--;
2735 }
2739 /*
2740 * We are still under min water mark. This
2741 * means that we have a GFP_ATOMIC allocation
2742 * failure risk. Hurry up!
2743 */
2748 /*
2749 * If a zone reaches its high watermark,
2750 * consider it to be no longer congested. It's
2751 * possible there are dirty pages backed by
2752 * congested BDIs but as pressure is relieved,
2753 * speculatively avoid congestion waits
2754 */
2756 }
2758 }
2760 /*
2761 * If the low watermark is met there is no need for processes
2762 * to be throttled on pfmemalloc_wait as they should not be
2763 * able to safely make forward progress. Wake them
2764 */
2771 /*
2772 * OK, kswapd is getting into trouble. Take a nap, then take
2773 * another pass across the zones.
2774 */
2780 }
2782 /*
2783 * We do this so kswapd doesn't build up large priorities for
2784 * example when it is freeing in parallel with allocators. It
2785 * matches the direct reclaim path behaviour in terms of impact
2786 * on zone->*_priority.
2787 */
2791 out:
2798 /*
2799 * Fragmentation may mean that the system cannot be
2800 * rebalanced for high-order allocations in all zones.
2801 * At this point, if nr_reclaimed < SWAP_CLUSTER_MAX,
2802 * it means the zones have been fully scanned and are still
2803 * not balanced. For high-order allocations, there is
2804 * little point trying all over again as kswapd may
2805 * infinite loop.
2806 *
2807 * Instead, recheck all watermarks at order-0 as they
2808 * are the most important. If watermarks are ok, kswapd will go
2809 * back to sleep. High-order users can still perform direct
2810 * reclaim if they wish.
2811 */
2816 }
2818 /*
2819 * If kswapd was reclaiming at a higher order, it has the option of
2820 * sleeping without all zones being balanced. Before it does, it must
2821 * ensure that the watermarks for order-0 on *all* zones are met and
2822 * that the congestion flags are cleared. The congestion flag must
2823 * be cleared as kswapd is the only mechanism that clears the flag
2824 * and it is potentially going to sleep here.
2825 */
2835 /* Check if the memory needs to be defragmented. */
2839 }
2843 }
2845 /*
2846 * Return the order we were reclaiming at so prepare_kswapd_sleep()
2847 * makes a decision on the order we were last reclaiming at. However,
2848 * if another caller entered the allocator slow path while kswapd
2849 * was awake, order will remain at the higher level
2850 */
2853 }
2856 {
2865 /* Try to sleep for a short interval */
2870 }
2872 /*
2873 * After a short sleep, check if it was a premature sleep. If not, then
2874 * go fully to sleep until explicitly woken up.
2875 */
2879 /*
2880 * vmstat counters are not perfectly accurate and the estimated
2881 * value for counters such as NR_FREE_PAGES can deviate from the
2882 * true value by nr_online_cpus * threshold. To avoid the zone
2883 * watermarks being breached while under pressure, we reduce the
2884 * per-cpu vmstat threshold while kswapd is awake and restore
2885 * them before going back to sleep.
2886 */
2889 /*
2890 * Compaction records what page blocks it recently failed to
2891 * isolate pages from and skips them in the future scanning.
2892 * When kswapd is going to sleep, it is reasonable to assume
2893 * that pages and compaction may succeed so reset the cache.
2894 */
2904 else
2906 }
2908 }
2910 /*
2911 * The background pageout daemon, started as a kernel thread
2912 * from the init process.
2913 *
2914 * This basically trickles out pages so that we have _some_
2915 * free memory available even if there is no other activity
2916 * that frees anything up. This is needed for things like routing
2917 * etc, where we otherwise might have all activity going on in
2918 * asynchronous contexts that cannot page things out.
2919 *
2920 * If there are applications that are active memory-allocators
2921 * (most normal use), this basically shouldn't matter.
2922 */
2924 {
2934 };
2943 /*
2944 * Tell the memory management that we're a "memory allocator",
2945 * and that if we need more memory we should get access to it
2946 * regardless (see "__alloc_pages()"). "kswapd" should
2947 * never get caught in the normal page freeing logic.
2948 *
2949 * (Kswapd normally doesn't need memory anyway, but sometimes
2950 * you need a small amount of memory in order to be able to
2951 * page out something else, and this flag essentially protects
2952 * us from recursively trying to free more memory as we're
2953 * trying to free the first piece of memory in the first place).
2954 */
2965 /*
2966 * If the last balance_pgdat was unsuccessful it's unlikely a
2967 * new request of a similar or harder type will succeed soon
2968 * so consider going to sleep on the basis we reclaimed at
2969 */
2976 }
2979 /*
2980 * Don't sleep if someone wants a larger 'order'
2981 * allocation or has tigher zone constraints
2982 */
2987 balanced_classzone_idx);
2994 }
3000 /*
3001 * We can speed up thawing tasks if we don't call balance_pgdat
3002 * after returning from the refrigerator
3003 */
3009 }
3010 }
3014 }
3016 /*
3017 * A zone is low on free memory, so wake its kswapd task to service it.
3018 */
3020 {
3032 }
3040 }
3042 /*
3043 * The reclaimable count would be mostly accurate.
3044 * The less reclaimable pages may be
3045 * - mlocked pages, which will be moved to unevictable list when encountered
3046 * - mapped pages, which may require several travels to be reclaimed
3047 * - dirty pages, which is not "instantly" reclaimable
3048 */
3050 {
3061 }
3064 {
3075 }
3077 #ifdef CONFIG_HIBERNATION
3078 /*
3079 * Try to free `nr_to_reclaim' of memory, system-wide, and return the number of
3080 * freed pages.
3081 *
3082 * Rather than trying to age LRUs the aim is to preserve the overall
3083 * LRU order by reclaiming preferentially
3084 * inactive > active > active referenced > active mapped
3085 */
3087 {
3098 };
3101 };
3118 }
3121 /* It's optimal to keep kswapds on the same CPUs as their memory, but
3122 not required for correctness. So if the last cpu in a node goes
3123 away, we get changed to run anywhere: as the first one comes back,
3124 restore their cpu bindings. */
3127 {
3138 /* One of our CPUs online: restore mask */
3140 }
3141 }
3143 }
3145 /*
3146 * This kswapd start function will be called by init and node-hot-add.
3147 * On node-hot-add, kswapd will moved to proper cpus if cpus are hot-added.
3148 */
3150 {
3159 /* failure at boot is fatal */
3164 }
3166 }
3168 /*
3169 * Called by memory hotplug when all memory in a node is offlined. Caller must
3170 * hold lock_memory_hotplug().
3171 */
3173 {
3179 }
3180 }
3183 {
3191 }
3195 #ifdef CONFIG_NUMA
3196 /*
3197 * Zone reclaim mode
3198 *
3199 * If non-zero call zone_reclaim when the number of free pages falls below
3200 * the watermarks.
3201 */
3204 #define RECLAIM_OFF 0
3209 /*
3210 * Priority for ZONE_RECLAIM. This determines the fraction of pages
3211 * of a node considered for each zone_reclaim. 4 scans 1/16th of
3212 * a zone.
3213 */
3214 #define ZONE_RECLAIM_PRIORITY 4
3216 /*
3217 * Percentage of pages in a zone that must be unmapped for zone_reclaim to
3218 * occur.
3219 */
3222 /*
3223 * If the number of slab pages in a zone grows beyond this percentage then
3224 * slab reclaim needs to occur.
3225 */
3229 {
3234 /*
3235 * It's possible for there to be more file mapped pages than
3236 * accounted for by the pages on the file LRU lists because
3237 * tmpfs pages accounted for as ANON can also be FILE_MAPPED
3238 */
3240 }
3242 /* Work out how many page cache pages we can reclaim in this reclaim_mode */
3244 {
3248 /*
3249 * If RECLAIM_SWAP is set, then all file pages are considered
3250 * potentially reclaimable. Otherwise, we have to worry about
3251 * pages like swapcache and zone_unmapped_file_pages() provides
3252 * a better estimate
3253 */
3256 else
3259 /* If we can't clean pages, remove dirty pages from consideration */
3263 /* Watch for any possible underflows due to delta */
3268 }
3270 /*
3271 * Try to free up some pages from this zone through reclaim.
3272 */
3274 {
3275 /* Minimum pages needed in order to stay on node */
3284 SWAP_CLUSTER_MAX),
3288 };
3291 };
3295 /*
3296 * We need to be able to allocate from the reserves for RECLAIM_SWAP
3297 * and we also need to be able to write out pages for RECLAIM_WRITE
3298 * and RECLAIM_SWAP.
3299 */
3306 /*
3307 * Free memory by calling shrink zone with increasing
3308 * priorities until we have enough memory freed.
3309 */
3313 }
3317 /*
3318 * shrink_slab() does not currently allow us to determine how
3319 * many pages were freed in this zone. So we take the current
3320 * number of slab pages and shake the slab until it is reduced
3321 * by the same nr_pages that we used for reclaiming unmapped
3322 * pages.
3323 *
3324 * Note that shrink_slab will free memory on all zones and may
3325 * take a long time.
3326 */
3330 /* No reclaimable slab or very low memory pressure */
3334 /* Freed enough memory */
3336 NR_SLAB_RECLAIMABLE);
3339 }
3341 /*
3342 * Update nr_reclaimed by the number of slab pages we
3343 * reclaimed from this zone.
3344 */
3348 }
3354 }
3357 {
3361 /*
3362 * Zone reclaim reclaims unmapped file backed pages and
3363 * slab pages if we are over the defined limits.
3364 *
3365 * A small portion of unmapped file backed pages is needed for
3366 * file I/O otherwise pages read by file I/O will be immediately
3367 * thrown out if the zone is overallocated. So we do not reclaim
3368 * if less than a specified percentage of the zone is used by
3369 * unmapped file backed pages.
3370 */
3378 /*
3379 * Do not scan if the allocation should not be delayed.
3380 */
3384 /*
3385 * Only run zone reclaim on the local zone or on zones that do not
3386 * have associated processors. This will favor the local processor
3387 * over remote processors and spread off node memory allocations
3388 * as wide as possible.
3389 */
3404 }
3405 #endif
3407 /*
3408 * page_evictable - test whether a page is evictable
3409 * @page: the page to test
3410 *
3411 * Test whether page is evictable--i.e., should be placed on active/inactive
3412 * lists vs unevictable list.
3413 *
3414 * Reasons page might not be evictable:
3415 * (1) page's mapping marked unevictable
3416 * (2) page is part of an mlocked VMA
3417 *
3418 */
3420 {
3422 }
3424 #ifdef CONFIG_SHMEM
3425 /**
3426 * check_move_unevictable_pages - check pages for evictability and move to appropriate zone lru list
3427 * @pages: array of pages to check
3428 * @nr_pages: number of pages to check
3429 *
3430 * Checks pages for evictability and moves them to the appropriate lru list.
3431 *
3432 * This function is only used for SysV IPC SHM_UNLOCK.
3433 */
3435 {
3446 pgscanned++;
3453 }
3466 pgrescued++;
3467 }
3468 }
3474 }
3475 }
3479 {
3481 "%s: The scan_unevictable_pages sysctl/node-interface has been "
3482 "disabled for lack of a legitimate use case. If you have "
3485 }
3487 /*
3488 * scan_unevictable_pages [vm] sysctl handler. On demand re-scan of
3489 * all nodes' unevictable lists for evictable pages
3490 */
3496 {
3501 }
3503 #ifdef CONFIG_NUMA
3504 /*
3505 * per node 'scan_unevictable_pages' attribute. On demand re-scan of
3506 * a specified node's per zone unevictable lists for evictable pages.
3507 */
3512 {
3515 }
3520 {
3523 }
3527 read_scan_unevictable_node,
3528 write_scan_unevictable_node);
3531 {
3533 }
3536 {
3538 }
3539 #endif