| blob | 8a2cdd736fa4da82374fa9392e76b5716cc0f89a |
1 /*
2 * Copyright (C) 1991, 1992 Linus Torvalds
3 * Copyright (C) 2000, 2001, 2002 Andi Kleen, SuSE Labs
4 * Copyright (C) 2011 Don Zickus Red Hat, Inc.
5 *
6 * Pentium III FXSR, SSE support
7 * Gareth Hughes <gareth@valinux.com>, May 2000
8 */
10 /*
11 * Handle hardware traps and faults.
12 */
13 #include <linux/spinlock.h>
14 #include <linux/kprobes.h>
15 #include <linux/kdebug.h>
16 #include <linux/nmi.h>
17 #include <linux/debugfs.h>
18 #include <linux/delay.h>
19 #include <linux/hardirq.h>
20 #include <linux/slab.h>
21 #include <linux/export.h>
23 #if defined(CONFIG_EDAC)
24 #include <linux/edac.h>
25 #endif
27 #include <linux/atomic.h>
28 #include <asm/traps.h>
29 #include <asm/mach_traps.h>
30 #include <asm/nmi.h>
31 #include <asm/x86_init.h>
32 #include <asm/reboot.h>
34 #define CREATE_TRACE_POINTS
35 #include <trace/events/nmi.h>
38 spinlock_t lock;
40 };
43 {
44 {
47 },
48 {
51 },
52 {
55 },
56 {
59 },
61 };
68 };
75 /*
76 * Prevent NMI reason port (0x61) being accessed simultaneously, can
77 * only be used in NMI handler.
78 */
82 {
85 }
88 #define nmi_to_desc(type) (&nmi_desc[type])
93 {
97 }
101 {
112 }
115 {
122 /*
123 * NMIs are edge-triggered, which means if you have enough
124 * of them concurrently, you can lose some because only one
125 * can be latched at any given time. Walk the whole list
126 * to handle those situations.
127 */
130 u64 delta;
143 }
147 /* return total number of NMI events handled */
149 }
153 {
164 /*
165 * most handlers of type NMI_UNKNOWN never return because
166 * they just assume the NMI is theirs. Just a sanity check
167 * to manage expectations
168 */
173 /*
174 * some handlers need to be executed first otherwise a fake
175 * event confuses some handlers (kdump uses this flag)
176 */
179 else
184 }
188 {
196 /*
197 * the name passed in to describe the nmi handler
198 * is used as the lookup key
199 */
205 }
206 }
210 }
213 static void
215 {
216 /* check to see if anyone registered against these types of errors */
223 /*
224 * On some machines, PCI SERR line is used to report memory
225 * errors. EDAC makes use of it.
226 */
227 #if defined(CONFIG_EDAC)
231 }
232 #endif
239 /* Clear and disable the PCI SERR error line. */
242 }
245 static void
247 {
250 /* check to see if anyone registered against these types of errors */
262 /*
263 * If we end up here, it means we have received an NMI while
264 * processing panic(). Simply return without delaying and
265 * re-enabling NMIs.
266 */
268 }
270 /* Re-enable the IOCK line, wait for a few seconds */
278 }
282 }
285 static void
287 {
290 /*
291 * Use 'false' as back-to-back NMIs are dealt with one level up.
292 * Of course this makes having multiple 'unknown' handlers useless
293 * as only the first one is ever run (unless it can actually determine
294 * if it caused the NMI)
295 */
300 }
312 }
319 {
324 /*
325 * CPU-specific NMI must be processed before non-CPU-specific
326 * NMI, otherwise we may lose it, because the CPU-specific
327 * NMI can not be detected/processed on other CPUs.
328 */
330 /*
331 * Back-to-back NMIs are interesting because they can either
332 * be two NMI or more than two NMIs (any thing over two is dropped
333 * due to NMI being edge-triggered). If this is the second half
334 * of the back-to-back NMI, assume we dropped things and process
335 * more handlers. Otherwise reset the 'swallow' NMI behaviour
336 */
339 else
347 /*
348 * There are cases when a NMI handler handles multiple
349 * events in the current NMI. One of these events may
350 * be queued for in the next NMI. Because the event is
351 * already handled, the next NMI will result in an unknown
352 * NMI. Instead lets flag this for a potential NMI to
353 * swallow.
354 */
358 }
360 /*
361 * Non-CPU-specific NMI: NMI sources can be processed on any CPU.
362 *
363 * Another CPU may be processing panic routines while holding
364 * nmi_reason_lock. Check if the CPU issued the IPI for crash dumping,
365 * and if so, call its callback directly. If there is no CPU preparing
366 * crash dump, we simply loop here.
367 */
371 }
380 #ifdef CONFIG_X86_32
381 /*
382 * Reassert NMI in case it became active
383 * meanwhile as it's edge-triggered:
384 */
386 #endif
390 }
393 /*
394 * Only one NMI can be latched at a time. To handle
395 * this we may process multiple nmi handlers at once to
396 * cover the case where an NMI is dropped. The downside
397 * to this approach is we may process an NMI prematurely,
398 * while its real NMI is sitting latched. This will cause
399 * an unknown NMI on the next run of the NMI processing.
400 *
401 * We tried to flag that condition above, by setting the
402 * swallow_nmi flag when we process more than one event.
403 * This condition is also only present on the second half
404 * of a back-to-back NMI, so we flag that condition too.
405 *
406 * If both are true, we assume we already processed this
407 * NMI previously and we swallow it. Otherwise we reset
408 * the logic.
409 *
410 * There are scenarios where we may accidentally swallow
411 * a 'real' unknown NMI. For example, while processing
412 * a perf NMI another perf NMI comes in along with a
413 * 'real' unknown NMI. These two NMIs get combined into
414 * one (as descibed above). When the next NMI gets
415 * processed, it will be flagged by perf as handled, but
416 * noone will know that there was a 'real' unknown NMI sent
417 * also. As a result it gets swallowed. Or if the first
418 * perf NMI returns two events handled then the second
419 * NMI will get eaten by the logic below, again losing a
420 * 'real' unknown NMI. But this is the best we can do
421 * for now.
422 */
425 else
427 }
430 /*
431 * NMIs can page fault or hit breakpoints which will cause it to lose
432 * its NMI context with the CPU when the breakpoint or page fault does an IRET.
433 *
434 * As a result, NMIs can nest if NMIs get unmasked due an IRET during
435 * NMI processing. On x86_64, the asm glue protects us from nested NMIs
436 * if the outer NMI came from kernel mode, but we can still nest if the
437 * outer NMI came from user mode.
438 *
439 * To handle these nested NMIs, we have three states:
440 *
441 * 1) not running
442 * 2) executing
443 * 3) latched
444 *
445 * When no NMI is in progress, it is in the "not running" state.
446 * When an NMI comes in, it goes into the "executing" state.
447 * Normally, if another NMI is triggered, it does not interrupt
448 * the running NMI and the HW will simply latch it so that when
449 * the first NMI finishes, it will restart the second NMI.
450 * (Note, the latch is binary, thus multiple NMIs triggering,
451 * when one is running, are ignored. Only one NMI is restarted.)
452 *
453 * If an NMI executes an iret, another NMI can preempt it. We do not
454 * want to allow this new NMI to run, but we want to execute it when the
455 * first one finishes. We set the state to "latched", and the exit of
456 * the first NMI will perform a dec_return, if the result is zero
457 * (NOT_RUNNING), then it will simply exit the NMI handler. If not, the
458 * dec_return would have set the state to NMI_EXECUTING (what we want it
459 * to be when we are running). In this case, we simply jump back to
460 * rerun the NMI handler again, and restart the 'latched' NMI.
461 *
462 * No trap (breakpoint or page fault) should be hit before nmi_restart,
463 * thus there is no race between the first check of state for NOT_RUNNING
464 * and setting it to NMI_EXECUTING. The HW will prevent nested NMIs
465 * at this point.
466 *
467 * In case the NMI takes a page fault, we need to save off the CR2
468 * because the NMI could have preempted another page fault and corrupt
469 * the CR2 that is about to be read. As nested NMIs must be restarted
470 * and they can not take breakpoints or page faults, the update of the
471 * CR2 must be done before converting the nmi state back to NOT_RUNNING.
472 * Otherwise, there would be a race of another nested NMI coming in
473 * after setting state to NOT_RUNNING but before updating the nmi_cr2.
474 */
477 NMI_EXECUTING,
478 NMI_LATCHED,
479 };
483 #ifdef CONFIG_X86_64
484 /*
485 * In x86_64, we need to handle breakpoint -> NMI -> breakpoint. Without
486 * some care, the inner breakpoint will clobber the outer breakpoint's
487 * stack.
488 *
489 * If a breakpoint is being processed, and the debug stack is being
490 * used, if an NMI comes in and also hits a breakpoint, the stack
491 * pointer will be set to the same fixed address as the breakpoint that
492 * was interrupted, causing that stack to be corrupted. To handle this
493 * case, check if the stack that was interrupted is the debug stack, and
494 * if so, change the IDT so that new breakpoints will use the current
495 * stack and not switch to the fixed address. On return of the NMI,
496 * switch back to the original IDT.
497 */
499 #endif
501 dotraplinkage notrace void
503 {
507 }
510 nmi_restart:
512 #ifdef CONFIG_X86_64
513 /*
514 * If we interrupted a breakpoint, it is possible that
515 * the nmi handler will have breakpoints too. We need to
516 * change the IDT such that breakpoints that happen here
517 * continue to use the NMI stack.
518 */
522 }
523 #endif
534 #ifdef CONFIG_X86_64
538 }
539 #endif
545 }
549 {
550 ignore_nmis++;
551 }
554 {
555 ignore_nmis--;
556 }
558 /* reset the back-to-back NMI logic */
560 {
562 }