| blob | 2b73dbde2274a535aadf90bb3ca2873347ef66f9 |
1 /*
2 * linux/mm/memory.c
3 *
4 * Copyright (C) 1991, 1992, 1993, 1994 Linus Torvalds
5 */
7 /*
8 * demand-loading started 01.12.91 - seems it is high on the list of
9 * things wanted, and it should be easy to implement. - Linus
10 */
12 /*
13 * Ok, demand-loading was easy, shared pages a little bit tricker. Shared
14 * pages started 02.12.91, seems to work. - Linus.
15 *
16 * Tested sharing by executing about 30 /bin/sh: under the old kernel it
17 * would have taken more than the 6M I have free, but it worked well as
18 * far as I could see.
19 *
20 * Also corrected some "invalidate()"s - I wasn't doing enough of them.
21 */
23 /*
24 * Real VM (paging to/from disk) started 18.12.91. Much more work and
25 * thought has to go into this. Oh, well..
26 * 19.12.91 - works, somewhat. Sometimes I get faults, don't know why.
27 * Found it. Everything seems to work now.
28 * 20.12.91 - Ok, making the swap-device changeable like the root.
29 */
31 /*
32 * 05.04.94 - Multi-page memory management added for v1.1.
33 * Idea by Alex Bligh (alex@cconcepts.co.uk)
34 *
35 * 16.07.99 - Support of BIGMEM added by Gerhard Wichert, Siemens AG
36 * (Gerhard.Wichert@pdb.siemens.de)
37 *
38 * Aug/Sep 2004 Changed to four level page tables (Andi Kleen)
39 */
41 #include <linux/kernel_stat.h>
42 #include <linux/mm.h>
43 #include <linux/hugetlb.h>
44 #include <linux/mman.h>
45 #include <linux/swap.h>
46 #include <linux/highmem.h>
47 #include <linux/pagemap.h>
48 #include <linux/ksm.h>
49 #include <linux/rmap.h>
50 #include <linux/export.h>
51 #include <linux/delayacct.h>
52 #include <linux/init.h>
53 #include <linux/writeback.h>
54 #include <linux/memcontrol.h>
55 #include <linux/mmu_notifier.h>
56 #include <linux/kallsyms.h>
57 #include <linux/swapops.h>
58 #include <linux/elf.h>
59 #include <linux/gfp.h>
60 #include <linux/migrate.h>
61 #include <linux/string.h>
63 #include <asm/io.h>
64 #include <asm/pgalloc.h>
65 #include <asm/uaccess.h>
66 #include <asm/tlb.h>
67 #include <asm/tlbflush.h>
68 #include <asm/pgtable.h>
72 #ifdef LAST_NID_NOT_IN_PAGE_FLAGS
73 #warning Unfortunate NUMA and NUMA Balancing config, growing page-frame for last_nid.
74 #endif
76 #ifndef CONFIG_NEED_MULTIPLE_NODES
77 /* use the per-pgdat data instead for discontigmem - mbligh */
83 #endif
85 /*
86 * A number of key systems in x86 including ioremap() rely on the assumption
87 * that high_memory defines the upper bound on direct map memory, then end
88 * of ZONE_NORMAL. Under CONFIG_DISCONTIG this means that max_low_pfn and
89 * highstart_pfn must be the same; there must be no gap between ZONE_NORMAL
90 * and ZONE_HIGHMEM.
91 */
96 /*
97 * Randomize the address space (stacks, mmaps, brk, etc.).
98 *
99 * ( When CONFIG_COMPAT_BRK=y we exclude brk from randomization,
100 * as ancient (libc5 based) binaries can segfault. )
101 */
103 #ifdef CONFIG_COMPAT_BRK
105 #else
107 #endif
110 {
113 }
119 /*
120 * CONFIG_MMU architectures set up ZERO_PAGE in their paging_init()
121 */
123 {
126 }
130 #if defined(SPLIT_RSS_COUNTING)
133 {
140 }
141 }
143 }
146 {
151 else
153 }
154 #define inc_mm_counter_fast(mm, member) add_mm_counter_fast(mm, member, 1)
155 #define dec_mm_counter_fast(mm, member) add_mm_counter_fast(mm, member, -1)
157 /* sync counter once per 64 page faults */
158 #define TASK_RSS_EVENTS_THRESH (64)
160 {
165 }
168 #define inc_mm_counter_fast(mm, member) inc_mm_counter(mm, member)
169 #define dec_mm_counter_fast(mm, member) dec_mm_counter(mm, member)
172 {
173 }
177 #ifdef HAVE_GENERIC_MMU_GATHER
180 {
187 }
205 }
207 /* tlb_gather_mmu
208 * Called to initialize an (on-stack) mmu_gather structure for page-table
209 * tear-down from @mm. The @fullmm argument is used when @mm is without
210 * users and we're going to destroy the full address space (exit/execve).
211 */
212 void tlb_gather_mmu(struct mmu_gather *tlb, struct mm_struct *mm, unsigned long start, unsigned long end)
213 {
216 /* Is it from 0 to ~0? */
228 #ifdef CONFIG_HAVE_RCU_TABLE_FREE
230 #endif
231 }
234 {
241 #ifdef CONFIG_HAVE_RCU_TABLE_FREE
243 #endif
248 }
250 }
252 /* tlb_finish_mmu
253 * Called at the end of the shootdown operation to free up any resources
254 * that were required.
255 */
257 {
262 /* keep the page table cache within bounds */
268 }
270 }
272 /* __tlb_remove_page
273 * Must perform the equivalent to __free_pte(pte_get_and_clear(ptep)), while
274 * handling the additional races in SMP caused by other CPUs caching valid
275 * mappings in their TLBs. Returns the number of free page slots left.
276 * When out of page slots we must call tlb_flush_mmu().
277 */
279 {
290 }
294 }
298 #ifdef CONFIG_HAVE_RCU_TABLE_FREE
300 /*
301 * See the comment near struct mmu_table_batch.
302 */
305 {
306 /* Simply deliver the interrupt */
307 }
310 {
311 /*
312 * This isn't an RCU grace period and hence the page-tables cannot be
313 * assumed to be actually RCU-freed.
314 *
315 * It is however sufficient for software page-table walkers that rely on
316 * IRQ disabling. See the comment near struct mmu_table_batch.
317 */
320 }
323 {
333 }
336 {
342 }
343 }
346 {
351 /*
352 * When there's less then two users of this mm there cannot be a
353 * concurrent page-table walk.
354 */
358 }
365 }
367 }
371 }
375 /*
376 * Note: this doesn't free the actual pages themselves. That
377 * has been handled earlier when unmapping all the memory regions.
378 */
381 {
386 }
391 {
412 }
419 }
424 {
445 }
452 }
454 /*
455 * This function frees user-level page tables of a process.
456 *
457 * Must be called with pagetable lock held.
458 */
462 {
466 /*
467 * The next few lines have given us lots of grief...
468 *
469 * Why are we testing PMD* at this top level? Because often
470 * there will be no work to do at all, and we'd prefer not to
471 * go all the way down to the bottom just to discover that.
472 *
473 * Why all these "- 1"s? Because 0 represents both the bottom
474 * of the address space and the top of it (using -1 for the
475 * top wouldn't help much: the masks would do the wrong thing).
476 * The rule is that addr 0 and floor 0 refer to the bottom of
477 * the address space, but end 0 and ceiling 0 refer to the top
478 * Comparisons need to use "end - 1" and "ceiling - 1" (though
479 * that end 0 case should be mythical).
480 *
481 * Wherever addr is brought up or ceiling brought down, we must
482 * be careful to reject "the opposite 0" before it confuses the
483 * subsequent tests. But what about where end is brought down
484 * by PMD_SIZE below? no, end can't go down to 0 there.
485 *
486 * Whereas we round start (addr) and ceiling down, by different
487 * masks at different levels, in order to test whether a table
488 * now has no other vmas using it, so can be freed, we don't
489 * bother to round floor or end up - the tests don't need that.
490 */
497 }
502 }
515 }
519 {
524 /*
525 * Hide vma from rmap and truncate_pagecache before freeing
526 * pgtables
527 */
535 /*
536 * Optimization: gather nearby vmas into one call down
537 */
544 }
547 }
549 }
550 }
554 {
560 /*
561 * Ensure all pte setup (eg. pte page lock and page clearing) are
562 * visible before the pte is made visible to other CPUs by being
563 * put into page tables.
564 *
565 * The other side of the story is the pointer chasing in the page
566 * table walking code (when walking the page table without locking;
567 * ie. most of the time). Fortunately, these data accesses consist
568 * of a chain of data-dependent loads, meaning most CPUs (alpha
569 * being the notable exception) will already guarantee loads are
570 * seen in-order. See the alpha page table accessors for the
571 * smp_read_barrier_depends() barriers in page table walking code.
572 */
589 }
592 {
609 }
612 {
614 }
617 {
625 }
627 /*
628 * This function is called to print an error when a bad pte
629 * is found. For example, we might have a PFN-mapped pte in
630 * a region that doesn't allow it.
631 *
632 * The calling function must still handle the error.
633 */
636 {
641 pgoff_t index;
646 /*
647 * Allow a burst of 60 reports, then keep quiet for that minute;
648 * or allow a steady drip of one report per second.
649 */
652 nr_unshown++;
654 }
658 nr_unshown);
660 }
662 }
678 /*
679 * Choose text because data symbols depend on CONFIG_KALLSYMS_ALL=y
680 */
689 }
692 {
694 }
696 /*
697 * vm_normal_page -- This function gets the "struct page" associated with a pte.
698 *
699 * "Special" mappings do not wish to be associated with a "struct page" (either
700 * it doesn't exist, or it exists but they don't want to touch it). In this
701 * case, NULL is returned here. "Normal" mappings do have a struct page.
702 *
703 * There are 2 broad cases. Firstly, an architecture may define a pte_special()
704 * pte bit, in which case this function is trivial. Secondly, an architecture
705 * may not have a spare pte bit, which requires a more complicated scheme,
706 * described below.
707 *
708 * A raw VM_PFNMAP mapping (ie. one that is not COWed) is always considered a
709 * special mapping (even if there are underlying and valid "struct pages").
710 * COWed pages of a VM_PFNMAP are always normal.
711 *
712 * The way we recognize COWed pages within VM_PFNMAP mappings is through the
713 * rules set up by "remap_pfn_range()": the vma will have the VM_PFNMAP bit
714 * set, and the vm_pgoff will point to the first PFN mapped: thus every special
715 * mapping will always honor the rule
716 *
717 * pfn_of_page == vma->vm_pgoff + ((addr - vma->vm_start) >> PAGE_SHIFT)
718 *
719 * And for normal mappings this is false.
720 *
721 * This restricts such mappings to be a linear translation from virtual address
722 * to pfn. To get around this restriction, we allow arbitrary mappings so long
723 * as the vma is not a COW mapping; in that case, we know that all ptes are
724 * special (because none can have been COWed).
725 *
726 *
727 * In order to support COW of arbitrary special mappings, we have VM_MIXEDMAP.
728 *
729 * VM_MIXEDMAP mappings can likewise contain memory with or without "struct
730 * page" backing, however the difference is that _all_ pages with a struct
731 * page (that is, those where pfn_valid is true) are refcounted and considered
732 * normal pages by the VM. The disadvantage is that pages are refcounted
733 * (which can be slower and simply not an option for some PFNMAP users). The
734 * advantage is that we don't have to follow the strict linearity rule of
735 * PFNMAP mappings in order to support COWable mappings.
736 *
737 */
738 #ifdef __HAVE_ARCH_PTE_SPECIAL
739 # define HAVE_PTE_SPECIAL 1
740 #else
741 # define HAVE_PTE_SPECIAL 0
742 #endif
744 pte_t pte)
745 {
756 }
758 /* !HAVE_PTE_SPECIAL case follows: */
772 }
773 }
777 check_pfn:
781 }
783 /*
784 * NOTE! We still have PageReserved() pages in the page tables.
785 * eg. VDSO mappings can cause them to exist.
786 */
787 out:
789 }
791 /*
792 * copy one vm_area from one task to the other. Assumes the page tables
793 * already present in the new task to be cleared in the whole range
794 * covered by this vma.
795 */
801 {
806 /* pte contains position in swap or file, so copy. */
814 /* make sure dst_mm is on swapoff's mmlist. */
821 }
829 else
834 /*
835 * COW mappings require pages in both
836 * parent and child to be set to read.
837 */
841 }
842 }
843 }
845 }
847 /*
848 * If it's a COW mapping, write protect it both
849 * in the parent and the child
850 */
854 }
856 /*
857 * If it's a shared mapping, mark it clean in
858 * the child
859 */
870 else
872 }
874 out_set_pte:
877 }
882 {
890 again:
904 /*
905 * We are holding two locks at this point - either of them
906 * could generate latencies in another task on another CPU.
907 */
913 }
915 progress++;
917 }
936 }
940 }
945 {
964 /* fall through */
965 }
973 }
978 {
995 }
999 {
1009 /*
1010 * Don't copy ptes where a page fault will fill them correctly.
1011 * Fork becomes much lighter when there are big shared or private
1012 * readonly mappings. The tradeoff is that copy_page_range is more
1013 * efficient than faulting.
1014 */
1019 }
1025 /*
1026 * We do not free on error cases below as remove_vma
1027 * gets called on error from higher level routine
1028 */
1032 }
1034 /*
1035 * We need to invalidate the secondary MMU mappings only when
1036 * there could be a permission downgrade on the ptes of the
1037 * parent mm. And a permission downgrade will only happen if
1038 * is_cow_mapping() returns true.
1039 */
1045 mmun_end);
1058 }
1064 }
1070 {
1078 again:
1087 }
1094 /*
1095 * unmap_shared_mapping_pages() wants to
1096 * invalidate cache without truncating:
1097 * unmap shared but keep private pages.
1098 */
1102 /*
1103 * Each page->index must be checked when
1104 * invalidating or truncating nonlinear.
1105 */
1110 }
1123 }
1133 }
1141 }
1142 /*
1143 * If details->check_mapping, we leave swap entries;
1144 * if details->nonlinear_vma, we leave file entries.
1145 */
1163 else
1165 }
1168 }
1176 /*
1177 * mmu_gather ran out of room to batch pages, we break out of
1178 * the PTE lock to avoid doing the potential expensive TLB invalidate
1179 * and page-free while holding it.
1180 */
1186 /*
1187 * Flush the TLB just for the previous segment,
1188 * then update the range to be the remaining
1189 * TLB range.
1190 */
1201 }
1204 }
1210 {
1219 #ifdef CONFIG_DEBUG_VM
1221 pr_err("%s: mmap_sem is unlocked! addr=0x%lx end=0x%lx vma->vm_start=0x%lx vma->vm_end=0x%lx\n",
1226 }
1227 #endif
1231 /* fall through */
1232 }
1233 /*
1234 * Here there can be other concurrent MADV_DONTNEED or
1235 * trans huge page faults running, and if the pmd is
1236 * none or trans huge it can change under us. This is
1237 * because MADV_DONTNEED holds the mmap_sem in read
1238 * mode.
1239 */
1243 next:
1248 }
1254 {
1267 }
1273 {
1292 }
1299 {
1317 /*
1318 * It is undesirable to test vma->vm_file as it
1319 * should be non-null for valid hugetlb area.
1320 * However, vm_file will be NULL in the error
1321 * cleanup path of do_mmap_pgoff. When
1322 * hugetlbfs ->mmap method fails,
1323 * do_mmap_pgoff() nullifies vma->vm_file
1324 * before calling this function to clean up.
1325 * Since no pte has actually been setup, it is
1326 * safe to do nothing in this case.
1327 */
1332 }
1335 }
1336 }
1338 /**
1339 * unmap_vmas - unmap a range of memory covered by a list of vma's
1340 * @tlb: address of the caller's struct mmu_gather
1341 * @vma: the starting vma
1342 * @start_addr: virtual address at which to start unmapping
1343 * @end_addr: virtual address at which to end unmapping
1344 *
1345 * Unmap all pages in the vma list.
1346 *
1347 * Only addresses between `start' and `end' will be unmapped.
1348 *
1349 * The VMA list must be sorted in ascending virtual address order.
1350 *
1351 * unmap_vmas() assumes that the caller will flush the whole unmapped address
1352 * range after unmap_vmas() returns. So the only responsibility here is to
1353 * ensure that any thus-far unmapped pages are flushed before unmap_vmas()
1354 * drops the lock and schedules.
1355 */
1359 {
1366 }
1368 /**
1369 * zap_page_range - remove user pages in a given range
1370 * @vma: vm_area_struct holding the applicable pages
1371 * @start: starting address of pages to zap
1372 * @size: number of bytes to zap
1373 * @details: details of nonlinear truncation or shared cache invalidation
1374 *
1375 * Caller must protect the VMA list
1376 */
1379 {
1392 }
1394 /**
1395 * zap_page_range_single - remove user pages in a given range
1396 * @vma: vm_area_struct holding the applicable pages
1397 * @address: starting address of pages to zap
1398 * @size: number of bytes to zap
1399 * @details: details of nonlinear truncation or shared cache invalidation
1400 *
1401 * The range must fit into one VMA.
1402 */
1405 {
1417 }
1419 /**
1420 * zap_vma_ptes - remove ptes mapping the vma
1421 * @vma: vm_area_struct holding ptes to be zapped
1422 * @address: starting address of pages to zap
1423 * @size: number of bytes to zap
1424 *
1425 * This function only unmaps ptes assigned to VM_PFNMAP vmas.
1426 *
1427 * The entire address range must be fully contained within the vma.
1428 *
1429 * Returns 0 if successful.
1430 */
1433 {
1439 }
1442 /**
1443 * follow_page_mask - look up a page descriptor from a user-virtual address
1444 * @vma: vm_area_struct mapping @address
1445 * @address: virtual address to look up
1446 * @flags: flags modifying lookup behaviour
1447 * @page_mask: on output, *page_mask is set according to the size of the page
1448 *
1449 * @flags can have FOLL_ flags set, defined in <linux/mm.h>
1450 *
1451 * Returns the mapped (struct page *), %NULL if no mapping exists, or
1452 * an error pointer if there is a mapping to something not represented
1453 * by a page descriptor (see also vm_normal_page()).
1454 */
1458 {
1473 }
1488 }
1498 /*
1499 * Refcount on tail pages are not well-defined and
1500 * shouldn't be taken. The caller should handle a NULL
1501 * return when trying to follow tail pages.
1502 */
1508 }
1509 }
1511 }
1518 }
1530 }
1533 /* fall through */
1534 }
1535 split_fallthrough:
1543 swp_entry_t entry;
1544 /*
1545 * KSM's break_ksm() relies upon recognizing a ksm page
1546 * even while it is being migrated, so for that case we
1547 * need migration_entry_wait().
1548 */
1559 }
1571 }
1579 /*
1580 * pte_mkyoung() would be more correct here, but atomic care
1581 * is needed to avoid losing the dirty bit: it is easier to use
1582 * mark_page_accessed().
1583 */
1585 }
1587 /*
1588 * The preliminary mapping check is mainly to avoid the
1589 * pointless overhead of lock_page on the ZERO_PAGE
1590 * which might bounce very badly if there is contention.
1591 *
1592 * If the page is already locked, we don't need to
1593 * handle it now - vmscan will handle it later if and
1594 * when it attempts to reclaim the page.
1595 */
1598 /*
1599 * Because we lock page here, and migration is
1600 * blocked by the pte's page reference, and we
1601 * know the page is still mapped, we don't even
1602 * need to check for file-cache page truncation.
1603 */
1606 }
1607 }
1608 unlock:
1610 out:
1613 bad_page:
1617 no_page:
1622 no_page_table:
1623 /*
1624 * When core dumping an enormous anonymous area that nobody
1625 * has touched so far, we don't want to allocate unnecessary pages or
1626 * page tables. Return error instead of NULL to skip handle_mm_fault,
1627 * then get_dump_page() will return NULL to leave a hole in the dump.
1628 * But we can only make this optimization where a hole would surely
1629 * be zero-filled if handle_mm_fault() actually did handle it.
1630 */
1635 }
1638 {
1641 }
1643 /**
1644 * __get_user_pages() - pin user pages in memory
1645 * @tsk: task_struct of target task
1646 * @mm: mm_struct of target mm
1647 * @start: starting user address
1648 * @nr_pages: number of pages from start to pin
1649 * @gup_flags: flags modifying pin behaviour
1650 * @pages: array that receives pointers to the pages pinned.
1651 * Should be at least nr_pages long. Or NULL, if caller
1652 * only intends to ensure the pages are faulted in.
1653 * @vmas: array of pointers to vmas corresponding to each page.
1654 * Or NULL if the caller does not require them.
1655 * @nonblocking: whether waiting for disk IO or mmap_sem contention
1656 *
1657 * Returns number of pages pinned. This may be fewer than the number
1658 * requested. If nr_pages is 0 or negative, returns 0. If no pages
1659 * were pinned, returns -errno. Each page returned must be released
1660 * with a put_page() call when it is finished with. vmas will only
1661 * remain valid while mmap_sem is held.
1662 *
1663 * Must be called with mmap_sem held for read or write.
1664 *
1665 * __get_user_pages walks a process's page tables and takes a reference to
1666 * each struct page that each user address corresponds to at a given
1667 * instant. That is, it takes the page that would be accessed if a user
1668 * thread accesses the given user virtual address at that instant.
1669 *
1670 * This does not guarantee that the page exists in the user mappings when
1671 * __get_user_pages returns, and there may even be a completely different
1672 * page there in some cases (eg. if mmapped pagecache has been invalidated
1673 * and subsequently re faulted). However it does guarantee that the page
1674 * won't be freed completely. And mostly callers simply care that the page
1675 * contains data that was valid *at some point in time*. Typically, an IO
1676 * or similar operation cannot guarantee anything stronger anyway because
1677 * locks can't be held over the syscall boundary.
1678 *
1679 * If @gup_flags & FOLL_WRITE == 0, the page must not be written to. If
1680 * the page is written to, set_page_dirty (or set_page_dirty_lock, as
1681 * appropriate) must be called after the page is finished with, and
1682 * before put_page is called.
1683 *
1684 * If @nonblocking != NULL, __get_user_pages will not wait for disk IO
1685 * or mmap_sem contention, and if waiting is needed to pin all pages,
1686 * *@nonblocking will be set to 0.
1687 *
1688 * In most cases, get_user_pages or get_user_pages_fast should be used
1689 * instead of __get_user_pages. __get_user_pages should be used only if
1690 * you need some special @gup_flags.
1691 */
1696 {
1706 /*
1707 * Require read or write permissions.
1708 * If FOLL_FORCE is set, we only require the "MAY" flags.
1709 */
1715 /*
1716 * If FOLL_FORCE and FOLL_NUMA are both set, handle_mm_fault
1717 * would be called on PROT_NONE ranges. We must never invoke
1718 * handle_mm_fault on PROT_NONE ranges or the NUMA hinting
1719 * page faults would unprotect the PROT_NONE ranges if
1720 * _PAGE_NUMA and _PAGE_PROTNONE are sharing the same pte/pmd
1721 * bitflag. So to avoid that, don't set FOLL_NUMA if
1722 * FOLL_FORCE is set.
1723 */
1740 /* user gate pages are read-only */
1745 else
1758 }
1771 }
1772 }
1775 }
1779 }
1790 }
1797 /*
1798 * If we have a pending SIGKILL, don't keep faulting
1799 * pages and potentially allocating memory.
1800 */
1810 /* For mlock, just skip the stack guard page. */
1814 }
1823 fault_flags);
1829 VM_FAULT_HWPOISON_LARGE)) {
1834 else
1836 }
1840 }
1845 else
1847 }
1853 }
1855 /*
1856 * The VM_FAULT_WRITE bit tells us that
1857 * do_wp_page has broken COW when necessary,
1858 * even if maybe_mkwrite decided not to set
1859 * pte_write. We can thus safely do subsequent
1860 * page lookups as if they were reads. But only
1861 * do so when looping for pte_write is futile:
1862 * in some cases userspace may also be wanting
1863 * to write to the gotten user page, which a
1864 * read fault here might prevent (a readonly
1865 * page might get reCOWed by userspace write).
1866 */
1872 }
1881 }
1882 next_page:
1886 }
1896 }
1899 /*
1900 * fixup_user_fault() - manually resolve a user page fault
1901 * @tsk: the task_struct to use for page fault accounting, or
1902 * NULL if faults are not to be recorded.
1903 * @mm: mm_struct of target mm
1904 * @address: user address
1905 * @fault_flags:flags to pass down to handle_mm_fault()
1906 *
1907 * This is meant to be called in the specific scenario where for locking reasons
1908 * we try to access user memory in atomic context (within a pagefault_disable()
1909 * section), this returns -EFAULT, and we want to resolve the user fault before
1910 * trying again.
1911 *
1912 * Typically this is meant to be used by the futex code.
1913 *
1914 * The main difference with get_user_pages() is that this function will
1915 * unconditionally call handle_mm_fault() which will in turn perform all the
1916 * necessary SW fixup of the dirty and young bits in the PTE, while
1917 * handle_mm_fault() only guarantees to update these in the struct page.
1918 *
1919 * This is important for some architectures where those bits also gate the
1920 * access permission to the page because they are maintained in software. On
1921 * such architectures, gup() will not be enough to make a subsequent access
1922 * succeed.
1923 *
1924 * This should be called with the mm_sem held for read.
1925 */
1928 {
1945 }
1949 else
1951 }
1953 }
1955 /*
1956 * get_user_pages() - pin user pages in memory
1957 * @tsk: the task_struct to use for page fault accounting, or
1958 * NULL if faults are not to be recorded.
1959 * @mm: mm_struct of target mm
1960 * @start: starting user address
1961 * @nr_pages: number of pages from start to pin
1962 * @write: whether pages will be written to by the caller
1963 * @force: whether to force write access even if user mapping is
1964 * readonly. This will result in the page being COWed even
1965 * in MAP_SHARED mappings. You do not want this.
1966 * @pages: array that receives pointers to the pages pinned.
1967 * Should be at least nr_pages long. Or NULL, if caller
1968 * only intends to ensure the pages are faulted in.
1969 * @vmas: array of pointers to vmas corresponding to each page.
1970 * Or NULL if the caller does not require them.
1971 *
1972 * Returns number of pages pinned. This may be fewer than the number
1973 * requested. If nr_pages is 0 or negative, returns 0. If no pages
1974 * were pinned, returns -errno. Each page returned must be released
1975 * with a put_page() call when it is finished with. vmas will only
1976 * remain valid while mmap_sem is held.
1977 *
1978 * Must be called with mmap_sem held for read or write.
1979 *
1980 * get_user_pages walks a process's page tables and takes a reference to
1981 * each struct page that each user address corresponds to at a given
1982 * instant. That is, it takes the page that would be accessed if a user
1983 * thread accesses the given user virtual address at that instant.
1984 *
1985 * This does not guarantee that the page exists in the user mappings when
1986 * get_user_pages returns, and there may even be a completely different
1987 * page there in some cases (eg. if mmapped pagecache has been invalidated
1988 * and subsequently re faulted). However it does guarantee that the page
1989 * won't be freed completely. And mostly callers simply care that the page
1990 * contains data that was valid *at some point in time*. Typically, an IO
1991 * or similar operation cannot guarantee anything stronger anyway because
1992 * locks can't be held over the syscall boundary.
1993 *
1994 * If write=0, the page must not be written to. If the page is written to,
1995 * set_page_dirty (or set_page_dirty_lock, as appropriate) must be called
1996 * after the page is finished with, and before put_page is called.
1997 *
1998 * get_user_pages is typically used for fewer-copy IO operations, to get a
1999 * handle on the memory by some means other than accesses via the user virtual
2000 * addresses. The pages may be submitted for DMA to devices or accessed via
2001 * their kernel linear mapping (via the kmap APIs). Care should be taken to
2002 * use the correct cache flushing APIs.
2003 *
2004 * See also get_user_pages_fast, for performance critical applications.
2005 */
2009 {
2020 NULL);
2021 }
2024 /**
2025 * get_dump_page() - pin user page in memory while writing it to core dump
2026 * @addr: user address
2027 *
2028 * Returns struct page pointer of user page pinned for dump,
2029 * to be freed afterwards by page_cache_release() or put_page().
2030 *
2031 * Returns NULL on any kind of failure - a hole must then be inserted into
2032 * the corefile, to preserve alignment with its headers; and also returns
2033 * NULL wherever the ZERO_PAGE, or an anonymous pte_none, has been found -
2034 * allowing a hole to be left in the corefile to save diskspace.
2035 *
2036 * Called without mmap_sem, but after all other threads have been killed.
2037 */
2038 #ifdef CONFIG_ELF_CORE
2040 {
2050 }
2055 {
2063 }
2064 }
2066 }
2068 /*
2069 * This is the old fallback for page remapping.
2070 *
2071 * For historical reasons, it only allows reserved pages. Only
2072 * old drivers should use this, and they needed to mark their
2073 * pages reserved for the old functions anyway.
2074 */
2077 {
2095 /* Ok, finally just insert the thing.. */
2104 out_unlock:
2106 out:
2108 }
2110 /**
2111 * vm_insert_page - insert single page into user vma
2112 * @vma: user vma to map to
2113 * @addr: target user address of this page
2114 * @page: source kernel page
2115 *
2116 * This allows drivers to insert individual pages they've allocated
2117 * into a user vma.
2118 *
2119 * The page has to be a nice clean _individual_ kernel allocation.
2120 * If you allocate a compound page, you need to have marked it as
2121 * such (__GFP_COMP), or manually just split the page up yourself
2122 * (see split_page()).
2123 *
2124 * NOTE! Traditionally this was done with "remap_pfn_range()" which
2125 * took an arbitrary page protection parameter. This doesn't allow
2126 * that. Your vma protection will have to be set up correctly, which
2127 * means that if you want a shared writable mapping, you'd better
2128 * ask for a shared writable mapping!
2129 *
2130 * The page does not need to be reserved.
2131 *
2132 * Usually this function is called from f_op->mmap() handler
2133 * under mm->mmap_sem write-lock, so it can change vma->vm_flags.
2134 * Caller must set VM_MIXEDMAP on vma if it wants to call this
2135 * function from other places, for example from page-fault handler.
2136 */
2139 {
2148 }
2150 }
2155 {
2169 /* Ok, finally just insert the thing.. */
2175 out_unlock:
2177 out:
2179 }
2181 /**
2182 * vm_insert_pfn - insert single pfn into user vma
2183 * @vma: user vma to map to
2184 * @addr: target user address of this page
2185 * @pfn: source kernel pfn
2186 *
2187 * Similar to vm_insert_page, this allows drivers to insert individual pages
2188 * they've allocated into a user vma. Same comments apply.
2189 *
2190 * This function should only be called from a vm_ops->fault handler, and
2191 * in that case the handler should return NULL.
2192 *
2193 * vma cannot be a COW mapping.
2194 *
2195 * As this is called only for pages that do not currently exist, we
2196 * do not need to flush old virtual caches or the TLB.
2197 */
2200 {
2203 /*
2204 * Technically, architectures with pte_special can avoid all these
2205 * restrictions (same for remap_pfn_range). However we would like
2206 * consistency in testing and feature parity among all, so we should
2207 * try to keep these invariants in place for everybody.
2208 */
2223 }
2228 {
2234 /*
2235 * If we don't have pte special, then we have to use the pfn_valid()
2236 * based VM_MIXEDMAP scheme (see vm_normal_page), and thus we *must*
2237 * refcount the page if pfn_valid is true (hence insert_page rather
2238 * than insert_pfn). If a zero_pfn were inserted into a VM_MIXEDMAP
2239 * without pte special, it would there be refcounted as a normal page.
2240 */
2246 }
2248 }
2251 /*
2252 * maps a range of physical memory into the requested pages. the old
2253 * mappings are removed. any references to nonexistent pages results
2254 * in null mappings (currently treated as "copy-on-access")
2255 */
2259 {
2270 pfn++;
2275 }
2280 {
2296 }
2301 {
2316 }
2318 /**
2319 * remap_pfn_range - remap kernel memory to userspace
2320 * @vma: user vma to map to
2321 * @addr: target user address to start at
2322 * @pfn: physical address of kernel memory
2323 * @size: size of map area
2324 * @prot: page protection flags for this mapping
2325 *
2326 * Note: this is only safe if the mm semaphore is held when called.
2327 */
2330 {
2337 /*
2338 * Physically remapped pages are special. Tell the
2339 * rest of the world about it:
2340 * VM_IO tells people not to look at these pages
2341 * (accesses can have side effects).
2342 * VM_PFNMAP tells the core MM that the base pages are just
2343 * raw PFN mappings, and do not have a "struct page" associated
2344 * with them.
2345 * VM_DONTEXPAND
2346 * Disable vma merging and expanding with mremap().
2347 * VM_DONTDUMP
2348 * Omit vma from core dump, even when VM_IO turned off.
2349 *
2350 * There's a horrible special case to handle copy-on-write
2351 * behaviour that some programs depend on. We mark the "original"
2352 * un-COW'ed pages by matching them up with "vma->vm_pgoff".
2353 * See vm_normal_page() for details.
2354 */
2359 }
2383 }
2386 /**
2387 * vm_iomap_memory - remap memory to userspace
2388 * @vma: user vma to map to
2389 * @start: start of area
2390 * @len: size of area
2391 *
2392 * This is a simplified io_remap_pfn_range() for common driver use. The
2393 * driver just needs to give us the physical memory range to be mapped,
2394 * we'll figure out the rest from the vma information.
2395 *
2396 * NOTE! Some drivers might want to tweak vma->vm_page_prot first to get
2397 * whatever write-combining details or similar.
2398 */
2400 {
2403 /* Check that the physical memory area passed in looks valid */
2406 /*
2407 * You *really* shouldn't map things that aren't page-aligned,
2408 * but we've historically allowed it because IO memory might
2409 * just have smaller alignment.
2410 */
2417 /* We start the mapping 'vm_pgoff' pages into the area */
2423 /* Can we fit all of the mapping? */
2428 /* Ok, let it rip */
2430 }
2436 {
2439 pgtable_t token;
2465 }
2470 {
2487 }
2492 {
2507 }
2509 /*
2510 * Scan a region of virtual memory, filling in page tables as necessary
2511 * and calling a provided function on each leaf page table.
2512 */
2515 {
2531 }
2534 /*
2535 * handle_pte_fault chooses page fault handler according to an entry
2536 * which was read non-atomically. Before making any commitment, on
2537 * those architectures or configurations (e.g. i386 with PAE) which
2538 * might give a mix of unmatched parts, do_swap_page and do_nonlinear_fault
2539 * must check under lock before unmapping the pte and proceeding
2540 * (but do_wp_page is only called after already making such a check;
2541 * and do_anonymous_page can safely check later on).
2542 */
2545 {
2547 #if defined(CONFIG_SMP) || defined(CONFIG_PREEMPT)
2553 }
2554 #endif
2557 }
2559 static inline void cow_user_page(struct page *dst, struct page *src, unsigned long va, struct vm_area_struct *vma)
2560 {
2561 /*
2562 * If the source page was a PFN mapping, we don't have
2563 * a "struct page" for it. We do a best-effort copy by
2564 * just copying from the original user address. If that
2565 * fails, we just zero-fill it. Live with it.
2566 */
2571 /*
2572 * This really shouldn't fail, because the page is there
2573 * in the page tables. But it might just be unreadable,
2574 * in which case we just give up and fill the result with
2575 * zeroes.
2576 */
2583 }
2585 /*
2586 * This routine handles present pages, when users try to write
2587 * to a shared page. It is done by copying the page to a new address
2588 * and decrementing the shared-page counter for the old page.
2589 *
2590 * Note that this routine assumes that the protection checks have been
2591 * done by the caller (the low-level page fault routine in most cases).
2592 * Thus we can safely just mark it writable once we've done any necessary
2593 * COW.
2594 *
2595 * We also mark the page dirty at this point even though the page will
2596 * change only once the write actually happens. This avoids a few races,
2597 * and potentially makes it more efficient.
2598 *
2599 * We enter with non-exclusive mmap_sem (to exclude vma changes,
2600 * but allow concurrent faults), with pte both mapped and locked.
2601 * We return with mmap_sem still held, but pte unmapped and unlocked.
2602 */
2607 {
2609 pte_t entry;
2618 /*
2619 * VM_MIXEDMAP !pfn_valid() case
2620 *
2621 * We should not cow pages in a shared writeable mapping.
2622 * Just mark the pages writable as we can't do any dirty
2623 * accounting on raw pfn maps.
2624 */
2629 }
2631 /*
2632 * Take out anonymous pages first, anonymous shared vmas are
2633 * not dirty accountable.
2634 */
2645 }
2647 }
2649 /*
2650 * The page is all ours. Move it to our anon_vma so
2651 * the rmap code will not search our parent or siblings.
2652 * Protected against the rmap code by the page lock.
2653 */
2657 }
2661 /*
2662 * Only catch write-faults on shared writable pages,
2663 * read-only shared pages can get COWed by
2664 * get_user_pages(.write=1, .force=1).
2665 */
2671 PAGE_MASK);
2676 /*
2677 * Notify the address space that the page is about to
2678 * become writable so that it can prohibit this or wait
2679 * for the page to get into an appropriate state.
2680 *
2681 * We do this without the lock held, so that it can
2682 * sleep if it needs to.
2683 */
2692 }
2699 }
2703 /*
2704 * Since we dropped the lock we need to revalidate
2705 * the PTE as someone else may have changed it. If
2706 * they did, we just return, as we can count on the
2707 * MMU to tell us if they didn't also make it writable.
2708 */
2714 }
2717 }
2721 reuse:
2733 /*
2734 * Yes, Virginia, this is actually required to prevent a race
2735 * with clear_page_dirty_for_io() from clearing the page dirty
2736 * bit after it clear all dirty ptes, but before a racing
2737 * do_wp_page installs a dirty pte.
2738 *
2739 * __do_fault is protected similarly.
2740 */
2744 /* file_update_time outside page_lock */
2747 }
2756 /*
2757 * Some device drivers do not set page.mapping
2758 * but still dirty their pages
2759 */
2761 }
2762 }
2765 }
2767 /*
2768 * Ok, we need to copy. Oh, well..
2769 */
2771 gotten:
2786 }
2796 /*
2797 * Re-check the pte - we dropped the lock
2798 */
2805 }
2811 /*
2812 * Clear the pte entry and flush it first, before updating the
2813 * pte with the new entry. This will avoid a race condition
2814 * seen in the presence of one thread doing SMC and another
2815 * thread doing COW.
2816 */
2819 /*
2820 * We call the notify macro here because, when using secondary
2821 * mmu page tables (such as kvm shadow page tables), we want the
2822 * new page to be mapped directly into the secondary page table.
2823 */
2827 /*
2828 * Only after switching the pte to the new page may
2829 * we remove the mapcount here. Otherwise another
2830 * process may come and find the rmap count decremented
2831 * before the pte is switched to the new page, and
2832 * "reuse" the old page writing into it while our pte
2833 * here still points into it and can be read by other
2834 * threads.
2835 *
2836 * The critical issue is to order this
2837 * page_remove_rmap with the ptp_clear_flush above.
2838 * Those stores are ordered by (if nothing else,)
2839 * the barrier present in the atomic_add_negative
2840 * in page_remove_rmap.
2841 *
2842 * Then the TLB flush in ptep_clear_flush ensures that
2843 * no process can access the old page before the
2844 * decremented mapcount is visible. And the old page
2845 * cannot be reused until after the decremented
2846 * mapcount is visible. So transitively, TLBs to
2847 * old page will be flushed before it can be reused.
2848 */
2850 }
2852 /* Free the old page.. */
2860 unlock:
2865 /*
2866 * Don't let another task, with possibly unlocked vma,
2867 * keep the mlocked page.
2868 */
2873 }
2875 }
2877 oom_free_new:
2879 oom:
2884 unwritable_page:
2887 }
2892 {
2894 }
2898 {
2907 /* Assume for now that PAGE_CACHE_SHIFT == PAGE_SHIFT */
2918 details);
2919 }
2920 }
2924 {
2927 /*
2928 * In nonlinear VMAs there is no correspondence between virtual address
2929 * offset and file offset. So we must perform an exhaustive search
2930 * across *all* the pages in each nonlinear VMA, not just the pages
2931 * whose virtual address lies outside the file truncation point.
2932 */
2936 }
2937 }
2939 /**
2940 * unmap_mapping_range - unmap the portion of all mmaps in the specified address_space corresponding to the specified page range in the underlying file.
2941 * @mapping: the address space containing mmaps to be unmapped.
2942 * @holebegin: byte in first page to unmap, relative to the start of
2943 * the underlying file. This will be rounded down to a PAGE_SIZE
2944 * boundary. Note that this is different from truncate_pagecache(), which
2945 * must keep the partial page. In contrast, we must get rid of
2946 * partial pages.
2947 * @holelen: size of prospective hole in bytes. This will be rounded
2948 * up to a PAGE_SIZE boundary. A holelen of zero truncates to the
2949 * end of the file.
2950 * @even_cows: 1 when truncating a file, unmap even private COWed pages;
2951 * but 0 when invalidating pagecache, don't throw away private data.
2952 */
2955 {
2960 /* Check for overflow. */
2966 }
2982 }
2985 /*
2986 * We enter with non-exclusive mmap_sem (to exclude vma changes,
2987 * but allow concurrent faults), and pte mapped but not yet locked.
2988 * We return with mmap_sem still held, but pte unmapped and unlocked.
2989 */
2993 {
2996 swp_entry_t entry;
2997 pte_t pte;
3015 }
3017 }
3024 /*
3025 * Back out if somebody else faulted in this pte
3026 * while we released the pte lock.
3027 */
3033 }
3035 /* Had to read the page from swap area: Major fault */
3040 /*
3041 * hwpoisoned dirty swapcache pages are kept for killing
3042 * owner processes (which may be unknown at hwpoison time)
3043 */
3048 }
3057 }
3059 /*
3060 * Make sure try_to_free_swap or reuse_swap_page or swapoff did not
3061 * release the swapcache from under us. The page pin, and pte_same
3062 * test below, are not enough to exclude that. Even if it is still
3063 * swapcache, we need to check that the page's swap has not changed.
3064 */
3073 }
3078 }
3080 /*
3081 * Back out if somebody else already faulted in this pte.
3082 */
3090 }
3092 /*
3093 * The page isn't present yet, go ahead with the fault.
3094 *
3095 * Be careful about the sequence of operations here.
3096 * To get its accounting right, reuse_swap_page() must be called
3097 * while the page is counted on swap but not yet in mapcount i.e.
3098 * before page_add_anon_rmap() and swap_free(); try_to_free_swap()
3099 * must be called after the swap_free(), or it will never succeed.
3100 * Because delete_from_swap_page() may be called by reuse_swap_page(),
3101 * mem_cgroup_commit_charge_swapin() may not be able to find swp_entry
3102 * in page->private. In this case, a record in swap_cgroup is silently
3103 * discarded at swap_free().
3104 */
3114 }
3123 /* It's better to call commit-charge after rmap is established */
3131 /*
3132 * Hold the lock to avoid the swap entry to be reused
3133 * until we take the PT lock for the pte_same() check
3134 * (to avoid false positives from pte_same). For
3135 * further safety release the lock after the swap_free
3136 * so that the swap count won't change under a
3137 * parallel locked swapcache.
3138 */
3141 }
3148 }
3150 /* No need to invalidate - it was non-present before */
3152 unlock:
3154 out:
3156 out_nomap:
3159 out_page:
3161 out_release:
3166 }
3168 }
3170 /*
3171 * This is like a special single-page "expand_{down|up}wards()",
3172 * except we must first make sure that 'address{-|+}PAGE_SIZE'
3173 * doesn't hit another vma.
3174 */
3176 {
3181 /*
3182 * Is there a mapping abutting this one below?
3183 *
3184 * That's only ok if it's the same stack mapping
3185 * that has gotten split..
3186 */
3191 }
3195 /* As VM_GROWSDOWN but s/below/above/ */
3200 }
3202 }
3204 /*
3205 * We enter with non-exclusive mmap_sem (to exclude vma changes,
3206 * but allow concurrent faults), and pte mapped but not yet locked.
3207 * We return with mmap_sem still held, but pte unmapped and unlocked.
3208 */
3212 {
3215 pte_t entry;
3219 /* Check if we need to add a guard page to the stack */
3223 /* Use the zero-page for reads */
3231 }
3233 /* Allocate our own private page. */
3239 /*
3240 * The memory barrier inside __SetPageUptodate makes sure that
3241 * preceeding stores to the page contents become visible before
3242 * the set_pte_at() write.
3243 */
3259 setpte:
3262 /* No need to invalidate - it was non-present before */
3264 unlock:
3267 release:
3271 oom_free_page:
3273 oom:
3275 }
3277 /*
3278 * __do_fault() tries to create a new page mapping. It aggressively
3279 * tries to share with existing pages, but makes a separate copy if
3280 * the FAULT_FLAG_WRITE is set in the flags parameter in order to avoid
3281 * the next page fault.
3282 *
3283 * As this is called only for pages that do not currently exist, we
3284 * do not need to flush old virtual caches or the TLB.
3285 *
3286 * We enter with non-exclusive mmap_sem (to exclude vma changes,
3287 * but allow concurrent faults), and pte neither mapped nor locked.
3288 * We return with mmap_sem still held, but pte unmapped and unlocked.
3289 */
3293 {
3298 pte_t entry;
3305 /*
3306 * If we do COW later, allocate page befor taking lock_page()
3307 * on the file cache page. This will reduce lock holding time.
3308 */
3321 }
3332 VM_FAULT_RETRY)))
3340 }
3342 /*
3343 * For consistency in subsequent calls, make the faulted page always
3344 * locked.
3345 */
3348 else
3351 /*
3352 * Should we do an early C-O-W break?
3353 */
3362 /*
3363 * If the page will be shareable, see if the backing
3364 * address space wants to know that the page is about
3365 * to become writable
3366 */
3377 }
3384 }
3388 }
3389 }
3391 }
3395 /*
3396 * This silly early PAGE_DIRTY setting removes a race
3397 * due to the bad i386 page protection. But it's valid
3398 * for other architectures too.
3399 *
3400 * Note that if FAULT_FLAG_WRITE is set, we either now have
3401 * an exclusive copy of the page, or this is a shared mapping,
3402 * so we can make it writable and dirty to avoid having to
3403 * handle that later.
3404 */
3405 /* Only go through if we didn't race with anybody else... */
3422 }
3423 }
3426 /* no need to invalidate: a not-present page won't be cached */
3433 else
3435 }
3448 /*
3449 * Some device drivers do not set page.mapping but still
3450 * dirty their pages
3451 */
3453 }
3455 /* file_update_time outside page_lock */
3462 }
3466 unwritable_page:
3469 uncharge_out:
3470 /* fs's fault handler get error */
3474 }
3476 }
3481 {
3487 }
3489 /*
3490 * Fault of a previously existing named mapping. Repopulate the pte
3491 * from the encoded file_pte if possible. This enables swappable
3492 * nonlinear vmas.
3493 *
3494 * We enter with non-exclusive mmap_sem (to exclude vma changes,
3495 * but allow concurrent faults), and pte mapped but not yet locked.
3496 * We return with mmap_sem still held, but pte unmapped and unlocked.
3497 */
3501 {
3502 pgoff_t pgoff;
3510 /*
3511 * Page table corrupted: show pte and kill process.
3512 */
3515 }
3519 }
3523 {
3531 }
3535 {
3542 /*
3543 * The "pte" at this point cannot be used safely without
3544 * validation through pte_unmap_same(). It's of NUMA type but
3545 * the pfn may be screwed if the read is non atomic.
3546 *
3547 * ptep_modify_prot_start is not called as this is clearing
3548 * the _PAGE_NUMA bit and it is not really expected that there
3549 * would be concurrent hardware modifications to the PTE.
3550 */
3556 }
3566 }
3572 /*
3573 * Account for the fault against the current node if it not
3574 * being replaced regardless of where the page is located.
3575 */
3579 }
3581 /* Migrate to the requested node */
3586 out:
3590 }
3592 /* NUMA hinting page fault entry point for regular pmds */
3593 #ifdef CONFIG_NUMA_BALANCING
3596 {
3597 pmd_t pmd;
3610 }
3616 /* we're in a page fault so some vma must be in the range */
3635 /* there's a pte present so there must be a vma */
3638 }
3642 }
3646 /* only check non-shared pages */
3650 /*
3651 * Note that the NUMA fault is later accounted to either
3652 * the node that is currently running or where the page is
3653 * migrated to.
3654 */
3661 }
3663 /* Migrate to the requested node */
3671 }
3675 }
3676 #else
3679 {
3682 }
3685 /*
3686 * These routines also need to handle stuff like marking pages dirty
3687 * and/or accessed for architectures that don't do it in hardware (most
3688 * RISC architectures). The early dirtying is also good on the i386.
3689 *
3690 * There is also a hook called "update_mmu_cache()" that architectures
3691 * with external mmu caches can use to update those (ie the Sparc or
3692 * PowerPC hashed page tables that act as extended TLBs).
3693 *
3694 * We enter with non-exclusive mmap_sem (to exclude vma changes,
3695 * but allow concurrent faults), and pte mapped but not yet locked.
3696 * We return with mmap_sem still held, but pte unmapped and unlocked.
3697 */
3701 {
3702 pte_t entry;
3712 }
3715 }
3721 }
3735 }
3740 /*
3741 * This is needed only for protection faults but the arch code
3742 * is not yet telling us if this is a protection fault or not.
3743 * This still avoids useless tlb flushes for .text page faults
3744 * with threads.
3745 */
3748 }
3749 unlock:
3752 }
3754 /*
3755 * By the time we get here, we already hold the mm semaphore
3756 */
3759 {
3770 /* do counter updates before entering really critical section. */
3776 retry:
3796 /*
3797 * If the pmd is splitting, return and retry the
3798 * the fault. Alternative: wait until the split
3799 * is done, and goto retry.
3800 */
3810 orig_pmd);
3811 /*
3812 * If COW results in an oom, the huge pmd will
3813 * have been split, so retry the fault on the
3814 * pte for a smaller charge.
3815 */
3822 }
3825 }
3826 }
3831 /*
3832 * Use __pte_alloc instead of pte_alloc_map, because we can't
3833 * run pte_offset_map on the pmd, if an huge pmd could
3834 * materialize from under us from a different thread.
3835 */
3839 /* if an huge pmd materialized from under us just retry later */
3842 /*
3843 * A regular pmd is established and it can't morph into a huge pmd
3844 * from under us anymore at this point because we hold the mmap_sem
3845 * read mode and khugepaged takes it in write mode. So now it's
3846 * safe to run pte_offset_map().
3847 */
3851 }
3853 #ifndef __PAGETABLE_PUD_FOLDED
3854 /*
3855 * Allocate page upper directory.
3856 * We've already handled the fast-path in-line.
3857 */
3859 {
3869 else
3873 }
3876 #ifndef __PAGETABLE_PMD_FOLDED
3877 /*
3878 * Allocate page middle directory.
3879 * We've already handled the fast-path in-line.
3880 */
3882 {
3890 #ifndef __ARCH_HAS_4LEVEL_HACK
3893 else
3895 #else
3898 else
3903 }
3906 #if !defined(__HAVE_ARCH_GATE_AREA)
3908 #if defined(AT_SYSINFO_EHDR)
3912 {
3920 }
3922 #endif
3925 {
3926 #ifdef AT_SYSINFO_EHDR
3928 #else
3930 #endif
3931 }
3934 {
3935 #ifdef AT_SYSINFO_EHDR
3938 #endif
3940 }
3946 {
3965 /* We cannot handle huge page PFN maps. Luckily they don't exist. */
3976 unlock:
3978 out:
3980 }
3984 {
3987 /* (void) is needed to make gcc happy */
3991 }
3993 /**
3994 * follow_pfn - look up PFN at a user virtual address
3995 * @vma: memory mapping
3996 * @address: user virtual address
3997 * @pfn: location to store found PFN
3998 *
3999 * Only IO mappings and raw PFN mappings are allowed.
4000 *
4001 * Returns zero and the pfn at @pfn on success, -ve otherwise.
4002 */
4005 {
4019 }
4022 #ifdef CONFIG_HAVE_IOREMAP_PROT
4026 {
4045 unlock:
4047 out:
4049 }
4053 {
4054 resource_size_t phys_addr;
4065 else
4070 }
4072 #endif
4074 /*
4075 * Access another process' address space as given in mm. If non-NULL, use the
4076 * given task for page fault accounting.
4077 */
4080 {
4085 /* ignore errors, just check how much was successfully transferred */
4094 /*
4095 * Check if this is a VM_IO | VM_PFNMAP VMA, which
4096 * we can access using slightly different code.
4097 */
4098 #ifdef CONFIG_HAVE_IOREMAP_PROT
4106 #endif
4123 }
4126 }
4130 }
4134 }
4136 /**
4137 * access_remote_vm - access another process' address space
4138 * @mm: the mm_struct of the target address space
4139 * @addr: start address to access
4140 * @buf: source or destination buffer
4141 * @len: number of bytes to transfer
4142 * @write: whether the access is a write
4143 *
4144 * The caller must hold a reference on @mm.
4145 */
4148 {
4150 }
4152 /*
4153 * Access another process' address space.
4154 * Source/target buffer must be kernel space,
4155 * Do not walk the page table directly, use get_user_pages
4156 */
4159 {
4171 }
4173 /*
4174 * Print the name of a VMA.
4175 */
4177 {
4181 /*
4182 * Do not print if we are in atomic
4183 * contexts (in exception stacks, etc.):
4184 */
4203 }
4204 }
4206 }
4208 #if defined(CONFIG_PROVE_LOCKING) || defined(CONFIG_DEBUG_ATOMIC_SLEEP)
4210 {
4211 /*
4212 * Some code (nfs/sunrpc) uses socket ops on kernel memory while
4213 * holding the mmap_sem, this is safe because kernel memory doesn't
4214 * get paged out, therefore we'll never actually fault, and the
4215 * below annotations will generate false positives.
4216 */
4220 /*
4221 * it would be nicer only to annotate paths which are not under
4222 * pagefault_disable, however that requires a larger audit and
4223 * providing helpers like get_user_atomic.
4224 */
4232 }
4234 #endif
4236 #if defined(CONFIG_TRANSPARENT_HUGEPAGE) || defined(CONFIG_HUGETLBFS)
4240 {
4249 }
4250 }
4253 {
4259 }
4265 }
4266 }
4272 {
4281 i++;
4284 }
4285 }
4290 {
4295 pages_per_huge_page);
4297 }
4303 }
4304 }