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[linux/fpc-iii.git] / tools / testing / selftests / x86 / sigreturn.c
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1 // SPDX-License-Identifier: GPL-2.0-only
2 /*
3 * sigreturn.c - tests for x86 sigreturn(2) and exit-to-userspace
4 * Copyright (c) 2014-2015 Andrew Lutomirski
6 * This is a series of tests that exercises the sigreturn(2) syscall and
7 * the IRET / SYSRET paths in the kernel.
9 * For now, this focuses on the effects of unusual CS and SS values,
10 * and it has a bunch of tests to make sure that ESP/RSP is restored
11 * properly.
13 * The basic idea behind these tests is to raise(SIGUSR1) to create a
14 * sigcontext frame, plug in the values to be tested, and then return,
15 * which implicitly invokes sigreturn(2) and programs the user context
16 * as desired.
18 * For tests for which we expect sigreturn and the subsequent return to
19 * user mode to succeed, we return to a short trampoline that generates
20 * SIGTRAP so that the meat of the tests can be ordinary C code in a
21 * SIGTRAP handler.
23 * The inner workings of each test is documented below.
25 * Do not run on outdated, unpatched kernels at risk of nasty crashes.
28 #define _GNU_SOURCE
30 #include <sys/time.h>
31 #include <time.h>
32 #include <stdlib.h>
33 #include <sys/syscall.h>
34 #include <unistd.h>
35 #include <stdio.h>
36 #include <string.h>
37 #include <inttypes.h>
38 #include <sys/mman.h>
39 #include <sys/signal.h>
40 #include <sys/ucontext.h>
41 #include <asm/ldt.h>
42 #include <err.h>
43 #include <setjmp.h>
44 #include <stddef.h>
45 #include <stdbool.h>
46 #include <sys/ptrace.h>
47 #include <sys/user.h>
49 /* Pull in AR_xyz defines. */
50 typedef unsigned int u32;
51 typedef unsigned short u16;
52 #include "../../../../arch/x86/include/asm/desc_defs.h"
55 * Copied from asm/ucontext.h, as asm/ucontext.h conflicts badly with the glibc
56 * headers.
58 #ifdef __x86_64__
60 * UC_SIGCONTEXT_SS will be set when delivering 64-bit or x32 signals on
61 * kernels that save SS in the sigcontext. All kernels that set
62 * UC_SIGCONTEXT_SS will correctly restore at least the low 32 bits of esp
63 * regardless of SS (i.e. they implement espfix).
65 * Kernels that set UC_SIGCONTEXT_SS will also set UC_STRICT_RESTORE_SS
66 * when delivering a signal that came from 64-bit code.
68 * Sigreturn restores SS as follows:
70 * if (saved SS is valid || UC_STRICT_RESTORE_SS is set ||
71 * saved CS is not 64-bit)
72 * new SS = saved SS (will fail IRET and signal if invalid)
73 * else
74 * new SS = a flat 32-bit data segment
76 #define UC_SIGCONTEXT_SS 0x2
77 #define UC_STRICT_RESTORE_SS 0x4
78 #endif
81 * In principle, this test can run on Linux emulation layers (e.g.
82 * Illumos "LX branded zones"). Solaris-based kernels reserve LDT
83 * entries 0-5 for their own internal purposes, so start our LDT
84 * allocations above that reservation. (The tests don't pass on LX
85 * branded zones, but at least this lets them run.)
87 #define LDT_OFFSET 6
89 /* An aligned stack accessible through some of our segments. */
90 static unsigned char stack16[65536] __attribute__((aligned(4096)));
93 * An aligned int3 instruction used as a trampoline. Some of the tests
94 * want to fish out their ss values, so this trampoline copies ss to eax
95 * before the int3.
97 asm (".pushsection .text\n\t"
98 ".type int3, @function\n\t"
99 ".align 4096\n\t"
100 "int3:\n\t"
101 "mov %ss,%ecx\n\t"
102 "int3\n\t"
103 ".size int3, . - int3\n\t"
104 ".align 4096, 0xcc\n\t"
105 ".popsection");
106 extern char int3[4096];
109 * At startup, we prepapre:
111 * - ldt_nonexistent_sel: An LDT entry that doesn't exist (all-zero
112 * descriptor or out of bounds).
113 * - code16_sel: A 16-bit LDT code segment pointing to int3.
114 * - data16_sel: A 16-bit LDT data segment pointing to stack16.
115 * - npcode32_sel: A 32-bit not-present LDT code segment pointing to int3.
116 * - npdata32_sel: A 32-bit not-present LDT data segment pointing to stack16.
117 * - gdt_data16_idx: A 16-bit GDT data segment pointing to stack16.
118 * - gdt_npdata32_idx: A 32-bit not-present GDT data segment pointing to
119 * stack16.
121 * For no particularly good reason, xyz_sel is a selector value with the
122 * RPL and LDT bits filled in, whereas xyz_idx is just an index into the
123 * descriptor table. These variables will be zero if their respective
124 * segments could not be allocated.
126 static unsigned short ldt_nonexistent_sel;
127 static unsigned short code16_sel, data16_sel, npcode32_sel, npdata32_sel;
129 static unsigned short gdt_data16_idx, gdt_npdata32_idx;
131 static unsigned short GDT3(int idx)
133 return (idx << 3) | 3;
136 static unsigned short LDT3(int idx)
138 return (idx << 3) | 7;
141 /* Our sigaltstack scratch space. */
142 static char altstack_data[SIGSTKSZ];
144 static void sethandler(int sig, void (*handler)(int, siginfo_t *, void *),
145 int flags)
147 struct sigaction sa;
148 memset(&sa, 0, sizeof(sa));
149 sa.sa_sigaction = handler;
150 sa.sa_flags = SA_SIGINFO | flags;
151 sigemptyset(&sa.sa_mask);
152 if (sigaction(sig, &sa, 0))
153 err(1, "sigaction");
156 static void clearhandler(int sig)
158 struct sigaction sa;
159 memset(&sa, 0, sizeof(sa));
160 sa.sa_handler = SIG_DFL;
161 sigemptyset(&sa.sa_mask);
162 if (sigaction(sig, &sa, 0))
163 err(1, "sigaction");
166 static void add_ldt(const struct user_desc *desc, unsigned short *var,
167 const char *name)
169 if (syscall(SYS_modify_ldt, 1, desc, sizeof(*desc)) == 0) {
170 *var = LDT3(desc->entry_number);
171 } else {
172 printf("[NOTE]\tFailed to create %s segment\n", name);
173 *var = 0;
177 static void setup_ldt(void)
179 if ((unsigned long)stack16 > (1ULL << 32) - sizeof(stack16))
180 errx(1, "stack16 is too high\n");
181 if ((unsigned long)int3 > (1ULL << 32) - sizeof(int3))
182 errx(1, "int3 is too high\n");
184 ldt_nonexistent_sel = LDT3(LDT_OFFSET + 2);
186 const struct user_desc code16_desc = {
187 .entry_number = LDT_OFFSET + 0,
188 .base_addr = (unsigned long)int3,
189 .limit = 4095,
190 .seg_32bit = 0,
191 .contents = 2, /* Code, not conforming */
192 .read_exec_only = 0,
193 .limit_in_pages = 0,
194 .seg_not_present = 0,
195 .useable = 0
197 add_ldt(&code16_desc, &code16_sel, "code16");
199 const struct user_desc data16_desc = {
200 .entry_number = LDT_OFFSET + 1,
201 .base_addr = (unsigned long)stack16,
202 .limit = 0xffff,
203 .seg_32bit = 0,
204 .contents = 0, /* Data, grow-up */
205 .read_exec_only = 0,
206 .limit_in_pages = 0,
207 .seg_not_present = 0,
208 .useable = 0
210 add_ldt(&data16_desc, &data16_sel, "data16");
212 const struct user_desc npcode32_desc = {
213 .entry_number = LDT_OFFSET + 3,
214 .base_addr = (unsigned long)int3,
215 .limit = 4095,
216 .seg_32bit = 1,
217 .contents = 2, /* Code, not conforming */
218 .read_exec_only = 0,
219 .limit_in_pages = 0,
220 .seg_not_present = 1,
221 .useable = 0
223 add_ldt(&npcode32_desc, &npcode32_sel, "npcode32");
225 const struct user_desc npdata32_desc = {
226 .entry_number = LDT_OFFSET + 4,
227 .base_addr = (unsigned long)stack16,
228 .limit = 0xffff,
229 .seg_32bit = 1,
230 .contents = 0, /* Data, grow-up */
231 .read_exec_only = 0,
232 .limit_in_pages = 0,
233 .seg_not_present = 1,
234 .useable = 0
236 add_ldt(&npdata32_desc, &npdata32_sel, "npdata32");
238 struct user_desc gdt_data16_desc = {
239 .entry_number = -1,
240 .base_addr = (unsigned long)stack16,
241 .limit = 0xffff,
242 .seg_32bit = 0,
243 .contents = 0, /* Data, grow-up */
244 .read_exec_only = 0,
245 .limit_in_pages = 0,
246 .seg_not_present = 0,
247 .useable = 0
250 if (syscall(SYS_set_thread_area, &gdt_data16_desc) == 0) {
252 * This probably indicates vulnerability to CVE-2014-8133.
253 * Merely getting here isn't definitive, though, and we'll
254 * diagnose the problem for real later on.
256 printf("[WARN]\tset_thread_area allocated data16 at index %d\n",
257 gdt_data16_desc.entry_number);
258 gdt_data16_idx = gdt_data16_desc.entry_number;
259 } else {
260 printf("[OK]\tset_thread_area refused 16-bit data\n");
263 struct user_desc gdt_npdata32_desc = {
264 .entry_number = -1,
265 .base_addr = (unsigned long)stack16,
266 .limit = 0xffff,
267 .seg_32bit = 1,
268 .contents = 0, /* Data, grow-up */
269 .read_exec_only = 0,
270 .limit_in_pages = 0,
271 .seg_not_present = 1,
272 .useable = 0
275 if (syscall(SYS_set_thread_area, &gdt_npdata32_desc) == 0) {
277 * As a hardening measure, newer kernels don't allow this.
279 printf("[WARN]\tset_thread_area allocated npdata32 at index %d\n",
280 gdt_npdata32_desc.entry_number);
281 gdt_npdata32_idx = gdt_npdata32_desc.entry_number;
282 } else {
283 printf("[OK]\tset_thread_area refused 16-bit data\n");
287 /* State used by our signal handlers. */
288 static gregset_t initial_regs, requested_regs, resulting_regs;
290 /* Instructions for the SIGUSR1 handler. */
291 static volatile unsigned short sig_cs, sig_ss;
292 static volatile sig_atomic_t sig_trapped, sig_err, sig_trapno;
293 #ifdef __x86_64__
294 static volatile sig_atomic_t sig_corrupt_final_ss;
295 #endif
297 /* Abstractions for some 32-bit vs 64-bit differences. */
298 #ifdef __x86_64__
299 # define REG_IP REG_RIP
300 # define REG_SP REG_RSP
301 # define REG_CX REG_RCX
303 struct selectors {
304 unsigned short cs, gs, fs, ss;
307 static unsigned short *ssptr(ucontext_t *ctx)
309 struct selectors *sels = (void *)&ctx->uc_mcontext.gregs[REG_CSGSFS];
310 return &sels->ss;
313 static unsigned short *csptr(ucontext_t *ctx)
315 struct selectors *sels = (void *)&ctx->uc_mcontext.gregs[REG_CSGSFS];
316 return &sels->cs;
318 #else
319 # define REG_IP REG_EIP
320 # define REG_SP REG_ESP
321 # define REG_CX REG_ECX
323 static greg_t *ssptr(ucontext_t *ctx)
325 return &ctx->uc_mcontext.gregs[REG_SS];
328 static greg_t *csptr(ucontext_t *ctx)
330 return &ctx->uc_mcontext.gregs[REG_CS];
332 #endif
335 * Checks a given selector for its code bitness or returns -1 if it's not
336 * a usable code segment selector.
338 int cs_bitness(unsigned short cs)
340 uint32_t valid = 0, ar;
341 asm ("lar %[cs], %[ar]\n\t"
342 "jnz 1f\n\t"
343 "mov $1, %[valid]\n\t"
344 "1:"
345 : [ar] "=r" (ar), [valid] "+rm" (valid)
346 : [cs] "r" (cs));
348 if (!valid)
349 return -1;
351 bool db = (ar & (1 << 22));
352 bool l = (ar & (1 << 21));
354 if (!(ar & (1<<11)))
355 return -1; /* Not code. */
357 if (l && !db)
358 return 64;
359 else if (!l && db)
360 return 32;
361 else if (!l && !db)
362 return 16;
363 else
364 return -1; /* Unknown bitness. */
368 * Checks a given selector for its code bitness or returns -1 if it's not
369 * a usable code segment selector.
371 bool is_valid_ss(unsigned short cs)
373 uint32_t valid = 0, ar;
374 asm ("lar %[cs], %[ar]\n\t"
375 "jnz 1f\n\t"
376 "mov $1, %[valid]\n\t"
377 "1:"
378 : [ar] "=r" (ar), [valid] "+rm" (valid)
379 : [cs] "r" (cs));
381 if (!valid)
382 return false;
384 if ((ar & AR_TYPE_MASK) != AR_TYPE_RWDATA &&
385 (ar & AR_TYPE_MASK) != AR_TYPE_RWDATA_EXPDOWN)
386 return false;
388 return (ar & AR_P);
391 /* Number of errors in the current test case. */
392 static volatile sig_atomic_t nerrs;
394 static void validate_signal_ss(int sig, ucontext_t *ctx)
396 #ifdef __x86_64__
397 bool was_64bit = (cs_bitness(*csptr(ctx)) == 64);
399 if (!(ctx->uc_flags & UC_SIGCONTEXT_SS)) {
400 printf("[FAIL]\tUC_SIGCONTEXT_SS was not set\n");
401 nerrs++;
404 * This happens on Linux 4.1. The rest will fail, too, so
405 * return now to reduce the noise.
407 return;
410 /* UC_STRICT_RESTORE_SS is set iff we came from 64-bit mode. */
411 if (!!(ctx->uc_flags & UC_STRICT_RESTORE_SS) != was_64bit) {
412 printf("[FAIL]\tUC_STRICT_RESTORE_SS was wrong in signal %d\n",
413 sig);
414 nerrs++;
417 if (is_valid_ss(*ssptr(ctx))) {
419 * DOSEMU was written before 64-bit sigcontext had SS, and
420 * it tries to figure out the signal source SS by looking at
421 * the physical register. Make sure that keeps working.
423 unsigned short hw_ss;
424 asm ("mov %%ss, %0" : "=rm" (hw_ss));
425 if (hw_ss != *ssptr(ctx)) {
426 printf("[FAIL]\tHW SS didn't match saved SS\n");
427 nerrs++;
430 #endif
434 * SIGUSR1 handler. Sets CS and SS as requested and points IP to the
435 * int3 trampoline. Sets SP to a large known value so that we can see
436 * whether the value round-trips back to user mode correctly.
438 static void sigusr1(int sig, siginfo_t *info, void *ctx_void)
440 ucontext_t *ctx = (ucontext_t*)ctx_void;
442 validate_signal_ss(sig, ctx);
444 memcpy(&initial_regs, &ctx->uc_mcontext.gregs, sizeof(gregset_t));
446 *csptr(ctx) = sig_cs;
447 *ssptr(ctx) = sig_ss;
449 ctx->uc_mcontext.gregs[REG_IP] =
450 sig_cs == code16_sel ? 0 : (unsigned long)&int3;
451 ctx->uc_mcontext.gregs[REG_SP] = (unsigned long)0x8badf00d5aadc0deULL;
452 ctx->uc_mcontext.gregs[REG_CX] = 0;
454 #ifdef __i386__
456 * Make sure the kernel doesn't inadvertently use DS or ES-relative
457 * accesses in a region where user DS or ES is loaded.
459 * Skip this for 64-bit builds because long mode doesn't care about
460 * DS and ES and skipping it increases test coverage a little bit,
461 * since 64-bit kernels can still run the 32-bit build.
463 ctx->uc_mcontext.gregs[REG_DS] = 0;
464 ctx->uc_mcontext.gregs[REG_ES] = 0;
465 #endif
467 memcpy(&requested_regs, &ctx->uc_mcontext.gregs, sizeof(gregset_t));
468 requested_regs[REG_CX] = *ssptr(ctx); /* The asm code does this. */
470 return;
474 * Called after a successful sigreturn (via int3) or from a failed
475 * sigreturn (directly by kernel). Restores our state so that the
476 * original raise(SIGUSR1) returns.
478 static void sigtrap(int sig, siginfo_t *info, void *ctx_void)
480 ucontext_t *ctx = (ucontext_t*)ctx_void;
482 validate_signal_ss(sig, ctx);
484 sig_err = ctx->uc_mcontext.gregs[REG_ERR];
485 sig_trapno = ctx->uc_mcontext.gregs[REG_TRAPNO];
487 unsigned short ss;
488 asm ("mov %%ss,%0" : "=r" (ss));
490 greg_t asm_ss = ctx->uc_mcontext.gregs[REG_CX];
491 if (asm_ss != sig_ss && sig == SIGTRAP) {
492 /* Sanity check failure. */
493 printf("[FAIL]\tSIGTRAP: ss = %hx, frame ss = %hx, ax = %llx\n",
494 ss, *ssptr(ctx), (unsigned long long)asm_ss);
495 nerrs++;
498 memcpy(&resulting_regs, &ctx->uc_mcontext.gregs, sizeof(gregset_t));
499 memcpy(&ctx->uc_mcontext.gregs, &initial_regs, sizeof(gregset_t));
501 #ifdef __x86_64__
502 if (sig_corrupt_final_ss) {
503 if (ctx->uc_flags & UC_STRICT_RESTORE_SS) {
504 printf("[FAIL]\tUC_STRICT_RESTORE_SS was set inappropriately\n");
505 nerrs++;
506 } else {
508 * DOSEMU transitions from 32-bit to 64-bit mode by
509 * adjusting sigcontext, and it requires that this work
510 * even if the saved SS is bogus.
512 printf("\tCorrupting SS on return to 64-bit mode\n");
513 *ssptr(ctx) = 0;
516 #endif
518 sig_trapped = sig;
521 #ifdef __x86_64__
522 /* Tests recovery if !UC_STRICT_RESTORE_SS */
523 static void sigusr2(int sig, siginfo_t *info, void *ctx_void)
525 ucontext_t *ctx = (ucontext_t*)ctx_void;
527 if (!(ctx->uc_flags & UC_STRICT_RESTORE_SS)) {
528 printf("[FAIL]\traise(2) didn't set UC_STRICT_RESTORE_SS\n");
529 nerrs++;
530 return; /* We can't do the rest. */
533 ctx->uc_flags &= ~UC_STRICT_RESTORE_SS;
534 *ssptr(ctx) = 0;
536 /* Return. The kernel should recover without sending another signal. */
539 static int test_nonstrict_ss(void)
541 clearhandler(SIGUSR1);
542 clearhandler(SIGTRAP);
543 clearhandler(SIGSEGV);
544 clearhandler(SIGILL);
545 sethandler(SIGUSR2, sigusr2, 0);
547 nerrs = 0;
549 printf("[RUN]\tClear UC_STRICT_RESTORE_SS and corrupt SS\n");
550 raise(SIGUSR2);
551 if (!nerrs)
552 printf("[OK]\tIt worked\n");
554 return nerrs;
556 #endif
558 /* Finds a usable code segment of the requested bitness. */
559 int find_cs(int bitness)
561 unsigned short my_cs;
563 asm ("mov %%cs,%0" : "=r" (my_cs));
565 if (cs_bitness(my_cs) == bitness)
566 return my_cs;
567 if (cs_bitness(my_cs + (2 << 3)) == bitness)
568 return my_cs + (2 << 3);
569 if (my_cs > (2<<3) && cs_bitness(my_cs - (2 << 3)) == bitness)
570 return my_cs - (2 << 3);
571 if (cs_bitness(code16_sel) == bitness)
572 return code16_sel;
574 printf("[WARN]\tCould not find %d-bit CS\n", bitness);
575 return -1;
578 static int test_valid_sigreturn(int cs_bits, bool use_16bit_ss, int force_ss)
580 int cs = find_cs(cs_bits);
581 if (cs == -1) {
582 printf("[SKIP]\tCode segment unavailable for %d-bit CS, %d-bit SS\n",
583 cs_bits, use_16bit_ss ? 16 : 32);
584 return 0;
587 if (force_ss != -1) {
588 sig_ss = force_ss;
589 } else {
590 if (use_16bit_ss) {
591 if (!data16_sel) {
592 printf("[SKIP]\tData segment unavailable for %d-bit CS, 16-bit SS\n",
593 cs_bits);
594 return 0;
596 sig_ss = data16_sel;
597 } else {
598 asm volatile ("mov %%ss,%0" : "=r" (sig_ss));
602 sig_cs = cs;
604 printf("[RUN]\tValid sigreturn: %d-bit CS (%hx), %d-bit SS (%hx%s)\n",
605 cs_bits, sig_cs, use_16bit_ss ? 16 : 32, sig_ss,
606 (sig_ss & 4) ? "" : ", GDT");
608 raise(SIGUSR1);
610 nerrs = 0;
613 * Check that each register had an acceptable value when the
614 * int3 trampoline was invoked.
616 for (int i = 0; i < NGREG; i++) {
617 greg_t req = requested_regs[i], res = resulting_regs[i];
619 if (i == REG_TRAPNO || i == REG_IP)
620 continue; /* don't care */
622 if (i == REG_SP) {
624 * If we were using a 16-bit stack segment, then
625 * the kernel is a bit stuck: IRET only restores
626 * the low 16 bits of ESP/RSP if SS is 16-bit.
627 * The kernel uses a hack to restore bits 31:16,
628 * but that hack doesn't help with bits 63:32.
629 * On Intel CPUs, bits 63:32 end up zeroed, and, on
630 * AMD CPUs, they leak the high bits of the kernel
631 * espfix64 stack pointer. There's very little that
632 * the kernel can do about it.
634 * Similarly, if we are returning to a 32-bit context,
635 * the CPU will often lose the high 32 bits of RSP.
638 if (res == req)
639 continue;
641 if (cs_bits != 64 && ((res ^ req) & 0xFFFFFFFF) == 0) {
642 printf("[NOTE]\tSP: %llx -> %llx\n",
643 (unsigned long long)req,
644 (unsigned long long)res);
645 continue;
648 printf("[FAIL]\tSP mismatch: requested 0x%llx; got 0x%llx\n",
649 (unsigned long long)requested_regs[i],
650 (unsigned long long)resulting_regs[i]);
651 nerrs++;
652 continue;
655 bool ignore_reg = false;
656 #if __i386__
657 if (i == REG_UESP)
658 ignore_reg = true;
659 #else
660 if (i == REG_CSGSFS) {
661 struct selectors *req_sels =
662 (void *)&requested_regs[REG_CSGSFS];
663 struct selectors *res_sels =
664 (void *)&resulting_regs[REG_CSGSFS];
665 if (req_sels->cs != res_sels->cs) {
666 printf("[FAIL]\tCS mismatch: requested 0x%hx; got 0x%hx\n",
667 req_sels->cs, res_sels->cs);
668 nerrs++;
671 if (req_sels->ss != res_sels->ss) {
672 printf("[FAIL]\tSS mismatch: requested 0x%hx; got 0x%hx\n",
673 req_sels->ss, res_sels->ss);
674 nerrs++;
677 continue;
679 #endif
681 /* Sanity check on the kernel */
682 if (i == REG_CX && req != res) {
683 printf("[FAIL]\tCX (saved SP) mismatch: requested 0x%llx; got 0x%llx\n",
684 (unsigned long long)req,
685 (unsigned long long)res);
686 nerrs++;
687 continue;
690 if (req != res && !ignore_reg) {
691 printf("[FAIL]\tReg %d mismatch: requested 0x%llx; got 0x%llx\n",
692 i, (unsigned long long)req,
693 (unsigned long long)res);
694 nerrs++;
698 if (nerrs == 0)
699 printf("[OK]\tall registers okay\n");
701 return nerrs;
704 static int test_bad_iret(int cs_bits, unsigned short ss, int force_cs)
706 int cs = force_cs == -1 ? find_cs(cs_bits) : force_cs;
707 if (cs == -1)
708 return 0;
710 sig_cs = cs;
711 sig_ss = ss;
713 printf("[RUN]\t%d-bit CS (%hx), bogus SS (%hx)\n",
714 cs_bits, sig_cs, sig_ss);
716 sig_trapped = 0;
717 raise(SIGUSR1);
718 if (sig_trapped) {
719 char errdesc[32] = "";
720 if (sig_err) {
721 const char *src = (sig_err & 1) ? " EXT" : "";
722 const char *table;
723 if ((sig_err & 0x6) == 0x0)
724 table = "GDT";
725 else if ((sig_err & 0x6) == 0x4)
726 table = "LDT";
727 else if ((sig_err & 0x6) == 0x2)
728 table = "IDT";
729 else
730 table = "???";
732 sprintf(errdesc, "%s%s index %d, ",
733 table, src, sig_err >> 3);
736 char trapname[32];
737 if (sig_trapno == 13)
738 strcpy(trapname, "GP");
739 else if (sig_trapno == 11)
740 strcpy(trapname, "NP");
741 else if (sig_trapno == 12)
742 strcpy(trapname, "SS");
743 else if (sig_trapno == 32)
744 strcpy(trapname, "IRET"); /* X86_TRAP_IRET */
745 else
746 sprintf(trapname, "%d", sig_trapno);
748 printf("[OK]\tGot #%s(0x%lx) (i.e. %s%s)\n",
749 trapname, (unsigned long)sig_err,
750 errdesc, strsignal(sig_trapped));
751 return 0;
752 } else {
754 * This also implicitly tests UC_STRICT_RESTORE_SS:
755 * We check that these signals set UC_STRICT_RESTORE_SS and,
756 * if UC_STRICT_RESTORE_SS doesn't cause strict behavior,
757 * then we won't get SIGSEGV.
759 printf("[FAIL]\tDid not get SIGSEGV\n");
760 return 1;
764 int main()
766 int total_nerrs = 0;
767 unsigned short my_cs, my_ss;
769 asm volatile ("mov %%cs,%0" : "=r" (my_cs));
770 asm volatile ("mov %%ss,%0" : "=r" (my_ss));
771 setup_ldt();
773 stack_t stack = {
774 .ss_sp = altstack_data,
775 .ss_size = SIGSTKSZ,
777 if (sigaltstack(&stack, NULL) != 0)
778 err(1, "sigaltstack");
780 sethandler(SIGUSR1, sigusr1, 0);
781 sethandler(SIGTRAP, sigtrap, SA_ONSTACK);
783 /* Easy cases: return to a 32-bit SS in each possible CS bitness. */
784 total_nerrs += test_valid_sigreturn(64, false, -1);
785 total_nerrs += test_valid_sigreturn(32, false, -1);
786 total_nerrs += test_valid_sigreturn(16, false, -1);
789 * Test easy espfix cases: return to a 16-bit LDT SS in each possible
790 * CS bitness. NB: with a long mode CS, the SS bitness is irrelevant.
792 * This catches the original missing-espfix-on-64-bit-kernels issue
793 * as well as CVE-2014-8134.
795 total_nerrs += test_valid_sigreturn(64, true, -1);
796 total_nerrs += test_valid_sigreturn(32, true, -1);
797 total_nerrs += test_valid_sigreturn(16, true, -1);
799 if (gdt_data16_idx) {
801 * For performance reasons, Linux skips espfix if SS points
802 * to the GDT. If we were able to allocate a 16-bit SS in
803 * the GDT, see if it leaks parts of the kernel stack pointer.
805 * This tests for CVE-2014-8133.
807 total_nerrs += test_valid_sigreturn(64, true,
808 GDT3(gdt_data16_idx));
809 total_nerrs += test_valid_sigreturn(32, true,
810 GDT3(gdt_data16_idx));
811 total_nerrs += test_valid_sigreturn(16, true,
812 GDT3(gdt_data16_idx));
815 #ifdef __x86_64__
816 /* Nasty ABI case: check SS corruption handling. */
817 sig_corrupt_final_ss = 1;
818 total_nerrs += test_valid_sigreturn(32, false, -1);
819 total_nerrs += test_valid_sigreturn(32, true, -1);
820 sig_corrupt_final_ss = 0;
821 #endif
824 * We're done testing valid sigreturn cases. Now we test states
825 * for which sigreturn itself will succeed but the subsequent
826 * entry to user mode will fail.
828 * Depending on the failure mode and the kernel bitness, these
829 * entry failures can generate SIGSEGV, SIGBUS, or SIGILL.
831 clearhandler(SIGTRAP);
832 sethandler(SIGSEGV, sigtrap, SA_ONSTACK);
833 sethandler(SIGBUS, sigtrap, SA_ONSTACK);
834 sethandler(SIGILL, sigtrap, SA_ONSTACK); /* 32-bit kernels do this */
836 /* Easy failures: invalid SS, resulting in #GP(0) */
837 test_bad_iret(64, ldt_nonexistent_sel, -1);
838 test_bad_iret(32, ldt_nonexistent_sel, -1);
839 test_bad_iret(16, ldt_nonexistent_sel, -1);
841 /* These fail because SS isn't a data segment, resulting in #GP(SS) */
842 test_bad_iret(64, my_cs, -1);
843 test_bad_iret(32, my_cs, -1);
844 test_bad_iret(16, my_cs, -1);
846 /* Try to return to a not-present code segment, triggering #NP(SS). */
847 test_bad_iret(32, my_ss, npcode32_sel);
850 * Try to return to a not-present but otherwise valid data segment.
851 * This will cause IRET to fail with #SS on the espfix stack. This
852 * exercises CVE-2014-9322.
854 * Note that, if espfix is enabled, 64-bit Linux will lose track
855 * of the actual cause of failure and report #GP(0) instead.
856 * This would be very difficult for Linux to avoid, because
857 * espfix64 causes IRET failures to be promoted to #DF, so the
858 * original exception frame is never pushed onto the stack.
860 test_bad_iret(32, npdata32_sel, -1);
863 * Try to return to a not-present but otherwise valid data
864 * segment without invoking espfix. Newer kernels don't allow
865 * this to happen in the first place. On older kernels, though,
866 * this can trigger CVE-2014-9322.
868 if (gdt_npdata32_idx)
869 test_bad_iret(32, GDT3(gdt_npdata32_idx), -1);
871 #ifdef __x86_64__
872 total_nerrs += test_nonstrict_ss();
873 #endif
875 return total_nerrs ? 1 : 0;