| blob | 46af369c13e5de4928c912fec2b5fd6aa87b48d2 |
1 // SPDX-License-Identifier: GPL-2.0
2 /*
3 * linux/mm/mlock.c
4 *
5 * (C) Copyright 1995 Linus Torvalds
6 * (C) Copyright 2002 Christoph Hellwig
7 */
9 #include <linux/capability.h>
10 #include <linux/mman.h>
11 #include <linux/mm.h>
12 #include <linux/sched/user.h>
13 #include <linux/swap.h>
14 #include <linux/swapops.h>
15 #include <linux/pagemap.h>
16 #include <linux/pagevec.h>
17 #include <linux/mempolicy.h>
18 #include <linux/syscalls.h>
19 #include <linux/sched.h>
20 #include <linux/export.h>
21 #include <linux/rmap.h>
22 #include <linux/mmzone.h>
23 #include <linux/hugetlb.h>
24 #include <linux/memcontrol.h>
25 #include <linux/mm_inline.h>
30 {
36 }
39 /*
40 * Mlocked pages are marked with PageMlocked() flag for efficient testing
41 * in vmscan and, possibly, the fault path; and to support semi-accurate
42 * statistics.
43 *
44 * An mlocked page [PageMlocked(page)] is unevictable. As such, it will
45 * be placed on the LRU "unevictable" list, rather than the [in]active lists.
46 * The unevictable list is an LRU sibling list to the [in]active lists.
47 * PageUnevictable is set to indicate the unevictable state.
48 *
49 * When lazy mlocking via vmscan, it is important to ensure that the
50 * vma's VM_LOCKED status is not concurrently being modified, otherwise we
51 * may have mlocked a page that is being munlocked. So lazy mlock must take
52 * the mmap_sem for read, and verify that the vma really is locked
53 * (see mm/rmap.c).
54 */
56 /*
57 * LRU accounting for clear_page_mlock()
58 */
60 {
70 /*
71 * We lost the race. the page already moved to evictable list.
72 */
75 }
76 }
78 /*
79 * Mark page as mlocked if not already.
80 * If page on LRU, isolate and putback to move to unevictable list.
81 */
83 {
84 /* Serialize with page migration */
96 }
97 }
99 /*
100 * Isolate a page from LRU with optional get_page() pin.
101 * Assumes lru_lock already held and page already pinned.
102 */
104 {
114 }
117 }
119 /*
120 * Finish munlock after successful page isolation
121 *
122 * Page must be locked. This is a wrapper for try_to_munlock()
123 * and putback_lru_page() with munlock accounting.
124 */
126 {
127 /*
128 * Optimization: if the page was mapped just once, that's our mapping
129 * and we don't need to check all the other vmas.
130 */
134 /* Did try_to_unlock() succeed or punt? */
139 }
141 /*
142 * Accounting for page isolation fail during munlock
143 *
144 * Performs accounting when page isolation fails in munlock. There is nothing
145 * else to do because it means some other task has already removed the page
146 * from the LRU. putback_lru_page() will take care of removing the page from
147 * the unevictable list, if necessary. vmscan [page_referenced()] will move
148 * the page back to the unevictable list if some other vma has it mlocked.
149 */
151 {
154 else
156 }
158 /**
159 * munlock_vma_page - munlock a vma page
160 * @page - page to be unlocked, either a normal page or THP page head
161 *
162 * returns the size of the page as a page mask (0 for normal page,
163 * HPAGE_PMD_NR - 1 for THP head page)
164 *
165 * called from munlock()/munmap() path with page supposedly on the LRU.
166 * When we munlock a page, because the vma where we found the page is being
167 * munlock()ed or munmap()ed, we want to check whether other vmas hold the
168 * page locked so that we can leave it on the unevictable lru list and not
169 * bother vmscan with it. However, to walk the page's rmap list in
170 * try_to_munlock() we must isolate the page from the LRU. If some other
171 * task has removed the page from the LRU, we won't be able to do that.
172 * So we clear the PageMlocked as we might not get another chance. If we
173 * can't isolate the page, we leave it for putback_lru_page() and vmscan
174 * [page_referenced()/try_to_unmap()] to deal with.
175 */
177 {
181 /* For try_to_munlock() and to serialize with page migration */
186 /*
187 * Serialize with any parallel __split_huge_page_refcount() which
188 * might otherwise copy PageMlocked to part of the tail pages before
189 * we clear it in the head page. It also stabilizes hpage_nr_pages().
190 */
194 /* Potentially, PTE-mapped THP: do not skip the rest PTEs */
197 }
206 }
209 unlock_out:
212 out:
214 }
216 /*
217 * convert get_user_pages() return value to posix mlock() error
218 */
220 {
226 }
228 /*
229 * Prepare page for fast batched LRU putback via putback_lru_evictable_pagevec()
230 *
231 * The fast path is available only for evictable pages with single mapping.
232 * Then we can bypass the per-cpu pvec and get better performance.
233 * when mapcount > 1 we need try_to_munlock() which can fail.
234 * when !page_evictable(), we need the full redo logic of putback_lru_page to
235 * avoid leaving evictable page in unevictable list.
236 *
237 * In case of success, @page is added to @pvec and @pgrescued is incremented
238 * in case that the page was previously unevictable. @page is also unlocked.
239 */
242 {
252 }
255 }
257 /*
258 * Putback multiple evictable pages to the LRU
259 *
260 * Batched putback of evictable pages that bypasses the per-cpu pvec. Some of
261 * the pages might have meanwhile become unevictable but that is OK.
262 */
264 {
266 /*
267 *__pagevec_lru_add() calls release_pages() so we don't call
268 * put_page() explicitly
269 */
272 }
274 /*
275 * Munlock a batch of pages from the same zone
276 *
277 * The work is split to two main phases. First phase clears the Mlocked flag
278 * and attempts to isolate the pages, all under a single zone lru lock.
279 * The second phase finishes the munlock only for pages where isolation
280 * succeeded.
281 *
282 * Note that the pagevec may be modified during the process.
283 */
285 {
294 /* Phase 1: page isolation */
300 /*
301 * We already have pin from follow_page_mask()
302 * so we can spare the get_page() here.
303 */
306 else
309 delta_munlocked++;
310 }
312 /*
313 * We won't be munlocking this page in the next phase
314 * but we still need to release the follow_page_mask()
315 * pin. We cannot do it under lru_lock however. If it's
316 * the last pin, __page_cache_release() would deadlock.
317 */
320 }
324 /* Now we can release pins of pages that we are not munlocking */
327 /* Phase 2: page munlock */
335 /*
336 * Slow path. We don't want to lose the last
337 * pin before unlock_page()
338 */
343 }
344 }
345 }
347 /*
348 * Phase 3: page putback for pages that qualified for the fast path
349 * This will also call put_page() to return pin from follow_page_mask()
350 */
353 }
355 /*
356 * Fill up pagevec for __munlock_pagevec using pte walk
357 *
358 * The function expects that the struct page corresponding to @start address is
359 * a non-TPH page already pinned and in the @pvec, and that it belongs to @zone.
360 *
361 * The rest of @pvec is filled by subsequent pages within the same pmd and same
362 * zone, as long as the pte's are present and vm_normal_page() succeeds. These
363 * pages also get pinned.
364 *
365 * Returns the address of the next page that should be scanned. This equals
366 * @start + PAGE_SIZE when no page could be added by the pte walk.
367 */
371 {
375 /*
376 * Initialize pte walk starting at the already pinned page where we
377 * are sure that there is a pte, as it was pinned under the same
378 * mmap_sem write op.
379 */
381 /* Make sure we do not cross the page table boundary */
387 /* The page next to the pinned page is the first we will try to get */
391 pte++;
394 /*
395 * Break if page could not be obtained or the page's node+zone does not
396 * match
397 */
401 /*
402 * Do not use pagevec for PTE-mapped THP,
403 * munlock_vma_pages_range() will handle them.
404 */
409 /*
410 * Increase the address that will be returned *before* the
411 * eventual break due to pvec becoming full by adding the page
412 */
416 }
419 }
421 /*
422 * munlock_vma_pages_range() - munlock all pages in the vma range.'
423 * @vma - vma containing range to be munlock()ed.
424 * @start - start address in @vma of the range
425 * @end - end of range in @vma.
426 *
427 * For mremap(), munmap() and exit().
428 *
429 * Called with @vma VM_LOCKED.
430 *
431 * Returns with VM_LOCKED cleared. Callers must be prepared to
432 * deal with this.
433 *
434 * We don't save and restore VM_LOCKED here because pages are
435 * still on lru. In unmap path, pages might be scanned by reclaim
436 * and re-mlocked by try_to_{munlock|unmap} before we unmap and
437 * free them. This will result in freeing mlocked pages.
438 */
441 {
452 /*
453 * Although FOLL_DUMP is intended for get_dump_page(),
454 * it just so happens that its special treatment of the
455 * ZERO_PAGE (returning an error instead of doing get_page)
456 * suits munlock very well (and if somehow an abnormal page
457 * has sneaked into the range, we won't oops here: great).
458 */
467 /*
468 * Any THP page found by follow_page_mask() may
469 * have gotten split before reaching
470 * munlock_vma_page(), so we need to compute
471 * the page_mask here instead.
472 */
477 /*
478 * Non-huge pages are handled in batches via
479 * pagevec. The pin from follow_page_mask()
480 * prevents them from collapsing by THP.
481 */
485 /*
486 * Try to fill the rest of pagevec using fast
487 * pte walk. This will also update start to
488 * the next page to process. Then munlock the
489 * pagevec.
490 */
495 }
496 }
499 next:
501 }
502 }
504 /*
505 * mlock_fixup - handle mlock[all]/munlock[all] requests.
506 *
507 * Filters out "special" vmas -- VM_LOCKED never gets set for these, and
508 * munlock is a no-op. However, for some special vmas, we go ahead and
509 * populate the ptes.
510 *
511 * For vmas that pass the filters, merge/split as appropriate.
512 */
515 {
517 pgoff_t pgoff;
525 /* don't set VM_LOCKED or VM_LOCKONFAULT and don't count */
535 }
541 }
547 }
549 success:
550 /*
551 * Keep track of amount of locked VM.
552 */
560 /*
561 * vm_flags is protected by the mmap_sem held in write mode.
562 * It's okay if try_to_unmap_one unmaps a page just after we
563 * set VM_LOCKED, populate_vma_page_range will bring it back.
564 */
568 else
571 out:
574 }
577 vm_flags_t flags)
578 {
603 /* Here we know that vma->vm_start <= nstart < vma->vm_end. */
620 }
621 }
623 }
625 /*
626 * Go through vma areas and sum size of mlocked
627 * vma pages, as return value.
628 * Note deferred memory locking case(mlock2(,,MLOCK_ONFAULT)
629 * is also counted.
630 * Return value: previously mlocked page counts
631 */
634 {
656 }
658 }
659 }
662 }
665 {
687 /*
688 * It is possible that the regions requested intersect with
689 * previously mlocked areas, that part area in "mm->locked_vm"
690 * should not be counted to new mlock increment count. So check
691 * and adjust locked count if necessary.
692 */
695 }
697 /* check against resource limits */
709 }
712 {
714 }
717 {
727 }
730 {
742 }
744 /*
745 * Take the MCL_* flags passed into mlockall (or 0 if called from munlockall)
746 * and translate into the appropriate modifications to mm->def_flags and/or the
747 * flags for all current VMAs.
748 *
749 * There are a couple of subtleties with this. If mlockall() is called multiple
750 * times with different flags, the values do not necessarily stack. If mlockall
751 * is called once including the MCL_FUTURE flag and then a second time without
752 * it, VM_LOCKED and VM_LOCKONFAULT will be cleared from mm->def_flags.
753 */
755 {
768 }
774 }
777 vm_flags_t newflags;
782 /* Ignore errors */
785 }
786 out:
788 }
791 {
819 }
822 {
830 }
832 /*
833 * Objects with different lifetime than processes (SHM_LOCK and SHM_HUGETLB
834 * shm segments) get accounted against the user_struct instead.
835 */
839 {
855 out:
858 }
861 {
866 }