1 /*- 2 * Copyright (c) 1989, 1992, 1993 3 * The Regents of the University of California. All rights reserved. 4 * 5 * This code is derived from software developed by the Computer Systems 6 * Engineering group at Lawrence Berkeley Laboratory under DARPA contract 7 * BG 91-66 and contributed to Berkeley. 8 * 9 * Redistribution and use in source and binary forms, with or without 10 * modification, are permitted provided that the following conditions 11 * are met: 12 * 1. Redistributions of source code must retain the above copyright 13 * notice, this list of conditions and the following disclaimer. 14 * 2. Redistributions in binary form must reproduce the above copyright 15 * notice, this list of conditions and the following disclaimer in the 16 * documentation and/or other materials provided with the distribution. 17 * 3. Neither the name of the University nor the names of its contributors 18 * may be used to endorse or promote products derived from this software 19 * without specific prior written permission. 20 * 21 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 22 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 23 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 24 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 25 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 26 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 27 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 28 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 29 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 30 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 31 * SUCH DAMAGE. 32 */ 33 34 #include <sys/cdefs.h> 35 __FBSDID("$FreeBSD$"); 36 37 #include <sys/param.h> 38 #include <sys/fnv_hash.h> 39 40 #define _WANT_VNET 41 42 #include <sys/user.h> 43 #include <sys/linker.h> 44 #include <sys/pcpu.h> 45 #include <sys/stat.h> 46 #include <sys/mman.h> 47 48 #include <stdbool.h> 49 #include <net/vnet.h> 50 51 #include <assert.h> 52 #include <fcntl.h> 53 #include <vm/vm.h> 54 #include <kvm.h> 55 #include <limits.h> 56 #include <paths.h> 57 #include <stdint.h> 58 #include <stdio.h> 59 #include <stdlib.h> 60 #include <string.h> 61 #include <unistd.h> 62 #include <stdarg.h> 63 #include <inttypes.h> 64 65 #include "kvm_private.h" 66 67 /* 68 * Routines private to libkvm. 69 */ 70 71 /* from src/lib/libc/gen/nlist.c */ 72 int __fdnlist(int, struct nlist *); 73 74 /* 75 * Report an error using printf style arguments. "program" is kd->program 76 * on hard errors, and 0 on soft errors, so that under sun error emulation, 77 * only hard errors are printed out (otherwise, programs like gdb will 78 * generate tons of error messages when trying to access bogus pointers). 79 */ 80 void 81 _kvm_err(kvm_t *kd, const char *program, const char *fmt, ...) 82 { 83 va_list ap; 84 85 va_start(ap, fmt); 86 if (program != NULL) { 87 (void)fprintf(stderr, "%s: ", program); 88 (void)vfprintf(stderr, fmt, ap); 89 (void)fputc('\n', stderr); 90 } else 91 (void)vsnprintf(kd->errbuf, 92 sizeof(kd->errbuf), fmt, ap); 93 94 va_end(ap); 95 } 96 97 void 98 _kvm_syserr(kvm_t *kd, const char *program, const char *fmt, ...) 99 { 100 va_list ap; 101 int n; 102 103 va_start(ap, fmt); 104 if (program != NULL) { 105 (void)fprintf(stderr, "%s: ", program); 106 (void)vfprintf(stderr, fmt, ap); 107 (void)fprintf(stderr, ": %s\n", strerror(errno)); 108 } else { 109 char *cp = kd->errbuf; 110 111 (void)vsnprintf(cp, sizeof(kd->errbuf), fmt, ap); 112 n = strlen(cp); 113 (void)snprintf(&cp[n], sizeof(kd->errbuf) - n, ": %s", 114 strerror(errno)); 115 } 116 va_end(ap); 117 } 118 119 void * 120 _kvm_malloc(kvm_t *kd, size_t n) 121 { 122 void *p; 123 124 if ((p = calloc(n, sizeof(char))) == NULL) 125 _kvm_err(kd, kd->program, "can't allocate %zu bytes: %s", 126 n, strerror(errno)); 127 return (p); 128 } 129 130 int 131 _kvm_probe_elf_kernel(kvm_t *kd, int class, int machine) 132 { 133 134 return (kd->nlehdr.e_ident[EI_CLASS] == class && 135 ((machine == EM_PPC || machine == EM_PPC64) ? 136 kd->nlehdr.e_type == ET_DYN : kd->nlehdr.e_type == ET_EXEC) && 137 kd->nlehdr.e_machine == machine); 138 } 139 140 int 141 _kvm_is_minidump(kvm_t *kd) 142 { 143 char minihdr[8]; 144 145 if (kd->rawdump) 146 return (0); 147 if (pread(kd->pmfd, &minihdr, 8, 0) == 8 && 148 memcmp(&minihdr, "minidump", 8) == 0) 149 return (1); 150 return (0); 151 } 152 153 /* 154 * The powerpc backend has a hack to strip a leading kerneldump 155 * header from the core before treating it as an ELF header. 156 * 157 * We can add that here if we can get a change to libelf to support 158 * an initial offset into the file. Alternatively we could patch 159 * savecore to extract cores from a regular file instead. 160 */ 161 int 162 _kvm_read_core_phdrs(kvm_t *kd, size_t *phnump, GElf_Phdr **phdrp) 163 { 164 GElf_Ehdr ehdr; 165 GElf_Phdr *phdr; 166 Elf *elf; 167 size_t i, phnum; 168 169 elf = elf_begin(kd->pmfd, ELF_C_READ, NULL); 170 if (elf == NULL) { 171 _kvm_err(kd, kd->program, "%s", elf_errmsg(0)); 172 return (-1); 173 } 174 if (elf_kind(elf) != ELF_K_ELF) { 175 _kvm_err(kd, kd->program, "invalid core"); 176 goto bad; 177 } 178 if (gelf_getclass(elf) != kd->nlehdr.e_ident[EI_CLASS]) { 179 _kvm_err(kd, kd->program, "invalid core"); 180 goto bad; 181 } 182 if (gelf_getehdr(elf, &ehdr) == NULL) { 183 _kvm_err(kd, kd->program, "%s", elf_errmsg(0)); 184 goto bad; 185 } 186 if (ehdr.e_type != ET_CORE) { 187 _kvm_err(kd, kd->program, "invalid core"); 188 goto bad; 189 } 190 if (ehdr.e_machine != kd->nlehdr.e_machine) { 191 _kvm_err(kd, kd->program, "invalid core"); 192 goto bad; 193 } 194 195 if (elf_getphdrnum(elf, &phnum) == -1) { 196 _kvm_err(kd, kd->program, "%s", elf_errmsg(0)); 197 goto bad; 198 } 199 200 phdr = calloc(phnum, sizeof(*phdr)); 201 if (phdr == NULL) { 202 _kvm_err(kd, kd->program, "failed to allocate phdrs"); 203 goto bad; 204 } 205 206 for (i = 0; i < phnum; i++) { 207 if (gelf_getphdr(elf, i, &phdr[i]) == NULL) { 208 free(phdr); 209 _kvm_err(kd, kd->program, "%s", elf_errmsg(0)); 210 goto bad; 211 } 212 } 213 elf_end(elf); 214 *phnump = phnum; 215 *phdrp = phdr; 216 return (0); 217 218 bad: 219 elf_end(elf); 220 return (-1); 221 } 222 223 /* 224 * Transform v such that only bits [bit0, bitN) may be set. Generates a 225 * bitmask covering the number of bits, then shifts so +bit0+ is the first. 226 */ 227 static uint64_t 228 bitmask_range(uint64_t v, uint64_t bit0, uint64_t bitN) 229 { 230 if (bit0 == 0 && bitN == BITS_IN(v)) 231 return (v); 232 233 return (v & (((1ULL << (bitN - bit0)) - 1ULL) << bit0)); 234 } 235 236 /* 237 * Returns the number of bits in a given byte array range starting at a 238 * given base, from bit0 to bitN. bit0 may be non-zero in the case of 239 * counting backwards from bitN. 240 */ 241 static uint64_t 242 popcount_bytes(uint64_t *addr, uint32_t bit0, uint32_t bitN) 243 { 244 uint32_t res = bitN - bit0; 245 uint64_t count = 0; 246 uint32_t bound; 247 248 /* Align to 64-bit boundary on the left side if needed. */ 249 if ((bit0 % BITS_IN(*addr)) != 0) { 250 bound = MIN(bitN, roundup2(bit0, BITS_IN(*addr))); 251 count += __bitcount64(bitmask_range(*addr, bit0, bound)); 252 res -= (bound - bit0); 253 addr++; 254 } 255 256 while (res > 0) { 257 bound = MIN(res, BITS_IN(*addr)); 258 count += __bitcount64(bitmask_range(*addr, 0, bound)); 259 res -= bound; 260 addr++; 261 } 262 263 return (count); 264 } 265 266 void * 267 _kvm_pmap_get(kvm_t *kd, u_long idx, size_t len) 268 { 269 uintptr_t off = idx * len; 270 271 if ((off_t)off >= kd->pt_sparse_off) 272 return (NULL); 273 return (void *)((uintptr_t)kd->page_map + off); 274 } 275 276 void * 277 _kvm_map_get(kvm_t *kd, u_long pa, unsigned int page_size) 278 { 279 off_t off; 280 uintptr_t addr; 281 282 off = _kvm_pt_find(kd, pa, page_size); 283 if (off == -1) 284 return NULL; 285 286 addr = (uintptr_t)kd->page_map + off; 287 if (off >= kd->pt_sparse_off) 288 addr = (uintptr_t)kd->sparse_map + (off - kd->pt_sparse_off); 289 return (void *)addr; 290 } 291 292 int 293 _kvm_pt_init(kvm_t *kd, size_t dump_avail_size, off_t dump_avail_off, 294 size_t map_len, off_t map_off, off_t sparse_off, int page_size) 295 { 296 uint64_t *addr; 297 uint32_t *popcount_bin; 298 int bin_popcounts = 0; 299 uint64_t pc_bins, res; 300 ssize_t rd; 301 302 kd->dump_avail_size = dump_avail_size; 303 if (dump_avail_size > 0) { 304 kd->dump_avail = mmap(NULL, kd->dump_avail_size, PROT_READ, 305 MAP_PRIVATE, kd->pmfd, dump_avail_off); 306 } else { 307 /* 308 * Older version minidumps don't provide dump_avail[], 309 * so the bitmap is fully populated from 0 to 310 * last_pa. Create an implied dump_avail that 311 * expresses this. 312 */ 313 kd->dump_avail = calloc(4, sizeof(uint64_t)); 314 kd->dump_avail[1] = _kvm64toh(kd, map_len * 8 * page_size); 315 } 316 317 /* 318 * Map the bitmap specified by the arguments. 319 */ 320 kd->pt_map = _kvm_malloc(kd, map_len); 321 if (kd->pt_map == NULL) { 322 _kvm_err(kd, kd->program, "cannot allocate %zu bytes for bitmap", 323 map_len); 324 return (-1); 325 } 326 rd = pread(kd->pmfd, kd->pt_map, map_len, map_off); 327 if (rd < 0 || rd != (ssize_t)map_len) { 328 _kvm_err(kd, kd->program, "cannot read %zu bytes for bitmap", 329 map_len); 330 return (-1); 331 } 332 kd->pt_map_size = map_len; 333 334 /* 335 * Generate a popcount cache for every POPCOUNT_BITS in the bitmap, 336 * so lookups only have to calculate the number of bits set between 337 * a cache point and their bit. This reduces lookups to O(1), 338 * without significantly increasing memory requirements. 339 * 340 * Round up the number of bins so that 'upper half' lookups work for 341 * the final bin, if needed. The first popcount is 0, since no bits 342 * precede bit 0, so add 1 for that also. Without this, extra work 343 * would be needed to handle the first PTEs in _kvm_pt_find(). 344 */ 345 addr = kd->pt_map; 346 res = map_len; 347 pc_bins = 1 + (res * NBBY + POPCOUNT_BITS / 2) / POPCOUNT_BITS; 348 kd->pt_popcounts = calloc(pc_bins, sizeof(uint32_t)); 349 if (kd->pt_popcounts == NULL) { 350 _kvm_err(kd, kd->program, "cannot allocate popcount bins"); 351 return (-1); 352 } 353 354 for (popcount_bin = &kd->pt_popcounts[1]; res > 0; 355 addr++, res -= sizeof(*addr)) { 356 *popcount_bin += popcount_bytes(addr, 0, 357 MIN(res * NBBY, BITS_IN(*addr))); 358 if (++bin_popcounts == POPCOUNTS_IN(*addr)) { 359 popcount_bin++; 360 *popcount_bin = *(popcount_bin - 1); 361 bin_popcounts = 0; 362 } 363 } 364 365 assert(pc_bins * sizeof(*popcount_bin) == 366 ((uintptr_t)popcount_bin - (uintptr_t)kd->pt_popcounts)); 367 368 kd->pt_sparse_off = sparse_off; 369 kd->pt_sparse_size = (uint64_t)*popcount_bin * page_size; 370 kd->pt_page_size = page_size; 371 372 /* 373 * Map the sparse page array. This is useful for performing point 374 * lookups of specific pages, e.g. for kvm_walk_pages. Generally, 375 * this is much larger than is reasonable to read in up front, so 376 * mmap it in instead. 377 */ 378 kd->sparse_map = mmap(NULL, kd->pt_sparse_size, PROT_READ, 379 MAP_PRIVATE, kd->pmfd, kd->pt_sparse_off); 380 if (kd->sparse_map == MAP_FAILED) { 381 _kvm_err(kd, kd->program, "cannot map %" PRIu64 382 " bytes from fd %d offset %jd for sparse map: %s", 383 kd->pt_sparse_size, kd->pmfd, 384 (intmax_t)kd->pt_sparse_off, strerror(errno)); 385 return (-1); 386 } 387 return (0); 388 } 389 390 int 391 _kvm_pmap_init(kvm_t *kd, uint32_t pmap_size, off_t pmap_off) 392 { 393 ssize_t exp_len = pmap_size; 394 395 kd->page_map_size = pmap_size; 396 kd->page_map_off = pmap_off; 397 kd->page_map = _kvm_malloc(kd, pmap_size); 398 if (kd->page_map == NULL) { 399 _kvm_err(kd, kd->program, "cannot allocate %u bytes " 400 "for page map", pmap_size); 401 return (-1); 402 } 403 if (pread(kd->pmfd, kd->page_map, pmap_size, pmap_off) != exp_len) { 404 _kvm_err(kd, kd->program, "cannot read %d bytes from " 405 "offset %jd for page map", pmap_size, (intmax_t)pmap_off); 406 return (-1); 407 } 408 return (0); 409 } 410 411 static inline uint64_t 412 dump_avail_n(kvm_t *kd, long i) 413 { 414 return (_kvm64toh(kd, kd->dump_avail[i])); 415 } 416 417 uint64_t 418 _kvm_pa_bit_id(kvm_t *kd, uint64_t pa, unsigned int page_size) 419 { 420 uint64_t adj; 421 long i; 422 423 adj = 0; 424 for (i = 0; dump_avail_n(kd, i + 1) != 0; i += 2) { 425 if (pa >= dump_avail_n(kd, i + 1)) { 426 adj += howmany(dump_avail_n(kd, i + 1), page_size) - 427 dump_avail_n(kd, i) / page_size; 428 } else { 429 return (pa / page_size - 430 dump_avail_n(kd, i) / page_size + adj); 431 } 432 } 433 return (_KVM_BIT_ID_INVALID); 434 } 435 436 uint64_t 437 _kvm_bit_id_pa(kvm_t *kd, uint64_t bit_id, unsigned int page_size) 438 { 439 uint64_t sz; 440 long i; 441 442 for (i = 0; dump_avail_n(kd, i + 1) != 0; i += 2) { 443 sz = howmany(dump_avail_n(kd, i + 1), page_size) - 444 dump_avail_n(kd, i) / page_size; 445 if (bit_id < sz) { 446 return (rounddown2(dump_avail_n(kd, i), page_size) + 447 bit_id * page_size); 448 } 449 bit_id -= sz; 450 } 451 return (_KVM_PA_INVALID); 452 } 453 454 /* 455 * Find the offset for the given physical page address; returns -1 otherwise. 456 * 457 * A page's offset is represented by the sparse page base offset plus the 458 * number of bits set before its bit multiplied by page size. This means 459 * that if a page exists in the dump, it's necessary to know how many pages 460 * in the dump precede it. Reduce this O(n) counting to O(1) by caching the 461 * number of bits set at POPCOUNT_BITS intervals. 462 * 463 * Then to find the number of pages before the requested address, simply 464 * index into the cache and count the number of bits set between that cache 465 * bin and the page's bit. Halve the number of bytes that have to be 466 * checked by also counting down from the next higher bin if it's closer. 467 */ 468 off_t 469 _kvm_pt_find(kvm_t *kd, uint64_t pa, unsigned int page_size) 470 { 471 uint64_t *bitmap = kd->pt_map; 472 uint64_t pte_bit_id = _kvm_pa_bit_id(kd, pa, page_size); 473 uint64_t pte_u64 = pte_bit_id / BITS_IN(*bitmap); 474 uint64_t popcount_id = pte_bit_id / POPCOUNT_BITS; 475 uint64_t pte_mask = 1ULL << (pte_bit_id % BITS_IN(*bitmap)); 476 uint64_t bitN; 477 uint32_t count; 478 479 /* Check whether the page address requested is in the dump. */ 480 if (pte_bit_id == _KVM_BIT_ID_INVALID || 481 pte_bit_id >= (kd->pt_map_size * NBBY) || 482 (bitmap[pte_u64] & pte_mask) == 0) 483 return (-1); 484 485 /* 486 * Add/sub popcounts from the bitmap until the PTE's bit is reached. 487 * For bits that are in the upper half between the calculated 488 * popcount id and the next one, use the next one and subtract to 489 * minimize the number of popcounts required. 490 */ 491 if ((pte_bit_id % POPCOUNT_BITS) < (POPCOUNT_BITS / 2)) { 492 count = kd->pt_popcounts[popcount_id] + popcount_bytes( 493 bitmap + popcount_id * POPCOUNTS_IN(*bitmap), 494 0, pte_bit_id - popcount_id * POPCOUNT_BITS); 495 } else { 496 /* 497 * Counting in reverse is trickier, since we must avoid 498 * reading from bytes that are not in range, and invert. 499 */ 500 uint64_t pte_u64_bit_off = pte_u64 * BITS_IN(*bitmap); 501 502 popcount_id++; 503 bitN = MIN(popcount_id * POPCOUNT_BITS, 504 kd->pt_map_size * BITS_IN(uint8_t)); 505 count = kd->pt_popcounts[popcount_id] - popcount_bytes( 506 bitmap + pte_u64, 507 pte_bit_id - pte_u64_bit_off, bitN - pte_u64_bit_off); 508 } 509 510 /* 511 * This can only happen if the core is truncated. Treat these 512 * entries as if they don't exist, since their backing doesn't. 513 */ 514 if (count >= (kd->pt_sparse_size / page_size)) 515 return (-1); 516 517 return (kd->pt_sparse_off + (uint64_t)count * page_size); 518 } 519 520 static int 521 kvm_fdnlist(kvm_t *kd, struct kvm_nlist *list) 522 { 523 kvaddr_t addr; 524 int error, nfail; 525 526 if (kd->resolve_symbol == NULL) { 527 struct nlist *nl; 528 int count, i; 529 530 for (count = 0; list[count].n_name != NULL && 531 list[count].n_name[0] != '\0'; count++) 532 ; 533 nl = calloc(count + 1, sizeof(*nl)); 534 for (i = 0; i < count; i++) 535 nl[i].n_name = list[i].n_name; 536 nfail = __fdnlist(kd->nlfd, nl); 537 for (i = 0; i < count; i++) { 538 list[i].n_type = nl[i].n_type; 539 list[i].n_value = nl[i].n_value; 540 } 541 free(nl); 542 return (nfail); 543 } 544 545 nfail = 0; 546 while (list->n_name != NULL && list->n_name[0] != '\0') { 547 error = kd->resolve_symbol(list->n_name, &addr); 548 if (error != 0) { 549 nfail++; 550 list->n_value = 0; 551 list->n_type = 0; 552 } else { 553 list->n_value = addr; 554 list->n_type = N_DATA | N_EXT; 555 } 556 list++; 557 } 558 return (nfail); 559 } 560 561 /* 562 * Walk the list of unresolved symbols, generate a new list and prefix the 563 * symbol names, try again, and merge back what we could resolve. 564 */ 565 static int 566 kvm_fdnlist_prefix(kvm_t *kd, struct kvm_nlist *nl, int missing, 567 const char *prefix, kvaddr_t (*validate_fn)(kvm_t *, kvaddr_t)) 568 { 569 struct kvm_nlist *n, *np, *p; 570 char *cp, *ce; 571 const char *ccp; 572 size_t len; 573 int slen, unresolved; 574 575 /* 576 * Calculate the space we need to malloc for nlist and names. 577 * We are going to store the name twice for later lookups: once 578 * with the prefix and once the unmodified name delmited by \0. 579 */ 580 len = 0; 581 unresolved = 0; 582 for (p = nl; p->n_name && p->n_name[0]; ++p) { 583 if (p->n_type != N_UNDF) 584 continue; 585 len += sizeof(struct kvm_nlist) + strlen(prefix) + 586 2 * (strlen(p->n_name) + 1); 587 unresolved++; 588 } 589 if (unresolved == 0) 590 return (unresolved); 591 /* Add space for the terminating nlist entry. */ 592 len += sizeof(struct kvm_nlist); 593 unresolved++; 594 595 /* Alloc one chunk for (nlist, [names]) and setup pointers. */ 596 n = np = malloc(len); 597 bzero(n, len); 598 if (n == NULL) 599 return (missing); 600 cp = ce = (char *)np; 601 cp += unresolved * sizeof(struct kvm_nlist); 602 ce += len; 603 604 /* Generate shortened nlist with special prefix. */ 605 unresolved = 0; 606 for (p = nl; p->n_name && p->n_name[0]; ++p) { 607 if (p->n_type != N_UNDF) 608 continue; 609 *np = *p; 610 /* Save the new\0orig. name so we can later match it again. */ 611 slen = snprintf(cp, ce - cp, "%s%s%c%s", prefix, 612 (prefix[0] != '\0' && p->n_name[0] == '_') ? 613 (p->n_name + 1) : p->n_name, '\0', p->n_name); 614 if (slen < 0 || slen >= ce - cp) 615 continue; 616 np->n_name = cp; 617 cp += slen + 1; 618 np++; 619 unresolved++; 620 } 621 622 /* Do lookup on the reduced list. */ 623 np = n; 624 unresolved = kvm_fdnlist(kd, np); 625 626 /* Check if we could resolve further symbols and update the list. */ 627 if (unresolved >= 0 && unresolved < missing) { 628 /* Find the first freshly resolved entry. */ 629 for (; np->n_name && np->n_name[0]; np++) 630 if (np->n_type != N_UNDF) 631 break; 632 /* 633 * The lists are both in the same order, 634 * so we can walk them in parallel. 635 */ 636 for (p = nl; np->n_name && np->n_name[0] && 637 p->n_name && p->n_name[0]; ++p) { 638 if (p->n_type != N_UNDF) 639 continue; 640 /* Skip expanded name and compare to orig. one. */ 641 ccp = np->n_name + strlen(np->n_name) + 1; 642 if (strcmp(ccp, p->n_name) != 0) 643 continue; 644 /* Update nlist with new, translated results. */ 645 p->n_type = np->n_type; 646 if (validate_fn) 647 p->n_value = (*validate_fn)(kd, np->n_value); 648 else 649 p->n_value = np->n_value; 650 missing--; 651 /* Find next freshly resolved entry. */ 652 for (np++; np->n_name && np->n_name[0]; np++) 653 if (np->n_type != N_UNDF) 654 break; 655 } 656 } 657 /* We could assert missing = unresolved here. */ 658 659 free(n); 660 return (unresolved); 661 } 662 663 int 664 _kvm_nlist(kvm_t *kd, struct kvm_nlist *nl, int initialize) 665 { 666 struct kvm_nlist *p; 667 int nvalid; 668 struct kld_sym_lookup lookup; 669 int error; 670 const char *prefix = ""; 671 char symname[1024]; /* XXX-BZ symbol name length limit? */ 672 int tried_vnet, tried_dpcpu; 673 674 /* 675 * If we can't use the kld symbol lookup, revert to the 676 * slow library call. 677 */ 678 if (!ISALIVE(kd)) { 679 error = kvm_fdnlist(kd, nl); 680 if (error <= 0) /* Hard error or success. */ 681 return (error); 682 683 if (_kvm_vnet_initialized(kd, initialize)) 684 error = kvm_fdnlist_prefix(kd, nl, error, 685 VNET_SYMPREFIX, _kvm_vnet_validaddr); 686 687 if (error > 0 && _kvm_dpcpu_initialized(kd, initialize)) 688 error = kvm_fdnlist_prefix(kd, nl, error, 689 DPCPU_SYMPREFIX, _kvm_dpcpu_validaddr); 690 691 return (error); 692 } 693 694 /* 695 * We can use the kld lookup syscall. Go through each nlist entry 696 * and look it up with a kldsym(2) syscall. 697 */ 698 nvalid = 0; 699 tried_vnet = 0; 700 tried_dpcpu = 0; 701 again: 702 for (p = nl; p->n_name && p->n_name[0]; ++p) { 703 if (p->n_type != N_UNDF) 704 continue; 705 706 lookup.version = sizeof(lookup); 707 lookup.symvalue = 0; 708 lookup.symsize = 0; 709 710 error = snprintf(symname, sizeof(symname), "%s%s", prefix, 711 (prefix[0] != '\0' && p->n_name[0] == '_') ? 712 (p->n_name + 1) : p->n_name); 713 if (error < 0 || error >= (int)sizeof(symname)) 714 continue; 715 lookup.symname = symname; 716 if (lookup.symname[0] == '_') 717 lookup.symname++; 718 719 if (kldsym(0, KLDSYM_LOOKUP, &lookup) != -1) { 720 p->n_type = N_TEXT; 721 if (_kvm_vnet_initialized(kd, initialize) && 722 strcmp(prefix, VNET_SYMPREFIX) == 0) 723 p->n_value = 724 _kvm_vnet_validaddr(kd, lookup.symvalue); 725 else if (_kvm_dpcpu_initialized(kd, initialize) && 726 strcmp(prefix, DPCPU_SYMPREFIX) == 0) 727 p->n_value = 728 _kvm_dpcpu_validaddr(kd, lookup.symvalue); 729 else 730 p->n_value = lookup.symvalue; 731 ++nvalid; 732 /* lookup.symsize */ 733 } 734 } 735 736 /* 737 * Check the number of entries that weren't found. If they exist, 738 * try again with a prefix for virtualized or DPCPU symbol names. 739 */ 740 error = ((p - nl) - nvalid); 741 if (error && _kvm_vnet_initialized(kd, initialize) && !tried_vnet) { 742 tried_vnet = 1; 743 prefix = VNET_SYMPREFIX; 744 goto again; 745 } 746 if (error && _kvm_dpcpu_initialized(kd, initialize) && !tried_dpcpu) { 747 tried_dpcpu = 1; 748 prefix = DPCPU_SYMPREFIX; 749 goto again; 750 } 751 752 /* 753 * Return the number of entries that weren't found. If they exist, 754 * also fill internal error buffer. 755 */ 756 error = ((p - nl) - nvalid); 757 if (error) 758 _kvm_syserr(kd, kd->program, "kvm_nlist"); 759 return (error); 760 } 761 762 int 763 _kvm_bitmap_init(struct kvm_bitmap *bm, u_long bitmapsize, u_long *idx) 764 { 765 766 *idx = ULONG_MAX; 767 bm->map = calloc(bitmapsize, sizeof *bm->map); 768 if (bm->map == NULL) 769 return (0); 770 bm->size = bitmapsize; 771 return (1); 772 } 773 774 void 775 _kvm_bitmap_set(struct kvm_bitmap *bm, u_long bm_index) 776 { 777 uint8_t *byte = &bm->map[bm_index / 8]; 778 779 if (bm_index / 8 < bm->size) 780 *byte |= (1UL << (bm_index % 8)); 781 } 782 783 int 784 _kvm_bitmap_next(struct kvm_bitmap *bm, u_long *idx) 785 { 786 u_long first_invalid = bm->size * CHAR_BIT; 787 788 if (*idx == ULONG_MAX) 789 *idx = 0; 790 else 791 (*idx)++; 792 793 /* Find the next valid idx. */ 794 for (; *idx < first_invalid; (*idx)++) { 795 unsigned int mask = 1U << (*idx % CHAR_BIT); 796 if ((bm->map[*idx / CHAR_BIT] & mask) != 0) 797 break; 798 } 799 800 return (*idx < first_invalid); 801 } 802 803 void 804 _kvm_bitmap_deinit(struct kvm_bitmap *bm) 805 { 806 807 free(bm->map); 808 } 809 810 int 811 _kvm_visit_cb(kvm_t *kd, kvm_walk_pages_cb_t *cb, void *arg, u_long pa, 812 u_long kmap_vaddr, u_long dmap_vaddr, vm_prot_t prot, size_t len, 813 unsigned int page_size) 814 { 815 unsigned int pgsz = page_size ? page_size : len; 816 struct kvm_page p = { 817 .kp_version = LIBKVM_WALK_PAGES_VERSION, 818 .kp_paddr = pa, 819 .kp_kmap_vaddr = kmap_vaddr, 820 .kp_dmap_vaddr = dmap_vaddr, 821 .kp_prot = prot, 822 .kp_offset = _kvm_pt_find(kd, pa, pgsz), 823 .kp_len = len, 824 }; 825 826 return cb(&p, arg); 827 } 828