| blob | b1cd120607230b0770c35e0823d6389782ae734a |
1 /*
2 * linux/mm/swapfile.c
3 *
4 * Copyright (C) 1991, 1992, 1993, 1994 Linus Torvalds
5 * Swap reorganised 29.12.95, Stephen Tweedie
6 */
8 #include <linux/mm.h>
9 #include <linux/hugetlb.h>
10 #include <linux/mman.h>
11 #include <linux/slab.h>
12 #include <linux/kernel_stat.h>
13 #include <linux/swap.h>
14 #include <linux/vmalloc.h>
15 #include <linux/pagemap.h>
16 #include <linux/namei.h>
17 #include <linux/shmem_fs.h>
18 #include <linux/blkdev.h>
19 #include <linux/random.h>
20 #include <linux/writeback.h>
21 #include <linux/proc_fs.h>
22 #include <linux/seq_file.h>
23 #include <linux/init.h>
24 #include <linux/ksm.h>
25 #include <linux/rmap.h>
26 #include <linux/security.h>
27 #include <linux/backing-dev.h>
28 #include <linux/mutex.h>
29 #include <linux/capability.h>
30 #include <linux/syscalls.h>
31 #include <linux/memcontrol.h>
32 #include <linux/poll.h>
33 #include <linux/oom.h>
35 #include <asm/pgtable.h>
36 #include <asm/tlbflush.h>
37 #include <linux/swapops.h>
38 #include <linux/page_cgroup.h>
63 /* Activity counter to indicate that a swapon or swapoff has occurred */
67 {
69 }
71 /* returns 1 if swap entry is freed */
72 static int
74 {
82 /*
83 * This function is called from scan_swap_map() and it's called
84 * by vmscan.c at reclaiming pages. So, we hold a lock on a page, here.
85 * We have to use trylock for avoiding deadlock. This is a special
86 * case and you should use try_to_free_swap() with explicit lock_page()
87 * in usual operations.
88 */
92 }
95 }
97 /*
98 * swapon tell device that all the old swap contents can be discarded,
99 * to allow the swap device to optimize its wear-levelling.
100 */
102 {
104 sector_t start_block;
105 sector_t nr_blocks;
108 /* Do not discard the swap header page! */
118 }
130 }
132 }
134 /*
135 * swap allocation tell device that a cluster of swap can now be discarded,
136 * to allow the swap device to optimize its wear-levelling.
137 */
140 {
166 }
170 }
171 }
174 {
177 }
179 #define SWAPFILE_CLUSTER 256
180 #define LATENCY_LIMIT 256
184 {
191 /*
192 * We try to cluster swap pages by allocating them sequentially
193 * in swap. Once we've allocated SWAPFILE_CLUSTER pages this
194 * way, however, we resort to first-free allocation, starting
195 * a new cluster. This prevents us from scattering swap pages
196 * all over the entire swap partition, so that we reduce
197 * overall disk seek times between swap pages. -- sct
198 * But we do now try to find an empty cluster. -Andrea
199 * And we let swap pages go all over an SSD partition. Hugh
200 */
209 }
211 /*
212 * Start range check on racing allocations, in case
213 * they overlap the cluster we eventually decide on
214 * (we scan without swap_lock to allow preemption).
215 * It's hardly conceivable that cluster_nr could be
216 * wrapped during our scan, but don't depend on it.
217 */
222 }
225 /*
226 * If seek is expensive, start searching for new cluster from
227 * start of partition, to minimize the span of allocated swap.
228 * But if seek is cheap, search from our current position, so
229 * that swap is allocated from all over the partition: if the
230 * Flash Translation Layer only remaps within limited zones,
231 * we don't want to wear out the first zone too quickly.
232 */
237 /* Locate the first empty (unaligned) cluster */
248 }
252 }
253 }
258 /* Locate the first empty (unaligned) cluster */
269 }
273 }
274 }
280 }
282 checks:
290 /* reuse swap entry of cache-only swap if not busy. */
296 /* entry was freed successfully, try to use this again */
300 }
313 }
319 /*
320 * Only set when SWP_DISCARDABLE, and there's a scan
321 * for a free cluster in progress or just completed.
322 */
324 /*
325 * To optimize wear-levelling, discard the
326 * old data of the cluster, taking care not to
327 * discard any of its pages that have already
328 * been allocated by racing tasks (offset has
329 * already stepped over any at the beginning).
330 */
349 /*
350 * Delay using pages allocated by racing tasks
351 * until the whole discard has been issued. We
352 * could defer that delay until swap_writepage,
353 * but it's easier to keep this self-contained.
354 */
360 /*
361 * Note pages allocated by racing tasks while
362 * scan for a free cluster is in progress, so
363 * that its final discard can exclude them.
364 */
369 }
370 }
373 scan:
379 }
383 }
387 }
388 }
394 }
398 }
402 }
403 }
406 no_page:
409 }
412 {
414 pgoff_t offset;
421 nr_swap_pages--;
429 wrapped++;
430 }
438 /* This is called for allocating swap entry for cache */
443 }
445 }
447 nr_swap_pages++;
448 noswap:
451 }
453 /* The only caller of this function is now susupend routine */
455 {
457 pgoff_t offset;
462 nr_swap_pages--;
463 /* This is called for allocating swap entry, not cache */
468 }
469 nr_swap_pages++;
470 }
473 }
476 {
496 bad_free:
499 bad_offset:
502 bad_device:
505 bad_nofile:
507 out:
509 }
513 {
526 /*
527 * Or we could insist on shmem.c using a special
528 * swap_shmem_free() and free_shmem_swap_and_cache()...
529 */
535 else
538 count--;
539 }
547 /* free if no reference */
557 nr_swap_pages++;
562 }
565 }
567 /*
568 * Caller has made sure that the swapdevice corresponding to entry
569 * is still around or has not been recycled.
570 */
572 {
579 }
580 }
582 /*
583 * Called after dropping swapcache to decrease refcnt to swap entries.
584 */
586 {
596 }
597 }
599 /*
600 * How many references to page are currently swapped out?
601 * This does not give an exact answer when swap count is continued,
602 * but does include the high COUNT_CONTINUED flag to allow for that.
603 */
605 {
608 swp_entry_t entry;
615 }
617 }
619 /*
620 * We can write to an anon page without COW if there are no other references
621 * to it. And as a side-effect, free up its swap: because the old content
622 * on disk will never be read, and seeking back there to write new content
623 * later would only waste time away from clustering.
624 */
626 {
638 }
639 }
641 }
643 /*
644 * If swap is getting full, or if there are no more mappings of this page,
645 * then try_to_free_swap is called to free its swap space.
646 */
648 {
658 /*
659 * Once hibernation has begun to create its image of memory,
660 * there's a danger that one of the calls to try_to_free_swap()
661 * - most probably a call from __try_to_reclaim_swap() while
662 * hibernation is allocating its own swap pages for the image,
663 * but conceivably even a call from memory reclaim - will free
664 * the swap from a page which has already been recorded in the
665 * image as a clean swapcache page, and then reuse its swap for
666 * another page of the image. On waking from hibernation, the
667 * original page might be freed under memory pressure, then
668 * later read back in from swap, now with the wrong data.
669 *
670 * Hibernation clears bits from gfp_allowed_mask to prevent
671 * memory reclaim from writing to disk, so check that here.
672 */
679 }
681 /*
682 * Free the swap entry like above, but also try to
683 * free the page cache entry if it is the last user.
684 */
686 {
700 }
701 }
703 }
705 /*
706 * Not mapped elsewhere, or swap space full? Free it!
707 * Also recheck PageSwapCache now page is locked (above).
708 */
713 }
716 }
718 }
720 #ifdef CONFIG_CGROUP_MEM_RES_CTLR
721 /**
722 * mem_cgroup_count_swap_user - count the user of a swap entry
723 * @ent: the swap entry to be checked
724 * @pagep: the pointer for the swap cache page of the entry to be stored
725 *
726 * Returns the number of the user of the swap entry. The number is valid only
727 * for swaps of anonymous pages.
728 * If the entry is found on swap cache, the page is stored to pagep with
729 * refcount of it being incremented.
730 */
732 {
744 }
748 }
749 #endif
751 #ifdef CONFIG_HIBERNATION
752 /*
753 * Find the swap type that corresponds to given device (if any).
754 *
755 * @offset - number of the PAGE_SIZE-sized block of the device, starting
756 * from 0, in which the swap header is expected to be located.
757 *
758 * This is needed for the suspend to disk (aka swsusp).
759 */
761 {
781 }
792 }
793 }
794 }
800 }
802 /*
803 * Get the (PAGE_SIZE) block corresponding to given offset on the swapdev
804 * corresponding to given index in swap_info (swap type).
805 */
807 {
815 }
817 /*
818 * Return either the total number of swap pages of given type, or the number
819 * of free pages of that type (depending on @free)
820 *
821 * This is needed for software suspend
822 */
824 {
835 }
836 }
839 }
842 /*
843 * No need to decide whether this PTE shares the swap entry with others,
844 * just let do_wp_page work it out if a write is requested later - to
845 * force COW, vm_page_prot omits write permission from any private vma.
846 */
849 {
858 }
866 }
876 /*
877 * Move the page to the active list so it is not
878 * immediately swapped out again after swapon.
879 */
881 out:
883 out_nolock:
885 }
890 {
895 /*
896 * We don't actually need pte lock while scanning for swp_pte: since
897 * we hold page lock and mmap_sem, swp_pte cannot be inserted into the
898 * page table while we're scanning; though it could get zapped, and on
899 * some architectures (e.g. x86_32 with PAE) we might catch a glimpse
900 * of unmatched parts which look like swp_pte, so unuse_pte must
901 * recheck under pte lock. Scanning without pte lock lets it be
902 * preemptible whenever CONFIG_PREEMPT but not CONFIG_HIGHPTE.
903 */
906 /*
907 * swapoff spends a _lot_ of time in this loop!
908 * Test inline before going to call unuse_pte.
909 */
916 }
919 out:
921 }
926 {
943 }
948 {
963 }
967 {
976 else
981 }
993 }
997 {
1002 /*
1003 * Activate page so shrink_inactive_list is unlikely to unmap
1004 * its ptes while lock is dropped, so swapoff can make progress.
1005 */
1010 }
1014 }
1017 }
1019 /*
1020 * Scan swap_map from current position to next entry still in use.
1021 * Recycle to start on reaching the end, returning 0 when empty.
1022 */
1025 {
1030 /*
1031 * No need for swap_lock here: we're just looking
1032 * for whether an entry is in use, not modifying it; false
1033 * hits are okay, and sys_swapoff() has already prevented new
1034 * allocations from this area (while holding swap_lock).
1035 */
1041 }
1042 /*
1043 * No entries in use at top of swap_map,
1044 * loop back to start and recheck there.
1045 */
1049 }
1053 }
1055 }
1057 /*
1058 * We completely avoid races by reading each swap page in advance,
1059 * and then search for the process using it. All the necessary
1060 * page table adjustments can then be made atomically.
1061 */
1063 {
1069 swp_entry_t entry;
1073 /*
1074 * When searching mms for an entry, a good strategy is to
1075 * start at the first mm we freed the previous entry from
1076 * (though actually we don't notice whether we or coincidence
1077 * freed the entry). Initialize this start_mm with a hold.
1078 *
1079 * A simpler strategy would be to start at the last mm we
1080 * freed the previous entry from; but that would take less
1081 * advantage of mmlist ordering, which clusters forked mms
1082 * together, child after parent. If we race with dup_mmap(), we
1083 * prefer to resolve parent before child, lest we miss entries
1084 * duplicated after we scanned child: using last mm would invert
1085 * that.
1086 */
1090 /*
1091 * Keep on scanning until all entries have gone. Usually,
1092 * one pass through swap_map is enough, but not necessarily:
1093 * there are races when an instance of an entry might be missed.
1094 */
1099 }
1101 /*
1102 * Get a page for the entry, using the existing swap
1103 * cache page if there is one. Otherwise, get a clean
1104 * page and read the swap into it.
1105 */
1111 /*
1112 * Either swap_duplicate() failed because entry
1113 * has been freed independently, and will not be
1114 * reused since sys_swapoff() already disabled
1115 * allocation from here, or alloc_page() failed.
1116 */
1121 }
1123 /*
1124 * Don't hold on to start_mm if it looks like exiting.
1125 */
1130 }
1132 /*
1133 * Wait for and lock page. When do_swap_page races with
1134 * try_to_unuse, do_swap_page can handle the fault much
1135 * faster than try_to_unuse can locate the entry. This
1136 * apparently redundant "wait_on_page_locked" lets try_to_unuse
1137 * defer to do_swap_page in such a case - in some tests,
1138 * do_swap_page and try_to_unuse repeatedly compete.
1139 */
1145 /*
1146 * Remove all references to entry.
1147 */
1151 /* page has already been unlocked and released */
1155 }
1182 ;
1185 else
1193 }
1195 }
1200 }
1205 }
1207 /*
1208 * If a reference remains (rare), we would like to leave
1209 * the page in the swap cache; but try_to_unmap could
1210 * then re-duplicate the entry once we drop page lock,
1211 * so we might loop indefinitely; also, that page could
1212 * not be swapped out to other storage meanwhile. So:
1213 * delete from cache even if there's another reference,
1214 * after ensuring that the data has been saved to disk -
1215 * since if the reference remains (rarer), it will be
1216 * read from disk into another page. Splitting into two
1217 * pages would be incorrect if swap supported "shared
1218 * private" pages, but they are handled by tmpfs files.
1219 *
1220 * Given how unuse_vma() targets one particular offset
1221 * in an anon_vma, once the anon_vma has been determined,
1222 * this splitting happens to be just what is needed to
1223 * handle where KSM pages have been swapped out: re-reading
1224 * is unnecessarily slow, but we can fix that later on.
1225 */
1230 };
1235 }
1237 /*
1238 * It is conceivable that a racing task removed this page from
1239 * swap cache just before we acquired the page lock at the top,
1240 * or while we dropped it in unuse_mm(). The page might even
1241 * be back in swap cache on another swap area: that we must not
1242 * delete, since it may not have been written out to swap yet.
1243 */
1248 /*
1249 * So we could skip searching mms once swap count went
1250 * to 1, we did not mark any present ptes as dirty: must
1251 * mark page dirty so shrink_page_list will preserve it.
1252 */
1257 /*
1258 * Make sure that we aren't completely killing
1259 * interactive performance.
1260 */
1262 }
1266 }
1268 /*
1269 * After a successful try_to_unuse, if no swap is now in use, we know
1270 * we can empty the mmlist. swap_lock must be held on entry and exit.
1271 * Note that mmlist_lock nests inside swap_lock, and an mm must be
1272 * added to the mmlist just after page_duplicate - before would be racy.
1273 */
1275 {
1286 }
1288 /*
1289 * Use this swapdev's extent info to locate the (PAGE_SIZE) block which
1290 * corresponds to page offset for the specified swap entry.
1291 * Note that the type of this function is sector_t, but it returns page offset
1292 * into the bdev, not sector offset.
1293 */
1295 {
1299 pgoff_t offset;
1314 }
1319 }
1320 }
1322 /*
1323 * Returns the page offset into bdev for the specified page's swap entry.
1324 */
1326 {
1327 swp_entry_t entry;
1330 }
1332 /*
1333 * Free all of a swapdev's extent information
1334 */
1336 {
1344 }
1345 }
1347 /*
1348 * Add a block range (and the corresponding page range) into this swapdev's
1349 * extent list. The extent list is kept sorted in page order.
1350 *
1351 * This function rather assumes that it is called in ascending page order.
1352 */
1353 static int
1356 {
1373 /* Merge it */
1376 }
1377 }
1379 /*
1380 * No merge. Insert a new extent, preserving ordering.
1381 */
1391 }
1393 /*
1394 * A `swap extent' is a simple thing which maps a contiguous range of pages
1395 * onto a contiguous range of disk blocks. An ordered list of swap extents
1396 * is built at swapon time and is then used at swap_writepage/swap_readpage
1397 * time for locating where on disk a page belongs.
1398 *
1399 * If the swapfile is an S_ISBLK block device, a single extent is installed.
1400 * This is done so that the main operating code can treat S_ISBLK and S_ISREG
1401 * swap files identically.
1402 *
1403 * Whether the swapdev is an S_ISREG file or an S_ISBLK blockdev, the swap
1404 * extent list operates in PAGE_SIZE disk blocks. Both S_ISREG and S_ISBLK
1405 * swapfiles are handled *identically* after swapon time.
1406 *
1407 * For S_ISREG swapfiles, setup_swap_extents() will walk all the file's blocks
1408 * and will parse them into an ordered extent list, in PAGE_SIZE chunks. If
1409 * some stray blocks are found which do not fall within the PAGE_SIZE alignment
1410 * requirements, they are simply tossed out - we will never use those blocks
1411 * for swapping.
1412 *
1413 * For S_ISREG swapfiles we set S_SWAPFILE across the life of the swapon. This
1414 * prevents root from shooting her foot off by ftruncating an in-use swapfile,
1415 * which will scribble on the fs.
1416 *
1417 * The amount of disk space which a single swap extent represents varies.
1418 * Typically it is in the 1-4 megabyte range. So we can have hundreds of
1419 * extents in the list. To avoid much list walking, we cache the previous
1420 * search location in `curr_swap_extent', and start new searches from there.
1421 * This is extremely effective. The average number of iterations in
1422 * map_swap_page() has been measured at about 0.3 per page. - akpm.
1423 */
1425 {
1430 sector_t probe_block;
1431 sector_t last_block;
1442 }
1447 /*
1448 * Map all the blocks into the extent list. This code doesn't try
1449 * to be very smart.
1450 */
1457 sector_t first_block;
1463 /*
1464 * It must be PAGE_SIZE aligned on-disk
1465 */
1467 probe_block++;
1469 }
1472 block_in_page++) {
1473 sector_t block;
1479 /* Discontiguity */
1480 probe_block++;
1482 }
1483 }
1491 }
1493 /*
1494 * We found a PAGE_SIZE-length, PAGE_SIZE-aligned run of blocks
1495 */
1500 page_no++;
1502 reprobe:
1504 }
1512 out:
1514 bad_bmap:
1518 }
1522 {
1528 else
1535 /* insert swap space into swap_list: */
1541 }
1545 else
1548 }
1551 {
1584 }
1586 }
1591 }
1598 }
1601 else
1604 /* just pick something that's safe... */
1606 }
1610 least_priority++;
1611 }
1622 /*
1623 * reading p->prio and p->swap_map outside the lock is
1624 * safe here because only sys_swapon and sys_swapoff
1625 * change them, and there can be no other sys_swapon or
1626 * sys_swapoff for this swap_info_struct at this point.
1627 */
1628 /* re-insert swap space back into swap_list */
1631 }
1641 /* wait for anyone still in scan_swap_map */
1647 }
1658 /* Destroy swap account informatin */
1670 }
1676 out_dput:
1678 out:
1680 }
1682 #ifdef CONFIG_PROC_FS
1684 {
1692 }
1695 }
1697 /* iterator */
1699 {
1716 }
1719 }
1722 {
1728 else
1738 }
1741 }
1744 {
1746 }
1749 {
1757 }
1769 }
1776 };
1779 {
1790 }
1798 };
1801 {
1804 }
1808 #ifdef MAX_SWAPFILES_CHECK
1810 {
1813 }
1815 #endif
1818 {
1830 }
1835 }
1839 /*
1840 * Write swap_info[type] before nr_swapfiles, in case a
1841 * racing procfs swap_start() or swap_next() is reading them.
1842 * (We never shrink nr_swapfiles, we never free this entry.)
1843 */
1845 nr_swapfiles++;
1849 /*
1850 * Do not memset this entry: a racing procfs swap_next()
1851 * would be relying on p->type to remain valid.
1852 */
1853 }
1860 }
1863 {
1870 sys_swapon);
1874 }
1889 }
1894 {
1902 }
1904 /* swap partition endianess hack... */
1911 }
1912 /* Check the swap header's sub-version */
1918 }
1924 /*
1925 * Find out how many pages are allowed for a single swap
1926 * device. There are three limiting factors: 1) the number
1927 * of bits for the swap offset in the swp_entry_t type, and
1928 * 2) the number of bits in the swap pte as defined by the
1929 * the different architectures, and 3) the number of free bits
1930 * in an exceptional radix_tree entry. In order to find the
1931 * largest possible bit mask, a swap entry with swap type 0
1932 * and swap offset ~0UL is created, encoded to a swap pte,
1933 * decoded to a swp_entry_t again, and finally the swap
1934 * offset is extracted. This will mask all the bits from
1935 * the initial ~0UL mask that can't be encoded in either
1936 * the swp_entry_t or the architecture definition of a
1937 * swap pte. Then the same is done for a radix_tree entry.
1938 */
1946 /* p->max is an unsigned int: don't overflow it */
1949 }
1959 }
1966 }
1973 {
1986 nr_good_pages--;
1987 }
1988 }
1998 }
2002 }
2005 }
2008 {
2018 sector_t span;
2036 }
2042 }
2055 }
2056 }
2059 /* If S_ISREG(inode->i_mode) will do mutex_lock(&inode->i_mutex); */
2064 /*
2065 * Read the swap header.
2066 */
2070 }
2075 }
2082 }
2084 /* OK, set up the swap map and apply the bad block list */
2089 }
2100 }
2106 }
2109 }
2114 prio =
2133 bad_swap:
2137 }
2149 }
2151 }
2152 out:
2156 }
2162 }
2165 {
2175 }
2179 }
2181 /*
2182 * Verify that a swap entry is valid and increment its swap map count.
2183 *
2184 * Returns error code in following case.
2185 * - success -> 0
2186 * - swp_entry is invalid -> EINVAL
2187 * - swp_entry is migration entry -> EINVAL
2188 * - swap-cache reference is requested but there is already one. -> EEXIST
2189 * - swap-cache reference is requested but the entry is not used. -> ENOENT
2190 * - swap-mapped reference requested but needs continued swap count. -> ENOMEM
2191 */
2193 {
2220 /* set SWAP_HAS_CACHE if there is no cache and entry is used */
2236 else
2243 unlock_out:
2245 out:
2248 bad_file:
2251 }
2253 /*
2254 * Help swapoff by noting that swap entry belongs to shmem/tmpfs
2255 * (in which case its reference count is never incremented).
2256 */
2258 {
2260 }
2262 /*
2263 * Increase reference count of swap entry by 1.
2264 * Returns 0 for success, or -ENOMEM if a swap_count_continuation is required
2265 * but could not be atomically allocated. Returns 0, just as if it succeeded,
2266 * if __swap_duplicate() fails for another reason (-EINVAL or -ENOENT), which
2267 * might occur if a page table entry has got corrupted.
2268 */
2270 {
2276 }
2278 /*
2279 * @entry: swap entry for which we allocate swap cache.
2280 *
2281 * Called when allocating swap cache for existing swap entry,
2282 * This can return error codes. Returns 0 at success.
2283 * -EBUSY means there is a swap cache.
2284 * Note: return code is different from swap_duplicate().
2285 */
2287 {
2289 }
2291 /*
2292 * swap_lock prevents swap_map being freed. Don't grab an extra
2293 * reference on the swaphandle, it doesn't matter if it becomes unused.
2294 */
2296 {
2311 base++;
2317 /* Count contiguous allocated slots above our target */
2319 /* Don't read in free or bad pages */
2324 }
2325 /* Count contiguous allocated slots below our target */
2327 /* Don't read in free or bad pages */
2332 }
2335 /*
2336 * Indicate starting offset, and return number of pages to get:
2337 * if only 1, say 0, since there's then no readahead to be done.
2338 */
2341 }
2343 /*
2344 * add_swap_count_continuation - called when a swap count is duplicated
2345 * beyond SWAP_MAP_MAX, it allocates a new page and links that to the entry's
2346 * page of the original vmalloc'ed swap_map, to hold the continuation count
2347 * (for that entry and for its neighbouring PAGE_SIZE swap entries). Called
2348 * again when count is duplicated beyond SWAP_MAP_MAX * SWAP_CONT_MAX, etc.
2349 *
2350 * These continuation pages are seldom referenced: the common paths all work
2351 * on the original swap_map, only referring to a continuation page when the
2352 * low "digit" of a count is incremented or decremented through SWAP_MAP_MAX.
2353 *
2354 * add_swap_count_continuation(, GFP_ATOMIC) can be called while holding
2355 * page table locks; if it fails, add_swap_count_continuation(, GFP_KERNEL)
2356 * can be called after dropping locks.
2357 */
2359 {
2364 pgoff_t offset;
2367 /*
2368 * When debugging, it's easier to use __GFP_ZERO here; but it's better
2369 * for latency not to zero a page while GFP_ATOMIC and holding locks.
2370 */
2375 /*
2376 * An acceptable race has occurred since the failing
2377 * __swap_duplicate(): the swap entry has been freed,
2378 * perhaps even the whole swap_map cleared for swapoff.
2379 */
2381 }
2387 /*
2388 * The higher the swap count, the more likely it is that tasks
2389 * will race to add swap count continuation: we need to avoid
2390 * over-provisioning.
2391 */
2393 }
2398 }
2400 /*
2401 * We are fortunate that although vmalloc_to_page uses pte_offset_map,
2402 * no architecture is using highmem pages for kernel pagetables: so it
2403 * will not corrupt the GFP_ATOMIC caller's atomic pagetable kmaps.
2404 */
2408 /*
2409 * Page allocation does not initialize the page's lru field,
2410 * but it does always reset its private field.
2411 */
2417 }
2422 /*
2423 * If the previous map said no continuation, but we've found
2424 * a continuation page, free our allocation and use this one.
2425 */
2433 /*
2434 * If this continuation count now has some space in it,
2435 * free our allocation and use this one.
2436 */
2439 }
2443 out:
2445 outer:
2449 }
2451 /*
2452 * swap_count_continued - when the original swap_map count is incremented
2453 * from SWAP_MAP_MAX, check if there is already a continuation page to carry
2454 * into, carry if so, or else fail until a new continuation page is allocated;
2455 * when the original swap_map count is decremented from 0 with continuation,
2456 * borrow from the continuation and report whether it still holds more.
2457 * Called while __swap_duplicate() or swap_entry_free() holds swap_lock.
2458 */
2461 {
2470 }
2480 /*
2481 * Think of how you add 1 to 999
2482 */
2488 }
2496 }
2505 }
2509 /*
2510 * Think of how you subtract 1 from 1000
2511 */
2518 }
2531 }
2533 }
2534 }
2536 /*
2537 * free_swap_count_continuations - swapoff free all the continuation pages
2538 * appended to the swap_map, after swap_map is quiesced, before vfree'ing it.
2539 */
2541 {
2542 pgoff_t offset;
2554 }
2555 }
2556 }
2557 }