| blob | 86cbb2f137158eca5eab239668045006636ef442 |
1 /*
2 * Generic hugetlb support.
3 * (C) Nadia Yvette Chambers, April 2004
4 */
5 #include <linux/list.h>
6 #include <linux/init.h>
7 #include <linux/module.h>
8 #include <linux/mm.h>
9 #include <linux/seq_file.h>
10 #include <linux/sysctl.h>
11 #include <linux/highmem.h>
12 #include <linux/mmu_notifier.h>
13 #include <linux/nodemask.h>
14 #include <linux/pagemap.h>
15 #include <linux/mempolicy.h>
16 #include <linux/cpuset.h>
17 #include <linux/mutex.h>
18 #include <linux/bootmem.h>
19 #include <linux/sysfs.h>
20 #include <linux/slab.h>
21 #include <linux/rmap.h>
22 #include <linux/swap.h>
23 #include <linux/swapops.h>
24 #include <linux/page-isolation.h>
26 #include <asm/page.h>
27 #include <asm/pgtable.h>
28 #include <asm/tlb.h>
30 #include <linux/io.h>
31 #include <linux/hugetlb.h>
32 #include <linux/hugetlb_cgroup.h>
33 #include <linux/node.h>
45 /* for command line parsing */
50 /*
51 * Protects updates to hugepage_freelists, hugepage_activelist, nr_huge_pages,
52 * free_huge_pages, and surplus_huge_pages.
53 */
57 {
62 /* If no pages are used, and no other handles to the subpool
63 * remain, free the subpool the subpool remain */
66 }
69 {
82 }
85 {
90 }
94 {
105 }
109 }
113 {
119 /* If hugetlbfs_put_super couldn't free spool due to
120 * an outstanding quota reference, free it now. */
122 }
125 {
127 }
130 {
132 }
134 /*
135 * Region tracking -- allows tracking of reservations and instantiated pages
136 * across the pages in a mapping.
137 *
138 * The region data structures are protected by a combination of the mmap_sem
139 * and the hugetlb_instantiation_mutex. To access or modify a region the caller
140 * must either hold the mmap_sem for write, or the mmap_sem for read and
141 * the hugetlb_instantiation_mutex:
142 *
143 * down_write(&mm->mmap_sem);
144 * or
145 * down_read(&mm->mmap_sem);
146 * mutex_lock(&hugetlb_instantiation_mutex);
147 */
152 };
155 {
158 /* Locate the region we are either in or before. */
163 /* Round our left edge to the current segment if it encloses us. */
167 /* Check for and consume any regions we now overlap with. */
175 /* If this area reaches higher then extend our area to
176 * include it completely. If this is not the first area
177 * which we intend to reuse, free it. */
183 }
184 }
188 }
191 {
195 /* Locate the region we are before or in. */
200 /* If we are below the current region then a new region is required.
201 * Subtle, allocate a new region at the position but make it zero
202 * size such that we can guarantee to record the reservation. */
213 }
215 /* Round our left edge to the current segment if it encloses us. */
220 /* Check for and consume any regions we now overlap with. */
227 /* We overlap with this area, if it extends further than
228 * us then we must extend ourselves. Account for its
229 * existing reservation. */
233 }
235 }
237 }
240 {
244 /* Locate the region we are either in or before. */
251 /* If we are in the middle of a region then adjust it. */
256 }
258 /* Drop any remaining regions. */
265 }
267 }
270 {
274 /* Locate each segment we overlap with, and count that overlap. */
288 }
291 }
293 /*
294 * Convert the address within this vma to the page offset within
295 * the mapping, in pagecache page units; huge pages here.
296 */
299 {
302 }
306 {
308 }
310 /*
311 * Return the size of the pages allocated when backing a VMA. In the majority
312 * cases this will be same size as used by the page table entries.
313 */
315 {
324 }
327 /*
328 * Return the page size being used by the MMU to back a VMA. In the majority
329 * of cases, the page size used by the kernel matches the MMU size. On
330 * architectures where it differs, an architecture-specific version of this
331 * function is required.
332 */
333 #ifndef vma_mmu_pagesize
335 {
337 }
338 #endif
340 /*
341 * Flags for MAP_PRIVATE reservations. These are stored in the bottom
342 * bits of the reservation map pointer, which are always clear due to
343 * alignment.
344 */
345 #define HPAGE_RESV_OWNER (1UL << 0)
346 #define HPAGE_RESV_UNMAPPED (1UL << 1)
347 #define HPAGE_RESV_MASK (HPAGE_RESV_OWNER | HPAGE_RESV_UNMAPPED)
349 /*
350 * These helpers are used to track how many pages are reserved for
351 * faults in a MAP_PRIVATE mapping. Only the process that called mmap()
352 * is guaranteed to have their future faults succeed.
353 *
354 * With the exception of reset_vma_resv_huge_pages() which is called at fork(),
355 * the reserve counters are updated with the hugetlb_lock held. It is safe
356 * to reset the VMA at fork() time as it is not in use yet and there is no
357 * chance of the global counters getting corrupted as a result of the values.
358 *
359 * The private mapping reservation is represented in a subtly different
360 * manner to a shared mapping. A shared mapping has a region map associated
361 * with the underlying file, this region map represents the backing file
362 * pages which have ever had a reservation assigned which this persists even
363 * after the page is instantiated. A private mapping has a region map
364 * associated with the original mmap which is attached to all VMAs which
365 * reference it, this region map represents those offsets which have consumed
366 * reservation ie. where pages have been instantiated.
367 */
369 {
371 }
375 {
377 }
382 };
385 {
394 }
397 {
400 /* Clear out any active regions before we release the map. */
403 }
406 {
412 }
415 {
421 }
424 {
429 }
432 {
436 }
438 /* Reset counters to 0 and clear all HPAGE_RESV_* flags */
440 {
444 }
446 /* Returns true if the VMA has associated reserve pages */
448 {
450 /*
451 * This address is already reserved by other process(chg == 0),
452 * so, we should decrement reserved count. Without decrementing,
453 * reserve count remains after releasing inode, because this
454 * allocated page will go into page cache and is regarded as
455 * coming from reserved pool in releasing step. Currently, we
456 * don't have any other solution to deal with this situation
457 * properly, so add work-around here.
458 */
461 else
463 }
465 /* Shared mappings always use reserves */
469 /*
470 * Only the process that called mmap() has reserves for
471 * private mappings.
472 */
477 }
480 {
485 }
488 {
494 /*
495 * if 'non-isolated free hugepage' not found on the list,
496 * the allocation fails.
497 */
505 }
507 /* Movability of hugepages depends on migration support. */
509 {
512 else
514 }
520 {
529 /*
530 * A child process with MAP_PRIVATE mappings created by their parent
531 * have no page reserves. This check ensures that reservations are
532 * not "stolen". The child may still get SIGKILLed
533 */
538 /* If reserves cannot be used, ensure enough pages are in the pool */
542 retry_cpuset:
560 }
561 }
562 }
569 err:
571 }
574 {
586 }
592 }
595 {
601 }
603 }
606 {
607 /*
608 * Can't pass hstate in here because it is called from the
609 * compound page destructor.
610 */
631 /* remove the page from active list */
639 }
642 }
645 {
654 }
657 {
662 /* we rely on prep_new_huge_page to set the destructor */
668 /*
669 * For gigantic hugepages allocated through bootmem at
670 * boot, it's safer to be consistent with the not-gigantic
671 * hugepages and clear the PG_reserved bit from all tail pages
672 * too. Otherwse drivers using get_user_pages() to access tail
673 * pages may get the reference counting wrong if they see
674 * PG_reserved set on a tail page (despite the head page not
675 * having PG_reserved set). Enforcing this consistency between
676 * head and tail pages allows drivers to optimize away a check
677 * on the head page when they need know if put_page() is needed
678 * after get_user_pages().
679 */
683 }
684 }
686 /*
687 * PageHuge() only returns true for hugetlbfs pages, but not for normal or
688 * transparent huge pages. See the PageTransHuge() documentation for more
689 * details.
690 */
692 {
698 }
701 /*
702 * PageHeadHuge() only returns true for hugetlbfs head page, but not for
703 * normal or transparent huge pages.
704 */
706 {
711 }
714 {
724 else
728 }
731 {
745 }
747 }
750 }
752 /*
753 * common helper functions for hstate_next_node_to_{alloc|free}.
754 * We may have allocated or freed a huge page based on a different
755 * nodes_allowed previously, so h->next_node_to_{alloc|free} might
756 * be outside of *nodes_allowed. Ensure that we use an allowed
757 * node for alloc or free.
758 */
760 {
767 }
770 {
774 }
776 /*
777 * returns the previously saved node ["this node"] from which to
778 * allocate a persistent huge page for the pool and advance the
779 * next node from which to allocate, handling wrap at end of node
780 * mask.
781 */
784 {
793 }
795 /*
796 * helper for free_pool_huge_page() - return the previously saved
797 * node ["this node"] from which to free a huge page. Advance the
798 * next node id whether or not we find a free huge page to free so
799 * that the next attempt to free addresses the next node.
800 */
802 {
811 }
813 #define for_each_node_mask_to_alloc(hs, nr_nodes, node, mask) \
814 for (nr_nodes = nodes_weight(*mask); \
815 nr_nodes > 0 && \
816 ((node = hstate_next_node_to_alloc(hs, mask)) || 1); \
817 nr_nodes--)
819 #define for_each_node_mask_to_free(hs, nr_nodes, node, mask) \
820 for (nr_nodes = nodes_weight(*mask); \
821 nr_nodes > 0 && \
822 ((node = hstate_next_node_to_free(hs, mask)) || 1); \
823 nr_nodes--)
826 {
836 }
837 }
841 else
845 }
847 /*
848 * Free huge page from pool from next node to free.
849 * Attempt to keep persistent huge pages more or less
850 * balanced over allowed nodes.
851 * Called with hugetlb_lock locked.
852 */
855 {
860 /*
861 * If we're returning unused surplus pages, only examine
862 * nodes with surplus pages.
863 */
875 }
879 }
880 }
883 }
885 /*
886 * Dissolve a given free hugepage into free buddy pages. This function does
887 * nothing for in-use (including surplus) hugepages.
888 */
890 {
899 }
901 }
903 /*
904 * Dissolve free hugepages in a given pfn range. Used by memory hotplug to
905 * make specified memory blocks removable from the system.
906 * Note that start_pfn should aligned with (minimum) hugepage size.
907 */
909 {
914 /* Set scan step to minimum hugepage size */
921 }
924 {
931 /*
932 * Assume we will successfully allocate the surplus page to
933 * prevent racing processes from causing the surplus to exceed
934 * overcommit
935 *
936 * This however introduces a different race, where a process B
937 * tries to grow the static hugepage pool while alloc_pages() is
938 * called by process A. B will only examine the per-node
939 * counters in determining if surplus huge pages can be
940 * converted to normal huge pages in adjust_pool_surplus(). A
941 * won't be able to increment the per-node counter, until the
942 * lock is dropped by B, but B doesn't drop hugetlb_lock until
943 * no more huge pages can be converted from surplus to normal
944 * state (and doesn't try to convert again). Thus, we have a
945 * case where a surplus huge page exists, the pool is grown, and
946 * the surplus huge page still exists after, even though it
947 * should just have been converted to a normal huge page. This
948 * does not leak memory, though, as the hugepage will be freed
949 * once it is out of use. It also does not allow the counters to
950 * go out of whack in adjust_pool_surplus() as we don't modify
951 * the node values until we've gotten the hugepage and only the
952 * per-node value is checked there.
953 */
961 }
968 else
976 }
984 /*
985 * We incremented the global counters already
986 */
994 }
998 }
1000 /*
1001 * This allocation function is useful in the context where vma is irrelevant.
1002 * E.g. soft-offlining uses this function because it only cares physical
1003 * address of error page.
1004 */
1006 {
1018 }
1020 /*
1021 * Increase the hugetlb pool such that it can accommodate a reservation
1022 * of size 'delta'.
1023 */
1025 {
1036 }
1042 retry:
1049 }
1051 }
1054 /*
1055 * After retaking hugetlb_lock, we need to recalculate 'needed'
1056 * because either resv_huge_pages or free_huge_pages may have changed.
1057 */
1064 /*
1065 * We were not able to allocate enough pages to
1066 * satisfy the entire reservation so we free what
1067 * we've allocated so far.
1068 */
1070 }
1071 /*
1072 * The surplus_list now contains _at_least_ the number of extra pages
1073 * needed to accommodate the reservation. Add the appropriate number
1074 * of pages to the hugetlb pool and free the extras back to the buddy
1075 * allocator. Commit the entire reservation here to prevent another
1076 * process from stealing the pages as they are added to the pool but
1077 * before they are reserved.
1078 */
1083 /* Free the needed pages to the hugetlb pool */
1087 /*
1088 * This page is now managed by the hugetlb allocator and has
1089 * no users -- drop the buddy allocator's reference.
1090 */
1094 }
1095 free:
1098 /* Free unnecessary surplus pages to the buddy allocator */
1104 }
1106 /*
1107 * When releasing a hugetlb pool reservation, any surplus pages that were
1108 * allocated to satisfy the reservation must be explicitly freed if they were
1109 * never used.
1110 * Called with hugetlb_lock held.
1111 */
1114 {
1117 /* Uncommit the reservation */
1120 /* Cannot return gigantic pages currently */
1126 /*
1127 * We want to release as many surplus pages as possible, spread
1128 * evenly across all nodes with memory. Iterate across these nodes
1129 * until we can no longer free unreserved surplus pages. This occurs
1130 * when the nodes with surplus pages have no free pages.
1131 * free_pool_huge_page() will balance the the freed pages across the
1132 * on-line nodes with memory and will handle the hstate accounting.
1133 */
1138 }
1139 }
1141 /*
1142 * Determine if the huge page at addr within the vma has an associated
1143 * reservation. Where it does not we will need to logically increase
1144 * reservation and actually increase subpool usage before an allocation
1145 * can occur. Where any new reservation would be required the
1146 * reservation change is prepared, but not committed. Once the page
1147 * has been allocated from the subpool and instantiated the change should
1148 * be committed via vma_commit_reservation. No action is required on
1149 * failure.
1150 */
1153 {
1174 }
1175 }
1178 {
1190 /* Mark this page used in the map. */
1192 }
1193 }
1197 {
1206 /*
1207 * Processes that did not create the mapping will have no
1208 * reserves and will not have accounted against subpool
1209 * limit. Check that the subpool limit can be made before
1210 * satisfying the allocation MAP_NORESERVE mappings may also
1211 * need pages and subpool limit allocated allocated if no reserve
1212 * mapping overlaps.
1213 */
1226 }
1235 h_cg);
1239 }
1242 /* Fall through */
1243 }
1251 }
1253 /*
1254 * alloc_huge_page()'s wrapper which simply returns the page if allocation
1255 * succeeds, otherwise NULL. This function is called from new_vma_page(),
1256 * where no ERR_VALUE is expected to be returned.
1257 */
1260 {
1265 }
1268 {
1279 /*
1280 * Use the beginning of the huge page to store the
1281 * huge_bootmem_page struct (until gather_bootmem
1282 * puts them into the mem_map).
1283 */
1286 }
1287 }
1290 found:
1292 /* Put them into a private list first because mem_map is not up yet */
1296 }
1299 {
1302 else
1304 }
1306 /* Put bootmem huge pages into the standard lists after mem_map is up */
1308 {
1315 #ifdef CONFIG_HIGHMEM
1319 #else
1321 #endif
1326 /*
1327 * If we had gigantic hugepages allocated at boot time, we need
1328 * to restore the 'stolen' pages to totalram_pages in order to
1329 * fix confusing memory reports from free(1) and another
1330 * side-effects, like CommitLimit going negative.
1331 */
1334 }
1335 }
1338 {
1348 }
1350 }
1353 {
1357 /* oversize hugepages were init'ed in early boot */
1360 }
1361 }
1364 {
1369 else
1372 }
1375 {
1383 }
1384 }
1386 #ifdef CONFIG_HIGHMEM
1389 {
1407 }
1408 }
1409 }
1410 #else
1413 {
1414 }
1415 #endif
1417 /*
1418 * Increment or decrement surplus_huge_pages. Keep node-specific counters
1419 * balanced by operating on them in a round-robin fashion.
1420 * Returns 1 if an adjustment was made.
1421 */
1424 {
1433 }
1439 }
1440 }
1443 found:
1447 }
1449 #define persistent_huge_pages(h) (h->nr_huge_pages - h->surplus_huge_pages)
1452 {
1458 /*
1459 * Increase the pool size
1460 * First take pages out of surplus state. Then make up the
1461 * remaining difference by allocating fresh huge pages.
1462 *
1463 * We might race with alloc_buddy_huge_page() here and be unable
1464 * to convert a surplus huge page to a normal huge page. That is
1465 * not critical, though, it just means the overall size of the
1466 * pool might be one hugepage larger than it needs to be, but
1467 * within all the constraints specified by the sysctls.
1468 */
1473 }
1476 /*
1477 * If this allocation races such that we no longer need the
1478 * page, free_huge_page will handle it by freeing the page
1479 * and reducing the surplus.
1480 */
1487 /* Bail for signals. Probably ctrl-c from user */
1490 }
1492 /*
1493 * Decrease the pool size
1494 * First return free pages to the buddy allocator (being careful
1495 * to keep enough around to satisfy reservations). Then place
1496 * pages into surplus state as needed so the pool will shrink
1497 * to the desired size as pages become free.
1498 *
1499 * By placing pages into the surplus state independent of the
1500 * overcommit value, we are allowing the surplus pool size to
1501 * exceed overcommit. There are few sane options here. Since
1502 * alloc_buddy_huge_page() is checking the global counter,
1503 * though, we'll note that we're not allowed to exceed surplus
1504 * and won't grow the pool anywhere else. Not until one of the
1505 * sysctls are changed, or the surplus pages go out of use.
1506 */
1514 }
1518 }
1519 out:
1523 }
1525 #define HSTATE_ATTR_RO(_name) \
1526 static struct kobj_attribute _name##_attr = __ATTR_RO(_name)
1528 #define HSTATE_ATTR(_name) \
1529 static struct kobj_attribute _name##_attr = \
1530 __ATTR(_name, 0644, _name##_show, _name##_store)
1538 {
1546 }
1549 }
1553 {
1561 else
1565 }
1570 {
1585 }
1588 /*
1589 * global hstate attribute
1590 */
1595 }
1597 /*
1598 * per node hstate attribute: adjust count to global,
1599 * but restrict alloc/free to the specified node.
1600 */
1612 out:
1615 }
1619 {
1621 }
1625 {
1627 }
1630 #ifdef CONFIG_NUMA
1632 /*
1633 * hstate attribute for optionally mempolicy-based constraint on persistent
1634 * huge page alloc/free.
1635 */
1638 {
1640 }
1644 {
1646 }
1648 #endif
1653 {
1656 }
1660 {
1677 }
1682 {
1690 else
1694 }
1699 {
1702 }
1707 {
1715 else
1719 }
1728 #ifdef CONFIG_NUMA
1730 #endif
1731 NULL,
1732 };
1736 };
1741 {
1754 }
1757 {
1770 }
1771 }
1773 #ifdef CONFIG_NUMA
1775 /*
1776 * node_hstate/s - associate per node hstate attributes, via their kobjects,
1777 * with node devices in node_devices[] using a parallel array. The array
1778 * index of a node device or _hstate == node id.
1779 * This is here to avoid any static dependency of the node device driver, in
1780 * the base kernel, on the hugetlb module.
1781 */
1785 };
1788 /*
1789 * A subset of global hstate attributes for node devices
1790 */
1795 NULL,
1796 };
1800 };
1802 /*
1803 * kobj_to_node_hstate - lookup global hstate for node device hstate attr kobj.
1804 * Returns node id via non-NULL nidp.
1805 */
1807 {
1818 }
1819 }
1823 }
1825 /*
1826 * Unregister hstate attributes from a single node device.
1827 * No-op if no hstate attributes attached.
1828 */
1830 {
1842 }
1843 }
1847 }
1849 /*
1850 * hugetlb module exit: unregister hstate attributes from node devices
1851 * that have them.
1852 */
1854 {
1857 /*
1858 * disable node device registrations.
1859 */
1862 /*
1863 * remove hstate attributes from any nodes that have them.
1864 */
1867 }
1869 /*
1870 * Register hstate attributes for a single node device.
1871 * No-op if attributes already registered.
1872 */
1874 {
1896 }
1897 }
1898 }
1900 /*
1901 * hugetlb init time: register hstate attributes for all registered node
1902 * devices of nodes that have memory. All on-line nodes should have
1903 * registered their associated device by this time.
1904 */
1906 {
1913 }
1915 /*
1916 * Let the node device driver know we're here so it can
1917 * [un]register hstate attributes on node hotplug.
1918 */
1920 hugetlb_unregister_node);
1921 }
1925 {
1930 }
1936 #endif
1939 {
1946 }
1949 }
1953 {
1954 /* Some platform decide whether they support huge pages at boot
1955 * time. On these, such as powerpc, HPAGE_SHIFT is set to 0 when
1956 * there is no such support
1957 */
1965 }
1979 }
1982 /* Should be called on processing a hugepagesz=... option */
1984 {
1991 }
2008 }
2011 {
2015 /*
2016 * !hugetlb_max_hstate means we haven't parsed a hugepagesz= parameter yet,
2017 * so this hugepages= parameter goes to the "default hstate".
2018 */
2021 else
2028 }
2033 /*
2034 * Global state is always initialized later in hugetlb_init.
2035 * But we need to allocate >= MAX_ORDER hstates here early to still
2036 * use the bootmem allocator.
2037 */
2044 }
2048 {
2051 }
2055 {
2063 }
2065 #ifdef CONFIG_SYSCTL
2069 {
2095 }
2100 }
2101 out:
2103 }
2107 {
2111 }
2113 #ifdef CONFIG_NUMA
2116 {
2119 }
2125 {
2148 }
2149 out:
2151 }
2156 {
2171 }
2174 {
2185 }
2188 {
2197 pr_info("Node %d hugepages_total=%u hugepages_free=%u hugepages_surp=%u hugepages_size=%lukB\n",
2198 nid,
2203 }
2205 /* Return the number pages of memory we physically have, in PAGE_SIZE units. */
2207 {
2214 }
2217 {
2221 /*
2222 * When cpuset is configured, it breaks the strict hugetlb page
2223 * reservation as the accounting is done on a global variable. Such
2224 * reservation is completely rubbish in the presence of cpuset because
2225 * the reservation is not checked against page availability for the
2226 * current cpuset. Application can still potentially OOM'ed by kernel
2227 * with lack of free htlb page in cpuset that the task is in.
2228 * Attempt to enforce strict accounting with cpuset is almost
2229 * impossible (or too ugly) because cpuset is too fluid that
2230 * task or memory node can be dynamically moved between cpusets.
2231 *
2232 * The change of semantics for shared hugetlb mapping with cpuset is
2233 * undesirable. However, in order to preserve some of the semantics,
2234 * we fall back to check against current free page availability as
2235 * a best attempt and hopefully to minimize the impact of changing
2236 * semantics that cpuset has.
2237 */
2245 }
2246 }
2252 out:
2255 }
2258 {
2261 /*
2262 * This new VMA should share its siblings reservation map if present.
2263 * The VMA will only ever have a valid reservation map pointer where
2264 * it is being copied for another still existing VMA. As that VMA
2265 * has a reference to the reservation map it cannot disappear until
2266 * after this open call completes. It is therefore safe to take a
2267 * new reference here without additional locking.
2268 */
2271 }
2274 {
2280 }
2283 {
2303 }
2304 }
2305 }
2307 /*
2308 * We cannot handle pagefaults against hugetlb pages at all. They cause
2309 * handle_mm_fault() to try to instantiate regular-sized pages in the
2310 * hugegpage VMA. do_page_fault() is supposed to trap this, so BUG is we get
2311 * this far.
2312 */
2314 {
2317 }
2323 };
2327 {
2328 pte_t entry;
2336 }
2342 }
2346 {
2347 pte_t entry;
2352 }
2355 {
2356 swp_entry_t swp;
2363 else
2365 }
2368 {
2369 swp_entry_t swp;
2376 else
2378 }
2382 {
2409 }
2411 /* If the pagetables are shared don't copy or take references */
2420 ;
2426 /*
2427 * COW mappings require pages in both
2428 * parent and child to be set to read.
2429 */
2433 }
2443 }
2446 }
2452 }
2457 {
2462 pte_t pte;
2476 again:
2490 /*
2491 * Migrating hugepage or HWPoisoned hugepage is already
2492 * unmapped and its refcount is dropped, so just clear pte here.
2493 */
2497 }
2500 /*
2501 * If a reference page is supplied, it is because a specific
2502 * page is being unmapped, not a range. Ensure the page we
2503 * are about to unmap is the actual page of interest.
2504 */
2509 /*
2510 * Mark the VMA as having unmapped its page so that
2511 * future faults in this VMA will fail rather than
2512 * looking like data was lost
2513 */
2515 }
2527 }
2528 /* Bail out after unmapping reference page if supplied */
2532 }
2533 unlock:
2535 }
2536 /*
2537 * mmu_gather ran out of room to batch pages, we break out of
2538 * the PTE lock to avoid doing the potential expensive TLB invalidate
2539 * and page-free while holding it.
2540 */
2546 }
2549 }
2554 {
2557 /*
2558 * Clear this flag so that x86's huge_pmd_share page_table_shareable
2559 * test will fail on a vma being torn down, and not grab a page table
2560 * on its way out. We're lucky that the flag has such an appropriate
2561 * name, and can in fact be safely cleared here. We could clear it
2562 * before the __unmap_hugepage_range above, but all that's necessary
2563 * is to clear it before releasing the i_mmap_mutex. This works
2564 * because in the context this is called, the VMA is about to be
2565 * destroyed and the i_mmap_mutex is held.
2566 */
2568 }
2572 {
2581 }
2583 /*
2584 * This is called when the original mapper is failing to COW a MAP_PRIVATE
2585 * mappping it owns the reserve page for. The intention is to unmap the page
2586 * from other VMAs and let the children be SIGKILLed if they are faulting the
2587 * same region.
2588 */
2591 {
2595 pgoff_t pgoff;
2597 /*
2598 * vm_pgoff is in PAGE_SIZE units, hence the different calculation
2599 * from page cache lookup which is in HPAGE_SIZE units.
2600 */
2606 /*
2607 * Take the mapping lock for the duration of the table walk. As
2608 * this mapping should be shared between all the VMAs,
2609 * __unmap_hugepage_range() is called as the lock is already held
2610 */
2613 /* Do not unmap the current VMA */
2617 /*
2618 * Shared VMAs have their own reserves and do not affect
2619 * MAP_PRIVATE accounting but it is possible that a shared
2620 * VMA is using the same page so check and skip such VMAs.
2621 */
2625 /*
2626 * Unmap the page from other VMAs without their own reserves.
2627 * They get marked to be SIGKILLed if they fault in these
2628 * areas. This is because a future no-page fault on this VMA
2629 * could insert a zeroed page instead of the data existing
2630 * from the time of fork. This would look like data corruption
2631 */
2635 }
2639 }
2641 /*
2642 * Hugetlb_cow() should be called with page lock of the original hugepage held.
2643 * Called with hugetlb_instantiation_mutex held and pte_page locked so we
2644 * cannot race with other handlers or page migration.
2645 * Keep the pte_same checks anyway to make transition from the mutex easier.
2646 */
2650 {
2659 retry_avoidcopy:
2660 /* If no-one else is actually using this page, avoid the copy
2661 * and just make the page writable */
2666 }
2668 /*
2669 * If the process that created a MAP_PRIVATE mapping is about to
2670 * perform a COW due to a shared page count, attempt to satisfy
2671 * the allocation without using the existing reserves. The pagecache
2672 * page is used to determine if the reserve at this address was
2673 * consumed or not. If reserves were used, a partial faulted mapping
2674 * at the time of fork() could consume its reserves on COW instead
2675 * of the full address range.
2676 */
2683 /* Drop page table lock as buddy allocator may be called */
2691 /*
2692 * If a process owning a MAP_PRIVATE mapping fails to COW,
2693 * it is due to references held by a child and an insufficient
2694 * huge page pool. To guarantee the original mappers
2695 * reliability, unmap the page from child processes. The child
2696 * may get SIGKILLed if it later faults.
2697 */
2706 /*
2707 * race occurs while re-acquiring page table
2708 * lock, and our job is done.
2709 */
2711 }
2713 }
2715 /* Caller expects lock to be held */
2719 else
2721 }
2723 /*
2724 * When the original hugepage is shared one, it does not have
2725 * anon_vma prepared.
2726 */
2730 /* Caller expects lock to be held */
2733 }
2742 /*
2743 * Retake the page table lock to check for racing updates
2744 * before the page tables are altered
2745 */
2751 /* Break COW */
2757 /* Make the old page be freed below */
2759 }
2765 /* Caller expects lock to be held */
2768 }
2770 /* Return the pagecache page at a given address within a VMA */
2773 {
2775 pgoff_t idx;
2781 }
2783 /*
2784 * Return whether there is a pagecache page to back given address within VMA.
2785 * Caller follow_hugetlb_page() holds page_table_lock so we cannot lock_page.
2786 */
2789 {
2791 pgoff_t idx;
2801 }
2805 {
2809 pgoff_t idx;
2813 pte_t new_pte;
2816 /*
2817 * Currently, we are forced to kill the process in the event the
2818 * original mapper has unmapped pages from the child due to a failed
2819 * COW. Warn that such a situation has occurred as it may not be obvious
2820 */
2825 }
2830 /*
2831 * Use page lock to guard against racing truncation
2832 * before we get page_table_lock.
2833 */
2834 retry:
2845 else
2848 }
2862 }
2873 }
2875 }
2877 /*
2878 * If memory error occurs between mmap() and fault, some process
2879 * don't have hwpoisoned swap entry for errored virtual address.
2880 * So we need to block hugepage fault by PG_hwpoison bit check.
2881 */
2886 }
2887 }
2889 /*
2890 * If we are going to COW a private mapping later, we examine the
2891 * pending reservations for this page now. This will ensure that
2892 * any allocations necessary to record that reservation occur outside
2893 * the spinlock.
2894 */
2899 }
2914 }
2915 else
2922 /* Optimization, do the COW without a second fault */
2924 }
2928 out:
2931 backout:
2933 backout_unlocked:
2937 }
2941 {
2943 pte_t entry;
2962 }
2968 /*
2969 * Serialize hugepage allocation and instantiation, so that we don't
2970 * get spurious allocation failures if two CPUs race to instantiate
2971 * the same page in the page cache.
2972 */
2978 }
2982 /*
2983 * If we are going to COW the mapping later, we examine the pending
2984 * reservations for this page now. This will ensure that any
2985 * allocations necessary to record that reservation occur outside the
2986 * spinlock. For private mappings, we also lookup the pagecache
2987 * page now as it is used to determine if a reservation has been
2988 * consumed.
2989 */
2994 }
2999 }
3001 /*
3002 * hugetlb_cow() requires page locks of pte_page(entry) and
3003 * pagecache_page, so here we need take the former one
3004 * when page != pagecache_page or !pagecache_page.
3005 * Note that locking order is always pagecache_page -> page,
3006 * so no worry about deadlock.
3007 */
3015 /* Check for a racing update before calling hugetlb_cow */
3025 }
3027 }
3033 out_ptl:
3039 }
3044 out_mutex:
3048 }
3054 {
3066 /*
3067 * Some archs (sparc64, sh*) have multiple pte_ts to
3068 * each hugepage. We have to make sure we get the
3069 * first, for the page indexing below to work.
3070 *
3071 * Note that page table lock is not held when pte is null.
3072 */
3078 /*
3079 * When coredumping, it suits get_dump_page if we just return
3080 * an error where there's an empty slot with no huge pagecache
3081 * to back it. This way, we avoid allocating a hugepage, and
3082 * the sparse dumpfile avoids allocating disk blocks, but its
3083 * huge holes still show up with zeroes where they need to be.
3084 */
3091 }
3093 /*
3094 * We need call hugetlb_fault for both hugepages under migration
3095 * (in which case hugetlb_fault waits for the migration,) and
3096 * hwpoisoned hugepages (in which case we need to prevent the
3097 * caller from accessing to them.) In order to do this, we use
3098 * here is_swap_pte instead of is_hugetlb_entry_migration and
3099 * is_hugetlb_entry_hwpoisoned. This is because it simply covers
3100 * both cases, and because we can't follow correct pages
3101 * directly from any kind of swap entries.
3102 */
3117 }
3121 same_page:
3125 }
3136 /*
3137 * We use pfn_offset to avoid touching the pageframes
3138 * of this compound page.
3139 */
3141 }
3143 }
3148 }
3152 {
3156 pte_t pte;
3171 pages++;
3174 }
3179 }
3184 pte_t newpte;
3189 pages++;
3190 }
3193 }
3199 pages++;
3200 }
3202 }
3203 /*
3204 * Must flush TLB before releasing i_mmap_mutex: x86's huge_pmd_unshare
3205 * may have cleared our pud entry and done put_page on the page table:
3206 * once we release i_mmap_mutex, another task can do the final put_page
3207 * and that page table be reused and filled with junk.
3208 */
3213 }
3218 vm_flags_t vm_flags)
3219 {
3224 /*
3225 * Only apply hugepage reservation if asked. At fault time, an
3226 * attempt will be made for VM_NORESERVE to allocate a page
3227 * without using reserves
3228 */
3232 /*
3233 * Shared mappings base their reservation on the number of pages that
3234 * are already allocated on behalf of the file. Private mappings need
3235 * to reserve the full area even if read-only as mprotect() may be
3236 * called to make the mapping read-write. Assume !vma is a shm mapping
3237 */
3249 }
3254 }
3256 /* There must be enough pages in the subpool for the mapping */
3260 }
3262 /*
3263 * Check enough hugepages are available for the reservation.
3264 * Hand the pages back to the subpool if there are not
3265 */
3270 }
3272 /*
3273 * Account for the reservations made. Shared mappings record regions
3274 * that have reservations as they are shared by multiple VMAs.
3275 * When the last VMA disappears, the region map says how much
3276 * the reservation was and the page cache tells how much of
3277 * the reservation was consumed. Private mappings are per-VMA and
3278 * only the consumed reservations are tracked. When the VMA
3279 * disappears, the original reservation is the VMA size and the
3280 * consumed reservations are stored in the map. Hence, nothing
3281 * else has to be done for private mappings here
3282 */
3286 out_err:
3290 }
3293 {
3304 }
3306 #ifdef CONFIG_ARCH_WANT_HUGE_PMD_SHARE
3310 {
3316 /* Allow segments to share if only one is marked locked */
3320 /*
3321 * match the virtual addresses, permission and the alignment of the
3322 * page table page.
3323 */
3330 }
3333 {
3337 /*
3338 * check on proper vm_flags and page table alignment
3339 */
3344 }
3346 /*
3347 * Search for a shareable pmd page for hugetlb. In any case calls pmd_alloc()
3348 * and returns the corresponding pte. While this is not necessary for the
3349 * !shared pmd case because we can allocate the pmd later as well, it makes the
3350 * code much cleaner. pmd allocation is essential for the shared case because
3351 * pud has to be populated inside the same i_mmap_mutex section - otherwise
3352 * racing tasks could either miss the sharing (see huge_pte_offset) or select a
3353 * bad pmd for sharing.
3354 */
3356 {
3381 }
3382 }
3383 }
3393 else
3396 out:
3400 }
3402 /*
3403 * unmap huge page backed by shared pte.
3404 *
3405 * Hugetlb pte page is ref counted at the time of mapping. If pte is shared
3406 * indicated by page_count > 1, unmap is achieved by clearing pud and
3407 * decrementing the ref count. If count == 1, the pte page is not shared.
3408 *
3409 * called with page table lock held.
3410 *
3411 * returns: 1 successfully unmapped a shared pte page
3412 * 0 the underlying pte page is not shared, or it is the last user
3413 */
3415 {
3427 }
3428 #define want_pmd_share() (1)
3431 {
3433 }
3434 #define want_pmd_share() (0)
3437 #ifdef CONFIG_ARCH_WANT_GENERAL_HUGETLB
3440 {
3454 else
3456 }
3457 }
3461 }
3464 {
3476 }
3477 }
3479 }
3484 {
3493 }
3498 {
3505 }
3509 /* Can be overriden by architectures */
3513 {
3516 }
3520 #ifdef CONFIG_MEMORY_FAILURE
3522 /* Should be called in hugetlb_lock */
3524 {
3534 }
3536 /*
3537 * This function is called from memory failure code.
3538 * Assume the caller holds page lock of the head page.
3539 */
3541 {
3548 /*
3549 * Hwpoisoned hugepage isn't linked to activelist or freelist,
3550 * but dangling hpage->lru can trigger list-debug warnings
3551 * (this happens when we call unpoison_memory() on it),
3552 * so let it point to itself with list_del_init().
3553 */
3559 }
3562 }
3563 #endif
3566 {
3574 }
3577 {
3583 }
3586 {
3588 /*
3589 * This function can be called for a tail page because the caller,
3590 * scan_movable_pages, scans through a given pfn-range which typically
3591 * covers one memory block. In systems using gigantic hugepage (1GB
3592 * for x86_64,) a hugepage is larger than a memory block, and we don't
3593 * support migrating such large hugepages for now, so return false
3594 * when called for tail pages.
3595 */
3598 /*
3599 * Refcount of a hwpoisoned hugepages is 1, but they are not active,
3600 * so we should return false for them.
3601 */
3605 }