diff options
author | Andi Kleen <andi@firstfloor.org> | 2009-09-16 05:50:15 -0400 |
---|---|---|
committer | Andi Kleen <ak@linux.intel.com> | 2009-09-16 05:50:15 -0400 |
commit | 6a46079cf57a7f7758e8b926980a4f852f89b34d (patch) | |
tree | efd72e830201370d6273bd436dda5a3c4cd6ed9b /mm/memory-failure.c | |
parent | 4db96cf077aa938b11fe7ac79ecc9b29ec00fbab (diff) |
HWPOISON: The high level memory error handler in the VM v7
Add the high level memory handler that poisons pages
that got corrupted by hardware (typically by a two bit flip in a DIMM
or a cache) on the Linux level. The goal is to prevent everyone
from accessing these pages in the future.
This done at the VM level by marking a page hwpoisoned
and doing the appropriate action based on the type of page
it is.
The code that does this is portable and lives in mm/memory-failure.c
To quote the overview comment:
High level machine check handler. Handles pages reported by the
hardware as being corrupted usually due to a 2bit ECC memory or cache
failure.
This focuses on pages detected as corrupted in the background.
When the current CPU tries to consume corruption the currently
running process can just be killed directly instead. This implies
that if the error cannot be handled for some reason it's safe to
just ignore it because no corruption has been consumed yet. Instead
when that happens another machine check will happen.
Handles page cache pages in various states. The tricky part
here is that we can access any page asynchronous to other VM
users, because memory failures could happen anytime and anywhere,
possibly violating some of their assumptions. This is why this code
has to be extremely careful. Generally it tries to use normal locking
rules, as in get the standard locks, even if that means the
error handling takes potentially a long time.
Some of the operations here are somewhat inefficient and have non
linear algorithmic complexity, because the data structures have not
been optimized for this case. This is in particular the case
for the mapping from a vma to a process. Since this case is expected
to be rare we hope we can get away with this.
There are in principle two strategies to kill processes on poison:
- just unmap the data and wait for an actual reference before
killing
- kill as soon as corruption is detected.
Both have advantages and disadvantages and should be used
in different situations. Right now both are implemented and can
be switched with a new sysctl vm.memory_failure_early_kill
The default is early kill.
The patch does some rmap data structure walking on its own to collect
processes to kill. This is unusual because normally all rmap data structure
knowledge is in rmap.c only. I put it here for now to keep
everything together and rmap knowledge has been seeping out anyways
Includes contributions from Johannes Weiner, Chris Mason, Fengguang Wu,
Nick Piggin (who did a lot of great work) and others.
Cc: npiggin@suse.de
Cc: riel@redhat.com
Signed-off-by: Andi Kleen <ak@linux.intel.com>
Acked-by: Rik van Riel <riel@redhat.com>
Reviewed-by: Hidehiro Kawai <hidehiro.kawai.ez@hitachi.com>
Diffstat (limited to 'mm/memory-failure.c')
-rw-r--r-- | mm/memory-failure.c | 832 |
1 files changed, 832 insertions, 0 deletions
diff --git a/mm/memory-failure.c b/mm/memory-failure.c new file mode 100644 index 000000000000..729d4b15b645 --- /dev/null +++ b/mm/memory-failure.c | |||
@@ -0,0 +1,832 @@ | |||
1 | /* | ||
2 | * Copyright (C) 2008, 2009 Intel Corporation | ||
3 | * Authors: Andi Kleen, Fengguang Wu | ||
4 | * | ||
5 | * This software may be redistributed and/or modified under the terms of | ||
6 | * the GNU General Public License ("GPL") version 2 only as published by the | ||
7 | * Free Software Foundation. | ||
8 | * | ||
9 | * High level machine check handler. Handles pages reported by the | ||
10 | * hardware as being corrupted usually due to a 2bit ECC memory or cache | ||
11 | * failure. | ||
12 | * | ||
13 | * Handles page cache pages in various states. The tricky part | ||
14 | * here is that we can access any page asynchronous to other VM | ||
15 | * users, because memory failures could happen anytime and anywhere, | ||
16 | * possibly violating some of their assumptions. This is why this code | ||
17 | * has to be extremely careful. Generally it tries to use normal locking | ||
18 | * rules, as in get the standard locks, even if that means the | ||
19 | * error handling takes potentially a long time. | ||
20 | * | ||
21 | * The operation to map back from RMAP chains to processes has to walk | ||
22 | * the complete process list and has non linear complexity with the number | ||
23 | * mappings. In short it can be quite slow. But since memory corruptions | ||
24 | * are rare we hope to get away with this. | ||
25 | */ | ||
26 | |||
27 | /* | ||
28 | * Notebook: | ||
29 | * - hugetlb needs more code | ||
30 | * - kcore/oldmem/vmcore/mem/kmem check for hwpoison pages | ||
31 | * - pass bad pages to kdump next kernel | ||
32 | */ | ||
33 | #define DEBUG 1 /* remove me in 2.6.34 */ | ||
34 | #include <linux/kernel.h> | ||
35 | #include <linux/mm.h> | ||
36 | #include <linux/page-flags.h> | ||
37 | #include <linux/sched.h> | ||
38 | #include <linux/rmap.h> | ||
39 | #include <linux/pagemap.h> | ||
40 | #include <linux/swap.h> | ||
41 | #include <linux/backing-dev.h> | ||
42 | #include "internal.h" | ||
43 | |||
44 | int sysctl_memory_failure_early_kill __read_mostly = 0; | ||
45 | |||
46 | int sysctl_memory_failure_recovery __read_mostly = 1; | ||
47 | |||
48 | atomic_long_t mce_bad_pages __read_mostly = ATOMIC_LONG_INIT(0); | ||
49 | |||
50 | /* | ||
51 | * Send all the processes who have the page mapped an ``action optional'' | ||
52 | * signal. | ||
53 | */ | ||
54 | static int kill_proc_ao(struct task_struct *t, unsigned long addr, int trapno, | ||
55 | unsigned long pfn) | ||
56 | { | ||
57 | struct siginfo si; | ||
58 | int ret; | ||
59 | |||
60 | printk(KERN_ERR | ||
61 | "MCE %#lx: Killing %s:%d early due to hardware memory corruption\n", | ||
62 | pfn, t->comm, t->pid); | ||
63 | si.si_signo = SIGBUS; | ||
64 | si.si_errno = 0; | ||
65 | si.si_code = BUS_MCEERR_AO; | ||
66 | si.si_addr = (void *)addr; | ||
67 | #ifdef __ARCH_SI_TRAPNO | ||
68 | si.si_trapno = trapno; | ||
69 | #endif | ||
70 | si.si_addr_lsb = PAGE_SHIFT; | ||
71 | /* | ||
72 | * Don't use force here, it's convenient if the signal | ||
73 | * can be temporarily blocked. | ||
74 | * This could cause a loop when the user sets SIGBUS | ||
75 | * to SIG_IGN, but hopefully noone will do that? | ||
76 | */ | ||
77 | ret = send_sig_info(SIGBUS, &si, t); /* synchronous? */ | ||
78 | if (ret < 0) | ||
79 | printk(KERN_INFO "MCE: Error sending signal to %s:%d: %d\n", | ||
80 | t->comm, t->pid, ret); | ||
81 | return ret; | ||
82 | } | ||
83 | |||
84 | /* | ||
85 | * Kill all processes that have a poisoned page mapped and then isolate | ||
86 | * the page. | ||
87 | * | ||
88 | * General strategy: | ||
89 | * Find all processes having the page mapped and kill them. | ||
90 | * But we keep a page reference around so that the page is not | ||
91 | * actually freed yet. | ||
92 | * Then stash the page away | ||
93 | * | ||
94 | * There's no convenient way to get back to mapped processes | ||
95 | * from the VMAs. So do a brute-force search over all | ||
96 | * running processes. | ||
97 | * | ||
98 | * Remember that machine checks are not common (or rather | ||
99 | * if they are common you have other problems), so this shouldn't | ||
100 | * be a performance issue. | ||
101 | * | ||
102 | * Also there are some races possible while we get from the | ||
103 | * error detection to actually handle it. | ||
104 | */ | ||
105 | |||
106 | struct to_kill { | ||
107 | struct list_head nd; | ||
108 | struct task_struct *tsk; | ||
109 | unsigned long addr; | ||
110 | unsigned addr_valid:1; | ||
111 | }; | ||
112 | |||
113 | /* | ||
114 | * Failure handling: if we can't find or can't kill a process there's | ||
115 | * not much we can do. We just print a message and ignore otherwise. | ||
116 | */ | ||
117 | |||
118 | /* | ||
119 | * Schedule a process for later kill. | ||
120 | * Uses GFP_ATOMIC allocations to avoid potential recursions in the VM. | ||
121 | * TBD would GFP_NOIO be enough? | ||
122 | */ | ||
123 | static void add_to_kill(struct task_struct *tsk, struct page *p, | ||
124 | struct vm_area_struct *vma, | ||
125 | struct list_head *to_kill, | ||
126 | struct to_kill **tkc) | ||
127 | { | ||
128 | struct to_kill *tk; | ||
129 | |||
130 | if (*tkc) { | ||
131 | tk = *tkc; | ||
132 | *tkc = NULL; | ||
133 | } else { | ||
134 | tk = kmalloc(sizeof(struct to_kill), GFP_ATOMIC); | ||
135 | if (!tk) { | ||
136 | printk(KERN_ERR | ||
137 | "MCE: Out of memory while machine check handling\n"); | ||
138 | return; | ||
139 | } | ||
140 | } | ||
141 | tk->addr = page_address_in_vma(p, vma); | ||
142 | tk->addr_valid = 1; | ||
143 | |||
144 | /* | ||
145 | * In theory we don't have to kill when the page was | ||
146 | * munmaped. But it could be also a mremap. Since that's | ||
147 | * likely very rare kill anyways just out of paranoia, but use | ||
148 | * a SIGKILL because the error is not contained anymore. | ||
149 | */ | ||
150 | if (tk->addr == -EFAULT) { | ||
151 | pr_debug("MCE: Unable to find user space address %lx in %s\n", | ||
152 | page_to_pfn(p), tsk->comm); | ||
153 | tk->addr_valid = 0; | ||
154 | } | ||
155 | get_task_struct(tsk); | ||
156 | tk->tsk = tsk; | ||
157 | list_add_tail(&tk->nd, to_kill); | ||
158 | } | ||
159 | |||
160 | /* | ||
161 | * Kill the processes that have been collected earlier. | ||
162 | * | ||
163 | * Only do anything when DOIT is set, otherwise just free the list | ||
164 | * (this is used for clean pages which do not need killing) | ||
165 | * Also when FAIL is set do a force kill because something went | ||
166 | * wrong earlier. | ||
167 | */ | ||
168 | static void kill_procs_ao(struct list_head *to_kill, int doit, int trapno, | ||
169 | int fail, unsigned long pfn) | ||
170 | { | ||
171 | struct to_kill *tk, *next; | ||
172 | |||
173 | list_for_each_entry_safe (tk, next, to_kill, nd) { | ||
174 | if (doit) { | ||
175 | /* | ||
176 | * In case something went wrong with munmaping | ||
177 | * make sure the process doesn't catch the | ||
178 | * signal and then access the memory. Just kill it. | ||
179 | * the signal handlers | ||
180 | */ | ||
181 | if (fail || tk->addr_valid == 0) { | ||
182 | printk(KERN_ERR | ||
183 | "MCE %#lx: forcibly killing %s:%d because of failure to unmap corrupted page\n", | ||
184 | pfn, tk->tsk->comm, tk->tsk->pid); | ||
185 | force_sig(SIGKILL, tk->tsk); | ||
186 | } | ||
187 | |||
188 | /* | ||
189 | * In theory the process could have mapped | ||
190 | * something else on the address in-between. We could | ||
191 | * check for that, but we need to tell the | ||
192 | * process anyways. | ||
193 | */ | ||
194 | else if (kill_proc_ao(tk->tsk, tk->addr, trapno, | ||
195 | pfn) < 0) | ||
196 | printk(KERN_ERR | ||
197 | "MCE %#lx: Cannot send advisory machine check signal to %s:%d\n", | ||
198 | pfn, tk->tsk->comm, tk->tsk->pid); | ||
199 | } | ||
200 | put_task_struct(tk->tsk); | ||
201 | kfree(tk); | ||
202 | } | ||
203 | } | ||
204 | |||
205 | static int task_early_kill(struct task_struct *tsk) | ||
206 | { | ||
207 | if (!tsk->mm) | ||
208 | return 0; | ||
209 | if (tsk->flags & PF_MCE_PROCESS) | ||
210 | return !!(tsk->flags & PF_MCE_EARLY); | ||
211 | return sysctl_memory_failure_early_kill; | ||
212 | } | ||
213 | |||
214 | /* | ||
215 | * Collect processes when the error hit an anonymous page. | ||
216 | */ | ||
217 | static void collect_procs_anon(struct page *page, struct list_head *to_kill, | ||
218 | struct to_kill **tkc) | ||
219 | { | ||
220 | struct vm_area_struct *vma; | ||
221 | struct task_struct *tsk; | ||
222 | struct anon_vma *av; | ||
223 | |||
224 | read_lock(&tasklist_lock); | ||
225 | av = page_lock_anon_vma(page); | ||
226 | if (av == NULL) /* Not actually mapped anymore */ | ||
227 | goto out; | ||
228 | for_each_process (tsk) { | ||
229 | if (!task_early_kill(tsk)) | ||
230 | continue; | ||
231 | list_for_each_entry (vma, &av->head, anon_vma_node) { | ||
232 | if (!page_mapped_in_vma(page, vma)) | ||
233 | continue; | ||
234 | if (vma->vm_mm == tsk->mm) | ||
235 | add_to_kill(tsk, page, vma, to_kill, tkc); | ||
236 | } | ||
237 | } | ||
238 | page_unlock_anon_vma(av); | ||
239 | out: | ||
240 | read_unlock(&tasklist_lock); | ||
241 | } | ||
242 | |||
243 | /* | ||
244 | * Collect processes when the error hit a file mapped page. | ||
245 | */ | ||
246 | static void collect_procs_file(struct page *page, struct list_head *to_kill, | ||
247 | struct to_kill **tkc) | ||
248 | { | ||
249 | struct vm_area_struct *vma; | ||
250 | struct task_struct *tsk; | ||
251 | struct prio_tree_iter iter; | ||
252 | struct address_space *mapping = page->mapping; | ||
253 | |||
254 | /* | ||
255 | * A note on the locking order between the two locks. | ||
256 | * We don't rely on this particular order. | ||
257 | * If you have some other code that needs a different order | ||
258 | * feel free to switch them around. Or add a reverse link | ||
259 | * from mm_struct to task_struct, then this could be all | ||
260 | * done without taking tasklist_lock and looping over all tasks. | ||
261 | */ | ||
262 | |||
263 | read_lock(&tasklist_lock); | ||
264 | spin_lock(&mapping->i_mmap_lock); | ||
265 | for_each_process(tsk) { | ||
266 | pgoff_t pgoff = page->index << (PAGE_CACHE_SHIFT - PAGE_SHIFT); | ||
267 | |||
268 | if (!task_early_kill(tsk)) | ||
269 | continue; | ||
270 | |||
271 | vma_prio_tree_foreach(vma, &iter, &mapping->i_mmap, pgoff, | ||
272 | pgoff) { | ||
273 | /* | ||
274 | * Send early kill signal to tasks where a vma covers | ||
275 | * the page but the corrupted page is not necessarily | ||
276 | * mapped it in its pte. | ||
277 | * Assume applications who requested early kill want | ||
278 | * to be informed of all such data corruptions. | ||
279 | */ | ||
280 | if (vma->vm_mm == tsk->mm) | ||
281 | add_to_kill(tsk, page, vma, to_kill, tkc); | ||
282 | } | ||
283 | } | ||
284 | spin_unlock(&mapping->i_mmap_lock); | ||
285 | read_unlock(&tasklist_lock); | ||
286 | } | ||
287 | |||
288 | /* | ||
289 | * Collect the processes who have the corrupted page mapped to kill. | ||
290 | * This is done in two steps for locking reasons. | ||
291 | * First preallocate one tokill structure outside the spin locks, | ||
292 | * so that we can kill at least one process reasonably reliable. | ||
293 | */ | ||
294 | static void collect_procs(struct page *page, struct list_head *tokill) | ||
295 | { | ||
296 | struct to_kill *tk; | ||
297 | |||
298 | if (!page->mapping) | ||
299 | return; | ||
300 | |||
301 | tk = kmalloc(sizeof(struct to_kill), GFP_NOIO); | ||
302 | if (!tk) | ||
303 | return; | ||
304 | if (PageAnon(page)) | ||
305 | collect_procs_anon(page, tokill, &tk); | ||
306 | else | ||
307 | collect_procs_file(page, tokill, &tk); | ||
308 | kfree(tk); | ||
309 | } | ||
310 | |||
311 | /* | ||
312 | * Error handlers for various types of pages. | ||
313 | */ | ||
314 | |||
315 | enum outcome { | ||
316 | FAILED, /* Error handling failed */ | ||
317 | DELAYED, /* Will be handled later */ | ||
318 | IGNORED, /* Error safely ignored */ | ||
319 | RECOVERED, /* Successfully recovered */ | ||
320 | }; | ||
321 | |||
322 | static const char *action_name[] = { | ||
323 | [FAILED] = "Failed", | ||
324 | [DELAYED] = "Delayed", | ||
325 | [IGNORED] = "Ignored", | ||
326 | [RECOVERED] = "Recovered", | ||
327 | }; | ||
328 | |||
329 | /* | ||
330 | * Error hit kernel page. | ||
331 | * Do nothing, try to be lucky and not touch this instead. For a few cases we | ||
332 | * could be more sophisticated. | ||
333 | */ | ||
334 | static int me_kernel(struct page *p, unsigned long pfn) | ||
335 | { | ||
336 | return DELAYED; | ||
337 | } | ||
338 | |||
339 | /* | ||
340 | * Already poisoned page. | ||
341 | */ | ||
342 | static int me_ignore(struct page *p, unsigned long pfn) | ||
343 | { | ||
344 | return IGNORED; | ||
345 | } | ||
346 | |||
347 | /* | ||
348 | * Page in unknown state. Do nothing. | ||
349 | */ | ||
350 | static int me_unknown(struct page *p, unsigned long pfn) | ||
351 | { | ||
352 | printk(KERN_ERR "MCE %#lx: Unknown page state\n", pfn); | ||
353 | return FAILED; | ||
354 | } | ||
355 | |||
356 | /* | ||
357 | * Free memory | ||
358 | */ | ||
359 | static int me_free(struct page *p, unsigned long pfn) | ||
360 | { | ||
361 | return DELAYED; | ||
362 | } | ||
363 | |||
364 | /* | ||
365 | * Clean (or cleaned) page cache page. | ||
366 | */ | ||
367 | static int me_pagecache_clean(struct page *p, unsigned long pfn) | ||
368 | { | ||
369 | int err; | ||
370 | int ret = FAILED; | ||
371 | struct address_space *mapping; | ||
372 | |||
373 | if (!isolate_lru_page(p)) | ||
374 | page_cache_release(p); | ||
375 | |||
376 | /* | ||
377 | * For anonymous pages we're done the only reference left | ||
378 | * should be the one m_f() holds. | ||
379 | */ | ||
380 | if (PageAnon(p)) | ||
381 | return RECOVERED; | ||
382 | |||
383 | /* | ||
384 | * Now truncate the page in the page cache. This is really | ||
385 | * more like a "temporary hole punch" | ||
386 | * Don't do this for block devices when someone else | ||
387 | * has a reference, because it could be file system metadata | ||
388 | * and that's not safe to truncate. | ||
389 | */ | ||
390 | mapping = page_mapping(p); | ||
391 | if (!mapping) { | ||
392 | /* | ||
393 | * Page has been teared down in the meanwhile | ||
394 | */ | ||
395 | return FAILED; | ||
396 | } | ||
397 | |||
398 | /* | ||
399 | * Truncation is a bit tricky. Enable it per file system for now. | ||
400 | * | ||
401 | * Open: to take i_mutex or not for this? Right now we don't. | ||
402 | */ | ||
403 | if (mapping->a_ops->error_remove_page) { | ||
404 | err = mapping->a_ops->error_remove_page(mapping, p); | ||
405 | if (err != 0) { | ||
406 | printk(KERN_INFO "MCE %#lx: Failed to punch page: %d\n", | ||
407 | pfn, err); | ||
408 | } else if (page_has_private(p) && | ||
409 | !try_to_release_page(p, GFP_NOIO)) { | ||
410 | pr_debug("MCE %#lx: failed to release buffers\n", pfn); | ||
411 | } else { | ||
412 | ret = RECOVERED; | ||
413 | } | ||
414 | } else { | ||
415 | /* | ||
416 | * If the file system doesn't support it just invalidate | ||
417 | * This fails on dirty or anything with private pages | ||
418 | */ | ||
419 | if (invalidate_inode_page(p)) | ||
420 | ret = RECOVERED; | ||
421 | else | ||
422 | printk(KERN_INFO "MCE %#lx: Failed to invalidate\n", | ||
423 | pfn); | ||
424 | } | ||
425 | return ret; | ||
426 | } | ||
427 | |||
428 | /* | ||
429 | * Dirty cache page page | ||
430 | * Issues: when the error hit a hole page the error is not properly | ||
431 | * propagated. | ||
432 | */ | ||
433 | static int me_pagecache_dirty(struct page *p, unsigned long pfn) | ||
434 | { | ||
435 | struct address_space *mapping = page_mapping(p); | ||
436 | |||
437 | SetPageError(p); | ||
438 | /* TBD: print more information about the file. */ | ||
439 | if (mapping) { | ||
440 | /* | ||
441 | * IO error will be reported by write(), fsync(), etc. | ||
442 | * who check the mapping. | ||
443 | * This way the application knows that something went | ||
444 | * wrong with its dirty file data. | ||
445 | * | ||
446 | * There's one open issue: | ||
447 | * | ||
448 | * The EIO will be only reported on the next IO | ||
449 | * operation and then cleared through the IO map. | ||
450 | * Normally Linux has two mechanisms to pass IO error | ||
451 | * first through the AS_EIO flag in the address space | ||
452 | * and then through the PageError flag in the page. | ||
453 | * Since we drop pages on memory failure handling the | ||
454 | * only mechanism open to use is through AS_AIO. | ||
455 | * | ||
456 | * This has the disadvantage that it gets cleared on | ||
457 | * the first operation that returns an error, while | ||
458 | * the PageError bit is more sticky and only cleared | ||
459 | * when the page is reread or dropped. If an | ||
460 | * application assumes it will always get error on | ||
461 | * fsync, but does other operations on the fd before | ||
462 | * and the page is dropped inbetween then the error | ||
463 | * will not be properly reported. | ||
464 | * | ||
465 | * This can already happen even without hwpoisoned | ||
466 | * pages: first on metadata IO errors (which only | ||
467 | * report through AS_EIO) or when the page is dropped | ||
468 | * at the wrong time. | ||
469 | * | ||
470 | * So right now we assume that the application DTRT on | ||
471 | * the first EIO, but we're not worse than other parts | ||
472 | * of the kernel. | ||
473 | */ | ||
474 | mapping_set_error(mapping, EIO); | ||
475 | } | ||
476 | |||
477 | return me_pagecache_clean(p, pfn); | ||
478 | } | ||
479 | |||
480 | /* | ||
481 | * Clean and dirty swap cache. | ||
482 | * | ||
483 | * Dirty swap cache page is tricky to handle. The page could live both in page | ||
484 | * cache and swap cache(ie. page is freshly swapped in). So it could be | ||
485 | * referenced concurrently by 2 types of PTEs: | ||
486 | * normal PTEs and swap PTEs. We try to handle them consistently by calling | ||
487 | * try_to_unmap(TTU_IGNORE_HWPOISON) to convert the normal PTEs to swap PTEs, | ||
488 | * and then | ||
489 | * - clear dirty bit to prevent IO | ||
490 | * - remove from LRU | ||
491 | * - but keep in the swap cache, so that when we return to it on | ||
492 | * a later page fault, we know the application is accessing | ||
493 | * corrupted data and shall be killed (we installed simple | ||
494 | * interception code in do_swap_page to catch it). | ||
495 | * | ||
496 | * Clean swap cache pages can be directly isolated. A later page fault will | ||
497 | * bring in the known good data from disk. | ||
498 | */ | ||
499 | static int me_swapcache_dirty(struct page *p, unsigned long pfn) | ||
500 | { | ||
501 | int ret = FAILED; | ||
502 | |||
503 | ClearPageDirty(p); | ||
504 | /* Trigger EIO in shmem: */ | ||
505 | ClearPageUptodate(p); | ||
506 | |||
507 | if (!isolate_lru_page(p)) { | ||
508 | page_cache_release(p); | ||
509 | ret = DELAYED; | ||
510 | } | ||
511 | |||
512 | return ret; | ||
513 | } | ||
514 | |||
515 | static int me_swapcache_clean(struct page *p, unsigned long pfn) | ||
516 | { | ||
517 | int ret = FAILED; | ||
518 | |||
519 | if (!isolate_lru_page(p)) { | ||
520 | page_cache_release(p); | ||
521 | ret = RECOVERED; | ||
522 | } | ||
523 | delete_from_swap_cache(p); | ||
524 | return ret; | ||
525 | } | ||
526 | |||
527 | /* | ||
528 | * Huge pages. Needs work. | ||
529 | * Issues: | ||
530 | * No rmap support so we cannot find the original mapper. In theory could walk | ||
531 | * all MMs and look for the mappings, but that would be non atomic and racy. | ||
532 | * Need rmap for hugepages for this. Alternatively we could employ a heuristic, | ||
533 | * like just walking the current process and hoping it has it mapped (that | ||
534 | * should be usually true for the common "shared database cache" case) | ||
535 | * Should handle free huge pages and dequeue them too, but this needs to | ||
536 | * handle huge page accounting correctly. | ||
537 | */ | ||
538 | static int me_huge_page(struct page *p, unsigned long pfn) | ||
539 | { | ||
540 | return FAILED; | ||
541 | } | ||
542 | |||
543 | /* | ||
544 | * Various page states we can handle. | ||
545 | * | ||
546 | * A page state is defined by its current page->flags bits. | ||
547 | * The table matches them in order and calls the right handler. | ||
548 | * | ||
549 | * This is quite tricky because we can access page at any time | ||
550 | * in its live cycle, so all accesses have to be extremly careful. | ||
551 | * | ||
552 | * This is not complete. More states could be added. | ||
553 | * For any missing state don't attempt recovery. | ||
554 | */ | ||
555 | |||
556 | #define dirty (1UL << PG_dirty) | ||
557 | #define sc (1UL << PG_swapcache) | ||
558 | #define unevict (1UL << PG_unevictable) | ||
559 | #define mlock (1UL << PG_mlocked) | ||
560 | #define writeback (1UL << PG_writeback) | ||
561 | #define lru (1UL << PG_lru) | ||
562 | #define swapbacked (1UL << PG_swapbacked) | ||
563 | #define head (1UL << PG_head) | ||
564 | #define tail (1UL << PG_tail) | ||
565 | #define compound (1UL << PG_compound) | ||
566 | #define slab (1UL << PG_slab) | ||
567 | #define buddy (1UL << PG_buddy) | ||
568 | #define reserved (1UL << PG_reserved) | ||
569 | |||
570 | static struct page_state { | ||
571 | unsigned long mask; | ||
572 | unsigned long res; | ||
573 | char *msg; | ||
574 | int (*action)(struct page *p, unsigned long pfn); | ||
575 | } error_states[] = { | ||
576 | { reserved, reserved, "reserved kernel", me_ignore }, | ||
577 | { buddy, buddy, "free kernel", me_free }, | ||
578 | |||
579 | /* | ||
580 | * Could in theory check if slab page is free or if we can drop | ||
581 | * currently unused objects without touching them. But just | ||
582 | * treat it as standard kernel for now. | ||
583 | */ | ||
584 | { slab, slab, "kernel slab", me_kernel }, | ||
585 | |||
586 | #ifdef CONFIG_PAGEFLAGS_EXTENDED | ||
587 | { head, head, "huge", me_huge_page }, | ||
588 | { tail, tail, "huge", me_huge_page }, | ||
589 | #else | ||
590 | { compound, compound, "huge", me_huge_page }, | ||
591 | #endif | ||
592 | |||
593 | { sc|dirty, sc|dirty, "swapcache", me_swapcache_dirty }, | ||
594 | { sc|dirty, sc, "swapcache", me_swapcache_clean }, | ||
595 | |||
596 | { unevict|dirty, unevict|dirty, "unevictable LRU", me_pagecache_dirty}, | ||
597 | { unevict, unevict, "unevictable LRU", me_pagecache_clean}, | ||
598 | |||
599 | #ifdef CONFIG_HAVE_MLOCKED_PAGE_BIT | ||
600 | { mlock|dirty, mlock|dirty, "mlocked LRU", me_pagecache_dirty }, | ||
601 | { mlock, mlock, "mlocked LRU", me_pagecache_clean }, | ||
602 | #endif | ||
603 | |||
604 | { lru|dirty, lru|dirty, "LRU", me_pagecache_dirty }, | ||
605 | { lru|dirty, lru, "clean LRU", me_pagecache_clean }, | ||
606 | { swapbacked, swapbacked, "anonymous", me_pagecache_clean }, | ||
607 | |||
608 | /* | ||
609 | * Catchall entry: must be at end. | ||
610 | */ | ||
611 | { 0, 0, "unknown page state", me_unknown }, | ||
612 | }; | ||
613 | |||
614 | #undef lru | ||
615 | |||
616 | static void action_result(unsigned long pfn, char *msg, int result) | ||
617 | { | ||
618 | struct page *page = NULL; | ||
619 | if (pfn_valid(pfn)) | ||
620 | page = pfn_to_page(pfn); | ||
621 | |||
622 | printk(KERN_ERR "MCE %#lx: %s%s page recovery: %s\n", | ||
623 | pfn, | ||
624 | page && PageDirty(page) ? "dirty " : "", | ||
625 | msg, action_name[result]); | ||
626 | } | ||
627 | |||
628 | static int page_action(struct page_state *ps, struct page *p, | ||
629 | unsigned long pfn, int ref) | ||
630 | { | ||
631 | int result; | ||
632 | |||
633 | result = ps->action(p, pfn); | ||
634 | action_result(pfn, ps->msg, result); | ||
635 | if (page_count(p) != 1 + ref) | ||
636 | printk(KERN_ERR | ||
637 | "MCE %#lx: %s page still referenced by %d users\n", | ||
638 | pfn, ps->msg, page_count(p) - 1); | ||
639 | |||
640 | /* Could do more checks here if page looks ok */ | ||
641 | /* | ||
642 | * Could adjust zone counters here to correct for the missing page. | ||
643 | */ | ||
644 | |||
645 | return result == RECOVERED ? 0 : -EBUSY; | ||
646 | } | ||
647 | |||
648 | #define N_UNMAP_TRIES 5 | ||
649 | |||
650 | /* | ||
651 | * Do all that is necessary to remove user space mappings. Unmap | ||
652 | * the pages and send SIGBUS to the processes if the data was dirty. | ||
653 | */ | ||
654 | static void hwpoison_user_mappings(struct page *p, unsigned long pfn, | ||
655 | int trapno) | ||
656 | { | ||
657 | enum ttu_flags ttu = TTU_UNMAP | TTU_IGNORE_MLOCK | TTU_IGNORE_ACCESS; | ||
658 | struct address_space *mapping; | ||
659 | LIST_HEAD(tokill); | ||
660 | int ret; | ||
661 | int i; | ||
662 | int kill = 1; | ||
663 | |||
664 | if (PageReserved(p) || PageCompound(p) || PageSlab(p)) | ||
665 | return; | ||
666 | |||
667 | if (!PageLRU(p)) | ||
668 | lru_add_drain_all(); | ||
669 | |||
670 | /* | ||
671 | * This check implies we don't kill processes if their pages | ||
672 | * are in the swap cache early. Those are always late kills. | ||
673 | */ | ||
674 | if (!page_mapped(p)) | ||
675 | return; | ||
676 | |||
677 | if (PageSwapCache(p)) { | ||
678 | printk(KERN_ERR | ||
679 | "MCE %#lx: keeping poisoned page in swap cache\n", pfn); | ||
680 | ttu |= TTU_IGNORE_HWPOISON; | ||
681 | } | ||
682 | |||
683 | /* | ||
684 | * Propagate the dirty bit from PTEs to struct page first, because we | ||
685 | * need this to decide if we should kill or just drop the page. | ||
686 | */ | ||
687 | mapping = page_mapping(p); | ||
688 | if (!PageDirty(p) && mapping && mapping_cap_writeback_dirty(mapping)) { | ||
689 | if (page_mkclean(p)) { | ||
690 | SetPageDirty(p); | ||
691 | } else { | ||
692 | kill = 0; | ||
693 | ttu |= TTU_IGNORE_HWPOISON; | ||
694 | printk(KERN_INFO | ||
695 | "MCE %#lx: corrupted page was clean: dropped without side effects\n", | ||
696 | pfn); | ||
697 | } | ||
698 | } | ||
699 | |||
700 | /* | ||
701 | * First collect all the processes that have the page | ||
702 | * mapped in dirty form. This has to be done before try_to_unmap, | ||
703 | * because ttu takes the rmap data structures down. | ||
704 | * | ||
705 | * Error handling: We ignore errors here because | ||
706 | * there's nothing that can be done. | ||
707 | */ | ||
708 | if (kill) | ||
709 | collect_procs(p, &tokill); | ||
710 | |||
711 | /* | ||
712 | * try_to_unmap can fail temporarily due to races. | ||
713 | * Try a few times (RED-PEN better strategy?) | ||
714 | */ | ||
715 | for (i = 0; i < N_UNMAP_TRIES; i++) { | ||
716 | ret = try_to_unmap(p, ttu); | ||
717 | if (ret == SWAP_SUCCESS) | ||
718 | break; | ||
719 | pr_debug("MCE %#lx: try_to_unmap retry needed %d\n", pfn, ret); | ||
720 | } | ||
721 | |||
722 | if (ret != SWAP_SUCCESS) | ||
723 | printk(KERN_ERR "MCE %#lx: failed to unmap page (mapcount=%d)\n", | ||
724 | pfn, page_mapcount(p)); | ||
725 | |||
726 | /* | ||
727 | * Now that the dirty bit has been propagated to the | ||
728 | * struct page and all unmaps done we can decide if | ||
729 | * killing is needed or not. Only kill when the page | ||
730 | * was dirty, otherwise the tokill list is merely | ||
731 | * freed. When there was a problem unmapping earlier | ||
732 | * use a more force-full uncatchable kill to prevent | ||
733 | * any accesses to the poisoned memory. | ||
734 | */ | ||
735 | kill_procs_ao(&tokill, !!PageDirty(p), trapno, | ||
736 | ret != SWAP_SUCCESS, pfn); | ||
737 | } | ||
738 | |||
739 | int __memory_failure(unsigned long pfn, int trapno, int ref) | ||
740 | { | ||
741 | struct page_state *ps; | ||
742 | struct page *p; | ||
743 | int res; | ||
744 | |||
745 | if (!sysctl_memory_failure_recovery) | ||
746 | panic("Memory failure from trap %d on page %lx", trapno, pfn); | ||
747 | |||
748 | if (!pfn_valid(pfn)) { | ||
749 | action_result(pfn, "memory outside kernel control", IGNORED); | ||
750 | return -EIO; | ||
751 | } | ||
752 | |||
753 | p = pfn_to_page(pfn); | ||
754 | if (TestSetPageHWPoison(p)) { | ||
755 | action_result(pfn, "already hardware poisoned", IGNORED); | ||
756 | return 0; | ||
757 | } | ||
758 | |||
759 | atomic_long_add(1, &mce_bad_pages); | ||
760 | |||
761 | /* | ||
762 | * We need/can do nothing about count=0 pages. | ||
763 | * 1) it's a free page, and therefore in safe hand: | ||
764 | * prep_new_page() will be the gate keeper. | ||
765 | * 2) it's part of a non-compound high order page. | ||
766 | * Implies some kernel user: cannot stop them from | ||
767 | * R/W the page; let's pray that the page has been | ||
768 | * used and will be freed some time later. | ||
769 | * In fact it's dangerous to directly bump up page count from 0, | ||
770 | * that may make page_freeze_refs()/page_unfreeze_refs() mismatch. | ||
771 | */ | ||
772 | if (!get_page_unless_zero(compound_head(p))) { | ||
773 | action_result(pfn, "free or high order kernel", IGNORED); | ||
774 | return PageBuddy(compound_head(p)) ? 0 : -EBUSY; | ||
775 | } | ||
776 | |||
777 | /* | ||
778 | * Lock the page and wait for writeback to finish. | ||
779 | * It's very difficult to mess with pages currently under IO | ||
780 | * and in many cases impossible, so we just avoid it here. | ||
781 | */ | ||
782 | lock_page_nosync(p); | ||
783 | wait_on_page_writeback(p); | ||
784 | |||
785 | /* | ||
786 | * Now take care of user space mappings. | ||
787 | */ | ||
788 | hwpoison_user_mappings(p, pfn, trapno); | ||
789 | |||
790 | /* | ||
791 | * Torn down by someone else? | ||
792 | */ | ||
793 | if (PageLRU(p) && !PageSwapCache(p) && p->mapping == NULL) { | ||
794 | action_result(pfn, "already truncated LRU", IGNORED); | ||
795 | res = 0; | ||
796 | goto out; | ||
797 | } | ||
798 | |||
799 | res = -EBUSY; | ||
800 | for (ps = error_states;; ps++) { | ||
801 | if ((p->flags & ps->mask) == ps->res) { | ||
802 | res = page_action(ps, p, pfn, ref); | ||
803 | break; | ||
804 | } | ||
805 | } | ||
806 | out: | ||
807 | unlock_page(p); | ||
808 | return res; | ||
809 | } | ||
810 | EXPORT_SYMBOL_GPL(__memory_failure); | ||
811 | |||
812 | /** | ||
813 | * memory_failure - Handle memory failure of a page. | ||
814 | * @pfn: Page Number of the corrupted page | ||
815 | * @trapno: Trap number reported in the signal to user space. | ||
816 | * | ||
817 | * This function is called by the low level machine check code | ||
818 | * of an architecture when it detects hardware memory corruption | ||
819 | * of a page. It tries its best to recover, which includes | ||
820 | * dropping pages, killing processes etc. | ||
821 | * | ||
822 | * The function is primarily of use for corruptions that | ||
823 | * happen outside the current execution context (e.g. when | ||
824 | * detected by a background scrubber) | ||
825 | * | ||
826 | * Must run in process context (e.g. a work queue) with interrupts | ||
827 | * enabled and no spinlocks hold. | ||
828 | */ | ||
829 | void memory_failure(unsigned long pfn, int trapno) | ||
830 | { | ||
831 | __memory_failure(pfn, trapno, 0); | ||
832 | } | ||