| blob | d2948af126ca2a7dcd5e39dbcb4989907d6b454e |
1 #ifndef _LINUX_MM_H
2 #define _LINUX_MM_H
4 #include <linux/errno.h>
6 #ifdef __KERNEL__
8 #include <linux/gfp.h>
9 #include <linux/list.h>
10 #include <linux/mmzone.h>
11 #include <linux/rbtree.h>
12 #include <linux/prio_tree.h>
13 #include <linux/debug_locks.h>
14 #include <linux/mm_types.h>
15 #include <linux/range.h>
16 #include <linux/pfn.h>
17 #include <linux/bit_spinlock.h>
27 #endif
34 #ifdef CONFIG_SYSCTL
36 #else
37 #define sysctl_legacy_va_layout 0
38 #endif
40 #include <asm/page.h>
41 #include <asm/pgtable.h>
42 #include <asm/processor.h>
44 #define nth_page(page,n) pfn_to_page(page_to_pfn((page)) + (n))
46 /* to align the pointer to the (next) page boundary */
47 #define PAGE_ALIGN(addr) ALIGN(addr, PAGE_SIZE)
49 /*
50 * Linux kernel virtual memory manager primitives.
51 * The idea being to have a "virtual" mm in the same way
52 * we have a virtual fs - giving a cleaner interface to the
53 * mm details, and allowing different kinds of memory mappings
54 * (from shared memory to executable loading to arbitrary
55 * mmap() functions).
56 */
60 #ifndef CONFIG_MMU
65 #endif
67 /*
68 * vm_flags in vm_area_struct, see mm_types.h.
69 */
71 #define VM_WRITE 0x00000002
72 #define VM_EXEC 0x00000004
73 #define VM_SHARED 0x00000008
75 /* mprotect() hardcodes VM_MAYREAD >> 4 == VM_READ, and so for r/w/x bits. */
77 #define VM_MAYWRITE 0x00000020
78 #define VM_MAYEXEC 0x00000040
79 #define VM_MAYSHARE 0x00000080
82 #if defined(CONFIG_STACK_GROWSUP) || defined(CONFIG_IA64)
83 #define VM_GROWSUP 0x00000200
84 #else
85 #define VM_GROWSUP 0x00000000
87 #endif
91 #define VM_EXECUTABLE 0x00001000
92 #define VM_LOCKED 0x00002000
95 /* Used by sys_madvise() */
106 #ifndef CONFIG_TRANSPARENT_HUGEPAGE
108 #else
110 #endif
120 /* Bits set in the VMA until the stack is in its final location */
121 #define VM_STACK_INCOMPLETE_SETUP (VM_RAND_READ | VM_SEQ_READ)
124 #define VM_STACK_DEFAULT_FLAGS VM_DATA_DEFAULT_FLAGS
125 #endif
127 #ifdef CONFIG_STACK_GROWSUP
128 #define VM_STACK_FLAGS (VM_GROWSUP | VM_STACK_DEFAULT_FLAGS | VM_ACCOUNT)
129 #else
130 #define VM_STACK_FLAGS (VM_GROWSDOWN | VM_STACK_DEFAULT_FLAGS | VM_ACCOUNT)
131 #endif
133 #define VM_READHINTMASK (VM_SEQ_READ | VM_RAND_READ)
134 #define VM_ClearReadHint(v) (v)->vm_flags &= ~VM_READHINTMASK
135 #define VM_NormalReadHint(v) (!((v)->vm_flags & VM_READHINTMASK))
136 #define VM_SequentialReadHint(v) ((v)->vm_flags & VM_SEQ_READ)
137 #define VM_RandomReadHint(v) ((v)->vm_flags & VM_RAND_READ)
139 /*
140 * Special vmas that are non-mergable, non-mlock()able.
141 * Note: mm/huge_memory.c VM_NO_THP depends on this definition.
142 */
143 #define VM_SPECIAL (VM_IO | VM_DONTEXPAND | VM_RESERVED | VM_PFNMAP)
145 /*
146 * mapping from the currently active vm_flags protection bits (the
147 * low four bits) to a page protection mask..
148 */
158 /*
159 * This interface is used by x86 PAT code to identify a pfn mapping that is
160 * linear over entire vma. This is to optimize PAT code that deals with
161 * marking the physical region with a particular prot. This is not for generic
162 * mm use. Note also that this check will not work if the pfn mapping is
163 * linear for a vma starting at physical address 0. In which case PAT code
164 * falls back to slow path of reserving physical range page by page.
165 */
167 {
169 }
172 {
174 }
176 /*
177 * vm_fault is filled by the the pagefault handler and passed to the vma's
178 * ->fault function. The vma's ->fault is responsible for returning a bitmask
179 * of VM_FAULT_xxx flags that give details about how the fault was handled.
180 *
181 * pgoff should be used in favour of virtual_address, if possible. If pgoff
182 * is used, one may set VM_CAN_NONLINEAR in the vma->vm_flags to get nonlinear
183 * mapping support.
184 */
191 * page here, unless VM_FAULT_NOPAGE
192 * is set (which is also implied by
193 * VM_FAULT_ERROR).
194 */
195 };
197 /*
198 * These are the virtual MM functions - opening of an area, closing and
199 * unmapping it (needed to keep files on disk up-to-date etc), pointer
200 * to the functions called when a no-page or a wp-page exception occurs.
201 */
207 /* notification that a previously read-only page is about to become
208 * writable, if an error is returned it will cause a SIGBUS */
211 /* called by access_process_vm when get_user_pages() fails, typically
212 * for use by special VMAs that can switch between memory and hardware
213 */
216 #ifdef CONFIG_NUMA
217 /*
218 * set_policy() op must add a reference to any non-NULL @new mempolicy
219 * to hold the policy upon return. Caller should pass NULL @new to
220 * remove a policy and fall back to surrounding context--i.e. do not
221 * install a MPOL_DEFAULT policy, nor the task or system default
222 * mempolicy.
223 */
226 /*
227 * get_policy() op must add reference [mpol_get()] to any policy at
228 * (vma,addr) marked as MPOL_SHARED. The shared policy infrastructure
229 * in mm/mempolicy.c will do this automatically.
230 * get_policy() must NOT add a ref if the policy at (vma,addr) is not
231 * marked as MPOL_SHARED. vma policies are protected by the mmap_sem.
232 * If no [shared/vma] mempolicy exists at the addr, get_policy() op
233 * must return NULL--i.e., do not "fallback" to task or system default
234 * policy.
235 */
240 #endif
241 };
246 #define page_private(page) ((page)->private)
247 #define set_page_private(page, v) ((page)->private = (v))
249 /*
250 * FIXME: take this include out, include page-flags.h in
251 * files which need it (119 of them)
252 */
253 #include <linux/page-flags.h>
254 #include <linux/huge_mm.h>
256 /*
257 * Methods to modify the page usage count.
258 *
259 * What counts for a page usage:
260 * - cache mapping (page->mapping)
261 * - private data (page->private)
262 * - page mapped in a task's page tables, each mapping
263 * is counted separately
264 *
265 * Also, many kernel routines increase the page count before a critical
266 * routine so they can be sure the page doesn't go away from under them.
267 */
269 /*
270 * Drop a ref, return true if the refcount fell to zero (the page has no users)
271 */
273 {
276 }
278 /*
279 * Try to grab a ref unless the page has a refcount of zero, return false if
280 * that is the case.
281 */
283 {
285 }
289 /* Support for virtually mapped pages */
293 /*
294 * Determine if an address is within the vmalloc range
295 *
296 * On nommu, vmalloc/vfree wrap through kmalloc/kfree directly, so there
297 * is no special casing required.
298 */
300 {
301 #ifdef CONFIG_MMU
305 #else
307 #endif
308 }
309 #ifdef CONFIG_MMU
311 #else
313 {
315 }
316 #endif
319 {
320 #ifdef CONFIG_TRANSPARENT_HUGEPAGE
322 #endif
323 }
326 {
327 #ifdef CONFIG_TRANSPARENT_HUGEPAGE
329 #endif
330 }
333 {
335 #ifdef CONFIG_TRANSPARENT_HUGEPAGE
338 #endif
340 }
344 {
345 #ifdef CONFIG_TRANSPARENT_HUGEPAGE
348 #endif
349 }
352 {
356 }
359 {
361 }
364 {
365 /*
366 * Getting a normal page or the head of a compound page
367 * requires to already have an elevated page->_count. Only if
368 * we're getting a tail page, the elevated page->_count is
369 * required only in the head page, so for tail pages the
370 * bugcheck only verifies that the page->_count isn't
371 * negative.
372 */
375 /*
376 * Getting a tail page will elevate both the head and tail
377 * page->_count(s).
378 */
380 /*
381 * This is safe only because
382 * __split_huge_page_refcount can't run under
383 * get_page().
384 */
387 }
388 }
391 {
394 }
396 /*
397 * Setup the page count before being freed into the page allocator for
398 * the first time (boot or memory hotplug)
399 */
401 {
403 }
405 /*
406 * PageBuddy() indicate that the page is free and in the buddy system
407 * (see mm/page_alloc.c).
408 *
409 * PAGE_BUDDY_MAPCOUNT_VALUE must be <= -2 but better not too close to
410 * -2 so that an underflow of the page_mapcount() won't be mistaken
411 * for a genuine PAGE_BUDDY_MAPCOUNT_VALUE. -128 can be created very
412 * efficiently by most CPU architectures.
413 */
414 #define PAGE_BUDDY_MAPCOUNT_VALUE (-128)
417 {
419 }
422 {
425 }
428 {
431 }
439 /*
440 * Compound pages have a destructor function. Provide a
441 * prototype for that function and accessor functions.
442 * These are _only_ valid on the head of a PG_compound page.
443 */
448 {
450 }
453 {
455 }
458 {
462 }
465 {
476 }
479 {
481 }
483 #ifdef CONFIG_MMU
484 /*
485 * Do pte_mkwrite, but only if the vma says VM_WRITE. We do this when
486 * servicing faults for write access. In the normal case, do always want
487 * pte_mkwrite. But get_user_pages can cause write faults for mappings
488 * that do not have writing enabled, when used by access_process_vm.
489 */
491 {
495 }
496 #endif
498 /*
499 * Multiple processes may "see" the same page. E.g. for untouched
500 * mappings of /dev/null, all processes see the same page full of
501 * zeroes, and text pages of executables and shared libraries have
502 * only one copy in memory, at most, normally.
503 *
504 * For the non-reserved pages, page_count(page) denotes a reference count.
505 * page_count() == 0 means the page is free. page->lru is then used for
506 * freelist management in the buddy allocator.
507 * page_count() > 0 means the page has been allocated.
508 *
509 * Pages are allocated by the slab allocator in order to provide memory
510 * to kmalloc and kmem_cache_alloc. In this case, the management of the
511 * page, and the fields in 'struct page' are the responsibility of mm/slab.c
512 * unless a particular usage is carefully commented. (the responsibility of
513 * freeing the kmalloc memory is the caller's, of course).
514 *
515 * A page may be used by anyone else who does a __get_free_page().
516 * In this case, page_count still tracks the references, and should only
517 * be used through the normal accessor functions. The top bits of page->flags
518 * and page->virtual store page management information, but all other fields
519 * are unused and could be used privately, carefully. The management of this
520 * page is the responsibility of the one who allocated it, and those who have
521 * subsequently been given references to it.
522 *
523 * The other pages (we may call them "pagecache pages") are completely
524 * managed by the Linux memory manager: I/O, buffers, swapping etc.
525 * The following discussion applies only to them.
526 *
527 * A pagecache page contains an opaque `private' member, which belongs to the
528 * page's address_space. Usually, this is the address of a circular list of
529 * the page's disk buffers. PG_private must be set to tell the VM to call
530 * into the filesystem to release these pages.
531 *
532 * A page may belong to an inode's memory mapping. In this case, page->mapping
533 * is the pointer to the inode, and page->index is the file offset of the page,
534 * in units of PAGE_CACHE_SIZE.
535 *
536 * If pagecache pages are not associated with an inode, they are said to be
537 * anonymous pages. These may become associated with the swapcache, and in that
538 * case PG_swapcache is set, and page->private is an offset into the swapcache.
539 *
540 * In either case (swapcache or inode backed), the pagecache itself holds one
541 * reference to the page. Setting PG_private should also increment the
542 * refcount. The each user mapping also has a reference to the page.
543 *
544 * The pagecache pages are stored in a per-mapping radix tree, which is
545 * rooted at mapping->page_tree, and indexed by offset.
546 * Where 2.4 and early 2.6 kernels kept dirty/clean pages in per-address_space
547 * lists, we instead now tag pages as dirty/writeback in the radix tree.
548 *
549 * All pagecache pages may be subject to I/O:
550 * - inode pages may need to be read from disk,
551 * - inode pages which have been modified and are MAP_SHARED may need
552 * to be written back to the inode on disk,
553 * - anonymous pages (including MAP_PRIVATE file mappings) which have been
554 * modified may need to be swapped out to swap space and (later) to be read
555 * back into memory.
556 */
558 /*
559 * The zone field is never updated after free_area_init_core()
560 * sets it, so none of the operations on it need to be atomic.
561 */
564 /*
565 * page->flags layout:
566 *
567 * There are three possibilities for how page->flags get
568 * laid out. The first is for the normal case, without
569 * sparsemem. The second is for sparsemem when there is
570 * plenty of space for node and section. The last is when
571 * we have run out of space and have to fall back to an
572 * alternate (slower) way of determining the node.
573 *
574 * No sparsemem or sparsemem vmemmap: | NODE | ZONE | ... | FLAGS |
575 * classic sparse with space for node:| SECTION | NODE | ZONE | ... | FLAGS |
576 * classic sparse no space for node: | SECTION | ZONE | ... | FLAGS |
577 */
578 #if defined(CONFIG_SPARSEMEM) && !defined(CONFIG_SPARSEMEM_VMEMMAP)
579 #define SECTIONS_WIDTH SECTIONS_SHIFT
580 #else
581 #define SECTIONS_WIDTH 0
582 #endif
584 #define ZONES_WIDTH ZONES_SHIFT
586 #if SECTIONS_WIDTH+ZONES_WIDTH+NODES_SHIFT <= BITS_PER_LONG - NR_PAGEFLAGS
587 #define NODES_WIDTH NODES_SHIFT
588 #else
589 #ifdef CONFIG_SPARSEMEM_VMEMMAP
591 #endif
592 #define NODES_WIDTH 0
593 #endif
595 /* Page flags: | [SECTION] | [NODE] | ZONE | ... | FLAGS | */
596 #define SECTIONS_PGOFF ((sizeof(unsigned long)*8) - SECTIONS_WIDTH)
597 #define NODES_PGOFF (SECTIONS_PGOFF - NODES_WIDTH)
598 #define ZONES_PGOFF (NODES_PGOFF - ZONES_WIDTH)
600 /*
601 * We are going to use the flags for the page to node mapping if its in
602 * there. This includes the case where there is no node, so it is implicit.
603 */
604 #if !(NODES_WIDTH > 0 || NODES_SHIFT == 0)
605 #define NODE_NOT_IN_PAGE_FLAGS
606 #endif
608 #ifndef PFN_SECTION_SHIFT
609 #define PFN_SECTION_SHIFT 0
610 #endif
612 /*
613 * Define the bit shifts to access each section. For non-existent
614 * sections we define the shift as 0; that plus a 0 mask ensures
615 * the compiler will optimise away reference to them.
616 */
617 #define SECTIONS_PGSHIFT (SECTIONS_PGOFF * (SECTIONS_WIDTH != 0))
618 #define NODES_PGSHIFT (NODES_PGOFF * (NODES_WIDTH != 0))
619 #define ZONES_PGSHIFT (ZONES_PGOFF * (ZONES_WIDTH != 0))
621 /* NODE:ZONE or SECTION:ZONE is used to ID a zone for the buddy allocator */
622 #ifdef NODE_NOT_IN_PAGE_FLAGS
623 #define ZONEID_SHIFT (SECTIONS_SHIFT + ZONES_SHIFT)
624 #define ZONEID_PGOFF ((SECTIONS_PGOFF < ZONES_PGOFF)? \
625 SECTIONS_PGOFF : ZONES_PGOFF)
626 #else
627 #define ZONEID_SHIFT (NODES_SHIFT + ZONES_SHIFT)
628 #define ZONEID_PGOFF ((NODES_PGOFF < ZONES_PGOFF)? \
629 NODES_PGOFF : ZONES_PGOFF)
630 #endif
632 #define ZONEID_PGSHIFT (ZONEID_PGOFF * (ZONEID_SHIFT != 0))
634 #if SECTIONS_WIDTH+NODES_WIDTH+ZONES_WIDTH > BITS_PER_LONG - NR_PAGEFLAGS
635 #error SECTIONS_WIDTH+NODES_WIDTH+ZONES_WIDTH > BITS_PER_LONG - NR_PAGEFLAGS
636 #endif
638 #define ZONES_MASK ((1UL << ZONES_WIDTH) - 1)
639 #define NODES_MASK ((1UL << NODES_WIDTH) - 1)
640 #define SECTIONS_MASK ((1UL << SECTIONS_WIDTH) - 1)
641 #define ZONEID_MASK ((1UL << ZONEID_SHIFT) - 1)
644 {
646 }
648 /*
649 * The identification function is only used by the buddy allocator for
650 * determining if two pages could be buddies. We are not really
651 * identifying a zone since we could be using a the section number
652 * id if we have not node id available in page flags.
653 * We guarantee only that it will return the same value for two
654 * combinable pages in a zone.
655 */
657 {
659 }
662 {
663 #ifdef CONFIG_NUMA
665 #else
667 #endif
668 }
670 #ifdef NODE_NOT_IN_PAGE_FLAGS
672 #else
674 {
676 }
677 #endif
680 {
682 }
684 #if defined(CONFIG_SPARSEMEM) && !defined(CONFIG_SPARSEMEM_VMEMMAP)
686 {
688 }
689 #endif
692 {
695 }
698 {
701 }
704 {
707 }
711 {
715 }
717 /*
718 * Some inline functions in vmstat.h depend on page_zone()
719 */
720 #include <linux/vmstat.h>
723 {
725 }
727 #if defined(CONFIG_HIGHMEM) && !defined(WANT_PAGE_VIRTUAL)
728 #define HASHED_PAGE_VIRTUAL
729 #endif
731 #if defined(WANT_PAGE_VIRTUAL)
732 #define page_address(page) ((page)->virtual)
733 #define set_page_address(page, address) \
734 do { \
735 (page)->virtual = (address); \
736 } while(0)
737 #define page_address_init() do { } while(0)
738 #endif
740 #if defined(HASHED_PAGE_VIRTUAL)
744 #endif
746 #if !defined(HASHED_PAGE_VIRTUAL) && !defined(WANT_PAGE_VIRTUAL)
747 #define page_address(page) lowmem_page_address(page)
748 #define set_page_address(page, address) do { } while(0)
749 #define page_address_init() do { } while(0)
750 #endif
752 /*
753 * On an anonymous page mapped into a user virtual memory area,
754 * page->mapping points to its anon_vma, not to a struct address_space;
755 * with the PAGE_MAPPING_ANON bit set to distinguish it. See rmap.h.
756 *
757 * On an anonymous page in a VM_MERGEABLE area, if CONFIG_KSM is enabled,
758 * the PAGE_MAPPING_KSM bit may be set along with the PAGE_MAPPING_ANON bit;
759 * and then page->mapping points, not to an anon_vma, but to a private
760 * structure which KSM associates with that merged page. See ksm.h.
761 *
762 * PAGE_MAPPING_KSM without PAGE_MAPPING_ANON is currently never used.
763 *
764 * Please note that, confusingly, "page_mapping" refers to the inode
765 * address_space which maps the page from disk; whereas "page_mapped"
766 * refers to user virtual address space into which the page is mapped.
767 */
768 #define PAGE_MAPPING_ANON 1
769 #define PAGE_MAPPING_KSM 2
770 #define PAGE_MAPPING_FLAGS (PAGE_MAPPING_ANON | PAGE_MAPPING_KSM)
774 {
783 }
785 /* Neutral page->mapping pointer to address_space or anon_vma or other */
787 {
789 }
792 {
794 }
796 /*
797 * Return the pagecache index of the passed page. Regular pagecache pages
798 * use ->index whereas swapcache pages use ->private
799 */
801 {
805 }
807 /*
808 * The atomic page->_mapcount, like _count, starts from -1:
809 * so that transitions both from it and to it can be tracked,
810 * using atomic_inc_and_test and atomic_add_negative(-1).
811 */
813 {
815 }
818 {
820 }
822 /*
823 * Return true if this page is mapped into pagetables.
824 */
826 {
828 }
830 /*
831 * Different kinds of faults, as returned by handle_mm_fault().
832 * Used to decide whether a process gets delivered SIGBUS or
833 * just gets major/minor fault counters bumped up.
834 */
838 #define VM_FAULT_OOM 0x0001
839 #define VM_FAULT_SIGBUS 0x0002
840 #define VM_FAULT_MAJOR 0x0004
843 #define VM_FAULT_HWPOISON_LARGE 0x0020 /* Hit poisoned large page. Index encoded in upper bits */
851 #define VM_FAULT_ERROR (VM_FAULT_OOM | VM_FAULT_SIGBUS | VM_FAULT_HWPOISON | \
852 VM_FAULT_HWPOISON_LARGE)
854 /* Encode hstate index for a hwpoisoned large page */
855 #define VM_FAULT_SET_HINDEX(x) ((x) << 12)
856 #define VM_FAULT_GET_HINDEX(x) (((x) >> 12) & 0xf)
858 /*
859 * Can be called by the pagefault handler when it gets a VM_FAULT_OOM.
860 */
863 #define offset_in_page(p) ((unsigned long)(p) & ~PAGE_MASK)
865 /*
866 * Flags passed to show_mem() and show_free_areas() to suppress output in
867 * various contexts.
868 */
878 #ifndef CONFIG_MMU
884 #endif
890 /*
891 * Parameter block passed down to zap_pte_range in exceptional cases.
892 */
900 };
903 pte_t pte);
914 /**
915 * mm_walk - callbacks for walk_page_range
916 * @pgd_entry: if set, called for each non-empty PGD (top-level) entry
917 * @pud_entry: if set, called for each non-empty PUD (2nd-level) entry
918 * @pmd_entry: if set, called for each non-empty PMD (3rd-level) entry
919 * this handler is required to be able to handle
920 * pmd_trans_huge() pmds. They may simply choose to
921 * split_huge_page() instead of handling it explicitly.
922 * @pte_entry: if set, called for each non-empty PTE (4th-level) entry
923 * @pte_hole: if set, called for each hole at all levels
924 * @hugetlb_entry: if set, called for each hugetlb entry
925 *
926 * (see walk_page_range for more details)
927 */
938 };
957 {
959 }
971 #ifdef CONFIG_MMU
974 #else
978 {
979 /* should never happen if there's no MMU */
982 }
983 #endif
986 extern int access_process_vm(struct task_struct *tsk, unsigned long addr, void *buf, int len, int write);
1014 /* Is the vma a continuation of the stack vma above it? */
1016 {
1018 }
1022 {
1026 }
1028 /* Is the vma a continuation of the stack vma below it? */
1030 {
1032 }
1036 {
1040 }
1052 /*
1053 * doesn't attempt to fault and will return short.
1054 */
1057 /*
1058 * per-process(per-mm_struct) statistics.
1059 */
1060 #if defined(SPLIT_RSS_COUNTING)
1061 /*
1062 * The mm counters are not protected by its page_table_lock,
1063 * so must be incremented atomically.
1064 */
1066 {
1068 }
1073 {
1075 }
1078 {
1080 }
1083 {
1085 }
1088 /*
1089 * The mm counters are protected by its page_table_lock,
1090 * so can be incremented directly.
1091 */
1093 {
1095 }
1098 {
1100 }
1103 {
1105 }
1108 {
1110 }
1113 {
1115 }
1120 {
1123 }
1126 {
1128 }
1131 {
1133 }
1136 {
1141 }
1144 {
1147 }
1151 {
1156 }
1158 #if defined(SPLIT_RSS_COUNTING)
1160 #else
1162 {
1163 }
1164 #endif
1166 /*
1167 * A callback you can register to apply pressure to ageable caches.
1168 *
1169 * 'shrink' is passed a count 'nr_to_scan' and a 'gfpmask'. It should
1170 * look through the least-recently-used 'nr_to_scan' entries and
1171 * attempt to free them up. It should return the number of objects
1172 * which remain in the cache. If it returns -1, it means it cannot do
1173 * any scanning at this time (eg. there is a risk of deadlock).
1174 *
1175 * The 'gfpmask' refers to the allocation we are currently trying to
1176 * fulfil.
1177 *
1178 * Note that 'shrink' will be passed nr_to_scan == 0 when the VM is
1179 * querying the cache size, so a fastpath for that case is appropriate.
1180 */
1185 /* These are for internal use */
1188 };
1199 {
1203 }
1205 #ifdef __PAGETABLE_PUD_FOLDED
1208 {
1210 }
1211 #else
1213 #endif
1215 #ifdef __PAGETABLE_PMD_FOLDED
1218 {
1220 }
1221 #else
1223 #endif
1229 /*
1230 * The following ifdef needed to get the 4level-fixup.h header to work.
1231 * Remove it when 4level-fixup.h has been removed.
1232 */
1233 #if defined(CONFIG_MMU) && !defined(__ARCH_HAS_4LEVEL_HACK)
1235 {
1238 }
1241 {
1244 }
1247 #if USE_SPLIT_PTLOCKS
1248 /*
1249 * We tuck a spinlock to guard each pagetable page into its struct page,
1250 * at page->private, with BUILD_BUG_ON to make sure that this will not
1251 * overflow into the next struct page (as it might with DEBUG_SPINLOCK).
1252 * When freeing, reset page->mapping so free_pages_check won't complain.
1253 */
1254 #define __pte_lockptr(page) &((page)->ptl)
1255 #define pte_lock_init(_page) do { \
1256 spin_lock_init(__pte_lockptr(_page)); \
1257 } while (0)
1258 #define pte_lock_deinit(page) ((page)->mapping = NULL)
1259 #define pte_lockptr(mm, pmd) ({(void)(mm); __pte_lockptr(pmd_page(*(pmd)));})
1261 /*
1262 * We use mm->page_table_lock to guard all pagetable pages of the mm.
1263 */
1264 #define pte_lock_init(page) do {} while (0)
1265 #define pte_lock_deinit(page) do {} while (0)
1266 #define pte_lockptr(mm, pmd) ({(void)(pmd); &(mm)->page_table_lock;})
1270 {
1273 }
1276 {
1279 }
1281 #define pte_offset_map_lock(mm, pmd, address, ptlp) \
1282 ({ \
1283 spinlock_t *__ptl = pte_lockptr(mm, pmd); \
1284 pte_t *__pte = pte_offset_map(pmd, address); \
1285 *(ptlp) = __ptl; \
1286 spin_lock(__ptl); \
1287 __pte; \
1288 })
1290 #define pte_unmap_unlock(pte, ptl) do { \
1291 spin_unlock(ptl); \
1292 pte_unmap(pte); \
1293 } while (0)
1295 #define pte_alloc_map(mm, vma, pmd, address) \
1296 ((unlikely(pmd_none(*(pmd))) && __pte_alloc(mm, vma, \
1297 pmd, address))? \
1298 NULL: pte_offset_map(pmd, address))
1300 #define pte_alloc_map_lock(mm, pmd, address, ptlp) \
1301 ((unlikely(pmd_none(*(pmd))) && __pte_alloc(mm, NULL, \
1302 pmd, address))? \
1303 NULL: pte_offset_map_lock(mm, pmd, address, ptlp))
1305 #define pte_alloc_kernel(pmd, address) \
1306 ((unlikely(pmd_none(*(pmd))) && __pte_alloc_kernel(pmd, address))? \
1307 NULL: pte_offset_kernel(pmd, address))
1312 #ifdef CONFIG_ARCH_POPULATES_NODE_MAP
1313 /*
1314 * With CONFIG_ARCH_POPULATES_NODE_MAP set, an architecture may initialise its
1315 * zones, allocate the backing mem_map and account for memory holes in a more
1316 * architecture independent manner. This is a substitute for creating the
1317 * zone_sizes[] and zholes_size[] arrays and passing them to
1318 * free_area_init_node()
1319 *
1320 * An architecture is expected to register range of page frames backed by
1321 * physical memory with add_active_range() before calling
1322 * free_area_init_nodes() passing in the PFN each zone ends at. At a basic
1323 * usage, an architecture is expected to do something like
1324 *
1325 * unsigned long max_zone_pfns[MAX_NR_ZONES] = {max_dma, max_normal_pfn,
1326 * max_highmem_pfn};
1327 * for_each_valid_physical_page_range()
1328 * add_active_range(node_id, start_pfn, end_pfn)
1329 * free_area_init_nodes(max_zone_pfns);
1330 *
1331 * If the architecture guarantees that there are no holes in the ranges
1332 * registered with add_active_range(), free_bootmem_active_regions()
1333 * will call free_bootmem_node() for each registered physical page range.
1334 * Similarly sparse_memory_present_with_active_regions() calls
1335 * memory_present() for each range when SPARSEMEM is enabled.
1336 *
1337 * See mm/page_alloc.c for more information on each function exposed by
1338 * CONFIG_ARCH_POPULATES_NODE_MAP
1339 */
1365 #if !defined(CONFIG_ARCH_POPULATES_NODE_MAP) && \
1366 !defined(CONFIG_HAVE_ARCH_EARLY_PFN_TO_NID)
1368 {
1370 }
1371 #else
1372 /* please see mm/page_alloc.c */
1374 #ifdef CONFIG_HAVE_ARCH_EARLY_PFN_TO_NID
1375 /* there is a per-arch backend function. */
1378 #endif
1396 /* nommu.c */
1400 /* prio_tree.c */
1407 #define vma_prio_tree_foreach(vma, iter, root, begin, end) \
1408 for (prio_tree_iter_init(iter, root, begin, end), vma = NULL; \
1409 (vma = vma_prio_tree_next(vma, iter)); )
1413 {
1416 }
1418 /* mmap.c */
1440 #ifdef CONFIG_PROC_FS
1441 /* From fs/proc/base.c. callers must _not_ hold the mm's exe_file_lock */
1444 #else
1446 {}
1449 {}
1457 extern unsigned long get_unmapped_area(struct file *, unsigned long, unsigned long, unsigned long, unsigned long);
1469 {
1475 out:
1477 }
1483 /* filemap.c */
1489 /* generic vm_area_ops exported for stackable file systems */
1492 /* mm/page-writeback.c */
1496 /* readahead.c */
1506 pgoff_t offset,
1513 pgoff_t offset,
1521 /* Generic expand stack which grows the stack according to GROWS{UP,DOWN} */
1524 /* CONFIG_STACK_GROWSUP still needs to to grow downwards at some places */
1527 #if VM_GROWSUP
1529 #else
1530 #define expand_upwards(vma, address) do { } while (0)
1531 #endif
1533 /* Look up the first VMA which satisfies addr < vm_end, NULL if none. */
1538 /* Look up the first VMA which intersects the interval start_addr..end_addr-1,
1539 NULL if none. Assume start_addr < end_addr. */
1540 static inline struct vm_area_struct * find_vma_intersection(struct mm_struct * mm, unsigned long start_addr, unsigned long end_addr)
1541 {
1547 }
1550 {
1552 }
1554 #ifdef CONFIG_MMU
1556 #else
1558 {
1560 }
1561 #endif
1580 * and return without waiting upon it */
1590 #ifdef CONFIG_PROC_FS
1592 #else
1595 {
1596 }
1599 #ifdef CONFIG_DEBUG_PAGEALLOC
1605 {
1607 }
1608 #ifdef CONFIG_HIBERNATION
1611 #else
1615 {
1616 }
1617 #ifdef CONFIG_HIBERNATION
1620 #endif
1623 #ifdef __HAVE_ARCH_GATE_AREA
1626 #else
1628 #define in_gate_area(mm, addr) ({(void)mm; in_gate_area_no_mm(addr);})
1636 #ifndef CONFIG_MMU
1637 #define randomize_va_space 0
1638 #else
1640 #endif
1667 };
1679 #if defined(CONFIG_TRANSPARENT_HUGEPAGE) || defined(CONFIG_HUGETLBFS)