tjh.dev / kernel
Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
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kernel / tools / testing / selftests / x86 / mpx-mini-test.c
at v4.16-rc5 1613 lines 40 kB view raw
1/* 2 * mpx-mini-test.c: routines to test Intel MPX (Memory Protection eXtentions) 3 * 4 * Written by: 5 * "Ren, Qiaowei" <qiaowei.ren@intel.com> 6 * "Wei, Gang" <gang.wei@intel.com> 7 * "Hansen, Dave" <dave.hansen@intel.com> 8 * 9 * This program is free software; you can redistribute it and/or modify it 10 * under the terms and conditions of the GNU General Public License, 11 * version 2. 12 */ 13 14/* 15 * 2014-12-05: Dave Hansen: fixed all of the compiler warnings, and made sure 16 * it works on 32-bit. 17 */ 18 19int inspect_every_this_many_mallocs = 100; 20int zap_all_every_this_many_mallocs = 1000; 21 22#define _GNU_SOURCE 23#define _LARGEFILE64_SOURCE 24 25#include <string.h> 26#include <stdio.h> 27#include <stdint.h> 28#include <stdbool.h> 29#include <signal.h> 30#include <assert.h> 31#include <stdlib.h> 32#include <ucontext.h> 33#include <sys/mman.h> 34#include <sys/types.h> 35#include <sys/stat.h> 36#include <fcntl.h> 37#include <unistd.h> 38 39#include "mpx-hw.h" 40#include "mpx-debug.h" 41#include "mpx-mm.h" 42 43#ifndef __always_inline 44#define __always_inline inline __attribute__((always_inline) 45#endif 46 47#ifndef TEST_DURATION_SECS 48#define TEST_DURATION_SECS 3 49#endif 50 51void write_int_to(char *prefix, char *file, int int_to_write) 52{ 53 char buf[100]; 54 int fd = open(file, O_RDWR); 55 int len; 56 int ret; 57 58 assert(fd >= 0); 59 len = snprintf(buf, sizeof(buf), "%s%d", prefix, int_to_write); 60 assert(len >= 0); 61 assert(len < sizeof(buf)); 62 ret = write(fd, buf, len); 63 assert(ret == len); 64 ret = close(fd); 65 assert(!ret); 66} 67 68void write_pid_to(char *prefix, char *file) 69{ 70 write_int_to(prefix, file, getpid()); 71} 72 73void trace_me(void) 74{ 75/* tracing events dir */ 76#define TED "/sys/kernel/debug/tracing/events/" 77/* 78 write_pid_to("common_pid=", TED "signal/filter"); 79 write_pid_to("common_pid=", TED "exceptions/filter"); 80 write_int_to("", TED "signal/enable", 1); 81 write_int_to("", TED "exceptions/enable", 1); 82*/ 83 write_pid_to("", "/sys/kernel/debug/tracing/set_ftrace_pid"); 84 write_int_to("", "/sys/kernel/debug/tracing/trace", 0); 85} 86 87#define test_failed() __test_failed(__FILE__, __LINE__) 88static void __test_failed(char *f, int l) 89{ 90 fprintf(stderr, "abort @ %s::%d\n", f, l); 91 abort(); 92} 93 94/* Error Printf */ 95#define eprintf(args...) fprintf(stderr, args) 96 97#ifdef __i386__ 98 99/* i386 directory size is 4MB */ 100#define REG_IP_IDX REG_EIP 101#define REX_PREFIX 102 103#define XSAVE_OFFSET_IN_FPMEM sizeof(struct _libc_fpstate) 104 105/* 106 * __cpuid() is from the Linux Kernel: 107 */ 108static inline void __cpuid(unsigned int *eax, unsigned int *ebx, 109 unsigned int *ecx, unsigned int *edx) 110{ 111 /* ecx is often an input as well as an output. */ 112 asm volatile( 113 "push %%ebx;" 114 "cpuid;" 115 "mov %%ebx, %1;" 116 "pop %%ebx" 117 : "=a" (*eax), 118 "=g" (*ebx), 119 "=c" (*ecx), 120 "=d" (*edx) 121 : "0" (*eax), "2" (*ecx)); 122} 123 124#else /* __i386__ */ 125 126#define REG_IP_IDX REG_RIP 127#define REX_PREFIX "0x48, " 128 129#define XSAVE_OFFSET_IN_FPMEM 0 130 131/* 132 * __cpuid() is from the Linux Kernel: 133 */ 134static inline void __cpuid(unsigned int *eax, unsigned int *ebx, 135 unsigned int *ecx, unsigned int *edx) 136{ 137 /* ecx is often an input as well as an output. */ 138 asm volatile( 139 "cpuid;" 140 : "=a" (*eax), 141 "=b" (*ebx), 142 "=c" (*ecx), 143 "=d" (*edx) 144 : "0" (*eax), "2" (*ecx)); 145} 146 147#endif /* !__i386__ */ 148 149struct xsave_hdr_struct { 150 uint64_t xstate_bv; 151 uint64_t reserved1[2]; 152 uint64_t reserved2[5]; 153} __attribute__((packed)); 154 155struct bndregs_struct { 156 uint64_t bndregs[8]; 157} __attribute__((packed)); 158 159struct bndcsr_struct { 160 uint64_t cfg_reg_u; 161 uint64_t status_reg; 162} __attribute__((packed)); 163 164struct xsave_struct { 165 uint8_t fpu_sse[512]; 166 struct xsave_hdr_struct xsave_hdr; 167 uint8_t ymm[256]; 168 uint8_t lwp[128]; 169 struct bndregs_struct bndregs; 170 struct bndcsr_struct bndcsr; 171} __attribute__((packed)); 172 173uint8_t __attribute__((__aligned__(64))) buffer[4096]; 174struct xsave_struct *xsave_buf = (struct xsave_struct *)buffer; 175 176uint8_t __attribute__((__aligned__(64))) test_buffer[4096]; 177struct xsave_struct *xsave_test_buf = (struct xsave_struct *)test_buffer; 178 179uint64_t num_bnd_chk; 180 181static __always_inline void xrstor_state(struct xsave_struct *fx, uint64_t mask) 182{ 183 uint32_t lmask = mask; 184 uint32_t hmask = mask >> 32; 185 186 asm volatile(".byte " REX_PREFIX "0x0f,0xae,0x2f\n\t" 187 : : "D" (fx), "m" (*fx), "a" (lmask), "d" (hmask) 188 : "memory"); 189} 190 191static __always_inline void xsave_state_1(void *_fx, uint64_t mask) 192{ 193 uint32_t lmask = mask; 194 uint32_t hmask = mask >> 32; 195 unsigned char *fx = _fx; 196 197 asm volatile(".byte " REX_PREFIX "0x0f,0xae,0x27\n\t" 198 : : "D" (fx), "m" (*fx), "a" (lmask), "d" (hmask) 199 : "memory"); 200} 201 202static inline uint64_t xgetbv(uint32_t index) 203{ 204 uint32_t eax, edx; 205 206 asm volatile(".byte 0x0f,0x01,0xd0" /* xgetbv */ 207 : "=a" (eax), "=d" (edx) 208 : "c" (index)); 209 return eax + ((uint64_t)edx << 32); 210} 211 212static uint64_t read_mpx_status_sig(ucontext_t *uctxt) 213{ 214 memset(buffer, 0, sizeof(buffer)); 215 memcpy(buffer, 216 (uint8_t *)uctxt->uc_mcontext.fpregs + XSAVE_OFFSET_IN_FPMEM, 217 sizeof(struct xsave_struct)); 218 219 return xsave_buf->bndcsr.status_reg; 220} 221 222#include <pthread.h> 223 224static uint8_t *get_next_inst_ip(uint8_t *addr) 225{ 226 uint8_t *ip = addr; 227 uint8_t sib; 228 uint8_t rm; 229 uint8_t mod; 230 uint8_t base; 231 uint8_t modrm; 232 233 /* determine the prefix. */ 234 switch(*ip) { 235 case 0xf2: 236 case 0xf3: 237 case 0x66: 238 ip++; 239 break; 240 } 241 242 /* look for rex prefix */ 243 if ((*ip & 0x40) == 0x40) 244 ip++; 245 246 /* Make sure we have a MPX instruction. */ 247 if (*ip++ != 0x0f) 248 return addr; 249 250 /* Skip the op code byte. */ 251 ip++; 252 253 /* Get the modrm byte. */ 254 modrm = *ip++; 255 256 /* Break it down into parts. */ 257 rm = modrm & 7; 258 mod = (modrm >> 6); 259 260 /* Init the parts of the address mode. */ 261 base = 8; 262 263 /* Is it a mem mode? */ 264 if (mod != 3) { 265 /* look for scaled indexed addressing */ 266 if (rm == 4) { 267 /* SIB addressing */ 268 sib = *ip++; 269 base = sib & 7; 270 switch (mod) { 271 case 0: 272 if (base == 5) 273 ip += 4; 274 break; 275 276 case 1: 277 ip++; 278 break; 279 280 case 2: 281 ip += 4; 282 break; 283 } 284 285 } else { 286 /* MODRM addressing */ 287 switch (mod) { 288 case 0: 289 /* DISP32 addressing, no base */ 290 if (rm == 5) 291 ip += 4; 292 break; 293 294 case 1: 295 ip++; 296 break; 297 298 case 2: 299 ip += 4; 300 break; 301 } 302 } 303 } 304 return ip; 305} 306 307#ifdef si_lower 308static inline void *__si_bounds_lower(siginfo_t *si) 309{ 310 return si->si_lower; 311} 312 313static inline void *__si_bounds_upper(siginfo_t *si) 314{ 315 return si->si_upper; 316} 317#else 318 319/* 320 * This deals with old version of _sigfault in some distros: 321 * 322 323old _sigfault: 324 struct { 325 void *si_addr; 326 } _sigfault; 327 328new _sigfault: 329 struct { 330 void __user *_addr; 331 int _trapno; 332 short _addr_lsb; 333 union { 334 struct { 335 void __user *_lower; 336 void __user *_upper; 337 } _addr_bnd; 338 __u32 _pkey; 339 }; 340 } _sigfault; 341 * 342 */ 343 344static inline void **__si_bounds_hack(siginfo_t *si) 345{ 346 void *sigfault = &si->_sifields._sigfault; 347 void *end_sigfault = sigfault + sizeof(si->_sifields._sigfault); 348 int *trapno = (int*)end_sigfault; 349 /* skip _trapno and _addr_lsb */ 350 void **__si_lower = (void**)(trapno + 2); 351 352 return __si_lower; 353} 354 355static inline void *__si_bounds_lower(siginfo_t *si) 356{ 357 return *__si_bounds_hack(si); 358} 359 360static inline void *__si_bounds_upper(siginfo_t *si) 361{ 362 return *(__si_bounds_hack(si) + 1); 363} 364#endif 365 366static int br_count; 367static int expected_bnd_index = -1; 368uint64_t shadow_plb[NR_MPX_BOUNDS_REGISTERS][2]; /* shadow MPX bound registers */ 369unsigned long shadow_map[NR_MPX_BOUNDS_REGISTERS]; 370 371/* 372 * The kernel is supposed to provide some information about the bounds 373 * exception in the siginfo. It should match what we have in the bounds 374 * registers that we are checking against. Just check against the shadow copy 375 * since it is easily available, and we also check that *it* matches the real 376 * registers. 377 */ 378void check_siginfo_vs_shadow(siginfo_t* si) 379{ 380 int siginfo_ok = 1; 381 void *shadow_lower = (void *)(unsigned long)shadow_plb[expected_bnd_index][0]; 382 void *shadow_upper = (void *)(unsigned long)shadow_plb[expected_bnd_index][1]; 383 384 if ((expected_bnd_index < 0) || 385 (expected_bnd_index >= NR_MPX_BOUNDS_REGISTERS)) { 386 fprintf(stderr, "ERROR: invalid expected_bnd_index: %d\n", 387 expected_bnd_index); 388 exit(6); 389 } 390 if (__si_bounds_lower(si) != shadow_lower) 391 siginfo_ok = 0; 392 if (__si_bounds_upper(si) != shadow_upper) 393 siginfo_ok = 0; 394 395 if (!siginfo_ok) { 396 fprintf(stderr, "ERROR: siginfo bounds do not match " 397 "shadow bounds for register %d\n", expected_bnd_index); 398 exit(7); 399 } 400} 401 402void handler(int signum, siginfo_t *si, void *vucontext) 403{ 404 int i; 405 ucontext_t *uctxt = vucontext; 406 int trapno; 407 unsigned long ip; 408 409 dprintf1("entered signal handler\n"); 410 411 trapno = uctxt->uc_mcontext.gregs[REG_TRAPNO]; 412 ip = uctxt->uc_mcontext.gregs[REG_IP_IDX]; 413 414 if (trapno == 5) { 415 typeof(si->si_addr) *si_addr_ptr = &si->si_addr; 416 uint64_t status = read_mpx_status_sig(uctxt); 417 uint64_t br_reason = status & 0x3; 418 419 br_count++; 420 dprintf1("#BR 0x%jx (total seen: %d)\n", status, br_count); 421 422#define SEGV_BNDERR 3 /* failed address bound checks */ 423 424 dprintf2("Saw a #BR! status 0x%jx at %016lx br_reason: %jx\n", 425 status, ip, br_reason); 426 dprintf2("si_signo: %d\n", si->si_signo); 427 dprintf2(" signum: %d\n", signum); 428 dprintf2("info->si_code == SEGV_BNDERR: %d\n", 429 (si->si_code == SEGV_BNDERR)); 430 dprintf2("info->si_code: %d\n", si->si_code); 431 dprintf2("info->si_lower: %p\n", __si_bounds_lower(si)); 432 dprintf2("info->si_upper: %p\n", __si_bounds_upper(si)); 433 434 for (i = 0; i < 8; i++) 435 dprintf3("[%d]: %p\n", i, si_addr_ptr[i]); 436 switch (br_reason) { 437 case 0: /* traditional BR */ 438 fprintf(stderr, 439 "Undefined status with bound exception:%jx\n", 440 status); 441 exit(5); 442 case 1: /* #BR MPX bounds exception */ 443 /* these are normal and we expect to see them */ 444 445 check_siginfo_vs_shadow(si); 446 447 dprintf1("bounds exception (normal): status 0x%jx at %p si_addr: %p\n", 448 status, (void *)ip, si->si_addr); 449 num_bnd_chk++; 450 uctxt->uc_mcontext.gregs[REG_IP_IDX] = 451 (greg_t)get_next_inst_ip((uint8_t *)ip); 452 break; 453 case 2: 454 fprintf(stderr, "#BR status == 2, missing bounds table," 455 "kernel should have handled!!\n"); 456 exit(4); 457 break; 458 default: 459 fprintf(stderr, "bound check error: status 0x%jx at %p\n", 460 status, (void *)ip); 461 num_bnd_chk++; 462 uctxt->uc_mcontext.gregs[REG_IP_IDX] = 463 (greg_t)get_next_inst_ip((uint8_t *)ip); 464 fprintf(stderr, "bound check error: si_addr %p\n", si->si_addr); 465 exit(3); 466 } 467 } else if (trapno == 14) { 468 eprintf("ERROR: In signal handler, page fault, trapno = %d, ip = %016lx\n", 469 trapno, ip); 470 eprintf("si_addr %p\n", si->si_addr); 471 eprintf("REG_ERR: %lx\n", (unsigned long)uctxt->uc_mcontext.gregs[REG_ERR]); 472 test_failed(); 473 } else { 474 eprintf("unexpected trap %d! at 0x%lx\n", trapno, ip); 475 eprintf("si_addr %p\n", si->si_addr); 476 eprintf("REG_ERR: %lx\n", (unsigned long)uctxt->uc_mcontext.gregs[REG_ERR]); 477 test_failed(); 478 } 479} 480 481static inline void cpuid_count(unsigned int op, int count, 482 unsigned int *eax, unsigned int *ebx, 483 unsigned int *ecx, unsigned int *edx) 484{ 485 *eax = op; 486 *ecx = count; 487 __cpuid(eax, ebx, ecx, edx); 488} 489 490#define XSTATE_CPUID 0x0000000d 491 492/* 493 * List of XSAVE features Linux knows about: 494 */ 495enum xfeature_bit { 496 XSTATE_BIT_FP, 497 XSTATE_BIT_SSE, 498 XSTATE_BIT_YMM, 499 XSTATE_BIT_BNDREGS, 500 XSTATE_BIT_BNDCSR, 501 XSTATE_BIT_OPMASK, 502 XSTATE_BIT_ZMM_Hi256, 503 XSTATE_BIT_Hi16_ZMM, 504 505 XFEATURES_NR_MAX, 506}; 507 508#define XSTATE_FP (1 << XSTATE_BIT_FP) 509#define XSTATE_SSE (1 << XSTATE_BIT_SSE) 510#define XSTATE_YMM (1 << XSTATE_BIT_YMM) 511#define XSTATE_BNDREGS (1 << XSTATE_BIT_BNDREGS) 512#define XSTATE_BNDCSR (1 << XSTATE_BIT_BNDCSR) 513#define XSTATE_OPMASK (1 << XSTATE_BIT_OPMASK) 514#define XSTATE_ZMM_Hi256 (1 << XSTATE_BIT_ZMM_Hi256) 515#define XSTATE_Hi16_ZMM (1 << XSTATE_BIT_Hi16_ZMM) 516 517#define MPX_XSTATES (XSTATE_BNDREGS | XSTATE_BNDCSR) /* 0x18 */ 518 519bool one_bit(unsigned int x, int bit) 520{ 521 return !!(x & (1<<bit)); 522} 523 524void print_state_component(int state_bit_nr, char *name) 525{ 526 unsigned int eax, ebx, ecx, edx; 527 unsigned int state_component_size; 528 unsigned int state_component_supervisor; 529 unsigned int state_component_user; 530 unsigned int state_component_aligned; 531 532 /* See SDM Section 13.2 */ 533 cpuid_count(XSTATE_CPUID, state_bit_nr, &eax, &ebx, &ecx, &edx); 534 assert(eax || ebx || ecx); 535 state_component_size = eax; 536 state_component_supervisor = ((!ebx) && one_bit(ecx, 0)); 537 state_component_user = !one_bit(ecx, 0); 538 state_component_aligned = one_bit(ecx, 1); 539 printf("%8s: size: %d user: %d supervisor: %d aligned: %d\n", 540 name, 541 state_component_size, state_component_user, 542 state_component_supervisor, state_component_aligned); 543 544} 545 546/* Intel-defined CPU features, CPUID level 0x00000001 (ecx) */ 547#define XSAVE_FEATURE_BIT (26) /* XSAVE/XRSTOR/XSETBV/XGETBV */ 548#define OSXSAVE_FEATURE_BIT (27) /* XSAVE enabled in the OS */ 549 550bool check_mpx_support(void) 551{ 552 unsigned int eax, ebx, ecx, edx; 553 554 cpuid_count(1, 0, &eax, &ebx, &ecx, &edx); 555 556 /* We can't do much without XSAVE, so just make these assert()'s */ 557 if (!one_bit(ecx, XSAVE_FEATURE_BIT)) { 558 fprintf(stderr, "processor lacks XSAVE, can not run MPX tests\n"); 559 exit(0); 560 } 561 562 if (!one_bit(ecx, OSXSAVE_FEATURE_BIT)) { 563 fprintf(stderr, "processor lacks OSXSAVE, can not run MPX tests\n"); 564 exit(0); 565 } 566 567 /* CPUs not supporting the XSTATE CPUID leaf do not support MPX */ 568 /* Is this redundant with the feature bit checks? */ 569 cpuid_count(0, 0, &eax, &ebx, &ecx, &edx); 570 if (eax < XSTATE_CPUID) { 571 fprintf(stderr, "processor lacks XSTATE CPUID leaf," 572 " can not run MPX tests\n"); 573 exit(0); 574 } 575 576 printf("XSAVE is supported by HW & OS\n"); 577 578 cpuid_count(XSTATE_CPUID, 0, &eax, &ebx, &ecx, &edx); 579 580 printf("XSAVE processor supported state mask: 0x%x\n", eax); 581 printf("XSAVE OS supported state mask: 0x%jx\n", xgetbv(0)); 582 583 /* Make sure that the MPX states are enabled in in XCR0 */ 584 if ((eax & MPX_XSTATES) != MPX_XSTATES) { 585 fprintf(stderr, "processor lacks MPX XSTATE(s), can not run MPX tests\n"); 586 exit(0); 587 } 588 589 /* Make sure the MPX states are supported by XSAVE* */ 590 if ((xgetbv(0) & MPX_XSTATES) != MPX_XSTATES) { 591 fprintf(stderr, "MPX XSTATE(s) no enabled in XCR0, " 592 "can not run MPX tests\n"); 593 exit(0); 594 } 595 596 print_state_component(XSTATE_BIT_BNDREGS, "BNDREGS"); 597 print_state_component(XSTATE_BIT_BNDCSR, "BNDCSR"); 598 599 return true; 600} 601 602void enable_mpx(void *l1base) 603{ 604 /* enable point lookup */ 605 memset(buffer, 0, sizeof(buffer)); 606 xrstor_state(xsave_buf, 0x18); 607 608 xsave_buf->xsave_hdr.xstate_bv = 0x10; 609 xsave_buf->bndcsr.cfg_reg_u = (unsigned long)l1base | 1; 610 xsave_buf->bndcsr.status_reg = 0; 611 612 dprintf2("bf xrstor\n"); 613 dprintf2("xsave cndcsr: status %jx, configu %jx\n", 614 xsave_buf->bndcsr.status_reg, xsave_buf->bndcsr.cfg_reg_u); 615 xrstor_state(xsave_buf, 0x18); 616 dprintf2("after xrstor\n"); 617 618 xsave_state_1(xsave_buf, 0x18); 619 620 dprintf1("xsave bndcsr: status %jx, configu %jx\n", 621 xsave_buf->bndcsr.status_reg, xsave_buf->bndcsr.cfg_reg_u); 622} 623 624#include <sys/prctl.h> 625 626struct mpx_bounds_dir *bounds_dir_ptr; 627 628unsigned long __bd_incore(const char *func, int line) 629{ 630 unsigned long ret = nr_incore(bounds_dir_ptr, MPX_BOUNDS_DIR_SIZE_BYTES); 631 return ret; 632} 633#define bd_incore() __bd_incore(__func__, __LINE__) 634 635void check_clear(void *ptr, unsigned long sz) 636{ 637 unsigned long *i; 638 639 for (i = ptr; (void *)i < ptr + sz; i++) { 640 if (*i) { 641 dprintf1("%p is NOT clear at %p\n", ptr, i); 642 assert(0); 643 } 644 } 645 dprintf1("%p is clear for %lx\n", ptr, sz); 646} 647 648void check_clear_bd(void) 649{ 650 check_clear(bounds_dir_ptr, 2UL << 30); 651} 652 653#define USE_MALLOC_FOR_BOUNDS_DIR 1 654bool process_specific_init(void) 655{ 656 unsigned long size; 657 unsigned long *dir; 658 /* Guarantee we have the space to align it, add padding: */ 659 unsigned long pad = getpagesize(); 660 661 size = 2UL << 30; /* 2GB */ 662 if (sizeof(unsigned long) == 4) 663 size = 4UL << 20; /* 4MB */ 664 dprintf1("trying to allocate %ld MB bounds directory\n", (size >> 20)); 665 666 if (USE_MALLOC_FOR_BOUNDS_DIR) { 667 unsigned long _dir; 668 669 dir = malloc(size + pad); 670 assert(dir); 671 _dir = (unsigned long)dir; 672 _dir += 0xfffUL; 673 _dir &= ~0xfffUL; 674 dir = (void *)_dir; 675 } else { 676 /* 677 * This makes debugging easier because the address 678 * calculations are simpler: 679 */ 680 dir = mmap((void *)0x200000000000, size + pad, 681 PROT_READ|PROT_WRITE, 682 MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 683 if (dir == (void *)-1) { 684 perror("unable to allocate bounds directory"); 685 abort(); 686 } 687 check_clear(dir, size); 688 } 689 bounds_dir_ptr = (void *)dir; 690 madvise(bounds_dir_ptr, size, MADV_NOHUGEPAGE); 691 bd_incore(); 692 dprintf1("bounds directory: 0x%p -> 0x%p\n", bounds_dir_ptr, 693 (char *)bounds_dir_ptr + size); 694 check_clear(dir, size); 695 enable_mpx(dir); 696 check_clear(dir, size); 697 if (prctl(43, 0, 0, 0, 0)) { 698 printf("no MPX support\n"); 699 abort(); 700 return false; 701 } 702 return true; 703} 704 705bool process_specific_finish(void) 706{ 707 if (prctl(44)) { 708 printf("no MPX support\n"); 709 return false; 710 } 711 return true; 712} 713 714void setup_handler() 715{ 716 int r, rs; 717 struct sigaction newact; 718 struct sigaction oldact; 719 720 /* #BR is mapped to sigsegv */ 721 int signum = SIGSEGV; 722 723 newact.sa_handler = 0; /* void(*)(int)*/ 724 newact.sa_sigaction = handler; /* void (*)(int, siginfo_t*, void *) */ 725 726 /*sigset_t - signals to block while in the handler */ 727 /* get the old signal mask. */ 728 rs = sigprocmask(SIG_SETMASK, 0, &newact.sa_mask); 729 assert(rs == 0); 730 731 /* call sa_sigaction, not sa_handler*/ 732 newact.sa_flags = SA_SIGINFO; 733 734 newact.sa_restorer = 0; /* void(*)(), obsolete */ 735 r = sigaction(signum, &newact, &oldact); 736 assert(r == 0); 737} 738 739void mpx_prepare(void) 740{ 741 dprintf2("%s()\n", __func__); 742 setup_handler(); 743 process_specific_init(); 744} 745 746void mpx_cleanup(void) 747{ 748 printf("%s(): %jd BRs. bye...\n", __func__, num_bnd_chk); 749 process_specific_finish(); 750} 751 752/*-------------- the following is test case ---------------*/ 753#include <stdint.h> 754#include <stdbool.h> 755#include <stdlib.h> 756#include <stdio.h> 757#include <time.h> 758 759uint64_t num_lower_brs; 760uint64_t num_upper_brs; 761 762#define MPX_CONFIG_OFFSET 1024 763#define MPX_BOUNDS_OFFSET 960 764#define MPX_HEADER_OFFSET 512 765#define MAX_ADDR_TESTED (1<<28) 766#define TEST_ROUNDS 100 767 768/* 769 0F 1A /r BNDLDX-Load 770 0F 1B /r BNDSTX-Store Extended Bounds Using Address Translation 771 66 0F 1A /r BNDMOV bnd1, bnd2/m128 772 66 0F 1B /r BNDMOV bnd1/m128, bnd2 773 F2 0F 1A /r BNDCU bnd, r/m64 774 F2 0F 1B /r BNDCN bnd, r/m64 775 F3 0F 1A /r BNDCL bnd, r/m64 776 F3 0F 1B /r BNDMK bnd, m64 777*/ 778 779static __always_inline void xsave_state(void *_fx, uint64_t mask) 780{ 781 uint32_t lmask = mask; 782 uint32_t hmask = mask >> 32; 783 unsigned char *fx = _fx; 784 785 asm volatile(".byte " REX_PREFIX "0x0f,0xae,0x27\n\t" 786 : : "D" (fx), "m" (*fx), "a" (lmask), "d" (hmask) 787 : "memory"); 788} 789 790static __always_inline void mpx_clear_bnd0(void) 791{ 792 long size = 0; 793 void *ptr = NULL; 794 /* F3 0F 1B /r BNDMK bnd, m64 */ 795 /* f3 0f 1b 04 11 bndmk (%rcx,%rdx,1),%bnd0 */ 796 asm volatile(".byte 0xf3,0x0f,0x1b,0x04,0x11\n\t" 797 : : "c" (ptr), "d" (size-1) 798 : "memory"); 799} 800 801static __always_inline void mpx_make_bound_helper(unsigned long ptr, 802 unsigned long size) 803{ 804 /* F3 0F 1B /r BNDMK bnd, m64 */ 805 /* f3 0f 1b 04 11 bndmk (%rcx,%rdx,1),%bnd0 */ 806 asm volatile(".byte 0xf3,0x0f,0x1b,0x04,0x11\n\t" 807 : : "c" (ptr), "d" (size-1) 808 : "memory"); 809} 810 811static __always_inline void mpx_check_lowerbound_helper(unsigned long ptr) 812{ 813 /* F3 0F 1A /r NDCL bnd, r/m64 */ 814 /* f3 0f 1a 01 bndcl (%rcx),%bnd0 */ 815 asm volatile(".byte 0xf3,0x0f,0x1a,0x01\n\t" 816 : : "c" (ptr) 817 : "memory"); 818} 819 820static __always_inline void mpx_check_upperbound_helper(unsigned long ptr) 821{ 822 /* F2 0F 1A /r BNDCU bnd, r/m64 */ 823 /* f2 0f 1a 01 bndcu (%rcx),%bnd0 */ 824 asm volatile(".byte 0xf2,0x0f,0x1a,0x01\n\t" 825 : : "c" (ptr) 826 : "memory"); 827} 828 829static __always_inline void mpx_movbndreg_helper() 830{ 831 /* 66 0F 1B /r BNDMOV bnd1/m128, bnd2 */ 832 /* 66 0f 1b c2 bndmov %bnd0,%bnd2 */ 833 834 asm volatile(".byte 0x66,0x0f,0x1b,0xc2\n\t"); 835} 836 837static __always_inline void mpx_movbnd2mem_helper(uint8_t *mem) 838{ 839 /* 66 0F 1B /r BNDMOV bnd1/m128, bnd2 */ 840 /* 66 0f 1b 01 bndmov %bnd0,(%rcx) */ 841 asm volatile(".byte 0x66,0x0f,0x1b,0x01\n\t" 842 : : "c" (mem) 843 : "memory"); 844} 845 846static __always_inline void mpx_movbnd_from_mem_helper(uint8_t *mem) 847{ 848 /* 66 0F 1A /r BNDMOV bnd1, bnd2/m128 */ 849 /* 66 0f 1a 01 bndmov (%rcx),%bnd0 */ 850 asm volatile(".byte 0x66,0x0f,0x1a,0x01\n\t" 851 : : "c" (mem) 852 : "memory"); 853} 854 855static __always_inline void mpx_store_dsc_helper(unsigned long ptr_addr, 856 unsigned long ptr_val) 857{ 858 /* 0F 1B /r BNDSTX-Store Extended Bounds Using Address Translation */ 859 /* 0f 1b 04 11 bndstx %bnd0,(%rcx,%rdx,1) */ 860 asm volatile(".byte 0x0f,0x1b,0x04,0x11\n\t" 861 : : "c" (ptr_addr), "d" (ptr_val) 862 : "memory"); 863} 864 865static __always_inline void mpx_load_dsc_helper(unsigned long ptr_addr, 866 unsigned long ptr_val) 867{ 868 /* 0F 1A /r BNDLDX-Load */ 869 /*/ 0f 1a 04 11 bndldx (%rcx,%rdx,1),%bnd0 */ 870 asm volatile(".byte 0x0f,0x1a,0x04,0x11\n\t" 871 : : "c" (ptr_addr), "d" (ptr_val) 872 : "memory"); 873} 874 875void __print_context(void *__print_xsave_buffer, int line) 876{ 877 uint64_t *bounds = (uint64_t *)(__print_xsave_buffer + MPX_BOUNDS_OFFSET); 878 uint64_t *cfg = (uint64_t *)(__print_xsave_buffer + MPX_CONFIG_OFFSET); 879 880 int i; 881 eprintf("%s()::%d\n", "print_context", line); 882 for (i = 0; i < 4; i++) { 883 eprintf("bound[%d]: 0x%016lx 0x%016lx(0x%016lx)\n", i, 884 (unsigned long)bounds[i*2], 885 ~(unsigned long)bounds[i*2+1], 886 (unsigned long)bounds[i*2+1]); 887 } 888 889 eprintf("cpcfg: %jx cpstatus: %jx\n", cfg[0], cfg[1]); 890} 891#define print_context(x) __print_context(x, __LINE__) 892#ifdef DEBUG 893#define dprint_context(x) print_context(x) 894#else 895#define dprint_context(x) do{}while(0) 896#endif 897 898void init() 899{ 900 int i; 901 902 srand((unsigned int)time(NULL)); 903 904 for (i = 0; i < 4; i++) { 905 shadow_plb[i][0] = 0; 906 shadow_plb[i][1] = ~(unsigned long)0; 907 } 908} 909 910long int __mpx_random(int line) 911{ 912#ifdef NOT_SO_RANDOM 913 static long fake = 722122311; 914 fake += 563792075; 915 return fakse; 916#else 917 return random(); 918#endif 919} 920#define mpx_random() __mpx_random(__LINE__) 921 922uint8_t *get_random_addr() 923{ 924 uint8_t*addr = (uint8_t *)(unsigned long)(rand() % MAX_ADDR_TESTED); 925 return (addr - (unsigned long)addr % sizeof(uint8_t *)); 926} 927 928static inline bool compare_context(void *__xsave_buffer) 929{ 930 uint64_t *bounds = (uint64_t *)(__xsave_buffer + MPX_BOUNDS_OFFSET); 931 932 int i; 933 for (i = 0; i < 4; i++) { 934 dprintf3("shadow[%d]{%016lx/%016lx}\nbounds[%d]{%016lx/%016lx}\n", 935 i, (unsigned long)shadow_plb[i][0], (unsigned long)shadow_plb[i][1], 936 i, (unsigned long)bounds[i*2], ~(unsigned long)bounds[i*2+1]); 937 if ((shadow_plb[i][0] != bounds[i*2]) || 938 (shadow_plb[i][1] != ~(unsigned long)bounds[i*2+1])) { 939 eprintf("ERROR comparing shadow to real bound register %d\n", i); 940 eprintf("shadow{0x%016lx/0x%016lx}\nbounds{0x%016lx/0x%016lx}\n", 941 (unsigned long)shadow_plb[i][0], (unsigned long)shadow_plb[i][1], 942 (unsigned long)bounds[i*2], (unsigned long)bounds[i*2+1]); 943 return false; 944 } 945 } 946 947 return true; 948} 949 950void mkbnd_shadow(uint8_t *ptr, int index, long offset) 951{ 952 uint64_t *lower = (uint64_t *)&(shadow_plb[index][0]); 953 uint64_t *upper = (uint64_t *)&(shadow_plb[index][1]); 954 *lower = (unsigned long)ptr; 955 *upper = (unsigned long)ptr + offset - 1; 956} 957 958void check_lowerbound_shadow(uint8_t *ptr, int index) 959{ 960 uint64_t *lower = (uint64_t *)&(shadow_plb[index][0]); 961 if (*lower > (uint64_t)(unsigned long)ptr) 962 num_lower_brs++; 963 else 964 dprintf1("LowerBoundChk passed:%p\n", ptr); 965} 966 967void check_upperbound_shadow(uint8_t *ptr, int index) 968{ 969 uint64_t upper = *(uint64_t *)&(shadow_plb[index][1]); 970 if (upper < (uint64_t)(unsigned long)ptr) 971 num_upper_brs++; 972 else 973 dprintf1("UpperBoundChk passed:%p\n", ptr); 974} 975 976__always_inline void movbndreg_shadow(int src, int dest) 977{ 978 shadow_plb[dest][0] = shadow_plb[src][0]; 979 shadow_plb[dest][1] = shadow_plb[src][1]; 980} 981 982__always_inline void movbnd2mem_shadow(int src, unsigned long *dest) 983{ 984 unsigned long *lower = (unsigned long *)&(shadow_plb[src][0]); 985 unsigned long *upper = (unsigned long *)&(shadow_plb[src][1]); 986 *dest = *lower; 987 *(dest+1) = *upper; 988} 989 990__always_inline void movbnd_from_mem_shadow(unsigned long *src, int dest) 991{ 992 unsigned long *lower = (unsigned long *)&(shadow_plb[dest][0]); 993 unsigned long *upper = (unsigned long *)&(shadow_plb[dest][1]); 994 *lower = *src; 995 *upper = *(src+1); 996} 997 998__always_inline void stdsc_shadow(int index, uint8_t *ptr, uint8_t *ptr_val) 999{ 1000 shadow_map[0] = (unsigned long)shadow_plb[index][0]; 1001 shadow_map[1] = (unsigned long)shadow_plb[index][1]; 1002 shadow_map[2] = (unsigned long)ptr_val; 1003 dprintf3("%s(%d, %p, %p) set shadow map[2]: %p\n", __func__, 1004 index, ptr, ptr_val, ptr_val); 1005 /*ptr ignored */ 1006} 1007 1008void lddsc_shadow(int index, uint8_t *ptr, uint8_t *ptr_val) 1009{ 1010 uint64_t lower = shadow_map[0]; 1011 uint64_t upper = shadow_map[1]; 1012 uint8_t *value = (uint8_t *)shadow_map[2]; 1013 1014 if (value != ptr_val) { 1015 dprintf2("%s(%d, %p, %p) init shadow bounds[%d] " 1016 "because %p != %p\n", __func__, index, ptr, 1017 ptr_val, index, value, ptr_val); 1018 shadow_plb[index][0] = 0; 1019 shadow_plb[index][1] = ~(unsigned long)0; 1020 } else { 1021 shadow_plb[index][0] = lower; 1022 shadow_plb[index][1] = upper; 1023 } 1024 /* ptr ignored */ 1025} 1026 1027static __always_inline void mpx_test_helper0(uint8_t *buf, uint8_t *ptr) 1028{ 1029 mpx_make_bound_helper((unsigned long)ptr, 0x1800); 1030} 1031 1032static __always_inline void mpx_test_helper0_shadow(uint8_t *buf, uint8_t *ptr) 1033{ 1034 mkbnd_shadow(ptr, 0, 0x1800); 1035} 1036 1037static __always_inline void mpx_test_helper1(uint8_t *buf, uint8_t *ptr) 1038{ 1039 /* these are hard-coded to check bnd0 */ 1040 expected_bnd_index = 0; 1041 mpx_check_lowerbound_helper((unsigned long)(ptr-1)); 1042 mpx_check_upperbound_helper((unsigned long)(ptr+0x1800)); 1043 /* reset this since we do not expect any more bounds exceptions */ 1044 expected_bnd_index = -1; 1045} 1046 1047static __always_inline void mpx_test_helper1_shadow(uint8_t *buf, uint8_t *ptr) 1048{ 1049 check_lowerbound_shadow(ptr-1, 0); 1050 check_upperbound_shadow(ptr+0x1800, 0); 1051} 1052 1053static __always_inline void mpx_test_helper2(uint8_t *buf, uint8_t *ptr) 1054{ 1055 mpx_make_bound_helper((unsigned long)ptr, 0x1800); 1056 mpx_movbndreg_helper(); 1057 mpx_movbnd2mem_helper(buf); 1058 mpx_make_bound_helper((unsigned long)(ptr+0x12), 0x1800); 1059} 1060 1061static __always_inline void mpx_test_helper2_shadow(uint8_t *buf, uint8_t *ptr) 1062{ 1063 mkbnd_shadow(ptr, 0, 0x1800); 1064 movbndreg_shadow(0, 2); 1065 movbnd2mem_shadow(0, (unsigned long *)buf); 1066 mkbnd_shadow(ptr+0x12, 0, 0x1800); 1067} 1068 1069static __always_inline void mpx_test_helper3(uint8_t *buf, uint8_t *ptr) 1070{ 1071 mpx_movbnd_from_mem_helper(buf); 1072} 1073 1074static __always_inline void mpx_test_helper3_shadow(uint8_t *buf, uint8_t *ptr) 1075{ 1076 movbnd_from_mem_shadow((unsigned long *)buf, 0); 1077} 1078 1079static __always_inline void mpx_test_helper4(uint8_t *buf, uint8_t *ptr) 1080{ 1081 mpx_store_dsc_helper((unsigned long)buf, (unsigned long)ptr); 1082 mpx_make_bound_helper((unsigned long)(ptr+0x12), 0x1800); 1083} 1084 1085static __always_inline void mpx_test_helper4_shadow(uint8_t *buf, uint8_t *ptr) 1086{ 1087 stdsc_shadow(0, buf, ptr); 1088 mkbnd_shadow(ptr+0x12, 0, 0x1800); 1089} 1090 1091static __always_inline void mpx_test_helper5(uint8_t *buf, uint8_t *ptr) 1092{ 1093 mpx_load_dsc_helper((unsigned long)buf, (unsigned long)ptr); 1094} 1095 1096static __always_inline void mpx_test_helper5_shadow(uint8_t *buf, uint8_t *ptr) 1097{ 1098 lddsc_shadow(0, buf, ptr); 1099} 1100 1101#define NR_MPX_TEST_FUNCTIONS 6 1102 1103/* 1104 * For compatibility reasons, MPX will clear the bounds registers 1105 * when you make function calls (among other things). We have to 1106 * preserve the registers in between calls to the "helpers" since 1107 * they build on each other. 1108 * 1109 * Be very careful not to make any function calls inside the 1110 * helpers, or anywhere else beween the xrstor and xsave. 1111 */ 1112#define run_helper(helper_nr, buf, buf_shadow, ptr) do { \ 1113 xrstor_state(xsave_test_buf, flags); \ 1114 mpx_test_helper##helper_nr(buf, ptr); \ 1115 xsave_state(xsave_test_buf, flags); \ 1116 mpx_test_helper##helper_nr##_shadow(buf_shadow, ptr); \ 1117} while (0) 1118 1119static void run_helpers(int nr, uint8_t *buf, uint8_t *buf_shadow, uint8_t *ptr) 1120{ 1121 uint64_t flags = 0x18; 1122 1123 dprint_context(xsave_test_buf); 1124 switch (nr) { 1125 case 0: 1126 run_helper(0, buf, buf_shadow, ptr); 1127 break; 1128 case 1: 1129 run_helper(1, buf, buf_shadow, ptr); 1130 break; 1131 case 2: 1132 run_helper(2, buf, buf_shadow, ptr); 1133 break; 1134 case 3: 1135 run_helper(3, buf, buf_shadow, ptr); 1136 break; 1137 case 4: 1138 run_helper(4, buf, buf_shadow, ptr); 1139 break; 1140 case 5: 1141 run_helper(5, buf, buf_shadow, ptr); 1142 break; 1143 default: 1144 test_failed(); 1145 break; 1146 } 1147 dprint_context(xsave_test_buf); 1148} 1149 1150unsigned long buf_shadow[1024]; /* used to check load / store descriptors */ 1151extern long inspect_me(struct mpx_bounds_dir *bounds_dir); 1152 1153long cover_buf_with_bt_entries(void *buf, long buf_len) 1154{ 1155 int i; 1156 long nr_to_fill; 1157 int ratio = 1000; 1158 unsigned long buf_len_in_ptrs; 1159 1160 /* Fill about 1/100 of the space with bt entries */ 1161 nr_to_fill = buf_len / (sizeof(unsigned long) * ratio); 1162 1163 if (!nr_to_fill) 1164 dprintf3("%s() nr_to_fill: %ld\n", __func__, nr_to_fill); 1165 1166 /* Align the buffer to pointer size */ 1167 while (((unsigned long)buf) % sizeof(void *)) { 1168 buf++; 1169 buf_len--; 1170 } 1171 /* We are storing pointers, so make */ 1172 buf_len_in_ptrs = buf_len / sizeof(void *); 1173 1174 for (i = 0; i < nr_to_fill; i++) { 1175 long index = (mpx_random() % buf_len_in_ptrs); 1176 void *ptr = buf + index * sizeof(unsigned long); 1177 unsigned long ptr_addr = (unsigned long)ptr; 1178 1179 /* ptr and size can be anything */ 1180 mpx_make_bound_helper((unsigned long)ptr, 8); 1181 1182 /* 1183 * take bnd0 and put it in to bounds tables "buf + index" is an 1184 * address inside the buffer where we are pretending that we 1185 * are going to put a pointer We do not, though because we will 1186 * never load entries from the table, so it doesn't matter. 1187 */ 1188 mpx_store_dsc_helper(ptr_addr, (unsigned long)ptr); 1189 dprintf4("storing bound table entry for %lx (buf start @ %p)\n", 1190 ptr_addr, buf); 1191 } 1192 return nr_to_fill; 1193} 1194 1195unsigned long align_down(unsigned long alignme, unsigned long align_to) 1196{ 1197 return alignme & ~(align_to-1); 1198} 1199 1200unsigned long align_up(unsigned long alignme, unsigned long align_to) 1201{ 1202 return (alignme + align_to - 1) & ~(align_to-1); 1203} 1204 1205/* 1206 * Using 1MB alignment guarantees that each no allocation 1207 * will overlap with another's bounds tables. 1208 * 1209 * We have to cook our own allocator here. malloc() can 1210 * mix other allocation with ours which means that even 1211 * if we free all of our allocations, there might still 1212 * be bounds tables for the *areas* since there is other 1213 * valid memory there. 1214 * 1215 * We also can't use malloc() because a free() of an area 1216 * might not free it back to the kernel. We want it 1217 * completely unmapped an malloc() does not guarantee 1218 * that. 1219 */ 1220#ifdef __i386__ 1221long alignment = 4096; 1222long sz_alignment = 4096; 1223#else 1224long alignment = 1 * MB; 1225long sz_alignment = 1 * MB; 1226#endif 1227void *mpx_mini_alloc(unsigned long sz) 1228{ 1229 unsigned long long tries = 0; 1230 static void *last; 1231 void *ptr; 1232 void *try_at; 1233 1234 sz = align_up(sz, sz_alignment); 1235 1236 try_at = last + alignment; 1237 while (1) { 1238 ptr = mmap(try_at, sz, PROT_READ|PROT_WRITE, 1239 MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 1240 if (ptr == (void *)-1) 1241 return NULL; 1242 if (ptr == try_at) 1243 break; 1244 1245 munmap(ptr, sz); 1246 try_at += alignment; 1247#ifdef __i386__ 1248 /* 1249 * This isn't quite correct for 32-bit binaries 1250 * on 64-bit kernels since they can use the 1251 * entire 32-bit address space, but it's close 1252 * enough. 1253 */ 1254 if (try_at > (void *)0xC0000000) 1255#else 1256 if (try_at > (void *)0x0000800000000000) 1257#endif 1258 try_at = (void *)0x0; 1259 if (!(++tries % 10000)) 1260 dprintf1("stuck in %s(), tries: %lld\n", __func__, tries); 1261 continue; 1262 } 1263 last = ptr; 1264 dprintf3("mpx_mini_alloc(0x%lx) returning: %p\n", sz, ptr); 1265 return ptr; 1266} 1267void mpx_mini_free(void *ptr, long sz) 1268{ 1269 dprintf2("%s() ptr: %p\n", __func__, ptr); 1270 if ((unsigned long)ptr > 0x100000000000) { 1271 dprintf1("uh oh !!!!!!!!!!!!!!! pointer too high: %p\n", ptr); 1272 test_failed(); 1273 } 1274 sz = align_up(sz, sz_alignment); 1275 dprintf3("%s() ptr: %p before munmap\n", __func__, ptr); 1276 munmap(ptr, sz); 1277 dprintf3("%s() ptr: %p DONE\n", __func__, ptr); 1278} 1279 1280#define NR_MALLOCS 100 1281struct one_malloc { 1282 char *ptr; 1283 int nr_filled_btes; 1284 unsigned long size; 1285}; 1286struct one_malloc mallocs[NR_MALLOCS]; 1287 1288void free_one_malloc(int index) 1289{ 1290 unsigned long free_ptr; 1291 unsigned long mask; 1292 1293 if (!mallocs[index].ptr) 1294 return; 1295 1296 mpx_mini_free(mallocs[index].ptr, mallocs[index].size); 1297 dprintf4("freed[%d]: %p\n", index, mallocs[index].ptr); 1298 1299 free_ptr = (unsigned long)mallocs[index].ptr; 1300 mask = alignment-1; 1301 dprintf4("lowerbits: %lx / %lx mask: %lx\n", free_ptr, 1302 (free_ptr & mask), mask); 1303 assert((free_ptr & mask) == 0); 1304 1305 mallocs[index].ptr = NULL; 1306} 1307 1308#ifdef __i386__ 1309#define MPX_BOUNDS_TABLE_COVERS 4096 1310#else 1311#define MPX_BOUNDS_TABLE_COVERS (1 * MB) 1312#endif 1313void zap_everything(void) 1314{ 1315 long after_zap; 1316 long before_zap; 1317 int i; 1318 1319 before_zap = inspect_me(bounds_dir_ptr); 1320 dprintf1("zapping everything start: %ld\n", before_zap); 1321 for (i = 0; i < NR_MALLOCS; i++) 1322 free_one_malloc(i); 1323 1324 after_zap = inspect_me(bounds_dir_ptr); 1325 dprintf1("zapping everything done: %ld\n", after_zap); 1326 /* 1327 * We only guarantee to empty the thing out if our allocations are 1328 * exactly aligned on the boundaries of a boudns table. 1329 */ 1330 if ((alignment >= MPX_BOUNDS_TABLE_COVERS) && 1331 (sz_alignment >= MPX_BOUNDS_TABLE_COVERS)) { 1332 if (after_zap != 0) 1333 test_failed(); 1334 1335 assert(after_zap == 0); 1336 } 1337} 1338 1339void do_one_malloc(void) 1340{ 1341 static int malloc_counter; 1342 long sz; 1343 int rand_index = (mpx_random() % NR_MALLOCS); 1344 void *ptr = mallocs[rand_index].ptr; 1345 1346 dprintf3("%s() enter\n", __func__); 1347 1348 if (ptr) { 1349 dprintf3("freeing one malloc at index: %d\n", rand_index); 1350 free_one_malloc(rand_index); 1351 if (mpx_random() % (NR_MALLOCS*3) == 3) { 1352 int i; 1353 dprintf3("zapping some more\n"); 1354 for (i = rand_index; i < NR_MALLOCS; i++) 1355 free_one_malloc(i); 1356 } 1357 if ((mpx_random() % zap_all_every_this_many_mallocs) == 4) 1358 zap_everything(); 1359 } 1360 1361 /* 1->~1M */ 1362 sz = (1 + mpx_random() % 1000) * 1000; 1363 ptr = mpx_mini_alloc(sz); 1364 if (!ptr) { 1365 /* 1366 * If we are failing allocations, just assume we 1367 * are out of memory and zap everything. 1368 */ 1369 dprintf3("zapping everything because out of memory\n"); 1370 zap_everything(); 1371 goto out; 1372 } 1373 1374 dprintf3("malloc: %p size: 0x%lx\n", ptr, sz); 1375 mallocs[rand_index].nr_filled_btes = cover_buf_with_bt_entries(ptr, sz); 1376 mallocs[rand_index].ptr = ptr; 1377 mallocs[rand_index].size = sz; 1378out: 1379 if ((++malloc_counter) % inspect_every_this_many_mallocs == 0) 1380 inspect_me(bounds_dir_ptr); 1381} 1382 1383void run_timed_test(void (*test_func)(void)) 1384{ 1385 int done = 0; 1386 long iteration = 0; 1387 static time_t last_print; 1388 time_t now; 1389 time_t start; 1390 1391 time(&start); 1392 while (!done) { 1393 time(&now); 1394 if ((now - start) > TEST_DURATION_SECS) 1395 done = 1; 1396 1397 test_func(); 1398 iteration++; 1399 1400 if ((now - last_print > 1) || done) { 1401 printf("iteration %ld complete, OK so far\n", iteration); 1402 last_print = now; 1403 } 1404 } 1405} 1406 1407void check_bounds_table_frees(void) 1408{ 1409 printf("executing unmaptest\n"); 1410 inspect_me(bounds_dir_ptr); 1411 run_timed_test(&do_one_malloc); 1412 printf("done with malloc() fun\n"); 1413} 1414 1415void insn_test_failed(int test_nr, int test_round, void *buf, 1416 void *buf_shadow, void *ptr) 1417{ 1418 print_context(xsave_test_buf); 1419 eprintf("ERROR: test %d round %d failed\n", test_nr, test_round); 1420 while (test_nr == 5) { 1421 struct mpx_bt_entry *bte; 1422 struct mpx_bounds_dir *bd = (void *)bounds_dir_ptr; 1423 struct mpx_bd_entry *bde = mpx_vaddr_to_bd_entry(buf, bd); 1424 1425 printf(" bd: %p\n", bd); 1426 printf("&bde: %p\n", bde); 1427 printf("*bde: %lx\n", *(unsigned long *)bde); 1428 if (!bd_entry_valid(bde)) 1429 break; 1430 1431 bte = mpx_vaddr_to_bt_entry(buf, bd); 1432 printf(" te: %p\n", bte); 1433 printf("bte[0]: %lx\n", bte->contents[0]); 1434 printf("bte[1]: %lx\n", bte->contents[1]); 1435 printf("bte[2]: %lx\n", bte->contents[2]); 1436 printf("bte[3]: %lx\n", bte->contents[3]); 1437 break; 1438 } 1439 test_failed(); 1440} 1441 1442void check_mpx_insns_and_tables(void) 1443{ 1444 int successes = 0; 1445 int failures = 0; 1446 int buf_size = (1024*1024); 1447 unsigned long *buf = malloc(buf_size); 1448 const int total_nr_tests = NR_MPX_TEST_FUNCTIONS * TEST_ROUNDS; 1449 int i, j; 1450 1451 memset(buf, 0, buf_size); 1452 memset(buf_shadow, 0, sizeof(buf_shadow)); 1453 1454 for (i = 0; i < TEST_ROUNDS; i++) { 1455 uint8_t *ptr = get_random_addr() + 8; 1456 1457 for (j = 0; j < NR_MPX_TEST_FUNCTIONS; j++) { 1458 if (0 && j != 5) { 1459 successes++; 1460 continue; 1461 } 1462 dprintf2("starting test %d round %d\n", j, i); 1463 dprint_context(xsave_test_buf); 1464 /* 1465 * test5 loads an address from the bounds tables. 1466 * The load will only complete if 'ptr' matches 1467 * the load and the store, so with random addrs, 1468 * the odds of this are very small. Make it 1469 * higher by only moving 'ptr' 1/10 times. 1470 */ 1471 if (random() % 10 <= 0) 1472 ptr = get_random_addr() + 8; 1473 dprintf3("random ptr{%p}\n", ptr); 1474 dprint_context(xsave_test_buf); 1475 run_helpers(j, (void *)buf, (void *)buf_shadow, ptr); 1476 dprint_context(xsave_test_buf); 1477 if (!compare_context(xsave_test_buf)) { 1478 insn_test_failed(j, i, buf, buf_shadow, ptr); 1479 failures++; 1480 goto exit; 1481 } 1482 successes++; 1483 dprint_context(xsave_test_buf); 1484 dprintf2("finished test %d round %d\n", j, i); 1485 dprintf3("\n"); 1486 dprint_context(xsave_test_buf); 1487 } 1488 } 1489 1490exit: 1491 dprintf2("\nabout to free:\n"); 1492 free(buf); 1493 dprintf1("successes: %d\n", successes); 1494 dprintf1(" failures: %d\n", failures); 1495 dprintf1(" tests: %d\n", total_nr_tests); 1496 dprintf1(" expected: %jd #BRs\n", num_upper_brs + num_lower_brs); 1497 dprintf1(" saw: %d #BRs\n", br_count); 1498 if (failures) { 1499 eprintf("ERROR: non-zero number of failures\n"); 1500 exit(20); 1501 } 1502 if (successes != total_nr_tests) { 1503 eprintf("ERROR: succeded fewer than number of tries (%d != %d)\n", 1504 successes, total_nr_tests); 1505 exit(21); 1506 } 1507 if (num_upper_brs + num_lower_brs != br_count) { 1508 eprintf("ERROR: unexpected number of #BRs: %jd %jd %d\n", 1509 num_upper_brs, num_lower_brs, br_count); 1510 eprintf("successes: %d\n", successes); 1511 eprintf(" failures: %d\n", failures); 1512 eprintf(" tests: %d\n", total_nr_tests); 1513 eprintf(" expected: %jd #BRs\n", num_upper_brs + num_lower_brs); 1514 eprintf(" saw: %d #BRs\n", br_count); 1515 exit(22); 1516 } 1517} 1518 1519/* 1520 * This is supposed to SIGSEGV nicely once the kernel 1521 * can no longer allocate vaddr space. 1522 */ 1523void exhaust_vaddr_space(void) 1524{ 1525 unsigned long ptr; 1526 /* Try to make sure there is no room for a bounds table anywhere */ 1527 unsigned long skip = MPX_BOUNDS_TABLE_SIZE_BYTES - PAGE_SIZE; 1528#ifdef __i386__ 1529 unsigned long max_vaddr = 0xf7788000UL; 1530#else 1531 unsigned long max_vaddr = 0x800000000000UL; 1532#endif 1533 1534 dprintf1("%s() start\n", __func__); 1535 /* do not start at 0, we aren't allowed to map there */ 1536 for (ptr = PAGE_SIZE; ptr < max_vaddr; ptr += skip) { 1537 void *ptr_ret; 1538 int ret = madvise((void *)ptr, PAGE_SIZE, MADV_NORMAL); 1539 1540 if (!ret) { 1541 dprintf1("madvise() %lx ret: %d\n", ptr, ret); 1542 continue; 1543 } 1544 ptr_ret = mmap((void *)ptr, PAGE_SIZE, PROT_READ|PROT_WRITE, 1545 MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 1546 if (ptr_ret != (void *)ptr) { 1547 perror("mmap"); 1548 dprintf1("mmap(%lx) ret: %p\n", ptr, ptr_ret); 1549 break; 1550 } 1551 if (!(ptr & 0xffffff)) 1552 dprintf1("mmap(%lx) ret: %p\n", ptr, ptr_ret); 1553 } 1554 for (ptr = PAGE_SIZE; ptr < max_vaddr; ptr += skip) { 1555 dprintf2("covering 0x%lx with bounds table entries\n", ptr); 1556 cover_buf_with_bt_entries((void *)ptr, PAGE_SIZE); 1557 } 1558 dprintf1("%s() end\n", __func__); 1559 printf("done with vaddr space fun\n"); 1560} 1561 1562void mpx_table_test(void) 1563{ 1564 printf("starting mpx bounds table test\n"); 1565 run_timed_test(check_mpx_insns_and_tables); 1566 printf("done with mpx bounds table test\n"); 1567} 1568 1569int main(int argc, char **argv) 1570{ 1571 int unmaptest = 0; 1572 int vaddrexhaust = 0; 1573 int tabletest = 0; 1574 int i; 1575 1576 check_mpx_support(); 1577 mpx_prepare(); 1578 srandom(11179); 1579 1580 bd_incore(); 1581 init(); 1582 bd_incore(); 1583 1584 trace_me(); 1585 1586 xsave_state((void *)xsave_test_buf, 0x1f); 1587 if (!compare_context(xsave_test_buf)) 1588 printf("Init failed\n"); 1589 1590 for (i = 1; i < argc; i++) { 1591 if (!strcmp(argv[i], "unmaptest")) 1592 unmaptest = 1; 1593 if (!strcmp(argv[i], "vaddrexhaust")) 1594 vaddrexhaust = 1; 1595 if (!strcmp(argv[i], "tabletest")) 1596 tabletest = 1; 1597 } 1598 if (!(unmaptest || vaddrexhaust || tabletest)) { 1599 unmaptest = 1; 1600 /* vaddrexhaust = 1; */ 1601 tabletest = 1; 1602 } 1603 if (unmaptest) 1604 check_bounds_table_frees(); 1605 if (tabletest) 1606 mpx_table_test(); 1607 if (vaddrexhaust) 1608 exhaust_vaddr_space(); 1609 printf("%s completed successfully\n", argv[0]); 1610 exit(0); 1611} 1612 1613#include "mpx-dig.c"