| blob | f336e2107f980e2546ecc118d2dd3239f655ebae |
1 /*
2 * kexec.c - kexec system call
3 * Copyright (C) 2002-2004 Eric Biederman <ebiederm@xmission.com>
4 *
5 * This source code is licensed under the GNU General Public License,
6 * Version 2. See the file COPYING for more details.
7 */
9 #include <linux/capability.h>
10 #include <linux/mm.h>
11 #include <linux/file.h>
12 #include <linux/slab.h>
13 #include <linux/fs.h>
14 #include <linux/kexec.h>
15 #include <linux/mutex.h>
16 #include <linux/list.h>
17 #include <linux/highmem.h>
18 #include <linux/syscalls.h>
19 #include <linux/reboot.h>
20 #include <linux/ioport.h>
21 #include <linux/hardirq.h>
22 #include <linux/elf.h>
23 #include <linux/elfcore.h>
24 #include <linux/utsrelease.h>
25 #include <linux/utsname.h>
26 #include <linux/numa.h>
27 #include <linux/suspend.h>
28 #include <linux/device.h>
29 #include <linux/freezer.h>
30 #include <linux/pm.h>
31 #include <linux/cpu.h>
32 #include <linux/console.h>
33 #include <linux/vmalloc.h>
35 #include <asm/page.h>
36 #include <asm/uaccess.h>
37 #include <asm/io.h>
38 #include <asm/system.h>
39 #include <asm/sections.h>
41 /* Per cpu memory for storing cpu states in case of system crash. */
44 /* vmcoreinfo stuff */
50 /* Location of the reserved area for the crash kernel */
56 };
59 {
63 }
65 /*
66 * When kexec transitions to the new kernel there is a one-to-one
67 * mapping between physical and virtual addresses. On processors
68 * where you can disable the MMU this is trivial, and easy. For
69 * others it is still a simple predictable page table to setup.
70 *
71 * In that environment kexec copies the new kernel to its final
72 * resting place. This means I can only support memory whose
73 * physical address can fit in an unsigned long. In particular
74 * addresses where (pfn << PAGE_SHIFT) > ULONG_MAX cannot be handled.
75 * If the assembly stub has more restrictive requirements
76 * KEXEC_SOURCE_MEMORY_LIMIT and KEXEC_DEST_MEMORY_LIMIT can be
77 * defined more restrictively in <asm/kexec.h>.
78 *
79 * The code for the transition from the current kernel to the
80 * the new kernel is placed in the control_code_buffer, whose size
81 * is given by KEXEC_CONTROL_PAGE_SIZE. In the best case only a single
82 * page of memory is necessary, but some architectures require more.
83 * Because this memory must be identity mapped in the transition from
84 * virtual to physical addresses it must live in the range
85 * 0 - TASK_SIZE, as only the user space mappings are arbitrarily
86 * modifiable.
87 *
88 * The assembly stub in the control code buffer is passed a linked list
89 * of descriptor pages detailing the source pages of the new kernel,
90 * and the destination addresses of those source pages. As this data
91 * structure is not used in the context of the current OS, it must
92 * be self-contained.
93 *
94 * The code has been made to work with highmem pages and will use a
95 * destination page in its final resting place (if it happens
96 * to allocate it). The end product of this is that most of the
97 * physical address space, and most of RAM can be used.
98 *
99 * Future directions include:
100 * - allocating a page table with the control code buffer identity
101 * mapped, to simplify machine_kexec and make kexec_on_panic more
102 * reliable.
103 */
105 /*
106 * KIMAGE_NO_DEST is an impossible destination address..., for
107 * allocating pages whose destination address we do not care about.
108 */
109 #define KIMAGE_NO_DEST (-1UL)
114 gfp_t gfp_mask,
120 {
126 /* Allocate a controlling structure */
139 /* Initialize the list of control pages */
142 /* Initialize the list of destination pages */
145 /* Initialize the list of unuseable pages */
148 /* Read in the segments */
155 /*
156 * Verify we have good destination addresses. The caller is
157 * responsible for making certain we don't attempt to load
158 * the new image into invalid or reserved areas of RAM. This
159 * just verifies it is an address we can use.
160 *
161 * Since the kernel does everything in page size chunks ensure
162 * the destination addreses are page aligned. Too many
163 * special cases crop of when we don't do this. The most
164 * insidious is getting overlapping destination addresses
165 * simply because addresses are changed to page size
166 * granularity.
167 */
178 }
180 /* Verify our destination addresses do not overlap.
181 * If we alloed overlapping destination addresses
182 * through very weird things can happen with no
183 * easy explanation as one segment stops on another.
184 */
196 /* Do the segments overlap ? */
199 }
200 }
202 /* Ensure our buffer sizes are strictly less than
203 * our memory sizes. This should always be the case,
204 * and it is easier to check up front than to be surprised
205 * later on.
206 */
211 }
214 out:
217 else
222 }
227 {
231 /* Allocate and initialize a controlling structure */
239 /*
240 * Find a location for the control code buffer, and add it
241 * the vector of segments so that it's pages will also be
242 * counted as destination pages.
243 */
250 }
256 }
259 out:
262 else
266 }
271 {
277 /* Verify we have a valid entry point */
281 }
283 /* Allocate and initialize a controlling structure */
288 /* Enable the special crash kernel control page
289 * allocation policy.
290 */
294 /*
295 * Verify we have good destination addresses. Normally
296 * the caller is responsible for making certain we don't
297 * attempt to load the new image into invalid or reserved
298 * areas of RAM. But crash kernels are preloaded into a
299 * reserved area of ram. We must ensure the addresses
300 * are in the reserved area otherwise preloading the
301 * kernel could corrupt things.
302 */
309 /* Ensure we are within the crash kernel limits */
312 }
314 /*
315 * Find a location for the control code buffer, and add
316 * the vector of segments so that it's pages will also be
317 * counted as destination pages.
318 */
325 }
328 out:
331 else
335 }
340 {
350 }
353 }
356 {
367 }
370 }
373 {
381 }
384 {
393 }
394 }
398 {
399 /* Control pages are special, they are the intermediaries
400 * that are needed while we copy the rest of the pages
401 * to their final resting place. As such they must
402 * not conflict with either the destination addresses
403 * or memory the kernel is already using.
404 *
405 * The only case where we really need more than one of
406 * these are for architectures where we cannot disable
407 * the MMU and must instead generate an identity mapped
408 * page table for all of the memory.
409 *
410 * At worst this runs in O(N) of the image size.
411 */
419 /* Loop while I can allocate a page and the page allocated
420 * is a destination page.
421 */
436 }
440 /* Remember the allocated page... */
443 /* Because the page is already in it's destination
444 * location we will never allocate another page at
445 * that address. Therefore kimage_alloc_pages
446 * will not return it (again) and we don't need
447 * to give it an entry in image->segment[].
448 */
449 }
450 /* Deal with the destination pages I have inadvertently allocated.
451 *
452 * Ideally I would convert multi-page allocations into single
453 * page allocations, and add everyting to image->dest_pages.
454 *
455 * For now it is simpler to just free the pages.
456 */
460 }
464 {
465 /* Control pages are special, they are the intermediaries
466 * that are needed while we copy the rest of the pages
467 * to their final resting place. As such they must
468 * not conflict with either the destination addresses
469 * or memory the kernel is already using.
470 *
471 * Control pages are also the only pags we must allocate
472 * when loading a crash kernel. All of the other pages
473 * are specified by the segments and we just memcpy
474 * into them directly.
475 *
476 * The only case where we really need more than one of
477 * these are for architectures where we cannot disable
478 * the MMU and must instead generate an identity mapped
479 * page table for all of the memory.
480 *
481 * Given the low demand this implements a very simple
482 * allocator that finds the first hole of the appropriate
483 * size in the reserved memory region, and allocates all
484 * of the memory up to and including the hole.
485 */
500 /* See if I overlap any of the segments */
507 /* Advance the hole to the end of the segment */
511 }
512 }
513 /* If I don't overlap any segments I have found my hole! */
517 }
518 }
523 }
528 {
538 }
541 }
544 {
561 }
567 }
571 {
580 }
584 {
593 }
597 {
598 /* Walk through and free any extra destination pages I may have */
601 /* Walk through and free any unuseable pages I have cached */
604 }
606 {
611 }
613 #define for_each_kimage_entry(image, ptr, entry) \
614 for (ptr = &image->head; (entry = *ptr) && !(entry & IND_DONE); \
615 ptr = (entry & IND_INDIRECTION)? \
616 phys_to_virt((entry & PAGE_MASK)): ptr +1)
619 {
624 }
627 {
637 /* Free the previous indirection page */
640 /* Save this indirection page until we are
641 * done with it.
642 */
644 }
647 }
648 /* Free the final indirection page */
652 /* Handle any machine specific cleanup */
655 /* Free the kexec control pages... */
658 }
662 {
673 }
674 }
677 }
680 gfp_t gfp_mask,
682 {
683 /*
684 * Here we implement safeguards to ensure that a source page
685 * is not copied to its destination page before the data on
686 * the destination page is no longer useful.
687 *
688 * To do this we maintain the invariant that a source page is
689 * either its own destination page, or it is not a
690 * destination page at all.
691 *
692 * That is slightly stronger than required, but the proof
693 * that no problems will not occur is trivial, and the
694 * implementation is simply to verify.
695 *
696 * When allocating all pages normally this algorithm will run
697 * in O(N) time, but in the worst case it will run in O(N^2)
698 * time. If the runtime is a problem the data structures can
699 * be fixed.
700 */
704 /*
705 * Walk through the list of destination pages, and see if I
706 * have a match.
707 */
713 }
714 }
719 /* Allocate a page, if we run out of memory give up */
723 /* If the page cannot be used file it away */
728 }
731 /* If it is the destination page we want use it */
735 /* If the page is not a destination page use it */
740 /*
741 * I know that the page is someones destination page.
742 * See if there is already a source page for this
743 * destination page. And if so swap the source pages.
744 */
747 /* If so move it */
756 /* The old page I have found cannot be a
757 * destination page, so return it if it's
758 * gfp_flags honor the ones passed in.
759 */
764 }
768 }
770 /* Place the page on the destination list I
771 * will use it later.
772 */
774 }
775 }
778 }
782 {
807 }
814 /* Start with a clear page */
830 }
835 }
836 out:
838 }
842 {
843 /* For crash dumps kernels we simply copy the data from
844 * user space to it's destination.
845 * We do things a page at a time for the sake of kmap.
846 */
866 }
876 /* Zero the trailing part of the page */
878 }
885 }
890 }
891 out:
893 }
897 {
907 }
910 }
912 /*
913 * Exec Kernel system call: for obvious reasons only root may call it.
914 *
915 * This call breaks up into three pieces.
916 * - A generic part which loads the new kernel from the current
917 * address space, and very carefully places the data in the
918 * allocated pages.
919 *
920 * - A generic part that interacts with the kernel and tells all of
921 * the devices to shut down. Preventing on-going dmas, and placing
922 * the devices in a consistent state so a later kernel can
923 * reinitialize them.
924 *
925 * - A machine specific part that includes the syscall number
926 * and the copies the image to it's final destination. And
927 * jumps into the image at entry.
928 *
929 * kexec does not sync, or unmount filesystems so if you need
930 * that to happen you need to do that yourself.
931 */
939 {
943 /* We only trust the superuser with rebooting the system. */
947 /*
948 * Verify we have a legal set of flags
949 * This leaves us room for future extensions.
950 */
954 /* Verify we are on the appropriate architecture */
959 /* Put an artificial cap on the number
960 * of segments passed to kexec_load.
961 */
968 /* Because we write directly to the reserved memory
969 * region when loading crash kernels we need a mutex here to
970 * prevent multiple crash kernels from attempting to load
971 * simultaneously, and to prevent a crash kernel from loading
972 * over the top of a in use crash kernel.
973 *
974 * KISS: always take the mutex.
975 */
985 /* Loading another kernel to reboot into */
989 /* Loading another kernel to switch to if this one crashes */
991 /* Free any current crash dump kernel before
992 * we corrupt it.
993 */
997 }
1011 }
1013 }
1014 /* Install the new kernel, and Uninstall the old */
1017 out:
1022 }
1024 #ifdef CONFIG_COMPAT
1029 {
1034 /* Don't allow clients that don't understand the native
1035 * architecture to do anything.
1036 */
1057 }
1060 }
1061 #endif
1064 {
1065 /* Take the kexec_mutex here to prevent sys_kexec_load
1066 * running on one cpu from replacing the crash kernel
1067 * we are using after a panic on a different cpu.
1068 *
1069 * If the crash kernel was not located in a fixed area
1070 * of memory the xchg(&kexec_crash_image) would be
1071 * sufficient. But since I reuse the memory...
1072 */
1080 }
1082 }
1083 }
1087 {
1101 }
1104 {
1111 }
1114 {
1121 /* Using ELF notes here is opportunistic.
1122 * I need a well defined structure format
1123 * for the data I pass, and I need tags
1124 * on the data to indicate what information I have
1125 * squirrelled away. ELF notes happen to provide
1126 * all of that, so there is no need to invent something new.
1127 */
1137 }
1140 {
1141 /* Allocate memory for saving cpu registers. */
1147 }
1149 }
1153 /*
1154 * parsing the "crashkernel" commandline
1155 *
1156 * this code is intended to be called from architecture specific code
1157 */
1160 /*
1161 * This function parses command lines in the format
1162 *
1163 * crashkernel=ramsize-range:size[,...][@offset]
1164 *
1165 * The function returns 0 on success and -EINVAL on failure.
1166 */
1171 {
1174 /* for each entry of the comma-separated list */
1178 /* get the start of the range */
1183 }
1188 }
1189 cur++;
1191 /* if no ':' is here, than we read the end */
1198 }
1203 }
1204 }
1209 }
1210 cur++;
1216 }
1221 }
1223 /* match ? */
1227 }
1232 cur++;
1234 cur++;
1240 }
1241 }
1242 }
1245 }
1247 /*
1248 * That function parses "simple" (old) crashkernel command lines like
1249 *
1250 * crashkernel=size[@offset]
1251 *
1252 * It returns 0 on success and -EINVAL on failure.
1253 */
1257 {
1264 }
1270 }
1272 /*
1273 * That function is the entry point for command line parsing and should be
1274 * called from the arch-specific code.
1275 */
1280 {
1288 /* find crashkernel and use the last one if there are more */
1293 }
1300 /*
1301 * if the commandline contains a ':', then that's the extended
1302 * syntax -- if not, it must be the classic syntax
1303 */
1309 else
1311 crash_base);
1314 }
1319 {
1330 vmcoreinfo_size);
1333 }
1336 {
1351 }
1353 /*
1354 * provide an empty default implementation here -- architecture
1355 * code may override this
1356 */
1358 {}
1361 {
1363 }
1366 {
1376 #ifndef CONFIG_NEED_MULTIPLE_NODES
1379 #endif
1380 #ifdef CONFIG_SPARSEMEM
1385 #endif
1398 #ifdef CONFIG_FLAT_NODE_MEM_MAP
1400 #endif
1422 }
1426 /*
1427 * Move into place and start executing a preloaded standalone
1428 * executable. If nothing was preloaded return an error.
1429 */
1431 {
1439 }
1441 #ifdef CONFIG_KEXEC_JUMP
1449 }
1454 /* At this point, dpm_suspend_start() has been called,
1455 * but *not* dpm_suspend_noirq(). We *must* call
1456 * dpm_suspend_noirq() now. Otherwise, drivers for
1457 * some devices (e.g. interrupt controllers) become
1458 * desynchronized with the actual state of the
1459 * hardware at resume time, and evil weirdness ensues.
1460 */
1468 /* Suspend system devices */
1473 #endif
1474 {
1478 }
1482 #ifdef CONFIG_KEXEC_JUMP
1485 Enable_irqs:
1487 Enable_cpus:
1490 Resume_devices:
1492 Resume_console:
1495 Restore_console:
1498 }
1499 #endif
1501 Unlock:
1504 }