| blob | 2b5886401e5f4eb2c221f813675927a53cc97d61 |
1 /*
2 * Copyright (C) 1991, 1992 Linus Torvalds
3 * Copyright (C) 2000, 2001, 2002 Andi Kleen, SuSE Labs
4 */
5 #include <linux/kallsyms.h>
6 #include <linux/kprobes.h>
7 #include <linux/uaccess.h>
8 #include <linux/utsname.h>
9 #include <linux/hardirq.h>
10 #include <linux/kdebug.h>
11 #include <linux/module.h>
12 #include <linux/ptrace.h>
13 #include <linux/sched/debug.h>
14 #include <linux/sched/task_stack.h>
15 #include <linux/ftrace.h>
16 #include <linux/kexec.h>
17 #include <linux/bug.h>
18 #include <linux/nmi.h>
19 #include <linux/sysfs.h>
20 #include <linux/kasan.h>
22 #include <asm/cpu_entry_area.h>
23 #include <asm/stacktrace.h>
24 #include <asm/unwind.h>
34 {
47 }
50 {
65 }
69 {
72 }
74 /*
75 * There are a couple of reasons for the 2/3rd prologue, courtesy of Linus:
76 *
77 * In case where we don't have the exact kernel image (which, if we did, we can
78 * simply disassemble and navigate to the RIP), the purpose of the bigger
79 * prologue is to have more context and to be able to correlate the code from
80 * the different toolchains better.
81 *
82 * In addition, it helps in recreating the register allocation of the failing
83 * kernel and thus make sense of the register dump.
84 *
85 * What is more, the additional complication of a variable length insn arch like
86 * x86 warrants having longer byte sequence before rIP so that the disassembler
87 * can "sync" up properly and find instruction boundaries when decoding the
88 * opcode bytes.
89 *
90 * Thus, the 2/3rds prologue and 64 byte OPCODE_BUFSIZE is just a random
91 * guesstimate in attempt to achieve all of the above.
92 */
94 {
95 #define PROLOGUE_SIZE 42
96 #define EPILOGUE_SIZE 21
97 #define OPCODE_BUFSIZE (PROLOGUE_SIZE + 1 + EPILOGUE_SIZE)
102 /*
103 * Make sure userspace isn't trying to trick us into dumping kernel
104 * memory by pointing the userspace instruction pointer at it.
105 */
110 OPCODE_BUFSIZE)) {
116 }
117 }
120 {
121 #ifdef CONFIG_X86_32
123 #else
125 #endif
127 }
130 {
134 }
138 {
139 /*
140 * These on_stack() checks aren't strictly necessary: the unwind code
141 * has already validated the 'regs' pointer. The checks are done for
142 * ordering reasons: if the registers are on the next stack, we don't
143 * want to print them out yet. Otherwise they'll be shown as part of
144 * the wrong stack. Later, when show_trace_log_lvl() switches to the
145 * next stack, this function will be called again with the same regs so
146 * they can be printed in the right context.
147 */
152 IRET_FRAME_SIZE)) {
153 /*
154 * When an interrupt or exception occurs in entry code, the
155 * full pt_regs might not have been saved yet. In that case
156 * just print the iret frame.
157 */
159 }
160 }
164 {
177 /*
178 * Iterate through the stacks, starting with the current stack pointer.
179 * Each stack has a pointer to the next one.
180 *
181 * x86-64 can have several stacks:
182 * - task stack
183 * - interrupt stack
184 * - HW exception stacks (double fault, nmi, debug, mce)
185 * - entry stack
186 *
187 * x86-32 can have up to four stacks:
188 * - task stack
189 * - softirq stack
190 * - hardirq stack
191 * - entry stack
192 */
197 /*
198 * We weren't on a valid stack. It's possible that
199 * we overflowed a valid stack into a guard page.
200 * See if the next page up is valid so that we can
201 * generate some kind of backtrace if this happens.
202 */
206 }
215 /*
216 * Scan the stack, printing any text addresses we find. At the
217 * same time, follow proper stack frames with the unwinder.
218 *
219 * Addresses found during the scan which are not reported by
220 * the unwinder are considered to be additional clues which are
221 * sometimes useful for debugging and are prefixed with '?'.
222 * This also serves as a failsafe option in case the unwinder
223 * goes off in the weeds.
224 */
235 /*
236 * Don't print regs->ip again if it was already printed
237 * by show_regs_if_on_stack().
238 */
245 /*
246 * When function graph tracing is enabled for a
247 * function, its return address on the stack is
248 * replaced with the address of an ftrace handler
249 * (return_to_handler). In that case, before printing
250 * the "real" address, we want to print the handler
251 * address as an "unreliable" hint that function graph
252 * tracing was involved.
253 */
263 next:
264 /*
265 * Get the next frame from the unwinder. No need to
266 * check for an error: if anything goes wrong, the rest
267 * of the addresses will just be printed as unreliable.
268 */
271 /* if the frame has entry regs, print them */
275 }
279 }
280 }
283 {
286 /*
287 * Stack frames below this one aren't interesting. Don't show them
288 * if we're printing for %current.
289 */
294 }
297 {
299 }
306 {
312 /* racy, but better than risking deadlock. */
318 else
320 }
321 die_nest_count++;
326 }
332 {
339 die_nest_count--;
341 /* Nest count reaches zero, release the lock. */
346 /* Executive summary in case the oops scrolled away */
356 /*
357 * We're not going to return, but we might be on an IST stack or
358 * have very little stack space left. Rewind the stack and kill
359 * the task.
360 * Before we rewind the stack, we have to tell KASAN that we're going to
361 * reuse the task stack and that existing poisons are invalid.
362 */
365 }
369 {
370 /* Save the regs of the first oops for the executive summary later. */
391 }
394 /*
395 * This is gone through when something in the kernel has done something bad
396 * and is about to be terminated:
397 */
399 {
406 }
409 {
414 /*
415 * When in-kernel, we also print out the stack at the time of the fault..
416 */
419 }