1 // SPDX-License-Identifier: GPL-2.0 2 /* 3 * Tests Memory Protection Keys (see Documentation/core-api/protection-keys.rst) 4 * 5 * There are examples in here of: 6 * * how to set protection keys on memory 7 * * how to set/clear bits in pkey registers (the rights register) 8 * * how to handle SEGV_PKUERR signals and extract pkey-relevant 9 * information from the siginfo 10 * 11 * Things to add: 12 * make sure KSM and KSM COW breaking works 13 * prefault pages in at malloc, or not 14 * protect MPX bounds tables with protection keys? 15 * make sure VMA splitting/merging is working correctly 16 * OOMs can destroy mm->mmap (see exit_mmap()), so make sure it is immune to pkeys 17 * look for pkey "leaks" where it is still set on a VMA but "freed" back to the kernel 18 * do a plain mprotect() to a mprotect_pkey() area and make sure the pkey sticks 19 * 20 * Compile like this: 21 * gcc -mxsave -o protection_keys -O2 -g -std=gnu99 -pthread -Wall protection_keys.c -lrt -ldl -lm 22 * gcc -mxsave -m32 -o protection_keys_32 -O2 -g -std=gnu99 -pthread -Wall protection_keys.c -lrt -ldl -lm 23 */ 24 #define _GNU_SOURCE 25 #define __SANE_USERSPACE_TYPES__ 26 #include <errno.h> 27 #include <linux/elf.h> 28 #include <linux/futex.h> 29 #include <time.h> 30 #include <sys/time.h> 31 #include <sys/syscall.h> 32 #include <string.h> 33 #include <stdio.h> 34 #include <stdint.h> 35 #include <stdbool.h> 36 #include <signal.h> 37 #include <assert.h> 38 #include <stdlib.h> 39 #include <ucontext.h> 40 #include <sys/mman.h> 41 #include <sys/types.h> 42 #include <sys/wait.h> 43 #include <sys/stat.h> 44 #include <fcntl.h> 45 #include <asm-generic/unistd.h> 46 #include <sys/ptrace.h> 47 #include <setjmp.h> 48 49 #include "pkey-helpers.h" 50 51 int iteration_nr = 1; 52 int test_nr; 53 54 u64 shadow_pkey_reg; 55 int dprint_in_signal; 56 char dprint_in_signal_buffer[DPRINT_IN_SIGNAL_BUF_SIZE]; 57 58 void cat_into_file(char *str, char *file) 59 { 60 int fd = open(file, O_RDWR); 61 int ret; 62 63 dprintf2("%s(): writing '%s' to '%s'\n", __func__, str, file); 64 /* 65 * these need to be raw because they are called under 66 * pkey_assert() 67 */ 68 if (fd < 0) { 69 fprintf(stderr, "error opening '%s'\n", str); 70 perror("error: "); 71 exit(__LINE__); 72 } 73 74 ret = write(fd, str, strlen(str)); 75 if (ret != strlen(str)) { 76 perror("write to file failed"); 77 fprintf(stderr, "filename: '%s' str: '%s'\n", file, str); 78 exit(__LINE__); 79 } 80 close(fd); 81 } 82 83 #if CONTROL_TRACING > 0 84 static int warned_tracing; 85 int tracing_root_ok(void) 86 { 87 if (geteuid() != 0) { 88 if (!warned_tracing) 89 fprintf(stderr, "WARNING: not run as root, " 90 "can not do tracing control\n"); 91 warned_tracing = 1; 92 return 0; 93 } 94 return 1; 95 } 96 #endif 97 98 void tracing_on(void) 99 { 100 #if CONTROL_TRACING > 0 101 #define TRACEDIR "/sys/kernel/tracing" 102 char pidstr[32]; 103 104 if (!tracing_root_ok()) 105 return; 106 107 sprintf(pidstr, "%d", getpid()); 108 cat_into_file("0", TRACEDIR "/tracing_on"); 109 cat_into_file("\n", TRACEDIR "/trace"); 110 if (1) { 111 cat_into_file("function_graph", TRACEDIR "/current_tracer"); 112 cat_into_file("1", TRACEDIR "/options/funcgraph-proc"); 113 } else { 114 cat_into_file("nop", TRACEDIR "/current_tracer"); 115 } 116 cat_into_file(pidstr, TRACEDIR "/set_ftrace_pid"); 117 cat_into_file("1", TRACEDIR "/tracing_on"); 118 dprintf1("enabled tracing\n"); 119 #endif 120 } 121 122 void tracing_off(void) 123 { 124 #if CONTROL_TRACING > 0 125 if (!tracing_root_ok()) 126 return; 127 cat_into_file("0", "/sys/kernel/tracing/tracing_on"); 128 #endif 129 } 130 131 void abort_hooks(void) 132 { 133 fprintf(stderr, "running %s()...\n", __func__); 134 tracing_off(); 135 #ifdef SLEEP_ON_ABORT 136 sleep(SLEEP_ON_ABORT); 137 #endif 138 } 139 140 /* 141 * This attempts to have roughly a page of instructions followed by a few 142 * instructions that do a write, and another page of instructions. That 143 * way, we are pretty sure that the write is in the second page of 144 * instructions and has at least a page of padding behind it. 145 * 146 * *That* lets us be sure to madvise() away the write instruction, which 147 * will then fault, which makes sure that the fault code handles 148 * execute-only memory properly. 149 */ 150 #ifdef __powerpc64__ 151 /* This way, both 4K and 64K alignment are maintained */ 152 __attribute__((__aligned__(65536))) 153 #else 154 __attribute__((__aligned__(PAGE_SIZE))) 155 #endif 156 void lots_o_noops_around_write(int *write_to_me) 157 { 158 dprintf3("running %s()\n", __func__); 159 __page_o_noops(); 160 /* Assume this happens in the second page of instructions: */ 161 *write_to_me = __LINE__; 162 /* pad out by another page: */ 163 __page_o_noops(); 164 dprintf3("%s() done\n", __func__); 165 } 166 167 void dump_mem(void *dumpme, int len_bytes) 168 { 169 char *c = (void *)dumpme; 170 int i; 171 172 for (i = 0; i < len_bytes; i += sizeof(u64)) { 173 u64 *ptr = (u64 *)(c + i); 174 dprintf1("dump[%03d][@%p]: %016llx\n", i, ptr, *ptr); 175 } 176 } 177 178 static u32 hw_pkey_get(int pkey, unsigned long flags) 179 { 180 u64 pkey_reg = __read_pkey_reg(); 181 182 dprintf1("%s(pkey=%d, flags=%lx) = %x / %d\n", 183 __func__, pkey, flags, 0, 0); 184 dprintf2("%s() raw pkey_reg: %016llx\n", __func__, pkey_reg); 185 186 return (u32) get_pkey_bits(pkey_reg, pkey); 187 } 188 189 static int hw_pkey_set(int pkey, unsigned long rights, unsigned long flags) 190 { 191 u32 mask = (PKEY_DISABLE_ACCESS|PKEY_DISABLE_WRITE); 192 u64 old_pkey_reg = __read_pkey_reg(); 193 u64 new_pkey_reg; 194 195 /* make sure that 'rights' only contains the bits we expect: */ 196 assert(!(rights & ~mask)); 197 198 /* modify bits accordingly in old pkey_reg and assign it */ 199 new_pkey_reg = set_pkey_bits(old_pkey_reg, pkey, rights); 200 201 __write_pkey_reg(new_pkey_reg); 202 203 dprintf3("%s(pkey=%d, rights=%lx, flags=%lx) = %x" 204 " pkey_reg now: %016llx old_pkey_reg: %016llx\n", 205 __func__, pkey, rights, flags, 0, __read_pkey_reg(), 206 old_pkey_reg); 207 return 0; 208 } 209 210 void pkey_disable_set(int pkey, int flags) 211 { 212 unsigned long syscall_flags = 0; 213 int ret; 214 int pkey_rights; 215 u64 orig_pkey_reg = read_pkey_reg(); 216 217 dprintf1("START->%s(%d, 0x%x)\n", __func__, 218 pkey, flags); 219 pkey_assert(flags & (PKEY_DISABLE_ACCESS | PKEY_DISABLE_WRITE)); 220 221 pkey_rights = hw_pkey_get(pkey, syscall_flags); 222 223 dprintf1("%s(%d) hw_pkey_get(%d): %x\n", __func__, 224 pkey, pkey, pkey_rights); 225 226 pkey_assert(pkey_rights >= 0); 227 228 pkey_rights |= flags; 229 230 ret = hw_pkey_set(pkey, pkey_rights, syscall_flags); 231 assert(!ret); 232 /* pkey_reg and flags have the same format */ 233 shadow_pkey_reg = set_pkey_bits(shadow_pkey_reg, pkey, pkey_rights); 234 dprintf1("%s(%d) shadow: 0x%016llx\n", 235 __func__, pkey, shadow_pkey_reg); 236 237 pkey_assert(ret >= 0); 238 239 pkey_rights = hw_pkey_get(pkey, syscall_flags); 240 dprintf1("%s(%d) hw_pkey_get(%d): %x\n", __func__, 241 pkey, pkey, pkey_rights); 242 243 dprintf1("%s(%d) pkey_reg: 0x%016llx\n", 244 __func__, pkey, read_pkey_reg()); 245 if (flags) 246 pkey_assert(read_pkey_reg() >= orig_pkey_reg); 247 dprintf1("END<---%s(%d, 0x%x)\n", __func__, 248 pkey, flags); 249 } 250 251 void pkey_disable_clear(int pkey, int flags) 252 { 253 unsigned long syscall_flags = 0; 254 int ret; 255 int pkey_rights = hw_pkey_get(pkey, syscall_flags); 256 u64 orig_pkey_reg = read_pkey_reg(); 257 258 pkey_assert(flags & (PKEY_DISABLE_ACCESS | PKEY_DISABLE_WRITE)); 259 260 dprintf1("%s(%d) hw_pkey_get(%d): %x\n", __func__, 261 pkey, pkey, pkey_rights); 262 pkey_assert(pkey_rights >= 0); 263 264 pkey_rights &= ~flags; 265 266 ret = hw_pkey_set(pkey, pkey_rights, 0); 267 shadow_pkey_reg = set_pkey_bits(shadow_pkey_reg, pkey, pkey_rights); 268 pkey_assert(ret >= 0); 269 270 pkey_rights = hw_pkey_get(pkey, syscall_flags); 271 dprintf1("%s(%d) hw_pkey_get(%d): %x\n", __func__, 272 pkey, pkey, pkey_rights); 273 274 dprintf1("%s(%d) pkey_reg: 0x%016llx\n", __func__, 275 pkey, read_pkey_reg()); 276 if (flags) 277 assert(read_pkey_reg() <= orig_pkey_reg); 278 } 279 280 void pkey_write_allow(int pkey) 281 { 282 pkey_disable_clear(pkey, PKEY_DISABLE_WRITE); 283 } 284 void pkey_write_deny(int pkey) 285 { 286 pkey_disable_set(pkey, PKEY_DISABLE_WRITE); 287 } 288 void pkey_access_allow(int pkey) 289 { 290 pkey_disable_clear(pkey, PKEY_DISABLE_ACCESS); 291 } 292 void pkey_access_deny(int pkey) 293 { 294 pkey_disable_set(pkey, PKEY_DISABLE_ACCESS); 295 } 296 297 static char *si_code_str(int si_code) 298 { 299 if (si_code == SEGV_MAPERR) 300 return "SEGV_MAPERR"; 301 if (si_code == SEGV_ACCERR) 302 return "SEGV_ACCERR"; 303 if (si_code == SEGV_BNDERR) 304 return "SEGV_BNDERR"; 305 if (si_code == SEGV_PKUERR) 306 return "SEGV_PKUERR"; 307 return "UNKNOWN"; 308 } 309 310 int pkey_faults; 311 int last_si_pkey = -1; 312 void signal_handler(int signum, siginfo_t *si, void *vucontext) 313 { 314 ucontext_t *uctxt = vucontext; 315 int trapno; 316 unsigned long ip; 317 char *fpregs; 318 #if defined(__i386__) || defined(__x86_64__) /* arch */ 319 u32 *pkey_reg_ptr; 320 int pkey_reg_offset; 321 #endif /* arch */ 322 u64 siginfo_pkey; 323 u32 *si_pkey_ptr; 324 325 dprint_in_signal = 1; 326 dprintf1(">>>>===============SIGSEGV============================\n"); 327 dprintf1("%s()::%d, pkey_reg: 0x%016llx shadow: %016llx\n", 328 __func__, __LINE__, 329 __read_pkey_reg(), shadow_pkey_reg); 330 331 trapno = uctxt->uc_mcontext.gregs[REG_TRAPNO]; 332 ip = uctxt->uc_mcontext.gregs[REG_IP_IDX]; 333 fpregs = (char *) uctxt->uc_mcontext.fpregs; 334 335 dprintf2("%s() trapno: %d ip: 0x%016lx info->si_code: %s/%d\n", 336 __func__, trapno, ip, si_code_str(si->si_code), 337 si->si_code); 338 339 #if defined(__i386__) || defined(__x86_64__) /* arch */ 340 #ifdef __i386__ 341 /* 342 * 32-bit has some extra padding so that userspace can tell whether 343 * the XSTATE header is present in addition to the "legacy" FPU 344 * state. We just assume that it is here. 345 */ 346 fpregs += 0x70; 347 #endif /* i386 */ 348 pkey_reg_offset = pkey_reg_xstate_offset(); 349 pkey_reg_ptr = (void *)(&fpregs[pkey_reg_offset]); 350 351 /* 352 * If we got a PKEY fault, we *HAVE* to have at least one bit set in 353 * here. 354 */ 355 dprintf1("pkey_reg_xstate_offset: %d\n", pkey_reg_xstate_offset()); 356 if (DEBUG_LEVEL > 4) 357 dump_mem(pkey_reg_ptr - 128, 256); 358 pkey_assert(*pkey_reg_ptr); 359 #endif /* arch */ 360 361 dprintf1("siginfo: %p\n", si); 362 dprintf1(" fpregs: %p\n", fpregs); 363 364 if ((si->si_code == SEGV_MAPERR) || 365 (si->si_code == SEGV_ACCERR) || 366 (si->si_code == SEGV_BNDERR)) { 367 printf("non-PK si_code, exiting...\n"); 368 exit(4); 369 } 370 371 si_pkey_ptr = siginfo_get_pkey_ptr(si); 372 dprintf1("si_pkey_ptr: %p\n", si_pkey_ptr); 373 dump_mem((u8 *)si_pkey_ptr - 8, 24); 374 siginfo_pkey = *si_pkey_ptr; 375 pkey_assert(siginfo_pkey < NR_PKEYS); 376 last_si_pkey = siginfo_pkey; 377 378 /* 379 * need __read_pkey_reg() version so we do not do shadow_pkey_reg 380 * checking 381 */ 382 dprintf1("signal pkey_reg from pkey_reg: %016llx\n", 383 __read_pkey_reg()); 384 dprintf1("pkey from siginfo: %016llx\n", siginfo_pkey); 385 #if defined(__i386__) || defined(__x86_64__) /* arch */ 386 dprintf1("signal pkey_reg from xsave: %08x\n", *pkey_reg_ptr); 387 *(u64 *)pkey_reg_ptr = 0x00000000; 388 dprintf1("WARNING: set PKEY_REG=0 to allow faulting instruction to continue\n"); 389 #elif defined(__powerpc64__) /* arch */ 390 /* restore access and let the faulting instruction continue */ 391 pkey_access_allow(siginfo_pkey); 392 #endif /* arch */ 393 pkey_faults++; 394 dprintf1("<<<<==================================================\n"); 395 dprint_in_signal = 0; 396 } 397 398 int wait_all_children(void) 399 { 400 int status; 401 return waitpid(-1, &status, 0); 402 } 403 404 void sig_chld(int x) 405 { 406 dprint_in_signal = 1; 407 dprintf2("[%d] SIGCHLD: %d\n", getpid(), x); 408 dprint_in_signal = 0; 409 } 410 411 void setup_sigsegv_handler(void) 412 { 413 int r, rs; 414 struct sigaction newact; 415 struct sigaction oldact; 416 417 /* #PF is mapped to sigsegv */ 418 int signum = SIGSEGV; 419 420 newact.sa_handler = 0; 421 newact.sa_sigaction = signal_handler; 422 423 /*sigset_t - signals to block while in the handler */ 424 /* get the old signal mask. */ 425 rs = sigprocmask(SIG_SETMASK, 0, &newact.sa_mask); 426 pkey_assert(rs == 0); 427 428 /* call sa_sigaction, not sa_handler*/ 429 newact.sa_flags = SA_SIGINFO; 430 431 newact.sa_restorer = 0; /* void(*)(), obsolete */ 432 r = sigaction(signum, &newact, &oldact); 433 r = sigaction(SIGALRM, &newact, &oldact); 434 pkey_assert(r == 0); 435 } 436 437 void setup_handlers(void) 438 { 439 signal(SIGCHLD, &sig_chld); 440 setup_sigsegv_handler(); 441 } 442 443 pid_t fork_lazy_child(void) 444 { 445 pid_t forkret; 446 447 forkret = fork(); 448 pkey_assert(forkret >= 0); 449 dprintf3("[%d] fork() ret: %d\n", getpid(), forkret); 450 451 if (!forkret) { 452 /* in the child */ 453 while (1) { 454 dprintf1("child sleeping...\n"); 455 sleep(30); 456 } 457 } 458 return forkret; 459 } 460 461 int sys_mprotect_pkey(void *ptr, size_t size, unsigned long orig_prot, 462 unsigned long pkey) 463 { 464 int sret; 465 466 dprintf2("%s(0x%p, %zx, prot=%lx, pkey=%lx)\n", __func__, 467 ptr, size, orig_prot, pkey); 468 469 errno = 0; 470 sret = syscall(__NR_pkey_mprotect, ptr, size, orig_prot, pkey); 471 if (errno) { 472 dprintf2("SYS_mprotect_key sret: %d\n", sret); 473 dprintf2("SYS_mprotect_key prot: 0x%lx\n", orig_prot); 474 dprintf2("SYS_mprotect_key failed, errno: %d\n", errno); 475 if (DEBUG_LEVEL >= 2) 476 perror("SYS_mprotect_pkey"); 477 } 478 return sret; 479 } 480 481 int sys_pkey_alloc(unsigned long flags, unsigned long init_val) 482 { 483 int ret = syscall(SYS_pkey_alloc, flags, init_val); 484 dprintf1("%s(flags=%lx, init_val=%lx) syscall ret: %d errno: %d\n", 485 __func__, flags, init_val, ret, errno); 486 return ret; 487 } 488 489 int alloc_pkey(void) 490 { 491 int ret; 492 unsigned long init_val = 0x0; 493 494 dprintf1("%s()::%d, pkey_reg: 0x%016llx shadow: %016llx\n", 495 __func__, __LINE__, __read_pkey_reg(), shadow_pkey_reg); 496 ret = sys_pkey_alloc(0, init_val); 497 /* 498 * pkey_alloc() sets PKEY register, so we need to reflect it in 499 * shadow_pkey_reg: 500 */ 501 dprintf4("%s()::%d, ret: %d pkey_reg: 0x%016llx" 502 " shadow: 0x%016llx\n", 503 __func__, __LINE__, ret, __read_pkey_reg(), 504 shadow_pkey_reg); 505 if (ret > 0) { 506 /* clear both the bits: */ 507 shadow_pkey_reg = set_pkey_bits(shadow_pkey_reg, ret, 508 ~PKEY_MASK); 509 dprintf4("%s()::%d, ret: %d pkey_reg: 0x%016llx" 510 " shadow: 0x%016llx\n", 511 __func__, 512 __LINE__, ret, __read_pkey_reg(), 513 shadow_pkey_reg); 514 /* 515 * move the new state in from init_val 516 * (remember, we cheated and init_val == pkey_reg format) 517 */ 518 shadow_pkey_reg = set_pkey_bits(shadow_pkey_reg, ret, 519 init_val); 520 } 521 dprintf4("%s()::%d, ret: %d pkey_reg: 0x%016llx" 522 " shadow: 0x%016llx\n", 523 __func__, __LINE__, ret, __read_pkey_reg(), 524 shadow_pkey_reg); 525 dprintf1("%s()::%d errno: %d\n", __func__, __LINE__, errno); 526 /* for shadow checking: */ 527 read_pkey_reg(); 528 dprintf4("%s()::%d, ret: %d pkey_reg: 0x%016llx" 529 " shadow: 0x%016llx\n", 530 __func__, __LINE__, ret, __read_pkey_reg(), 531 shadow_pkey_reg); 532 return ret; 533 } 534 535 int sys_pkey_free(unsigned long pkey) 536 { 537 int ret = syscall(SYS_pkey_free, pkey); 538 dprintf1("%s(pkey=%ld) syscall ret: %d\n", __func__, pkey, ret); 539 return ret; 540 } 541 542 /* 543 * I had a bug where pkey bits could be set by mprotect() but 544 * not cleared. This ensures we get lots of random bit sets 545 * and clears on the vma and pte pkey bits. 546 */ 547 int alloc_random_pkey(void) 548 { 549 int max_nr_pkey_allocs; 550 int ret; 551 int i; 552 int alloced_pkeys[NR_PKEYS]; 553 int nr_alloced = 0; 554 int random_index; 555 memset(alloced_pkeys, 0, sizeof(alloced_pkeys)); 556 557 /* allocate every possible key and make a note of which ones we got */ 558 max_nr_pkey_allocs = NR_PKEYS; 559 for (i = 0; i < max_nr_pkey_allocs; i++) { 560 int new_pkey = alloc_pkey(); 561 if (new_pkey < 0) 562 break; 563 alloced_pkeys[nr_alloced++] = new_pkey; 564 } 565 566 pkey_assert(nr_alloced > 0); 567 /* select a random one out of the allocated ones */ 568 random_index = rand() % nr_alloced; 569 ret = alloced_pkeys[random_index]; 570 /* now zero it out so we don't free it next */ 571 alloced_pkeys[random_index] = 0; 572 573 /* go through the allocated ones that we did not want and free them */ 574 for (i = 0; i < nr_alloced; i++) { 575 int free_ret; 576 if (!alloced_pkeys[i]) 577 continue; 578 free_ret = sys_pkey_free(alloced_pkeys[i]); 579 pkey_assert(!free_ret); 580 } 581 dprintf1("%s()::%d, ret: %d pkey_reg: 0x%016llx" 582 " shadow: 0x%016llx\n", __func__, 583 __LINE__, ret, __read_pkey_reg(), shadow_pkey_reg); 584 return ret; 585 } 586 587 int mprotect_pkey(void *ptr, size_t size, unsigned long orig_prot, 588 unsigned long pkey) 589 { 590 int nr_iterations = random() % 100; 591 int ret; 592 593 while (0) { 594 int rpkey = alloc_random_pkey(); 595 ret = sys_mprotect_pkey(ptr, size, orig_prot, pkey); 596 dprintf1("sys_mprotect_pkey(%p, %zx, prot=0x%lx, pkey=%ld) ret: %d\n", 597 ptr, size, orig_prot, pkey, ret); 598 if (nr_iterations-- < 0) 599 break; 600 601 dprintf1("%s()::%d, ret: %d pkey_reg: 0x%016llx" 602 " shadow: 0x%016llx\n", 603 __func__, __LINE__, ret, __read_pkey_reg(), 604 shadow_pkey_reg); 605 sys_pkey_free(rpkey); 606 dprintf1("%s()::%d, ret: %d pkey_reg: 0x%016llx" 607 " shadow: 0x%016llx\n", 608 __func__, __LINE__, ret, __read_pkey_reg(), 609 shadow_pkey_reg); 610 } 611 pkey_assert(pkey < NR_PKEYS); 612 613 ret = sys_mprotect_pkey(ptr, size, orig_prot, pkey); 614 dprintf1("mprotect_pkey(%p, %zx, prot=0x%lx, pkey=%ld) ret: %d\n", 615 ptr, size, orig_prot, pkey, ret); 616 pkey_assert(!ret); 617 dprintf1("%s()::%d, ret: %d pkey_reg: 0x%016llx" 618 " shadow: 0x%016llx\n", __func__, 619 __LINE__, ret, __read_pkey_reg(), shadow_pkey_reg); 620 return ret; 621 } 622 623 struct pkey_malloc_record { 624 void *ptr; 625 long size; 626 int prot; 627 }; 628 struct pkey_malloc_record *pkey_malloc_records; 629 struct pkey_malloc_record *pkey_last_malloc_record; 630 long nr_pkey_malloc_records; 631 void record_pkey_malloc(void *ptr, long size, int prot) 632 { 633 long i; 634 struct pkey_malloc_record *rec = NULL; 635 636 for (i = 0; i < nr_pkey_malloc_records; i++) { 637 rec = &pkey_malloc_records[i]; 638 /* find a free record */ 639 if (rec) 640 break; 641 } 642 if (!rec) { 643 /* every record is full */ 644 size_t old_nr_records = nr_pkey_malloc_records; 645 size_t new_nr_records = (nr_pkey_malloc_records * 2 + 1); 646 size_t new_size = new_nr_records * sizeof(struct pkey_malloc_record); 647 dprintf2("new_nr_records: %zd\n", new_nr_records); 648 dprintf2("new_size: %zd\n", new_size); 649 pkey_malloc_records = realloc(pkey_malloc_records, new_size); 650 pkey_assert(pkey_malloc_records != NULL); 651 rec = &pkey_malloc_records[nr_pkey_malloc_records]; 652 /* 653 * realloc() does not initialize memory, so zero it from 654 * the first new record all the way to the end. 655 */ 656 for (i = 0; i < new_nr_records - old_nr_records; i++) 657 memset(rec + i, 0, sizeof(*rec)); 658 } 659 dprintf3("filling malloc record[%d/%p]: {%p, %ld}\n", 660 (int)(rec - pkey_malloc_records), rec, ptr, size); 661 rec->ptr = ptr; 662 rec->size = size; 663 rec->prot = prot; 664 pkey_last_malloc_record = rec; 665 nr_pkey_malloc_records++; 666 } 667 668 void free_pkey_malloc(void *ptr) 669 { 670 long i; 671 int ret; 672 dprintf3("%s(%p)\n", __func__, ptr); 673 for (i = 0; i < nr_pkey_malloc_records; i++) { 674 struct pkey_malloc_record *rec = &pkey_malloc_records[i]; 675 dprintf4("looking for ptr %p at record[%ld/%p]: {%p, %ld}\n", 676 ptr, i, rec, rec->ptr, rec->size); 677 if ((ptr < rec->ptr) || 678 (ptr >= rec->ptr + rec->size)) 679 continue; 680 681 dprintf3("found ptr %p at record[%ld/%p]: {%p, %ld}\n", 682 ptr, i, rec, rec->ptr, rec->size); 683 nr_pkey_malloc_records--; 684 ret = munmap(rec->ptr, rec->size); 685 dprintf3("munmap ret: %d\n", ret); 686 pkey_assert(!ret); 687 dprintf3("clearing rec->ptr, rec: %p\n", rec); 688 rec->ptr = NULL; 689 dprintf3("done clearing rec->ptr, rec: %p\n", rec); 690 return; 691 } 692 pkey_assert(false); 693 } 694 695 696 void *malloc_pkey_with_mprotect(long size, int prot, u16 pkey) 697 { 698 void *ptr; 699 int ret; 700 701 read_pkey_reg(); 702 dprintf1("doing %s(size=%ld, prot=0x%x, pkey=%d)\n", __func__, 703 size, prot, pkey); 704 pkey_assert(pkey < NR_PKEYS); 705 ptr = mmap(NULL, size, prot, MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 706 pkey_assert(ptr != (void *)-1); 707 ret = mprotect_pkey((void *)ptr, PAGE_SIZE, prot, pkey); 708 pkey_assert(!ret); 709 record_pkey_malloc(ptr, size, prot); 710 read_pkey_reg(); 711 712 dprintf1("%s() for pkey %d @ %p\n", __func__, pkey, ptr); 713 return ptr; 714 } 715 716 void *malloc_pkey_anon_huge(long size, int prot, u16 pkey) 717 { 718 int ret; 719 void *ptr; 720 721 dprintf1("doing %s(size=%ld, prot=0x%x, pkey=%d)\n", __func__, 722 size, prot, pkey); 723 /* 724 * Guarantee we can fit at least one huge page in the resulting 725 * allocation by allocating space for 2: 726 */ 727 size = ALIGN_UP(size, HPAGE_SIZE * 2); 728 ptr = mmap(NULL, size, PROT_NONE, MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 729 pkey_assert(ptr != (void *)-1); 730 record_pkey_malloc(ptr, size, prot); 731 mprotect_pkey(ptr, size, prot, pkey); 732 733 dprintf1("unaligned ptr: %p\n", ptr); 734 ptr = ALIGN_PTR_UP(ptr, HPAGE_SIZE); 735 dprintf1(" aligned ptr: %p\n", ptr); 736 ret = madvise(ptr, HPAGE_SIZE, MADV_HUGEPAGE); 737 dprintf1("MADV_HUGEPAGE ret: %d\n", ret); 738 ret = madvise(ptr, HPAGE_SIZE, MADV_WILLNEED); 739 dprintf1("MADV_WILLNEED ret: %d\n", ret); 740 memset(ptr, 0, HPAGE_SIZE); 741 742 dprintf1("mmap()'d thp for pkey %d @ %p\n", pkey, ptr); 743 return ptr; 744 } 745 746 int hugetlb_setup_ok; 747 #define SYSFS_FMT_NR_HUGE_PAGES "/sys/kernel/mm/hugepages/hugepages-%ldkB/nr_hugepages" 748 #define GET_NR_HUGE_PAGES 10 749 void setup_hugetlbfs(void) 750 { 751 int err; 752 int fd; 753 char buf[256]; 754 long hpagesz_kb; 755 long hpagesz_mb; 756 757 if (geteuid() != 0) { 758 fprintf(stderr, "WARNING: not run as root, can not do hugetlb test\n"); 759 return; 760 } 761 762 cat_into_file(__stringify(GET_NR_HUGE_PAGES), "/proc/sys/vm/nr_hugepages"); 763 764 /* 765 * Now go make sure that we got the pages and that they 766 * are PMD-level pages. Someone might have made PUD-level 767 * pages the default. 768 */ 769 hpagesz_kb = HPAGE_SIZE / 1024; 770 hpagesz_mb = hpagesz_kb / 1024; 771 sprintf(buf, SYSFS_FMT_NR_HUGE_PAGES, hpagesz_kb); 772 fd = open(buf, O_RDONLY); 773 if (fd < 0) { 774 fprintf(stderr, "opening sysfs %ldM hugetlb config: %s\n", 775 hpagesz_mb, strerror(errno)); 776 return; 777 } 778 779 /* -1 to guarantee leaving the trailing \0 */ 780 err = read(fd, buf, sizeof(buf)-1); 781 close(fd); 782 if (err <= 0) { 783 fprintf(stderr, "reading sysfs %ldM hugetlb config: %s\n", 784 hpagesz_mb, strerror(errno)); 785 return; 786 } 787 788 if (atoi(buf) != GET_NR_HUGE_PAGES) { 789 fprintf(stderr, "could not confirm %ldM pages, got: '%s' expected %d\n", 790 hpagesz_mb, buf, GET_NR_HUGE_PAGES); 791 return; 792 } 793 794 hugetlb_setup_ok = 1; 795 } 796 797 void *malloc_pkey_hugetlb(long size, int prot, u16 pkey) 798 { 799 void *ptr; 800 int flags = MAP_ANONYMOUS|MAP_PRIVATE|MAP_HUGETLB; 801 802 if (!hugetlb_setup_ok) 803 return PTR_ERR_ENOTSUP; 804 805 dprintf1("doing %s(%ld, %x, %x)\n", __func__, size, prot, pkey); 806 size = ALIGN_UP(size, HPAGE_SIZE * 2); 807 pkey_assert(pkey < NR_PKEYS); 808 ptr = mmap(NULL, size, PROT_NONE, flags, -1, 0); 809 pkey_assert(ptr != (void *)-1); 810 mprotect_pkey(ptr, size, prot, pkey); 811 812 record_pkey_malloc(ptr, size, prot); 813 814 dprintf1("mmap()'d hugetlbfs for pkey %d @ %p\n", pkey, ptr); 815 return ptr; 816 } 817 818 void *malloc_pkey_mmap_dax(long size, int prot, u16 pkey) 819 { 820 void *ptr; 821 int fd; 822 823 dprintf1("doing %s(size=%ld, prot=0x%x, pkey=%d)\n", __func__, 824 size, prot, pkey); 825 pkey_assert(pkey < NR_PKEYS); 826 fd = open("/dax/foo", O_RDWR); 827 pkey_assert(fd >= 0); 828 829 ptr = mmap(0, size, prot, MAP_SHARED, fd, 0); 830 pkey_assert(ptr != (void *)-1); 831 832 mprotect_pkey(ptr, size, prot, pkey); 833 834 record_pkey_malloc(ptr, size, prot); 835 836 dprintf1("mmap()'d for pkey %d @ %p\n", pkey, ptr); 837 close(fd); 838 return ptr; 839 } 840 841 void *(*pkey_malloc[])(long size, int prot, u16 pkey) = { 842 843 malloc_pkey_with_mprotect, 844 malloc_pkey_with_mprotect_subpage, 845 malloc_pkey_anon_huge, 846 malloc_pkey_hugetlb 847 /* can not do direct with the pkey_mprotect() API: 848 malloc_pkey_mmap_direct, 849 malloc_pkey_mmap_dax, 850 */ 851 }; 852 853 void *malloc_pkey(long size, int prot, u16 pkey) 854 { 855 void *ret; 856 static int malloc_type; 857 int nr_malloc_types = ARRAY_SIZE(pkey_malloc); 858 859 pkey_assert(pkey < NR_PKEYS); 860 861 while (1) { 862 pkey_assert(malloc_type < nr_malloc_types); 863 864 ret = pkey_malloc[malloc_type](size, prot, pkey); 865 pkey_assert(ret != (void *)-1); 866 867 malloc_type++; 868 if (malloc_type >= nr_malloc_types) 869 malloc_type = (random()%nr_malloc_types); 870 871 /* try again if the malloc_type we tried is unsupported */ 872 if (ret == PTR_ERR_ENOTSUP) 873 continue; 874 875 break; 876 } 877 878 dprintf3("%s(%ld, prot=%x, pkey=%x) returning: %p\n", __func__, 879 size, prot, pkey, ret); 880 return ret; 881 } 882 883 int last_pkey_faults; 884 #define UNKNOWN_PKEY -2 885 void expected_pkey_fault(int pkey) 886 { 887 dprintf2("%s(): last_pkey_faults: %d pkey_faults: %d\n", 888 __func__, last_pkey_faults, pkey_faults); 889 dprintf2("%s(%d): last_si_pkey: %d\n", __func__, pkey, last_si_pkey); 890 pkey_assert(last_pkey_faults + 1 == pkey_faults); 891 892 /* 893 * For exec-only memory, we do not know the pkey in 894 * advance, so skip this check. 895 */ 896 if (pkey != UNKNOWN_PKEY) 897 pkey_assert(last_si_pkey == pkey); 898 899 #if defined(__i386__) || defined(__x86_64__) /* arch */ 900 /* 901 * The signal handler shold have cleared out PKEY register to let the 902 * test program continue. We now have to restore it. 903 */ 904 if (__read_pkey_reg() != 0) 905 #else /* arch */ 906 if (__read_pkey_reg() != shadow_pkey_reg) 907 #endif /* arch */ 908 pkey_assert(0); 909 910 __write_pkey_reg(shadow_pkey_reg); 911 dprintf1("%s() set pkey_reg=%016llx to restore state after signal " 912 "nuked it\n", __func__, shadow_pkey_reg); 913 last_pkey_faults = pkey_faults; 914 last_si_pkey = -1; 915 } 916 917 #define do_not_expect_pkey_fault(msg) do { \ 918 if (last_pkey_faults != pkey_faults) \ 919 dprintf0("unexpected PKey fault: %s\n", msg); \ 920 pkey_assert(last_pkey_faults == pkey_faults); \ 921 } while (0) 922 923 int test_fds[10] = { -1 }; 924 int nr_test_fds; 925 void __save_test_fd(int fd) 926 { 927 pkey_assert(fd >= 0); 928 pkey_assert(nr_test_fds < ARRAY_SIZE(test_fds)); 929 test_fds[nr_test_fds] = fd; 930 nr_test_fds++; 931 } 932 933 int get_test_read_fd(void) 934 { 935 int test_fd = open("/etc/passwd", O_RDONLY); 936 __save_test_fd(test_fd); 937 return test_fd; 938 } 939 940 void close_test_fds(void) 941 { 942 int i; 943 944 for (i = 0; i < nr_test_fds; i++) { 945 if (test_fds[i] < 0) 946 continue; 947 close(test_fds[i]); 948 test_fds[i] = -1; 949 } 950 nr_test_fds = 0; 951 } 952 953 #define barrier() __asm__ __volatile__("": : :"memory") 954 __attribute__((noinline)) int read_ptr(int *ptr) 955 { 956 /* 957 * Keep GCC from optimizing this away somehow 958 */ 959 barrier(); 960 return *ptr; 961 } 962 963 void test_pkey_alloc_free_attach_pkey0(int *ptr, u16 pkey) 964 { 965 int i, err; 966 int max_nr_pkey_allocs; 967 int alloced_pkeys[NR_PKEYS]; 968 int nr_alloced = 0; 969 long size; 970 971 pkey_assert(pkey_last_malloc_record); 972 size = pkey_last_malloc_record->size; 973 /* 974 * This is a bit of a hack. But mprotect() requires 975 * huge-page-aligned sizes when operating on hugetlbfs. 976 * So, make sure that we use something that's a multiple 977 * of a huge page when we can. 978 */ 979 if (size >= HPAGE_SIZE) 980 size = HPAGE_SIZE; 981 982 /* allocate every possible key and make sure key-0 never got allocated */ 983 max_nr_pkey_allocs = NR_PKEYS; 984 for (i = 0; i < max_nr_pkey_allocs; i++) { 985 int new_pkey = alloc_pkey(); 986 pkey_assert(new_pkey != 0); 987 988 if (new_pkey < 0) 989 break; 990 alloced_pkeys[nr_alloced++] = new_pkey; 991 } 992 /* free all the allocated keys */ 993 for (i = 0; i < nr_alloced; i++) { 994 int free_ret; 995 996 if (!alloced_pkeys[i]) 997 continue; 998 free_ret = sys_pkey_free(alloced_pkeys[i]); 999 pkey_assert(!free_ret); 1000 } 1001 1002 /* attach key-0 in various modes */ 1003 err = sys_mprotect_pkey(ptr, size, PROT_READ, 0); 1004 pkey_assert(!err); 1005 err = sys_mprotect_pkey(ptr, size, PROT_WRITE, 0); 1006 pkey_assert(!err); 1007 err = sys_mprotect_pkey(ptr, size, PROT_EXEC, 0); 1008 pkey_assert(!err); 1009 err = sys_mprotect_pkey(ptr, size, PROT_READ|PROT_WRITE, 0); 1010 pkey_assert(!err); 1011 err = sys_mprotect_pkey(ptr, size, PROT_READ|PROT_WRITE|PROT_EXEC, 0); 1012 pkey_assert(!err); 1013 } 1014 1015 void test_read_of_write_disabled_region(int *ptr, u16 pkey) 1016 { 1017 int ptr_contents; 1018 1019 dprintf1("disabling write access to PKEY[1], doing read\n"); 1020 pkey_write_deny(pkey); 1021 ptr_contents = read_ptr(ptr); 1022 dprintf1("*ptr: %d\n", ptr_contents); 1023 dprintf1("\n"); 1024 } 1025 void test_read_of_access_disabled_region(int *ptr, u16 pkey) 1026 { 1027 int ptr_contents; 1028 1029 dprintf1("disabling access to PKEY[%02d], doing read @ %p\n", pkey, ptr); 1030 read_pkey_reg(); 1031 pkey_access_deny(pkey); 1032 ptr_contents = read_ptr(ptr); 1033 dprintf1("*ptr: %d\n", ptr_contents); 1034 expected_pkey_fault(pkey); 1035 } 1036 1037 void test_read_of_access_disabled_region_with_page_already_mapped(int *ptr, 1038 u16 pkey) 1039 { 1040 int ptr_contents; 1041 1042 dprintf1("disabling access to PKEY[%02d], doing read @ %p\n", 1043 pkey, ptr); 1044 ptr_contents = read_ptr(ptr); 1045 dprintf1("reading ptr before disabling the read : %d\n", 1046 ptr_contents); 1047 read_pkey_reg(); 1048 pkey_access_deny(pkey); 1049 ptr_contents = read_ptr(ptr); 1050 dprintf1("*ptr: %d\n", ptr_contents); 1051 expected_pkey_fault(pkey); 1052 } 1053 1054 void test_write_of_write_disabled_region_with_page_already_mapped(int *ptr, 1055 u16 pkey) 1056 { 1057 *ptr = __LINE__; 1058 dprintf1("disabling write access; after accessing the page, " 1059 "to PKEY[%02d], doing write\n", pkey); 1060 pkey_write_deny(pkey); 1061 *ptr = __LINE__; 1062 expected_pkey_fault(pkey); 1063 } 1064 1065 void test_write_of_write_disabled_region(int *ptr, u16 pkey) 1066 { 1067 dprintf1("disabling write access to PKEY[%02d], doing write\n", pkey); 1068 pkey_write_deny(pkey); 1069 *ptr = __LINE__; 1070 expected_pkey_fault(pkey); 1071 } 1072 void test_write_of_access_disabled_region(int *ptr, u16 pkey) 1073 { 1074 dprintf1("disabling access to PKEY[%02d], doing write\n", pkey); 1075 pkey_access_deny(pkey); 1076 *ptr = __LINE__; 1077 expected_pkey_fault(pkey); 1078 } 1079 1080 void test_write_of_access_disabled_region_with_page_already_mapped(int *ptr, 1081 u16 pkey) 1082 { 1083 *ptr = __LINE__; 1084 dprintf1("disabling access; after accessing the page, " 1085 " to PKEY[%02d], doing write\n", pkey); 1086 pkey_access_deny(pkey); 1087 *ptr = __LINE__; 1088 expected_pkey_fault(pkey); 1089 } 1090 1091 void test_kernel_write_of_access_disabled_region(int *ptr, u16 pkey) 1092 { 1093 int ret; 1094 int test_fd = get_test_read_fd(); 1095 1096 dprintf1("disabling access to PKEY[%02d], " 1097 "having kernel read() to buffer\n", pkey); 1098 pkey_access_deny(pkey); 1099 ret = read(test_fd, ptr, 1); 1100 dprintf1("read ret: %d\n", ret); 1101 pkey_assert(ret); 1102 } 1103 void test_kernel_write_of_write_disabled_region(int *ptr, u16 pkey) 1104 { 1105 int ret; 1106 int test_fd = get_test_read_fd(); 1107 1108 pkey_write_deny(pkey); 1109 ret = read(test_fd, ptr, 100); 1110 dprintf1("read ret: %d\n", ret); 1111 if (ret < 0 && (DEBUG_LEVEL > 0)) 1112 perror("verbose read result (OK for this to be bad)"); 1113 pkey_assert(ret); 1114 } 1115 1116 void test_kernel_gup_of_access_disabled_region(int *ptr, u16 pkey) 1117 { 1118 int pipe_ret, vmsplice_ret; 1119 struct iovec iov; 1120 int pipe_fds[2]; 1121 1122 pipe_ret = pipe(pipe_fds); 1123 1124 pkey_assert(pipe_ret == 0); 1125 dprintf1("disabling access to PKEY[%02d], " 1126 "having kernel vmsplice from buffer\n", pkey); 1127 pkey_access_deny(pkey); 1128 iov.iov_base = ptr; 1129 iov.iov_len = PAGE_SIZE; 1130 vmsplice_ret = vmsplice(pipe_fds[1], &iov, 1, SPLICE_F_GIFT); 1131 dprintf1("vmsplice() ret: %d\n", vmsplice_ret); 1132 pkey_assert(vmsplice_ret == -1); 1133 1134 close(pipe_fds[0]); 1135 close(pipe_fds[1]); 1136 } 1137 1138 void test_kernel_gup_write_to_write_disabled_region(int *ptr, u16 pkey) 1139 { 1140 int ignored = 0xdada; 1141 int futex_ret; 1142 int some_int = __LINE__; 1143 1144 dprintf1("disabling write to PKEY[%02d], " 1145 "doing futex gunk in buffer\n", pkey); 1146 *ptr = some_int; 1147 pkey_write_deny(pkey); 1148 futex_ret = syscall(SYS_futex, ptr, FUTEX_WAIT, some_int-1, NULL, 1149 &ignored, ignored); 1150 if (DEBUG_LEVEL > 0) 1151 perror("futex"); 1152 dprintf1("futex() ret: %d\n", futex_ret); 1153 } 1154 1155 /* Assumes that all pkeys other than 'pkey' are unallocated */ 1156 void test_pkey_syscalls_on_non_allocated_pkey(int *ptr, u16 pkey) 1157 { 1158 int err; 1159 int i; 1160 1161 /* Note: 0 is the default pkey, so don't mess with it */ 1162 for (i = 1; i < NR_PKEYS; i++) { 1163 if (pkey == i) 1164 continue; 1165 1166 dprintf1("trying get/set/free to non-allocated pkey: %2d\n", i); 1167 err = sys_pkey_free(i); 1168 pkey_assert(err); 1169 1170 err = sys_pkey_free(i); 1171 pkey_assert(err); 1172 1173 err = sys_mprotect_pkey(ptr, PAGE_SIZE, PROT_READ, i); 1174 pkey_assert(err); 1175 } 1176 } 1177 1178 /* Assumes that all pkeys other than 'pkey' are unallocated */ 1179 void test_pkey_syscalls_bad_args(int *ptr, u16 pkey) 1180 { 1181 int err; 1182 int bad_pkey = NR_PKEYS+99; 1183 1184 /* pass a known-invalid pkey in: */ 1185 err = sys_mprotect_pkey(ptr, PAGE_SIZE, PROT_READ, bad_pkey); 1186 pkey_assert(err); 1187 } 1188 1189 void become_child(void) 1190 { 1191 pid_t forkret; 1192 1193 forkret = fork(); 1194 pkey_assert(forkret >= 0); 1195 dprintf3("[%d] fork() ret: %d\n", getpid(), forkret); 1196 1197 if (!forkret) { 1198 /* in the child */ 1199 return; 1200 } 1201 exit(0); 1202 } 1203 1204 /* Assumes that all pkeys other than 'pkey' are unallocated */ 1205 void test_pkey_alloc_exhaust(int *ptr, u16 pkey) 1206 { 1207 int err; 1208 int allocated_pkeys[NR_PKEYS] = {0}; 1209 int nr_allocated_pkeys = 0; 1210 int i; 1211 1212 for (i = 0; i < NR_PKEYS*3; i++) { 1213 int new_pkey; 1214 dprintf1("%s() alloc loop: %d\n", __func__, i); 1215 new_pkey = alloc_pkey(); 1216 dprintf4("%s()::%d, err: %d pkey_reg: 0x%016llx" 1217 " shadow: 0x%016llx\n", 1218 __func__, __LINE__, err, __read_pkey_reg(), 1219 shadow_pkey_reg); 1220 read_pkey_reg(); /* for shadow checking */ 1221 dprintf2("%s() errno: %d ENOSPC: %d\n", __func__, errno, ENOSPC); 1222 if ((new_pkey == -1) && (errno == ENOSPC)) { 1223 dprintf2("%s() failed to allocate pkey after %d tries\n", 1224 __func__, nr_allocated_pkeys); 1225 } else { 1226 /* 1227 * Ensure the number of successes never 1228 * exceeds the number of keys supported 1229 * in the hardware. 1230 */ 1231 pkey_assert(nr_allocated_pkeys < NR_PKEYS); 1232 allocated_pkeys[nr_allocated_pkeys++] = new_pkey; 1233 } 1234 1235 /* 1236 * Make sure that allocation state is properly 1237 * preserved across fork(). 1238 */ 1239 if (i == NR_PKEYS*2) 1240 become_child(); 1241 } 1242 1243 dprintf3("%s()::%d\n", __func__, __LINE__); 1244 1245 /* 1246 * On x86: 1247 * There are 16 pkeys supported in hardware. Three are 1248 * allocated by the time we get here: 1249 * 1. The default key (0) 1250 * 2. One possibly consumed by an execute-only mapping. 1251 * 3. One allocated by the test code and passed in via 1252 * 'pkey' to this function. 1253 * Ensure that we can allocate at least another 13 (16-3). 1254 * 1255 * On powerpc: 1256 * There are either 5, 28, 29 or 32 pkeys supported in 1257 * hardware depending on the page size (4K or 64K) and 1258 * platform (powernv or powervm). Four are allocated by 1259 * the time we get here. These include pkey-0, pkey-1, 1260 * exec-only pkey and the one allocated by the test code. 1261 * Ensure that we can allocate the remaining. 1262 */ 1263 pkey_assert(i >= (NR_PKEYS - get_arch_reserved_keys() - 1)); 1264 1265 for (i = 0; i < nr_allocated_pkeys; i++) { 1266 err = sys_pkey_free(allocated_pkeys[i]); 1267 pkey_assert(!err); 1268 read_pkey_reg(); /* for shadow checking */ 1269 } 1270 } 1271 1272 void arch_force_pkey_reg_init(void) 1273 { 1274 #if defined(__i386__) || defined(__x86_64__) /* arch */ 1275 u64 *buf; 1276 1277 /* 1278 * All keys should be allocated and set to allow reads and 1279 * writes, so the register should be all 0. If not, just 1280 * skip the test. 1281 */ 1282 if (read_pkey_reg()) 1283 return; 1284 1285 /* 1286 * Just allocate an absurd about of memory rather than 1287 * doing the XSAVE size enumeration dance. 1288 */ 1289 buf = mmap(NULL, 1*MB, PROT_READ|PROT_WRITE, MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 1290 1291 /* These __builtins require compiling with -mxsave */ 1292 1293 /* XSAVE to build a valid buffer: */ 1294 __builtin_ia32_xsave(buf, XSTATE_PKEY); 1295 /* Clear XSTATE_BV[PKRU]: */ 1296 buf[XSTATE_BV_OFFSET/sizeof(u64)] &= ~XSTATE_PKEY; 1297 /* XRSTOR will likely get PKRU back to the init state: */ 1298 __builtin_ia32_xrstor(buf, XSTATE_PKEY); 1299 1300 munmap(buf, 1*MB); 1301 #endif 1302 } 1303 1304 1305 /* 1306 * This is mostly useless on ppc for now. But it will not 1307 * hurt anything and should give some better coverage as 1308 * a long-running test that continually checks the pkey 1309 * register. 1310 */ 1311 void test_pkey_init_state(int *ptr, u16 pkey) 1312 { 1313 int err; 1314 int allocated_pkeys[NR_PKEYS] = {0}; 1315 int nr_allocated_pkeys = 0; 1316 int i; 1317 1318 for (i = 0; i < NR_PKEYS; i++) { 1319 int new_pkey = alloc_pkey(); 1320 1321 if (new_pkey < 0) 1322 continue; 1323 allocated_pkeys[nr_allocated_pkeys++] = new_pkey; 1324 } 1325 1326 dprintf3("%s()::%d\n", __func__, __LINE__); 1327 1328 arch_force_pkey_reg_init(); 1329 1330 /* 1331 * Loop for a bit, hoping to get exercise the kernel 1332 * context switch code. 1333 */ 1334 for (i = 0; i < 1000000; i++) 1335 read_pkey_reg(); 1336 1337 for (i = 0; i < nr_allocated_pkeys; i++) { 1338 err = sys_pkey_free(allocated_pkeys[i]); 1339 pkey_assert(!err); 1340 read_pkey_reg(); /* for shadow checking */ 1341 } 1342 } 1343 1344 /* 1345 * pkey 0 is special. It is allocated by default, so you do not 1346 * have to call pkey_alloc() to use it first. Make sure that it 1347 * is usable. 1348 */ 1349 void test_mprotect_with_pkey_0(int *ptr, u16 pkey) 1350 { 1351 long size; 1352 int prot; 1353 1354 assert(pkey_last_malloc_record); 1355 size = pkey_last_malloc_record->size; 1356 /* 1357 * This is a bit of a hack. But mprotect() requires 1358 * huge-page-aligned sizes when operating on hugetlbfs. 1359 * So, make sure that we use something that's a multiple 1360 * of a huge page when we can. 1361 */ 1362 if (size >= HPAGE_SIZE) 1363 size = HPAGE_SIZE; 1364 prot = pkey_last_malloc_record->prot; 1365 1366 /* Use pkey 0 */ 1367 mprotect_pkey(ptr, size, prot, 0); 1368 1369 /* Make sure that we can set it back to the original pkey. */ 1370 mprotect_pkey(ptr, size, prot, pkey); 1371 } 1372 1373 void test_ptrace_of_child(int *ptr, u16 pkey) 1374 { 1375 __attribute__((__unused__)) int peek_result; 1376 pid_t child_pid; 1377 void *ignored = 0; 1378 long ret; 1379 int status; 1380 /* 1381 * This is the "control" for our little expermient. Make sure 1382 * we can always access it when ptracing. 1383 */ 1384 int *plain_ptr_unaligned = malloc(HPAGE_SIZE); 1385 int *plain_ptr = ALIGN_PTR_UP(plain_ptr_unaligned, PAGE_SIZE); 1386 1387 /* 1388 * Fork a child which is an exact copy of this process, of course. 1389 * That means we can do all of our tests via ptrace() and then plain 1390 * memory access and ensure they work differently. 1391 */ 1392 child_pid = fork_lazy_child(); 1393 dprintf1("[%d] child pid: %d\n", getpid(), child_pid); 1394 1395 ret = ptrace(PTRACE_ATTACH, child_pid, ignored, ignored); 1396 if (ret) 1397 perror("attach"); 1398 dprintf1("[%d] attach ret: %ld %d\n", getpid(), ret, __LINE__); 1399 pkey_assert(ret != -1); 1400 ret = waitpid(child_pid, &status, WUNTRACED); 1401 if ((ret != child_pid) || !(WIFSTOPPED(status))) { 1402 fprintf(stderr, "weird waitpid result %ld stat %x\n", 1403 ret, status); 1404 pkey_assert(0); 1405 } 1406 dprintf2("waitpid ret: %ld\n", ret); 1407 dprintf2("waitpid status: %d\n", status); 1408 1409 pkey_access_deny(pkey); 1410 pkey_write_deny(pkey); 1411 1412 /* Write access, untested for now: 1413 ret = ptrace(PTRACE_POKEDATA, child_pid, peek_at, data); 1414 pkey_assert(ret != -1); 1415 dprintf1("poke at %p: %ld\n", peek_at, ret); 1416 */ 1417 1418 /* 1419 * Try to access the pkey-protected "ptr" via ptrace: 1420 */ 1421 ret = ptrace(PTRACE_PEEKDATA, child_pid, ptr, ignored); 1422 /* expect it to work, without an error: */ 1423 pkey_assert(ret != -1); 1424 /* Now access from the current task, and expect an exception: */ 1425 peek_result = read_ptr(ptr); 1426 expected_pkey_fault(pkey); 1427 1428 /* 1429 * Try to access the NON-pkey-protected "plain_ptr" via ptrace: 1430 */ 1431 ret = ptrace(PTRACE_PEEKDATA, child_pid, plain_ptr, ignored); 1432 /* expect it to work, without an error: */ 1433 pkey_assert(ret != -1); 1434 /* Now access from the current task, and expect NO exception: */ 1435 peek_result = read_ptr(plain_ptr); 1436 do_not_expect_pkey_fault("read plain pointer after ptrace"); 1437 1438 ret = ptrace(PTRACE_DETACH, child_pid, ignored, 0); 1439 pkey_assert(ret != -1); 1440 1441 ret = kill(child_pid, SIGKILL); 1442 pkey_assert(ret != -1); 1443 1444 wait(&status); 1445 1446 free(plain_ptr_unaligned); 1447 } 1448 1449 void *get_pointer_to_instructions(void) 1450 { 1451 void *p1; 1452 1453 p1 = ALIGN_PTR_UP(&lots_o_noops_around_write, PAGE_SIZE); 1454 dprintf3("&lots_o_noops: %p\n", &lots_o_noops_around_write); 1455 /* lots_o_noops_around_write should be page-aligned already */ 1456 assert(p1 == &lots_o_noops_around_write); 1457 1458 /* Point 'p1' at the *second* page of the function: */ 1459 p1 += PAGE_SIZE; 1460 1461 /* 1462 * Try to ensure we fault this in on next touch to ensure 1463 * we get an instruction fault as opposed to a data one 1464 */ 1465 madvise(p1, PAGE_SIZE, MADV_DONTNEED); 1466 1467 return p1; 1468 } 1469 1470 void test_executing_on_unreadable_memory(int *ptr, u16 pkey) 1471 { 1472 void *p1; 1473 int scratch; 1474 int ptr_contents; 1475 int ret; 1476 1477 p1 = get_pointer_to_instructions(); 1478 lots_o_noops_around_write(&scratch); 1479 ptr_contents = read_ptr(p1); 1480 dprintf2("ptr (%p) contents@%d: %x\n", p1, __LINE__, ptr_contents); 1481 1482 ret = mprotect_pkey(p1, PAGE_SIZE, PROT_EXEC, (u64)pkey); 1483 pkey_assert(!ret); 1484 pkey_access_deny(pkey); 1485 1486 dprintf2("pkey_reg: %016llx\n", read_pkey_reg()); 1487 1488 /* 1489 * Make sure this is an *instruction* fault 1490 */ 1491 madvise(p1, PAGE_SIZE, MADV_DONTNEED); 1492 lots_o_noops_around_write(&scratch); 1493 do_not_expect_pkey_fault("executing on PROT_EXEC memory"); 1494 expect_fault_on_read_execonly_key(p1, pkey); 1495 } 1496 1497 void test_implicit_mprotect_exec_only_memory(int *ptr, u16 pkey) 1498 { 1499 void *p1; 1500 int scratch; 1501 int ptr_contents; 1502 int ret; 1503 1504 dprintf1("%s() start\n", __func__); 1505 1506 p1 = get_pointer_to_instructions(); 1507 lots_o_noops_around_write(&scratch); 1508 ptr_contents = read_ptr(p1); 1509 dprintf2("ptr (%p) contents@%d: %x\n", p1, __LINE__, ptr_contents); 1510 1511 /* Use a *normal* mprotect(), not mprotect_pkey(): */ 1512 ret = mprotect(p1, PAGE_SIZE, PROT_EXEC); 1513 pkey_assert(!ret); 1514 1515 /* 1516 * Reset the shadow, assuming that the above mprotect() 1517 * correctly changed PKRU, but to an unknown value since 1518 * the actual allocated pkey is unknown. 1519 */ 1520 shadow_pkey_reg = __read_pkey_reg(); 1521 1522 dprintf2("pkey_reg: %016llx\n", read_pkey_reg()); 1523 1524 /* Make sure this is an *instruction* fault */ 1525 madvise(p1, PAGE_SIZE, MADV_DONTNEED); 1526 lots_o_noops_around_write(&scratch); 1527 do_not_expect_pkey_fault("executing on PROT_EXEC memory"); 1528 expect_fault_on_read_execonly_key(p1, UNKNOWN_PKEY); 1529 1530 /* 1531 * Put the memory back to non-PROT_EXEC. Should clear the 1532 * exec-only pkey off the VMA and allow it to be readable 1533 * again. Go to PROT_NONE first to check for a kernel bug 1534 * that did not clear the pkey when doing PROT_NONE. 1535 */ 1536 ret = mprotect(p1, PAGE_SIZE, PROT_NONE); 1537 pkey_assert(!ret); 1538 1539 ret = mprotect(p1, PAGE_SIZE, PROT_READ|PROT_EXEC); 1540 pkey_assert(!ret); 1541 ptr_contents = read_ptr(p1); 1542 do_not_expect_pkey_fault("plain read on recently PROT_EXEC area"); 1543 } 1544 1545 #if defined(__i386__) || defined(__x86_64__) 1546 void test_ptrace_modifies_pkru(int *ptr, u16 pkey) 1547 { 1548 u32 new_pkru; 1549 pid_t child; 1550 int status, ret; 1551 int pkey_offset = pkey_reg_xstate_offset(); 1552 size_t xsave_size = cpu_max_xsave_size(); 1553 void *xsave; 1554 u32 *pkey_register; 1555 u64 *xstate_bv; 1556 struct iovec iov; 1557 1558 new_pkru = ~read_pkey_reg(); 1559 /* Don't make PROT_EXEC mappings inaccessible */ 1560 new_pkru &= ~3; 1561 1562 child = fork(); 1563 pkey_assert(child >= 0); 1564 dprintf3("[%d] fork() ret: %d\n", getpid(), child); 1565 if (!child) { 1566 ptrace(PTRACE_TRACEME, 0, 0, 0); 1567 /* Stop and allow the tracer to modify PKRU directly */ 1568 raise(SIGSTOP); 1569 1570 /* 1571 * need __read_pkey_reg() version so we do not do shadow_pkey_reg 1572 * checking 1573 */ 1574 if (__read_pkey_reg() != new_pkru) 1575 exit(1); 1576 1577 /* Stop and allow the tracer to clear XSTATE_BV for PKRU */ 1578 raise(SIGSTOP); 1579 1580 if (__read_pkey_reg() != 0) 1581 exit(1); 1582 1583 /* Stop and allow the tracer to examine PKRU */ 1584 raise(SIGSTOP); 1585 1586 exit(0); 1587 } 1588 1589 pkey_assert(child == waitpid(child, &status, 0)); 1590 dprintf3("[%d] waitpid(%d) status: %x\n", getpid(), child, status); 1591 pkey_assert(WIFSTOPPED(status) && WSTOPSIG(status) == SIGSTOP); 1592 1593 xsave = (void *)malloc(xsave_size); 1594 pkey_assert(xsave > 0); 1595 1596 /* Modify the PKRU register directly */ 1597 iov.iov_base = xsave; 1598 iov.iov_len = xsave_size; 1599 ret = ptrace(PTRACE_GETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1600 pkey_assert(ret == 0); 1601 1602 pkey_register = (u32 *)(xsave + pkey_offset); 1603 pkey_assert(*pkey_register == read_pkey_reg()); 1604 1605 *pkey_register = new_pkru; 1606 1607 ret = ptrace(PTRACE_SETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1608 pkey_assert(ret == 0); 1609 1610 /* Test that the modification is visible in ptrace before any execution */ 1611 memset(xsave, 0xCC, xsave_size); 1612 ret = ptrace(PTRACE_GETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1613 pkey_assert(ret == 0); 1614 pkey_assert(*pkey_register == new_pkru); 1615 1616 /* Execute the tracee */ 1617 ret = ptrace(PTRACE_CONT, child, 0, 0); 1618 pkey_assert(ret == 0); 1619 1620 /* Test that the tracee saw the PKRU value change */ 1621 pkey_assert(child == waitpid(child, &status, 0)); 1622 dprintf3("[%d] waitpid(%d) status: %x\n", getpid(), child, status); 1623 pkey_assert(WIFSTOPPED(status) && WSTOPSIG(status) == SIGSTOP); 1624 1625 /* Test that the modification is visible in ptrace after execution */ 1626 memset(xsave, 0xCC, xsave_size); 1627 ret = ptrace(PTRACE_GETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1628 pkey_assert(ret == 0); 1629 pkey_assert(*pkey_register == new_pkru); 1630 1631 /* Clear the PKRU bit from XSTATE_BV */ 1632 xstate_bv = (u64 *)(xsave + 512); 1633 *xstate_bv &= ~(1 << 9); 1634 1635 ret = ptrace(PTRACE_SETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1636 pkey_assert(ret == 0); 1637 1638 /* Test that the modification is visible in ptrace before any execution */ 1639 memset(xsave, 0xCC, xsave_size); 1640 ret = ptrace(PTRACE_GETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1641 pkey_assert(ret == 0); 1642 pkey_assert(*pkey_register == 0); 1643 1644 ret = ptrace(PTRACE_CONT, child, 0, 0); 1645 pkey_assert(ret == 0); 1646 1647 /* Test that the tracee saw the PKRU value go to 0 */ 1648 pkey_assert(child == waitpid(child, &status, 0)); 1649 dprintf3("[%d] waitpid(%d) status: %x\n", getpid(), child, status); 1650 pkey_assert(WIFSTOPPED(status) && WSTOPSIG(status) == SIGSTOP); 1651 1652 /* Test that the modification is visible in ptrace after execution */ 1653 memset(xsave, 0xCC, xsave_size); 1654 ret = ptrace(PTRACE_GETREGSET, child, (void *)NT_X86_XSTATE, &iov); 1655 pkey_assert(ret == 0); 1656 pkey_assert(*pkey_register == 0); 1657 1658 ret = ptrace(PTRACE_CONT, child, 0, 0); 1659 pkey_assert(ret == 0); 1660 pkey_assert(child == waitpid(child, &status, 0)); 1661 dprintf3("[%d] waitpid(%d) status: %x\n", getpid(), child, status); 1662 pkey_assert(WIFEXITED(status)); 1663 pkey_assert(WEXITSTATUS(status) == 0); 1664 free(xsave); 1665 } 1666 #endif 1667 1668 void test_mprotect_pkey_on_unsupported_cpu(int *ptr, u16 pkey) 1669 { 1670 int size = PAGE_SIZE; 1671 int sret; 1672 1673 if (cpu_has_pkeys()) { 1674 dprintf1("SKIP: %s: no CPU support\n", __func__); 1675 return; 1676 } 1677 1678 sret = syscall(__NR_pkey_mprotect, ptr, size, PROT_READ, pkey); 1679 pkey_assert(sret < 0); 1680 } 1681 1682 void (*pkey_tests[])(int *ptr, u16 pkey) = { 1683 test_read_of_write_disabled_region, 1684 test_read_of_access_disabled_region, 1685 test_read_of_access_disabled_region_with_page_already_mapped, 1686 test_write_of_write_disabled_region, 1687 test_write_of_write_disabled_region_with_page_already_mapped, 1688 test_write_of_access_disabled_region, 1689 test_write_of_access_disabled_region_with_page_already_mapped, 1690 test_kernel_write_of_access_disabled_region, 1691 test_kernel_write_of_write_disabled_region, 1692 test_kernel_gup_of_access_disabled_region, 1693 test_kernel_gup_write_to_write_disabled_region, 1694 test_executing_on_unreadable_memory, 1695 test_implicit_mprotect_exec_only_memory, 1696 test_mprotect_with_pkey_0, 1697 test_ptrace_of_child, 1698 test_pkey_init_state, 1699 test_pkey_syscalls_on_non_allocated_pkey, 1700 test_pkey_syscalls_bad_args, 1701 test_pkey_alloc_exhaust, 1702 test_pkey_alloc_free_attach_pkey0, 1703 #if defined(__i386__) || defined(__x86_64__) 1704 test_ptrace_modifies_pkru, 1705 #endif 1706 }; 1707 1708 void run_tests_once(void) 1709 { 1710 int *ptr; 1711 int prot = PROT_READ|PROT_WRITE; 1712 1713 for (test_nr = 0; test_nr < ARRAY_SIZE(pkey_tests); test_nr++) { 1714 int pkey; 1715 int orig_pkey_faults = pkey_faults; 1716 1717 dprintf1("======================\n"); 1718 dprintf1("test %d preparing...\n", test_nr); 1719 1720 tracing_on(); 1721 pkey = alloc_random_pkey(); 1722 dprintf1("test %d starting with pkey: %d\n", test_nr, pkey); 1723 ptr = malloc_pkey(PAGE_SIZE, prot, pkey); 1724 dprintf1("test %d starting...\n", test_nr); 1725 pkey_tests[test_nr](ptr, pkey); 1726 dprintf1("freeing test memory: %p\n", ptr); 1727 free_pkey_malloc(ptr); 1728 sys_pkey_free(pkey); 1729 1730 dprintf1("pkey_faults: %d\n", pkey_faults); 1731 dprintf1("orig_pkey_faults: %d\n", orig_pkey_faults); 1732 1733 tracing_off(); 1734 close_test_fds(); 1735 1736 printf("test %2d PASSED (iteration %d)\n", test_nr, iteration_nr); 1737 dprintf1("======================\n\n"); 1738 } 1739 iteration_nr++; 1740 } 1741 1742 void pkey_setup_shadow(void) 1743 { 1744 shadow_pkey_reg = __read_pkey_reg(); 1745 } 1746 1747 int main(void) 1748 { 1749 int nr_iterations = 22; 1750 int pkeys_supported = is_pkeys_supported(); 1751 1752 srand((unsigned int)time(NULL)); 1753 1754 setup_handlers(); 1755 1756 printf("has pkeys: %d\n", pkeys_supported); 1757 1758 if (!pkeys_supported) { 1759 int size = PAGE_SIZE; 1760 int *ptr; 1761 1762 printf("running PKEY tests for unsupported CPU/OS\n"); 1763 1764 ptr = mmap(NULL, size, PROT_NONE, MAP_ANONYMOUS|MAP_PRIVATE, -1, 0); 1765 assert(ptr != (void *)-1); 1766 test_mprotect_pkey_on_unsupported_cpu(ptr, 1); 1767 exit(0); 1768 } 1769 1770 pkey_setup_shadow(); 1771 printf("startup pkey_reg: %016llx\n", read_pkey_reg()); 1772 setup_hugetlbfs(); 1773 1774 while (nr_iterations-- > 0) 1775 run_tests_once(); 1776 1777 printf("done (all tests OK)\n"); 1778 return 0; 1779 } 1780