1 /* 2 * CDDL HEADER START 3 * 4 * The contents of this file are subject to the terms of the 5 * Common Development and Distribution License (the "License"). 6 * You may not use this file except in compliance with the License. 7 * 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9 * or http://www.opensolaris.org/os/licensing. 10 * See the License for the specific language governing permissions 11 * and limitations under the License. 12 * 13 * When distributing Covered Code, include this CDDL HEADER in each 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15 * If applicable, add the following below this CDDL HEADER, with the 16 * fields enclosed by brackets "[]" replaced with your own identifying 17 * information: Portions Copyright [yyyy] [name of copyright owner] 18 * 19 * CDDL HEADER END 20 */ 21 22 /* 23 * Copyright 2009 Sun Microsystems, Inc. All rights reserved. 24 * Use is subject to license terms. 25 */ 26 27 /* 28 * Dump an elf file. 29 */ 30 #include <stddef.h> 31 #include <sys/elf_386.h> 32 #include <sys/elf_amd64.h> 33 #include <sys/elf_SPARC.h> 34 #include <_libelf.h> 35 #include <dwarf.h> 36 #include <stdio.h> 37 #include <unistd.h> 38 #include <errno.h> 39 #include <strings.h> 40 #include <debug.h> 41 #include <conv.h> 42 #include <msg.h> 43 #include <_elfdump.h> 44 45 46 /* 47 * VERSYM_STATE is used to maintain information about the VERSYM section 48 * in the object being analyzed. It is filled in by versions(), and used 49 * by init_symtbl_state() when displaying symbol information. 50 * 51 * There are three forms of symbol versioning known to us: 52 * 53 * 1) The original form, introduced with Solaris 2.5, in which 54 * the Versym contains indexes to Verdef records, and the 55 * Versym values for UNDEF symbols resolved by other objects 56 * are all set to 0. 57 * 2) The GNU form, which is backward compatible with the original 58 * Solaris form, but which adds several extensions: 59 * - The Versym also contains indexes to Verneed records, recording 60 * which object/version contributed the external symbol at 61 * link time. These indexes start with the next value following 62 * the final Verdef index. The index is written to the previously 63 * reserved vna_other field of the ELF Vernaux structure. 64 * - The top bit of the Versym value is no longer part of the index, 65 * but is used as a "hidden bit" to prevent binding to the symbol. 66 * - Multiple implementations of a given symbol, contained in varying 67 * versions are allowed, using special assembler pseudo ops, 68 * and encoded in the symbol name using '@' characters. 69 * 3) Modified Solaris form, in which we adopt the first GNU extension 70 * (Versym indexes to Verneed records), but not the others. 71 * 72 * elfdump can handle any of these cases. The presence of a DT_VERSYM 73 * dynamic element indicates a full GNU object. An object that lacks 74 * a DT_VERSYM entry, but which has non-zero vna_other fields in the Vernaux 75 * structures is a modified Solaris object. An object that has neither of 76 * these uses the original form. 77 * 78 * max_verndx contains the largest version index that can appear 79 * in a Versym entry. This can never be less than 1: In the case where 80 * there is no verdef/verneed sections, the [0] index is reserved 81 * for local symbols, and the [1] index for globals. If the original 82 * Solaris versioning rules are in effect and there is a verdef section, 83 * then max_verndex is the number of defined versions. If one of the 84 * other versioning forms is in effect, then: 85 * 1) If there is no verneed section, it is the same as for 86 * original Solaris versioning. 87 * 2) If there is a verneed section, the vna_other field of the 88 * Vernaux structs contain versions, and max_verndx is the 89 * largest such index. 90 * 91 * If gnu_full is True, the object uses the full GNU form of versioning. 92 * The value of the gnu_full field is based on the presence of 93 * a DT_VERSYM entry in the dynamic section: GNU ld produces these, and 94 * Solaris ld does not. 95 * 96 * The gnu_needed field is True if the Versym contains indexes to 97 * Verneed records, as indicated by non-zero vna_other fields in the Verneed 98 * section. If gnu_full is True, then gnu_needed will always be true. 99 * However, gnu_needed can be true without gnu_full. This is the modified 100 * Solaris form. 101 */ 102 typedef struct { 103 Cache *cache; /* Pointer to cache entry for VERSYM */ 104 Versym *data; /* Pointer to versym array */ 105 int gnu_full; /* True if object uses GNU versioning rules */ 106 int gnu_needed; /* True if object uses VERSYM indexes for */ 107 /* VERNEED (subset of gnu_full) */ 108 int max_verndx; /* largest versym index value */ 109 } VERSYM_STATE; 110 111 /* 112 * SYMTBL_STATE is used to maintain information about a single symbol 113 * table section, for use by the routines that display symbol information. 114 */ 115 typedef struct { 116 const char *file; /* Name of file */ 117 Ehdr *ehdr; /* ELF header for file */ 118 Cache *cache; /* Cache of all section headers */ 119 uchar_t osabi; /* OSABI to use */ 120 Word shnum; /* # of sections in cache */ 121 Cache *seccache; /* Cache of symbol table section hdr */ 122 Word secndx; /* Index of symbol table section hdr */ 123 const char *secname; /* Name of section */ 124 uint_t flags; /* Command line option flags */ 125 struct { /* Extended section index data */ 126 int checked; /* TRUE if already checked for shxndx */ 127 Word *data; /* NULL, or extended section index */ 128 /* used for symbol table entries */ 129 uint_t n; /* # items in shxndx.data */ 130 } shxndx; 131 VERSYM_STATE *versym; /* NULL, or associated VERSYM section */ 132 Sym *sym; /* Array of symbols */ 133 Word symn; /* # of symbols */ 134 } SYMTBL_STATE; 135 136 /* 137 * A variable of this type is used to track information related to 138 * .eh_frame and .eh_frame_hdr sections across calls to unwind_eh_frame(). 139 */ 140 typedef struct { 141 Word frame_cnt; /* # .eh_frame sections seen */ 142 Word frame_ndx; /* Section index of 1st .eh_frame */ 143 Word hdr_cnt; /* # .eh_frame_hdr sections seen */ 144 Word hdr_ndx; /* Section index of 1st .eh_frame_hdr */ 145 uint64_t frame_ptr; /* Value of FramePtr field from first */ 146 /* .eh_frame_hdr section */ 147 uint64_t frame_base; /* Data addr of 1st .eh_frame */ 148 } gnu_eh_state_t; 149 150 /* 151 * C++ .exception_ranges entries make use of the signed ptrdiff_t 152 * type to record self-relative pointer values. We need a type 153 * for this that is matched to the ELFCLASS being processed. 154 */ 155 #if defined(_ELF64) 156 typedef int64_t PTRDIFF_T; 157 #else 158 typedef int32_t PTRDIFF_T; 159 #endif 160 161 /* 162 * The Sun C++ ABI uses this struct to define each .exception_ranges 163 * entry. From the ABI: 164 * 165 * The field ret_addr is a self relative pointer to the start of the address 166 * range. The name was chosen because in the current implementation the range 167 * typically starts at the return address for a call site. 168 * 169 * The field length is the difference, in bytes, between the pc of the last 170 * instruction covered by the exception range and the first. When only a 171 * single call site is represented without optimization, this will equal zero. 172 * 173 * The field handler_addr is a relative pointer which stores the difference 174 * between the start of the exception range and the address of all code to 175 * catch exceptions and perform the cleanup for stack unwinding. 176 * 177 * The field type_block is a relative pointer which stores the difference 178 * between the start of the exception range and the address of an array used 179 * for storing a list of the types of exceptions which can be caught within 180 * the exception range. 181 */ 182 typedef struct { 183 PTRDIFF_T ret_addr; 184 Xword length; 185 PTRDIFF_T handler_addr; 186 PTRDIFF_T type_block; 187 Xword reserved; 188 } exception_range_entry; 189 190 /* 191 * Focal point for verifying symbol names. 192 */ 193 static const char * 194 string(Cache *refsec, Word ndx, Cache *strsec, const char *file, Word name) 195 { 196 /* 197 * If an error in this routine is due to a property of the string 198 * section, as opposed to a bad offset into the section (a property of 199 * the referencing section), then we will detect the same error on 200 * every call involving those sections. We use these static variables 201 * to retain the information needed to only issue each such error once. 202 */ 203 static Cache *last_refsec; /* Last referencing section seen */ 204 static int strsec_err; /* True if error issued */ 205 206 const char *strs; 207 Word strn; 208 209 if (strsec->c_data == NULL) 210 return (NULL); 211 212 strs = (char *)strsec->c_data->d_buf; 213 strn = strsec->c_data->d_size; 214 215 /* 216 * We only print a diagnostic regarding a bad string table once per 217 * input section being processed. If the refsec has changed, reset 218 * our retained error state. 219 */ 220 if (last_refsec != refsec) { 221 last_refsec = refsec; 222 strsec_err = 0; 223 } 224 225 /* Verify that strsec really is a string table */ 226 if (strsec->c_shdr->sh_type != SHT_STRTAB) { 227 if (!strsec_err) { 228 (void) fprintf(stderr, MSG_INTL(MSG_ERR_NOTSTRTAB), 229 file, strsec->c_ndx, refsec->c_ndx); 230 strsec_err = 1; 231 } 232 return (MSG_INTL(MSG_STR_UNKNOWN)); 233 } 234 235 /* 236 * Is the string table offset within range of the available strings? 237 */ 238 if (name >= strn) { 239 /* 240 * Do we have a empty string table? 241 */ 242 if (strs == NULL) { 243 if (!strsec_err) { 244 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 245 file, strsec->c_name); 246 strsec_err = 1; 247 } 248 } else { 249 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSTOFF), 250 file, refsec->c_name, EC_WORD(ndx), strsec->c_name, 251 EC_WORD(name), EC_WORD(strn - 1)); 252 } 253 254 /* 255 * Return the empty string so that the calling function can 256 * continue it's output diagnostics. 257 */ 258 return (MSG_INTL(MSG_STR_UNKNOWN)); 259 } 260 return (strs + name); 261 } 262 263 /* 264 * Relocations can reference section symbols and standard symbols. If the 265 * former, establish the section name. 266 */ 267 static const char * 268 relsymname(Cache *cache, Cache *csec, Cache *strsec, Word symndx, Word symnum, 269 Word relndx, Sym *syms, char *secstr, size_t secsz, const char *file) 270 { 271 Sym *sym; 272 const char *name; 273 274 if (symndx >= symnum) { 275 (void) fprintf(stderr, MSG_INTL(MSG_ERR_RELBADSYMNDX), 276 file, EC_WORD(symndx), EC_WORD(relndx)); 277 return (MSG_INTL(MSG_STR_UNKNOWN)); 278 } 279 280 sym = (Sym *)(syms + symndx); 281 name = string(csec, symndx, strsec, file, sym->st_name); 282 283 /* 284 * If the symbol represents a section offset construct an appropriate 285 * string. Note, although section symbol table entries typically have 286 * a NULL name pointer, entries do exist that point into the string 287 * table to their own NULL strings. 288 */ 289 if ((ELF_ST_TYPE(sym->st_info) == STT_SECTION) && 290 ((sym->st_name == 0) || (*name == '\0'))) { 291 (void) snprintf(secstr, secsz, MSG_INTL(MSG_STR_SECTION), 292 cache[sym->st_shndx].c_name); 293 return ((const char *)secstr); 294 } 295 296 return (name); 297 } 298 299 /* 300 * Focal point for establishing a string table section. Data such as the 301 * dynamic information simply points to a string table. Data such as 302 * relocations, reference a symbol table, which in turn is associated with a 303 * string table. 304 */ 305 static int 306 stringtbl(Cache *cache, int symtab, Word ndx, Word shnum, const char *file, 307 Word *symnum, Cache **symsec, Cache **strsec) 308 { 309 Shdr *shdr = cache[ndx].c_shdr; 310 311 if (symtab) { 312 /* 313 * Validate the symbol table section. 314 */ 315 if ((shdr->sh_link == 0) || (shdr->sh_link >= shnum)) { 316 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 317 file, cache[ndx].c_name, EC_WORD(shdr->sh_link)); 318 return (0); 319 } 320 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0)) { 321 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 322 file, cache[ndx].c_name); 323 return (0); 324 } 325 326 /* 327 * Obtain, and verify the symbol table data. 328 */ 329 if ((cache[ndx].c_data == NULL) || 330 (cache[ndx].c_data->d_buf == NULL)) { 331 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 332 file, cache[ndx].c_name); 333 return (0); 334 } 335 336 /* 337 * Establish the string table index. 338 */ 339 ndx = shdr->sh_link; 340 shdr = cache[ndx].c_shdr; 341 342 /* 343 * Return symbol table information. 344 */ 345 if (symnum) 346 *symnum = (shdr->sh_size / shdr->sh_entsize); 347 if (symsec) 348 *symsec = &cache[ndx]; 349 } 350 351 /* 352 * Validate the associated string table section. 353 */ 354 if ((shdr->sh_link == 0) || (shdr->sh_link >= shnum)) { 355 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 356 file, cache[ndx].c_name, EC_WORD(shdr->sh_link)); 357 return (0); 358 } 359 360 if (strsec) 361 *strsec = &cache[shdr->sh_link]; 362 363 return (1); 364 } 365 366 /* 367 * Lookup a symbol and set Sym accordingly. 368 */ 369 static int 370 symlookup(const char *name, Cache *cache, Word shnum, Sym **sym, 371 Cache *symtab, const char *file) 372 { 373 Shdr *shdr; 374 Word symn, cnt; 375 Sym *syms; 376 377 if (symtab == 0) 378 return (0); 379 380 shdr = symtab->c_shdr; 381 382 /* 383 * Determine the symbol data and number. 384 */ 385 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0)) { 386 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 387 file, symtab->c_name); 388 return (0); 389 } 390 if (symtab->c_data == NULL) 391 return (0); 392 393 /* LINTED */ 394 symn = (Word)(shdr->sh_size / shdr->sh_entsize); 395 syms = (Sym *)symtab->c_data->d_buf; 396 397 /* 398 * Get the associated string table section. 399 */ 400 if ((shdr->sh_link == 0) || (shdr->sh_link >= shnum)) { 401 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 402 file, symtab->c_name, EC_WORD(shdr->sh_link)); 403 return (0); 404 } 405 406 /* 407 * Loop through the symbol table to find a match. 408 */ 409 for (cnt = 0; cnt < symn; syms++, cnt++) { 410 const char *symname; 411 412 symname = string(symtab, cnt, &cache[shdr->sh_link], file, 413 syms->st_name); 414 415 if (symname && (strcmp(name, symname) == 0)) { 416 *sym = syms; 417 return (1); 418 } 419 } 420 return (0); 421 } 422 423 /* 424 * Print section headers. 425 */ 426 static void 427 sections(const char *file, Cache *cache, Word shnum, Ehdr *ehdr, uchar_t osabi) 428 { 429 size_t seccnt; 430 431 for (seccnt = 1; seccnt < shnum; seccnt++) { 432 Cache *_cache = &cache[seccnt]; 433 Shdr *shdr = _cache->c_shdr; 434 const char *secname = _cache->c_name; 435 436 /* 437 * Although numerous section header entries can be zero, it's 438 * usually a sign of trouble if the type is zero. 439 */ 440 if (shdr->sh_type == 0) { 441 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHTYPE), 442 file, secname, EC_WORD(shdr->sh_type)); 443 } 444 445 if (!match(MATCH_F_ALL, secname, seccnt, shdr->sh_type)) 446 continue; 447 448 /* 449 * Identify any sections that are suspicious. A .got section 450 * shouldn't exist in a relocatable object. 451 */ 452 if (ehdr->e_type == ET_REL) { 453 if (strncmp(secname, MSG_ORIG(MSG_ELF_GOT), 454 MSG_ELF_GOT_SIZE) == 0) { 455 (void) fprintf(stderr, 456 MSG_INTL(MSG_GOT_UNEXPECTED), file, 457 secname); 458 } 459 } 460 461 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 462 dbg_print(0, MSG_INTL(MSG_ELF_SHDR), EC_WORD(seccnt), secname); 463 Elf_shdr(0, osabi, ehdr->e_machine, shdr); 464 } 465 } 466 467 /* 468 * Obtain a specified Phdr entry. 469 */ 470 static Phdr * 471 getphdr(Word phnum, Word *type_arr, Word type_cnt, const char *file, Elf *elf) 472 { 473 Word cnt, tcnt; 474 Phdr *phdr; 475 476 if ((phdr = elf_getphdr(elf)) == NULL) { 477 failure(file, MSG_ORIG(MSG_ELF_GETPHDR)); 478 return (NULL); 479 } 480 481 for (cnt = 0; cnt < phnum; phdr++, cnt++) { 482 for (tcnt = 0; tcnt < type_cnt; tcnt++) { 483 if (phdr->p_type == type_arr[tcnt]) 484 return (phdr); 485 } 486 } 487 return (NULL); 488 } 489 490 /* 491 * Display the contents of GNU/amd64 .eh_frame and .eh_frame_hdr 492 * sections. 493 * 494 * entry: 495 * cache - Cache of all section headers 496 * shndx - Index of .eh_frame or .eh_frame_hdr section to be displayed 497 * uphdr - NULL, or unwind program header associated with 498 * the .eh_frame_hdr section. 499 * ehdr - ELF header for file 500 * eh_state - Data used across calls to this routine. The 501 * caller should zero it before the first call, and 502 * pass it on every call. 503 * osabi - OSABI to use in displaying information 504 * file - Name of file 505 * flags - Command line option flags 506 */ 507 static void 508 unwind_eh_frame(Cache *cache, Word shndx, Phdr *uphdr, Ehdr *ehdr, 509 gnu_eh_state_t *eh_state, uchar_t osabi, const char *file, uint_t flags) 510 { 511 #if defined(_ELF64) 512 #define MSG_UNW_BINSRTAB2 MSG_UNW_BINSRTAB2_64 513 #define MSG_UNW_BINSRTABENT MSG_UNW_BINSRTABENT_64 514 #else 515 #define MSG_UNW_BINSRTAB2 MSG_UNW_BINSRTAB2_32 516 #define MSG_UNW_BINSRTABENT MSG_UNW_BINSRTABENT_32 517 #endif 518 519 Cache *_cache = &cache[shndx]; 520 Shdr *shdr = _cache->c_shdr; 521 uchar_t *data = (uchar_t *)(_cache->c_data->d_buf); 522 size_t datasize = _cache->c_data->d_size; 523 Conv_dwarf_ehe_buf_t dwarf_ehe_buf; 524 uint64_t ndx, frame_ptr, fde_cnt, tabndx; 525 uint_t vers, frame_ptr_enc, fde_cnt_enc, table_enc; 526 uint64_t initloc, initloc0; 527 528 529 /* 530 * Is this a .eh_frame_hdr? 531 */ 532 if ((uphdr && (shdr->sh_addr == uphdr->p_vaddr)) || 533 (strncmp(_cache->c_name, MSG_ORIG(MSG_SCN_FRMHDR), 534 MSG_SCN_FRMHDR_SIZE) == 0)) { 535 /* 536 * There can only be a single .eh_frame_hdr. 537 * Flag duplicates. 538 */ 539 if (++eh_state->hdr_cnt > 1) 540 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MULTEHFRMHDR), 541 file, EC_WORD(shndx), _cache->c_name); 542 543 dbg_print(0, MSG_ORIG(MSG_UNW_FRMHDR)); 544 ndx = 0; 545 546 vers = data[ndx++]; 547 frame_ptr_enc = data[ndx++]; 548 fde_cnt_enc = data[ndx++]; 549 table_enc = data[ndx++]; 550 551 dbg_print(0, MSG_ORIG(MSG_UNW_FRMVERS), vers); 552 553 frame_ptr = dwarf_ehe_extract(data, &ndx, frame_ptr_enc, 554 ehdr->e_ident, shdr->sh_addr, ndx); 555 if (eh_state->hdr_cnt == 1) { 556 eh_state->hdr_ndx = shndx; 557 eh_state->frame_ptr = frame_ptr; 558 } 559 560 dbg_print(0, MSG_ORIG(MSG_UNW_FRPTRENC), 561 conv_dwarf_ehe(frame_ptr_enc, &dwarf_ehe_buf), 562 EC_XWORD(frame_ptr)); 563 564 fde_cnt = dwarf_ehe_extract(data, &ndx, fde_cnt_enc, 565 ehdr->e_ident, shdr->sh_addr, ndx); 566 567 dbg_print(0, MSG_ORIG(MSG_UNW_FDCNENC), 568 conv_dwarf_ehe(fde_cnt_enc, &dwarf_ehe_buf), 569 EC_XWORD(fde_cnt)); 570 dbg_print(0, MSG_ORIG(MSG_UNW_TABENC), 571 conv_dwarf_ehe(table_enc, &dwarf_ehe_buf)); 572 dbg_print(0, MSG_ORIG(MSG_UNW_BINSRTAB1)); 573 dbg_print(0, MSG_ORIG(MSG_UNW_BINSRTAB2)); 574 575 for (tabndx = 0; tabndx < fde_cnt; tabndx++) { 576 initloc = dwarf_ehe_extract(data, &ndx, table_enc, 577 ehdr->e_ident, shdr->sh_addr, ndx); 578 /*LINTED:E_VAR_USED_BEFORE_SET*/ 579 if ((tabndx != 0) && (initloc0 > initloc)) 580 (void) fprintf(stderr, 581 MSG_INTL(MSG_ERR_BADSORT), file, 582 _cache->c_name, EC_WORD(tabndx)); 583 dbg_print(0, MSG_ORIG(MSG_UNW_BINSRTABENT), 584 EC_XWORD(initloc), 585 EC_XWORD(dwarf_ehe_extract(data, &ndx, 586 table_enc, ehdr->e_ident, shdr->sh_addr, 587 ndx))); 588 initloc0 = initloc; 589 } 590 } else { /* Display the .eh_frame section */ 591 eh_state->frame_cnt++; 592 if (eh_state->frame_cnt == 1) { 593 eh_state->frame_ndx = shndx; 594 eh_state->frame_base = shdr->sh_addr; 595 } else if ((eh_state->frame_cnt > 1) && 596 (ehdr->e_type != ET_REL)) { 597 Conv_inv_buf_t inv_buf; 598 599 (void) fprintf(stderr, MSG_INTL(MSG_WARN_MULTEHFRM), 600 file, EC_WORD(shndx), _cache->c_name, 601 conv_ehdr_type(osabi, ehdr->e_type, 0, &inv_buf)); 602 } 603 dump_eh_frame(data, datasize, shdr->sh_addr, 604 ehdr->e_machine, ehdr->e_ident); 605 } 606 607 /* 608 * If we've seen the .eh_frame_hdr and the first .eh_frame section, 609 * compare the header frame_ptr to the address of the actual frame 610 * section to ensure the link-editor got this right. Note, this 611 * diagnostic is only produced when unwind information is explicitly 612 * asked for, as shared objects built with an older ld(1) may reveal 613 * this inconsistency. Although an inconsistency, it doesn't seem to 614 * have any adverse effect on existing tools. 615 */ 616 if (((flags & FLG_MASK_SHOW) != FLG_MASK_SHOW) && 617 (eh_state->hdr_cnt > 0) && (eh_state->frame_cnt > 0) && 618 (eh_state->frame_ptr != eh_state->frame_base)) 619 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADEHFRMPTR), 620 file, EC_WORD(eh_state->hdr_ndx), 621 cache[eh_state->hdr_ndx].c_name, 622 EC_XWORD(eh_state->frame_ptr), 623 EC_WORD(eh_state->frame_ndx), 624 cache[eh_state->frame_ndx].c_name, 625 EC_XWORD(eh_state->frame_base)); 626 #undef MSG_UNW_BINSRTAB2 627 #undef MSG_UNW_BINSRTABENT 628 } 629 630 /* 631 * Convert a self relative pointer into an address. A self relative 632 * pointer adds the address where the pointer resides to the offset 633 * contained in the pointer. The benefit is that the value of the 634 * pointer does not require relocation. 635 * 636 * entry: 637 * base_addr - Address of the pointer. 638 * delta - Offset relative to base_addr giving desired address 639 * 640 * exit: 641 * The computed address is returned. 642 * 643 * note: 644 * base_addr is an unsigned value, while ret_addr is signed. This routine 645 * used explicit testing and casting to explicitly control type 646 * conversion, and ensure that we handle the maximum possible range. 647 */ 648 static Addr 649 srelptr(Addr base_addr, PTRDIFF_T delta) 650 { 651 if (delta < 0) 652 return (base_addr - (Addr) (-delta)); 653 654 return (base_addr + (Addr) delta); 655 } 656 657 /* 658 * Byte swap a PTRDIFF_T value. 659 */ 660 static PTRDIFF_T 661 swap_ptrdiff(PTRDIFF_T value) 662 { 663 PTRDIFF_T r; 664 uchar_t *dst = (uchar_t *)&r; 665 uchar_t *src = (uchar_t *)&value; 666 667 UL_ASSIGN_BSWAP_XWORD(dst, src); 668 return (r); 669 } 670 671 /* 672 * Display exception_range_entry items from the .exception_ranges section 673 * of a Sun C++ object. 674 */ 675 static void 676 unwind_exception_ranges(Cache *_cache, const char *file, int do_swap) 677 { 678 /* 679 * Translate a PTRDIFF_T self-relative address field of 680 * an exception_range_entry struct into an address. 681 * 682 * entry: 683 * exc_addr - Address of base of exception_range_entry struct 684 * cur_ent - Pointer to data in the struct to be translated 685 * 686 * _f - Field of struct to be translated 687 */ 688 #define SRELPTR(_f) \ 689 srelptr(exc_addr + offsetof(exception_range_entry, _f), cur_ent->_f) 690 691 #if defined(_ELF64) 692 #define MSG_EXR_TITLE MSG_EXR_TITLE_64 693 #define MSG_EXR_ENTRY MSG_EXR_ENTRY_64 694 #else 695 #define MSG_EXR_TITLE MSG_EXR_TITLE_32 696 #define MSG_EXR_ENTRY MSG_EXR_ENTRY_32 697 #endif 698 699 exception_range_entry scratch, *ent, *cur_ent = &scratch; 700 char index[MAXNDXSIZE]; 701 Word i, nelts; 702 Addr addr, addr0, offset = 0; 703 Addr exc_addr = _cache->c_shdr->sh_addr; 704 705 dbg_print(0, MSG_INTL(MSG_EXR_TITLE)); 706 ent = (exception_range_entry *)(_cache->c_data->d_buf); 707 nelts = _cache->c_data->d_size / sizeof (exception_range_entry); 708 709 for (i = 0; i < nelts; i++, ent++) { 710 if (do_swap) { 711 /* 712 * Copy byte swapped values into the scratch buffer. 713 * The reserved field is not used, so we skip it. 714 */ 715 scratch.ret_addr = swap_ptrdiff(ent->ret_addr); 716 scratch.length = BSWAP_XWORD(ent->length); 717 scratch.handler_addr = swap_ptrdiff(ent->handler_addr); 718 scratch.type_block = swap_ptrdiff(ent->type_block); 719 } else { 720 cur_ent = ent; 721 } 722 723 /* 724 * The table is required to be sorted by the address 725 * derived from ret_addr, to allow binary searching. Ensure 726 * that addresses grow monotonically. 727 */ 728 addr = SRELPTR(ret_addr); 729 /*LINTED:E_VAR_USED_BEFORE_SET*/ 730 if ((i != 0) && (addr0 > addr)) 731 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSORT), 732 file, _cache->c_name, EC_WORD(i)); 733 734 (void) snprintf(index, MAXNDXSIZE, MSG_ORIG(MSG_FMT_INDEX), 735 EC_XWORD(i)); 736 dbg_print(0, MSG_INTL(MSG_EXR_ENTRY), index, EC_ADDR(offset), 737 EC_ADDR(addr), EC_ADDR(cur_ent->length), 738 EC_ADDR(SRELPTR(handler_addr)), 739 EC_ADDR(SRELPTR(type_block))); 740 741 addr0 = addr; 742 exc_addr += sizeof (exception_range_entry); 743 offset += sizeof (exception_range_entry); 744 } 745 746 #undef SRELPTR 747 #undef MSG_EXR_TITLE 748 #undef MSG_EXR_ENTRY 749 } 750 751 /* 752 * Display information from unwind/exception sections: 753 * 754 * - GNU/amd64 .eh_frame and .eh_frame_hdr 755 * - Sun C++ .exception_ranges 756 * 757 */ 758 static void 759 unwind(Cache *cache, Word shnum, Word phnum, Ehdr *ehdr, uchar_t osabi, 760 const char *file, Elf *elf, uint_t flags) 761 { 762 static Word phdr_types[] = { PT_SUNW_UNWIND, PT_SUNW_EH_FRAME }; 763 764 Word cnt; 765 Phdr *uphdr = NULL; 766 gnu_eh_state_t eh_state; 767 768 /* 769 * Historical background: .eh_frame and .eh_frame_hdr sections 770 * come from the GNU compilers (particularly C++), and are used 771 * under all architectures. Their format is based on DWARF. When 772 * the amd64 ABI was defined, these sections were adopted wholesale 773 * from the existing practice. 774 * 775 * When amd64 support was added to Solaris, support for these 776 * sections was added, using the SHT_AMD64_UNWIND section type 777 * to identify them. At first, we ignored them in objects for 778 * non-amd64 targets, but later broadened our support to include 779 * other architectures in order to better support gcc-generated 780 * objects. 781 * 782 * .exception_ranges implement the same basic concepts, but 783 * were invented at Sun for the Sun C++ compiler. 784 * 785 * We match these sections by name, rather than section type, 786 * because they can come in as either SHT_AMD64_UNWIND, or as 787 * SHT_PROGBITS, and because the type isn't enough to determine 788 * how they should be interprteted. 789 */ 790 791 /* Find the program header for .eh_frame_hdr if present */ 792 if (phnum) 793 uphdr = getphdr(phnum, phdr_types, 794 sizeof (phdr_types) / sizeof (*phdr_types), file, elf); 795 796 /* 797 * eh_state is used to retain data used by unwind_eh_frame() 798 * accross calls. 799 */ 800 bzero(&eh_state, sizeof (eh_state)); 801 802 for (cnt = 1; cnt < shnum; cnt++) { 803 Cache *_cache = &cache[cnt]; 804 Shdr *shdr = _cache->c_shdr; 805 int is_exrange; 806 807 /* 808 * Skip sections of the wrong type. On amd64, they 809 * can be SHT_AMD64_UNWIND. On all platforms, they 810 * can be SHT_PROGBITS (including amd64, if using 811 * the GNU compilers). 812 * 813 * Skip anything other than these two types. The name 814 * test below will thin out the SHT_PROGBITS that don't apply. 815 */ 816 if ((shdr->sh_type != SHT_PROGBITS) && 817 (shdr->sh_type != SHT_AMD64_UNWIND)) 818 continue; 819 820 /* 821 * Only sections with certain well known names are of interest. 822 * These are: 823 * 824 * .eh_frame - amd64/GNU-compiler unwind sections 825 * .eh_frame_hdr - Sorted table referencing .eh_frame 826 * .exception_ranges - Sun C++ unwind sections 827 * 828 * We do a prefix comparison, allowing for naming conventions 829 * like .eh_frame.foo, hence the use of strncmp() rather than 830 * strcmp(). This means that we only really need to test for 831 * .eh_frame, as it's a prefix of .eh_frame_hdr. 832 */ 833 is_exrange = strncmp(_cache->c_name, 834 MSG_ORIG(MSG_SCN_EXRANGE), MSG_SCN_EXRANGE_SIZE) == 0; 835 if ((strncmp(_cache->c_name, MSG_ORIG(MSG_SCN_FRM), 836 MSG_SCN_FRM_SIZE) != 0) && !is_exrange) 837 continue; 838 839 if (!match(MATCH_F_ALL, _cache->c_name, cnt, shdr->sh_type)) 840 continue; 841 842 if (_cache->c_data == NULL) 843 continue; 844 845 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 846 dbg_print(0, MSG_INTL(MSG_ELF_SCN_UNWIND), _cache->c_name); 847 848 if (is_exrange) 849 unwind_exception_ranges(_cache, file, 850 _elf_sys_encoding() != ehdr->e_ident[EI_DATA]); 851 else 852 unwind_eh_frame(cache, cnt, uphdr, ehdr, &eh_state, 853 osabi, file, flags); 854 } 855 } 856 857 /* 858 * Print the hardware/software capabilities. For executables and shared objects 859 * this should be accompanied with a program header. 860 */ 861 static void 862 cap(const char *file, Cache *cache, Word shnum, Word phnum, Ehdr *ehdr, 863 Elf *elf) 864 { 865 Word cnt; 866 Shdr *cshdr = NULL; 867 Cache *ccache; 868 Off cphdr_off = 0; 869 Xword cphdr_sz; 870 871 /* 872 * Determine if a hardware/software capabilities header exists. 873 */ 874 if (phnum) { 875 Phdr *phdr; 876 877 if ((phdr = elf_getphdr(elf)) == NULL) { 878 failure(file, MSG_ORIG(MSG_ELF_GETPHDR)); 879 return; 880 } 881 882 for (cnt = 0; cnt < phnum; phdr++, cnt++) { 883 if (phdr->p_type == PT_SUNWCAP) { 884 cphdr_off = phdr->p_offset; 885 cphdr_sz = phdr->p_filesz; 886 break; 887 } 888 } 889 } 890 891 /* 892 * Determine if a hardware/software capabilities section exists. 893 */ 894 for (cnt = 1; cnt < shnum; cnt++) { 895 Cache *_cache = &cache[cnt]; 896 Shdr *shdr = _cache->c_shdr; 897 898 if (shdr->sh_type != SHT_SUNW_cap) 899 continue; 900 901 if (cphdr_off && ((cphdr_off < shdr->sh_offset) || 902 (cphdr_off + cphdr_sz) > (shdr->sh_offset + shdr->sh_size))) 903 continue; 904 905 if (_cache->c_data == NULL) 906 continue; 907 908 ccache = _cache; 909 cshdr = shdr; 910 break; 911 } 912 913 if ((cshdr == NULL) && (cphdr_off == 0)) 914 return; 915 916 /* 917 * Print the hardware/software capabilities section. 918 */ 919 if (cshdr) { 920 Word ndx, capn; 921 Cap *cap = (Cap *)ccache->c_data->d_buf; 922 923 if ((cshdr->sh_entsize == 0) || (cshdr->sh_size == 0)) { 924 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 925 file, ccache->c_name); 926 return; 927 } 928 929 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 930 dbg_print(0, MSG_INTL(MSG_ELF_SCN_CAP), ccache->c_name); 931 932 Elf_cap_title(0); 933 934 capn = (Word)(cshdr->sh_size / cshdr->sh_entsize); 935 936 for (ndx = 0; ndx < capn; cap++, ndx++) { 937 if (cap->c_tag == CA_SUNW_NULL) 938 continue; 939 940 Elf_cap_entry(0, cap, ndx, ehdr->e_machine); 941 942 /* 943 * An SF1_SUNW_ADDR32 software capability in a 32-bit 944 * object is suspicious as it has no effect. 945 */ 946 if ((cap->c_tag == CA_SUNW_SF_1) && 947 (ehdr->e_ident[EI_CLASS] == ELFCLASS32) && 948 (cap->c_un.c_val & SF1_SUNW_ADDR32)) { 949 (void) fprintf(stderr, 950 MSG_INTL(MSG_WARN_INADDR32SF1), 951 file, ccache->c_name); 952 } 953 } 954 } else 955 (void) fprintf(stderr, MSG_INTL(MSG_WARN_INVCAP1), file); 956 957 /* 958 * If this object is an executable or shared object, then the 959 * hardware/software capabilities section should have an accompanying 960 * program header. 961 */ 962 if (cshdr && ((ehdr->e_type == ET_EXEC) || (ehdr->e_type == ET_DYN))) { 963 if (cphdr_off == 0) 964 (void) fprintf(stderr, MSG_INTL(MSG_WARN_INVCAP2), 965 file, ccache->c_name); 966 else if ((cphdr_off != cshdr->sh_offset) || 967 (cphdr_sz != cshdr->sh_size)) 968 (void) fprintf(stderr, MSG_INTL(MSG_WARN_INVCAP3), 969 file, ccache->c_name); 970 } 971 } 972 973 /* 974 * Print the interpretor. 975 */ 976 static void 977 interp(const char *file, Cache *cache, Word shnum, Word phnum, Elf *elf) 978 { 979 static Word phdr_types[] = { PT_INTERP }; 980 981 982 Word cnt; 983 Shdr *ishdr = NULL; 984 Cache *icache; 985 Off iphdr_off = 0; 986 Xword iphdr_fsz; 987 988 /* 989 * Determine if an interp header exists. 990 */ 991 if (phnum) { 992 Phdr *phdr; 993 994 phdr = getphdr(phnum, phdr_types, 995 sizeof (phdr_types) / sizeof (*phdr_types), file, elf); 996 if (phdr != NULL) { 997 iphdr_off = phdr->p_offset; 998 iphdr_fsz = phdr->p_filesz; 999 } 1000 } 1001 1002 if (iphdr_off == 0) 1003 return; 1004 1005 /* 1006 * Determine if an interp section exists. 1007 */ 1008 for (cnt = 1; cnt < shnum; cnt++) { 1009 Cache *_cache = &cache[cnt]; 1010 Shdr *shdr = _cache->c_shdr; 1011 1012 /* 1013 * Scan sections to find a section which contains the PT_INTERP 1014 * string. The target section can't be in a NOBITS section. 1015 */ 1016 if ((shdr->sh_type == SHT_NOBITS) || 1017 (iphdr_off < shdr->sh_offset) || 1018 (iphdr_off + iphdr_fsz) > (shdr->sh_offset + shdr->sh_size)) 1019 continue; 1020 1021 icache = _cache; 1022 ishdr = shdr; 1023 break; 1024 } 1025 1026 /* 1027 * Print the interpreter string based on the offset defined in the 1028 * program header, as this is the offset used by the kernel. 1029 */ 1030 if (ishdr && icache->c_data) { 1031 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1032 dbg_print(0, MSG_INTL(MSG_ELF_SCN_INTERP), icache->c_name); 1033 dbg_print(0, MSG_ORIG(MSG_FMT_INDENT), 1034 (char *)icache->c_data->d_buf + 1035 (iphdr_off - ishdr->sh_offset)); 1036 } else 1037 (void) fprintf(stderr, MSG_INTL(MSG_WARN_INVINTERP1), file); 1038 1039 /* 1040 * If there are any inconsistences between the program header and 1041 * section information, flag them. 1042 */ 1043 if (ishdr && ((iphdr_off != ishdr->sh_offset) || 1044 (iphdr_fsz != ishdr->sh_size))) { 1045 (void) fprintf(stderr, MSG_INTL(MSG_WARN_INVINTERP2), file, 1046 icache->c_name); 1047 } 1048 } 1049 1050 /* 1051 * Print the syminfo section. 1052 */ 1053 static void 1054 syminfo(Cache *cache, Word shnum, const char *file) 1055 { 1056 Shdr *infoshdr; 1057 Syminfo *info; 1058 Sym *syms; 1059 Dyn *dyns; 1060 Word infonum, cnt, ndx, symnum; 1061 Cache *infocache = NULL, *symsec, *strsec; 1062 1063 for (cnt = 1; cnt < shnum; cnt++) { 1064 if (cache[cnt].c_shdr->sh_type == SHT_SUNW_syminfo) { 1065 infocache = &cache[cnt]; 1066 break; 1067 } 1068 } 1069 if (infocache == NULL) 1070 return; 1071 1072 infoshdr = infocache->c_shdr; 1073 if ((infoshdr->sh_entsize == 0) || (infoshdr->sh_size == 0)) { 1074 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 1075 file, infocache->c_name); 1076 return; 1077 } 1078 if (infocache->c_data == NULL) 1079 return; 1080 1081 infonum = (Word)(infoshdr->sh_size / infoshdr->sh_entsize); 1082 info = (Syminfo *)infocache->c_data->d_buf; 1083 1084 /* 1085 * Get the data buffer of the associated dynamic section. 1086 */ 1087 if ((infoshdr->sh_info == 0) || (infoshdr->sh_info >= shnum)) { 1088 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHINFO), 1089 file, infocache->c_name, EC_WORD(infoshdr->sh_info)); 1090 return; 1091 } 1092 if (cache[infoshdr->sh_info].c_data == NULL) 1093 return; 1094 1095 dyns = cache[infoshdr->sh_info].c_data->d_buf; 1096 if (dyns == NULL) { 1097 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 1098 file, cache[infoshdr->sh_info].c_name); 1099 return; 1100 } 1101 1102 /* 1103 * Get the data buffer for the associated symbol table and string table. 1104 */ 1105 if (stringtbl(cache, 1, cnt, shnum, file, 1106 &symnum, &symsec, &strsec) == 0) 1107 return; 1108 1109 syms = symsec->c_data->d_buf; 1110 1111 /* 1112 * Loop through the syminfo entries. 1113 */ 1114 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1115 dbg_print(0, MSG_INTL(MSG_ELF_SCN_SYMINFO), infocache->c_name); 1116 Elf_syminfo_title(0); 1117 1118 for (ndx = 1, info++; ndx < infonum; ndx++, info++) { 1119 Sym *sym; 1120 const char *needed = NULL, *name; 1121 1122 if ((info->si_flags == 0) && (info->si_boundto == 0)) 1123 continue; 1124 1125 sym = &syms[ndx]; 1126 name = string(infocache, ndx, strsec, file, sym->st_name); 1127 1128 if (info->si_boundto < SYMINFO_BT_LOWRESERVE) { 1129 Dyn *dyn = &dyns[info->si_boundto]; 1130 1131 needed = string(infocache, info->si_boundto, 1132 strsec, file, dyn->d_un.d_val); 1133 } 1134 Elf_syminfo_entry(0, ndx, info, name, needed); 1135 } 1136 } 1137 1138 /* 1139 * Print version definition section entries. 1140 */ 1141 static void 1142 version_def(Verdef *vdf, Word vdf_num, Cache *vcache, Cache *scache, 1143 const char *file) 1144 { 1145 Word cnt; 1146 char index[MAXNDXSIZE]; 1147 1148 Elf_ver_def_title(0); 1149 1150 for (cnt = 1; cnt <= vdf_num; cnt++, 1151 vdf = (Verdef *)((uintptr_t)vdf + vdf->vd_next)) { 1152 Conv_ver_flags_buf_t ver_flags_buf; 1153 const char *name, *dep; 1154 Half vcnt = vdf->vd_cnt - 1; 1155 Half ndx = vdf->vd_ndx; 1156 Verdaux *vdap = (Verdaux *)((uintptr_t)vdf + vdf->vd_aux); 1157 1158 /* 1159 * Obtain the name and first dependency (if any). 1160 */ 1161 name = string(vcache, cnt, scache, file, vdap->vda_name); 1162 vdap = (Verdaux *)((uintptr_t)vdap + vdap->vda_next); 1163 if (vcnt) 1164 dep = string(vcache, cnt, scache, file, vdap->vda_name); 1165 else 1166 dep = MSG_ORIG(MSG_STR_EMPTY); 1167 1168 (void) snprintf(index, MAXNDXSIZE, MSG_ORIG(MSG_FMT_INDEX), 1169 EC_XWORD(ndx)); 1170 Elf_ver_line_1(0, index, name, dep, 1171 conv_ver_flags(vdf->vd_flags, 0, &ver_flags_buf)); 1172 1173 /* 1174 * Print any additional dependencies. 1175 */ 1176 if (vcnt) { 1177 vdap = (Verdaux *)((uintptr_t)vdap + vdap->vda_next); 1178 for (vcnt--; vcnt; vcnt--, 1179 vdap = (Verdaux *)((uintptr_t)vdap + 1180 vdap->vda_next)) { 1181 dep = string(vcache, cnt, scache, file, 1182 vdap->vda_name); 1183 Elf_ver_line_2(0, MSG_ORIG(MSG_STR_EMPTY), dep); 1184 } 1185 } 1186 } 1187 } 1188 1189 /* 1190 * Print version needed section entries. 1191 * 1192 * entry: 1193 * vnd - Address of verneed data 1194 * vnd_num - # of Verneed entries 1195 * vcache - Cache of verneed section being processed 1196 * scache - Cache of associated string table section 1197 * file - Name of object being processed. 1198 * versym - Information about versym section 1199 * 1200 * exit: 1201 * The versions have been printed. If GNU style versioning 1202 * is in effect, versym->max_verndx has been updated to 1203 * contain the largest version index seen. 1204 * 1205 * note: 1206 * The versym section of an object that follows the original 1207 * Solaris versioning rules only contains indexes into the verdef 1208 * section. Symbols defined in other objects (UNDEF) are given 1209 * a version of 0, indicating that they are not defined by 1210 * this file, and the Verneed entries do not have associated version 1211 * indexes. For these reasons, we do not display a version index 1212 * for original-style Verneed sections. 1213 * 1214 * The GNU versioning extensions alter this: Symbols defined in other 1215 * objects receive a version index in the range above those defined 1216 * by the Verdef section, and the vna_other field of the Vernaux 1217 * structs inside the Verneed section contain the version index for 1218 * that item. We therefore display the index when showing the 1219 * contents of a GNU style Verneed section. You should not 1220 * necessarily expect these indexes to appear in sorted 1221 * order --- it seems that the GNU ld assigns the versions as 1222 * symbols are encountered during linking, and then the results 1223 * are assembled into the Verneed section afterwards. 1224 */ 1225 static void 1226 version_need(Verneed *vnd, Word vnd_num, Cache *vcache, Cache *scache, 1227 const char *file, VERSYM_STATE *versym) 1228 { 1229 Word cnt; 1230 char index[MAXNDXSIZE]; 1231 const char *index_str; 1232 1233 Elf_ver_need_title(0, versym->gnu_needed); 1234 1235 for (cnt = 1; cnt <= vnd_num; cnt++, 1236 vnd = (Verneed *)((uintptr_t)vnd + vnd->vn_next)) { 1237 Conv_ver_flags_buf_t ver_flags_buf; 1238 const char *name, *dep; 1239 Half vcnt = vnd->vn_cnt; 1240 Vernaux *vnap = (Vernaux *)((uintptr_t)vnd + vnd->vn_aux); 1241 1242 /* 1243 * Obtain the name of the needed file and the version name 1244 * within it that we're dependent on. Note that the count 1245 * should be at least one, otherwise this is a pretty bogus 1246 * entry. 1247 */ 1248 name = string(vcache, cnt, scache, file, vnd->vn_file); 1249 if (vcnt) 1250 dep = string(vcache, cnt, scache, file, vnap->vna_name); 1251 else 1252 dep = MSG_INTL(MSG_STR_NULL); 1253 1254 if (vnap->vna_other == 0) { /* Traditional form */ 1255 index_str = MSG_ORIG(MSG_STR_EMPTY); 1256 } else { /* GNU form */ 1257 index_str = index; 1258 /* Format the version index value */ 1259 (void) snprintf(index, MAXNDXSIZE, 1260 MSG_ORIG(MSG_FMT_INDEX), EC_XWORD(vnap->vna_other)); 1261 if (vnap->vna_other > versym->max_verndx) 1262 versym->max_verndx = vnap->vna_other; 1263 } 1264 Elf_ver_line_1(0, index_str, name, dep, 1265 conv_ver_flags(vnap->vna_flags, 0, &ver_flags_buf)); 1266 1267 /* 1268 * Print any additional version dependencies. 1269 */ 1270 if (vcnt) { 1271 vnap = (Vernaux *)((uintptr_t)vnap + vnap->vna_next); 1272 for (vcnt--; vcnt; vcnt--, 1273 vnap = (Vernaux *)((uintptr_t)vnap + 1274 vnap->vna_next)) { 1275 dep = string(vcache, cnt, scache, file, 1276 vnap->vna_name); 1277 if (vnap->vna_other > 0) { 1278 /* Format the next index value */ 1279 (void) snprintf(index, MAXNDXSIZE, 1280 MSG_ORIG(MSG_FMT_INDEX), 1281 EC_XWORD(vnap->vna_other)); 1282 Elf_ver_line_1(0, index, 1283 MSG_ORIG(MSG_STR_EMPTY), dep, 1284 conv_ver_flags(vnap->vna_flags, 1285 0, &ver_flags_buf)); 1286 if (vnap->vna_other > 1287 versym->max_verndx) 1288 versym->max_verndx = 1289 vnap->vna_other; 1290 } else { 1291 Elf_ver_line_3(0, 1292 MSG_ORIG(MSG_STR_EMPTY), dep, 1293 conv_ver_flags(vnap->vna_flags, 1294 0, &ver_flags_buf)); 1295 } 1296 } 1297 } 1298 } 1299 } 1300 1301 /* 1302 * Examine the Verneed section for information related to GNU 1303 * style Versym indexing: 1304 * - A non-zero vna_other field indicates that Versym indexes can 1305 * reference Verneed records. 1306 * - If the object uses GNU style Versym indexing, the 1307 * maximum index value is needed to detect bad Versym entries. 1308 * 1309 * entry: 1310 * vnd - Address of verneed data 1311 * vnd_num - # of Verneed entries 1312 * versym - Information about versym section 1313 * 1314 * exit: 1315 * If a non-zero vna_other field is seen, versym->gnu_needed is set. 1316 * 1317 * versym->max_verndx has been updated to contain the largest 1318 * version index seen. 1319 */ 1320 static void 1321 update_gnu_verndx(Verneed *vnd, Word vnd_num, VERSYM_STATE *versym) 1322 { 1323 Word cnt; 1324 1325 for (cnt = 1; cnt <= vnd_num; cnt++, 1326 vnd = (Verneed *)((uintptr_t)vnd + vnd->vn_next)) { 1327 Half vcnt = vnd->vn_cnt; 1328 Vernaux *vnap = (Vernaux *)((uintptr_t)vnd + vnd->vn_aux); 1329 1330 /* 1331 * A non-zero value of vna_other indicates that this 1332 * object references VERNEED items from the VERSYM 1333 * array. 1334 */ 1335 if (vnap->vna_other != 0) { 1336 versym->gnu_needed = 1; 1337 if (vnap->vna_other > versym->max_verndx) 1338 versym->max_verndx = vnap->vna_other; 1339 } 1340 1341 /* 1342 * Check any additional version dependencies. 1343 */ 1344 if (vcnt) { 1345 vnap = (Vernaux *)((uintptr_t)vnap + vnap->vna_next); 1346 for (vcnt--; vcnt; vcnt--, 1347 vnap = (Vernaux *)((uintptr_t)vnap + 1348 vnap->vna_next)) { 1349 if (vnap->vna_other == 0) 1350 continue; 1351 1352 versym->gnu_needed = 1; 1353 if (vnap->vna_other > versym->max_verndx) 1354 versym->max_verndx = vnap->vna_other; 1355 } 1356 } 1357 } 1358 } 1359 1360 /* 1361 * Display version section information if the flags require it. 1362 * Return version information needed by other output. 1363 * 1364 * entry: 1365 * cache - Cache of all section headers 1366 * shnum - # of sections in cache 1367 * file - Name of file 1368 * flags - Command line option flags 1369 * versym - VERSYM_STATE block to be filled in. 1370 */ 1371 static void 1372 versions(Cache *cache, Word shnum, const char *file, uint_t flags, 1373 VERSYM_STATE *versym) 1374 { 1375 GElf_Word cnt; 1376 Cache *verdef_cache = NULL, *verneed_cache = NULL; 1377 1378 1379 /* Gather information about the version sections */ 1380 bzero(versym, sizeof (*versym)); 1381 versym->max_verndx = 1; 1382 for (cnt = 1; cnt < shnum; cnt++) { 1383 Cache *_cache = &cache[cnt]; 1384 Shdr *shdr = _cache->c_shdr; 1385 Dyn *dyn; 1386 ulong_t numdyn; 1387 1388 switch (shdr->sh_type) { 1389 case SHT_DYNAMIC: 1390 /* 1391 * The GNU ld puts a DT_VERSYM entry in the dynamic 1392 * section so that the runtime linker can use it to 1393 * implement their versioning rules. They allow multiple 1394 * incompatible functions with the same name to exist 1395 * in different versions. The Solaris ld does not 1396 * support this mechanism, and as such, does not 1397 * produce DT_VERSYM. We use this fact to determine 1398 * which ld produced this object, and how to interpret 1399 * the version values. 1400 */ 1401 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0) || 1402 (_cache->c_data == NULL)) 1403 continue; 1404 numdyn = shdr->sh_size / shdr->sh_entsize; 1405 dyn = (Dyn *)_cache->c_data->d_buf; 1406 for (; numdyn-- > 0; dyn++) 1407 if (dyn->d_tag == DT_VERSYM) { 1408 versym->gnu_full = 1409 versym->gnu_needed = 1; 1410 break; 1411 } 1412 break; 1413 1414 case SHT_SUNW_versym: 1415 /* Record data address for later symbol processing */ 1416 if (_cache->c_data != NULL) { 1417 versym->cache = _cache; 1418 versym->data = _cache->c_data->d_buf; 1419 continue; 1420 } 1421 break; 1422 1423 case SHT_SUNW_verdef: 1424 case SHT_SUNW_verneed: 1425 /* 1426 * Ensure the data is non-NULL and the number 1427 * of items is non-zero. Otherwise, we don't 1428 * understand the section, and will not use it. 1429 */ 1430 if ((_cache->c_data == NULL) || 1431 (_cache->c_data->d_buf == NULL)) { 1432 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 1433 file, _cache->c_name); 1434 continue; 1435 } 1436 if (shdr->sh_info == 0) { 1437 (void) fprintf(stderr, 1438 MSG_INTL(MSG_ERR_BADSHINFO), 1439 file, _cache->c_name, 1440 EC_WORD(shdr->sh_info)); 1441 continue; 1442 } 1443 1444 /* Make sure the string table index is in range */ 1445 if ((shdr->sh_link == 0) || (shdr->sh_link >= shnum)) { 1446 (void) fprintf(stderr, 1447 MSG_INTL(MSG_ERR_BADSHLINK), file, 1448 _cache->c_name, EC_WORD(shdr->sh_link)); 1449 continue; 1450 } 1451 1452 /* 1453 * The section is usable. Save the cache entry. 1454 */ 1455 if (shdr->sh_type == SHT_SUNW_verdef) { 1456 verdef_cache = _cache; 1457 /* 1458 * Under Solaris rules, if there is a verdef 1459 * section, the max versym index is number 1460 * of version definitions it supplies. 1461 */ 1462 versym->max_verndx = shdr->sh_info; 1463 } else { 1464 verneed_cache = _cache; 1465 } 1466 break; 1467 } 1468 } 1469 1470 /* 1471 * If there is a Verneed section, examine it for information 1472 * related to GNU style versioning. 1473 */ 1474 if (verneed_cache != NULL) 1475 update_gnu_verndx((Verneed *)verneed_cache->c_data->d_buf, 1476 verneed_cache->c_shdr->sh_info, versym); 1477 1478 /* 1479 * Now that all the information is available, display the 1480 * Verdef and Verneed section contents, if requested. 1481 */ 1482 if ((flags & FLG_SHOW_VERSIONS) == 0) 1483 return; 1484 if (verdef_cache != NULL) { 1485 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1486 dbg_print(0, MSG_INTL(MSG_ELF_SCN_VERDEF), 1487 verdef_cache->c_name); 1488 version_def((Verdef *)verdef_cache->c_data->d_buf, 1489 verdef_cache->c_shdr->sh_info, verdef_cache, 1490 &cache[verdef_cache->c_shdr->sh_link], file); 1491 } 1492 if (verneed_cache != NULL) { 1493 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1494 dbg_print(0, MSG_INTL(MSG_ELF_SCN_VERNEED), 1495 verneed_cache->c_name); 1496 /* 1497 * If GNU versioning applies to this object, version_need() 1498 * will update versym->max_verndx, and it is not 1499 * necessary to call update_gnu_verndx(). 1500 */ 1501 version_need((Verneed *)verneed_cache->c_data->d_buf, 1502 verneed_cache->c_shdr->sh_info, verneed_cache, 1503 &cache[verneed_cache->c_shdr->sh_link], file, versym); 1504 } 1505 } 1506 1507 /* 1508 * Initialize a symbol table state structure 1509 * 1510 * entry: 1511 * state - State structure to be initialized 1512 * cache - Cache of all section headers 1513 * shnum - # of sections in cache 1514 * secndx - Index of symbol table section 1515 * ehdr - ELF header for file 1516 * versym - Information about versym section 1517 * file - Name of file 1518 * flags - Command line option flags 1519 */ 1520 static int 1521 init_symtbl_state(SYMTBL_STATE *state, Cache *cache, Word shnum, Word secndx, 1522 Ehdr *ehdr, uchar_t osabi, VERSYM_STATE *versym, const char *file, 1523 uint_t flags) 1524 { 1525 Shdr *shdr; 1526 1527 state->file = file; 1528 state->ehdr = ehdr; 1529 state->cache = cache; 1530 state->osabi = osabi; 1531 state->shnum = shnum; 1532 state->seccache = &cache[secndx]; 1533 state->secndx = secndx; 1534 state->secname = state->seccache->c_name; 1535 state->flags = flags; 1536 state->shxndx.checked = 0; 1537 state->shxndx.data = NULL; 1538 state->shxndx.n = 0; 1539 1540 shdr = state->seccache->c_shdr; 1541 1542 /* 1543 * Check the symbol data and per-item size. 1544 */ 1545 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0)) { 1546 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 1547 file, state->secname); 1548 return (0); 1549 } 1550 if (state->seccache->c_data == NULL) 1551 return (0); 1552 1553 /* LINTED */ 1554 state->symn = (Word)(shdr->sh_size / shdr->sh_entsize); 1555 state->sym = (Sym *)state->seccache->c_data->d_buf; 1556 1557 /* 1558 * Check associated string table section. 1559 */ 1560 if ((shdr->sh_link == 0) || (shdr->sh_link >= shnum)) { 1561 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 1562 file, state->secname, EC_WORD(shdr->sh_link)); 1563 return (0); 1564 } 1565 1566 /* 1567 * Determine if there is a associated Versym section 1568 * with this Symbol Table. 1569 */ 1570 if (versym->cache && 1571 (versym->cache->c_shdr->sh_link == state->secndx)) 1572 state->versym = versym; 1573 else 1574 state->versym = NULL; 1575 1576 1577 return (1); 1578 } 1579 1580 /* 1581 * Determine the extended section index used for symbol tables entries. 1582 */ 1583 static void 1584 symbols_getxindex(SYMTBL_STATE *state) 1585 { 1586 uint_t symn; 1587 Word symcnt; 1588 1589 state->shxndx.checked = 1; /* Note that we've been called */ 1590 for (symcnt = 1; symcnt < state->shnum; symcnt++) { 1591 Cache *_cache = &state->cache[symcnt]; 1592 Shdr *shdr = _cache->c_shdr; 1593 1594 if ((shdr->sh_type != SHT_SYMTAB_SHNDX) || 1595 (shdr->sh_link != state->secndx)) 1596 continue; 1597 1598 if ((shdr->sh_entsize) && 1599 /* LINTED */ 1600 ((symn = (uint_t)(shdr->sh_size / shdr->sh_entsize)) == 0)) 1601 continue; 1602 1603 if (_cache->c_data == NULL) 1604 continue; 1605 1606 state->shxndx.data = _cache->c_data->d_buf; 1607 state->shxndx.n = symn; 1608 return; 1609 } 1610 } 1611 1612 /* 1613 * Produce a line of output for the given symbol 1614 * 1615 * entry: 1616 * state - Symbol table state 1617 * symndx - Index of symbol within the table 1618 * info - Value of st_info (indicates local/global range) 1619 * symndx_disp - Index to display. This may not be the same 1620 * as symndx if the display is relative to the logical 1621 * combination of the SUNW_ldynsym/dynsym tables. 1622 * sym - Symbol to display 1623 */ 1624 static void 1625 output_symbol(SYMTBL_STATE *state, Word symndx, Word info, Word disp_symndx, 1626 Sym *sym) 1627 { 1628 /* 1629 * Symbol types for which we check that the specified 1630 * address/size land inside the target section. 1631 */ 1632 static const int addr_symtype[] = { 1633 0, /* STT_NOTYPE */ 1634 1, /* STT_OBJECT */ 1635 1, /* STT_FUNC */ 1636 0, /* STT_SECTION */ 1637 0, /* STT_FILE */ 1638 1, /* STT_COMMON */ 1639 0, /* STT_TLS */ 1640 0, /* STT_IFUNC */ 1641 0, /* 8 */ 1642 0, /* 9 */ 1643 0, /* 10 */ 1644 0, /* 11 */ 1645 0, /* 12 */ 1646 0, /* STT_SPARC_REGISTER */ 1647 0, /* 14 */ 1648 0, /* 15 */ 1649 }; 1650 #if STT_NUM != (STT_IFUNC + 1) 1651 #error "STT_NUM has grown. Update addr_symtype[]" 1652 #endif 1653 1654 char index[MAXNDXSIZE]; 1655 const char *symname, *sec; 1656 Versym verndx; 1657 int gnuver; 1658 uchar_t type; 1659 Shdr *tshdr; 1660 Word shndx; 1661 Conv_inv_buf_t inv_buf; 1662 1663 /* Ensure symbol index is in range */ 1664 if (symndx >= state->symn) { 1665 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSORTNDX), 1666 state->file, state->secname, EC_WORD(symndx)); 1667 return; 1668 } 1669 1670 /* 1671 * If we are using extended symbol indexes, find the 1672 * corresponding SHN_SYMTAB_SHNDX table. 1673 */ 1674 if ((sym->st_shndx == SHN_XINDEX) && (state->shxndx.checked == 0)) 1675 symbols_getxindex(state); 1676 1677 /* LINTED */ 1678 symname = string(state->seccache, symndx, 1679 &state->cache[state->seccache->c_shdr->sh_link], state->file, 1680 sym->st_name); 1681 1682 tshdr = NULL; 1683 sec = NULL; 1684 1685 if (state->ehdr->e_type == ET_CORE) { 1686 sec = (char *)MSG_INTL(MSG_STR_UNKNOWN); 1687 } else if (state->flags & FLG_CTL_FAKESHDR) { 1688 /* 1689 * If we are using fake section headers derived from 1690 * the program headers, then the section indexes 1691 * in the symbols do not correspond to these headers. 1692 * The section names are not available, so all we can 1693 * do is to display them in numeric form. 1694 */ 1695 sec = conv_sym_shndx(state->osabi, state->ehdr->e_machine, 1696 sym->st_shndx, CONV_FMT_DECIMAL, &inv_buf); 1697 } else if ((sym->st_shndx < SHN_LORESERVE) && 1698 (sym->st_shndx < state->shnum)) { 1699 shndx = sym->st_shndx; 1700 tshdr = state->cache[shndx].c_shdr; 1701 sec = state->cache[shndx].c_name; 1702 } else if (sym->st_shndx == SHN_XINDEX) { 1703 if (state->shxndx.data) { 1704 Word _shxndx; 1705 1706 if (symndx > state->shxndx.n) { 1707 (void) fprintf(stderr, 1708 MSG_INTL(MSG_ERR_BADSYMXINDEX1), 1709 state->file, state->secname, 1710 EC_WORD(symndx)); 1711 } else if ((_shxndx = 1712 state->shxndx.data[symndx]) > state->shnum) { 1713 (void) fprintf(stderr, 1714 MSG_INTL(MSG_ERR_BADSYMXINDEX2), 1715 state->file, state->secname, 1716 EC_WORD(symndx), EC_WORD(_shxndx)); 1717 } else { 1718 shndx = _shxndx; 1719 tshdr = state->cache[shndx].c_shdr; 1720 sec = state->cache[shndx].c_name; 1721 } 1722 } else { 1723 (void) fprintf(stderr, 1724 MSG_INTL(MSG_ERR_BADSYMXINDEX3), 1725 state->file, state->secname, EC_WORD(symndx)); 1726 } 1727 } else if ((sym->st_shndx < SHN_LORESERVE) && 1728 (sym->st_shndx >= state->shnum)) { 1729 (void) fprintf(stderr, 1730 MSG_INTL(MSG_ERR_BADSYM5), state->file, 1731 state->secname, EC_WORD(symndx), 1732 demangle(symname, state->flags), sym->st_shndx); 1733 } 1734 1735 /* 1736 * If versioning is available display the 1737 * version index. If not, then use 0. 1738 */ 1739 if (state->versym) { 1740 Versym test_verndx; 1741 1742 verndx = test_verndx = state->versym->data[symndx]; 1743 gnuver = state->versym->gnu_full; 1744 1745 /* 1746 * Check to see if this is a defined symbol with a 1747 * version index that is outside the valid range for 1748 * the file. The interpretation of this depends on 1749 * the style of versioning used by the object. 1750 * 1751 * Versions >= VER_NDX_LORESERVE have special meanings, 1752 * and are exempt from this checking. 1753 * 1754 * GNU style version indexes use the top bit of the 1755 * 16-bit index value (0x8000) as the "hidden bit". 1756 * We must mask off this bit in order to compare 1757 * the version against the maximum value. 1758 */ 1759 if (gnuver) 1760 test_verndx &= ~0x8000; 1761 1762 if ((test_verndx > state->versym->max_verndx) && 1763 (verndx < VER_NDX_LORESERVE)) 1764 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADVER), 1765 state->file, state->secname, EC_WORD(symndx), 1766 EC_HALF(test_verndx), state->versym->max_verndx); 1767 } else { 1768 verndx = 0; 1769 gnuver = 0; 1770 } 1771 1772 /* 1773 * Error checking for TLS. 1774 */ 1775 type = ELF_ST_TYPE(sym->st_info); 1776 if (type == STT_TLS) { 1777 if (tshdr && 1778 (sym->st_shndx != SHN_UNDEF) && 1779 ((tshdr->sh_flags & SHF_TLS) == 0)) { 1780 (void) fprintf(stderr, 1781 MSG_INTL(MSG_ERR_BADSYM3), state->file, 1782 state->secname, EC_WORD(symndx), 1783 demangle(symname, state->flags)); 1784 } 1785 } else if ((type != STT_SECTION) && sym->st_size && 1786 tshdr && (tshdr->sh_flags & SHF_TLS)) { 1787 (void) fprintf(stderr, 1788 MSG_INTL(MSG_ERR_BADSYM4), state->file, 1789 state->secname, EC_WORD(symndx), 1790 demangle(symname, state->flags)); 1791 } 1792 1793 /* 1794 * If a symbol with non-zero size has a type that 1795 * specifies an address, then make sure the location 1796 * it references is actually contained within the 1797 * section. UNDEF symbols don't count in this case, 1798 * so we ignore them. 1799 * 1800 * The meaning of the st_value field in a symbol 1801 * depends on the type of object. For a relocatable 1802 * object, it is the offset within the section. 1803 * For sharable objects, it is the offset relative to 1804 * the base of the object, and for other types, it is 1805 * the virtual address. To get an offset within the 1806 * section for non-ET_REL files, we subtract the 1807 * base address of the section. 1808 */ 1809 if (addr_symtype[type] && (sym->st_size > 0) && 1810 (sym->st_shndx != SHN_UNDEF) && ((sym->st_shndx < SHN_LORESERVE) || 1811 (sym->st_shndx == SHN_XINDEX)) && (tshdr != NULL)) { 1812 Word v = sym->st_value; 1813 if (state->ehdr->e_type != ET_REL) 1814 v -= tshdr->sh_addr; 1815 if (((v + sym->st_size) > tshdr->sh_size)) { 1816 (void) fprintf(stderr, 1817 MSG_INTL(MSG_ERR_BADSYM6), state->file, 1818 state->secname, EC_WORD(symndx), 1819 demangle(symname, state->flags), 1820 EC_WORD(shndx), EC_XWORD(tshdr->sh_size), 1821 EC_XWORD(sym->st_value), EC_XWORD(sym->st_size)); 1822 } 1823 } 1824 1825 /* 1826 * A typical symbol table uses the sh_info field to indicate one greater 1827 * than the symbol table index of the last local symbol, STB_LOCAL. 1828 * Therefore, symbol indexes less than sh_info should have local 1829 * binding. Symbol indexes greater than, or equal to sh_info, should 1830 * have global binding. Note, we exclude UNDEF/NOTY symbols with zero 1831 * value and size, as these symbols may be the result of an mcs(1) 1832 * section deletion. 1833 */ 1834 if (info) { 1835 uchar_t bind = ELF_ST_BIND(sym->st_info); 1836 1837 if ((symndx < info) && (bind != STB_LOCAL)) { 1838 (void) fprintf(stderr, 1839 MSG_INTL(MSG_ERR_BADSYM7), state->file, 1840 state->secname, EC_WORD(symndx), 1841 demangle(symname, state->flags), EC_XWORD(info)); 1842 1843 } else if ((symndx >= info) && (bind == STB_LOCAL) && 1844 ((sym->st_shndx != SHN_UNDEF) || 1845 (ELF_ST_TYPE(sym->st_info) != STT_NOTYPE) || 1846 (sym->st_size != 0) || (sym->st_value != 0))) { 1847 (void) fprintf(stderr, 1848 MSG_INTL(MSG_ERR_BADSYM8), state->file, 1849 state->secname, EC_WORD(symndx), 1850 demangle(symname, state->flags), EC_XWORD(info)); 1851 } 1852 } 1853 1854 (void) snprintf(index, MAXNDXSIZE, 1855 MSG_ORIG(MSG_FMT_INDEX), EC_XWORD(disp_symndx)); 1856 Elf_syms_table_entry(0, ELF_DBG_ELFDUMP, index, state->osabi, 1857 state->ehdr->e_machine, sym, verndx, gnuver, sec, symname); 1858 } 1859 1860 /* 1861 * Search for and process any symbol tables. 1862 */ 1863 void 1864 symbols(Cache *cache, Word shnum, Ehdr *ehdr, uchar_t osabi, 1865 VERSYM_STATE *versym, const char *file, uint_t flags) 1866 { 1867 SYMTBL_STATE state; 1868 Cache *_cache; 1869 Word secndx; 1870 1871 for (secndx = 1; secndx < shnum; secndx++) { 1872 Word symcnt; 1873 Shdr *shdr; 1874 1875 _cache = &cache[secndx]; 1876 shdr = _cache->c_shdr; 1877 1878 if ((shdr->sh_type != SHT_SYMTAB) && 1879 (shdr->sh_type != SHT_DYNSYM) && 1880 ((shdr->sh_type != SHT_SUNW_LDYNSYM) || 1881 (osabi != ELFOSABI_SOLARIS))) 1882 continue; 1883 if (!match(MATCH_F_ALL, _cache->c_name, secndx, shdr->sh_type)) 1884 continue; 1885 1886 if (!init_symtbl_state(&state, cache, shnum, secndx, ehdr, 1887 osabi, versym, file, flags)) 1888 continue; 1889 /* 1890 * Loop through the symbol tables entries. 1891 */ 1892 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1893 dbg_print(0, MSG_INTL(MSG_ELF_SCN_SYMTAB), state.secname); 1894 Elf_syms_table_title(0, ELF_DBG_ELFDUMP); 1895 1896 for (symcnt = 0; symcnt < state.symn; symcnt++) 1897 output_symbol(&state, symcnt, shdr->sh_info, symcnt, 1898 state.sym + symcnt); 1899 } 1900 } 1901 1902 /* 1903 * Search for and process any SHT_SUNW_symsort or SHT_SUNW_tlssort sections. 1904 * These sections are always associated with the .SUNW_ldynsym./.dynsym pair. 1905 */ 1906 static void 1907 sunw_sort(Cache *cache, Word shnum, Ehdr *ehdr, uchar_t osabi, 1908 VERSYM_STATE *versym, const char *file, uint_t flags) 1909 { 1910 SYMTBL_STATE ldynsym_state, dynsym_state; 1911 Cache *sortcache, *symcache; 1912 Shdr *sortshdr, *symshdr; 1913 Word sortsecndx, symsecndx; 1914 Word ldynsym_cnt; 1915 Word *ndx; 1916 Word ndxn; 1917 int output_cnt = 0; 1918 Conv_inv_buf_t inv_buf; 1919 1920 for (sortsecndx = 1; sortsecndx < shnum; sortsecndx++) { 1921 1922 sortcache = &cache[sortsecndx]; 1923 sortshdr = sortcache->c_shdr; 1924 1925 if ((sortshdr->sh_type != SHT_SUNW_symsort) && 1926 (sortshdr->sh_type != SHT_SUNW_tlssort)) 1927 continue; 1928 if (!match(MATCH_F_ALL, sortcache->c_name, sortsecndx, 1929 sortshdr->sh_type)) 1930 continue; 1931 1932 /* 1933 * If the section references a SUNW_ldynsym, then we 1934 * expect to see the associated .dynsym immediately 1935 * following. If it references a .dynsym, there is no 1936 * SUNW_ldynsym. If it is any other type, then we don't 1937 * know what to do with it. 1938 */ 1939 if ((sortshdr->sh_link == 0) || (sortshdr->sh_link >= shnum)) { 1940 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 1941 file, sortcache->c_name, 1942 EC_WORD(sortshdr->sh_link)); 1943 continue; 1944 } 1945 symcache = &cache[sortshdr->sh_link]; 1946 symshdr = symcache->c_shdr; 1947 symsecndx = sortshdr->sh_link; 1948 ldynsym_cnt = 0; 1949 switch (symshdr->sh_type) { 1950 case SHT_SUNW_LDYNSYM: 1951 if (!init_symtbl_state(&ldynsym_state, cache, shnum, 1952 symsecndx, ehdr, osabi, versym, file, flags)) 1953 continue; 1954 ldynsym_cnt = ldynsym_state.symn; 1955 /* 1956 * We know that the dynsym follows immediately 1957 * after the SUNW_ldynsym, and so, should be at 1958 * (sortshdr->sh_link + 1). However, elfdump is a 1959 * diagnostic tool, so we do the full paranoid 1960 * search instead. 1961 */ 1962 for (symsecndx = 1; symsecndx < shnum; symsecndx++) { 1963 symcache = &cache[symsecndx]; 1964 symshdr = symcache->c_shdr; 1965 if (symshdr->sh_type == SHT_DYNSYM) 1966 break; 1967 } 1968 if (symsecndx >= shnum) { /* Dynsym not found! */ 1969 (void) fprintf(stderr, 1970 MSG_INTL(MSG_ERR_NODYNSYM), 1971 file, sortcache->c_name); 1972 continue; 1973 } 1974 /* Fallthrough to process associated dynsym */ 1975 /* FALLTHROUGH */ 1976 case SHT_DYNSYM: 1977 if (!init_symtbl_state(&dynsym_state, cache, shnum, 1978 symsecndx, ehdr, osabi, versym, file, flags)) 1979 continue; 1980 break; 1981 default: 1982 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADNDXSEC), 1983 file, sortcache->c_name, 1984 conv_sec_type(osabi, ehdr->e_machine, 1985 symshdr->sh_type, 0, &inv_buf)); 1986 continue; 1987 } 1988 1989 /* 1990 * Output header 1991 */ 1992 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 1993 if (ldynsym_cnt > 0) { 1994 dbg_print(0, MSG_INTL(MSG_ELF_SCN_SYMSORT2), 1995 sortcache->c_name, ldynsym_state.secname, 1996 dynsym_state.secname); 1997 /* 1998 * The data for .SUNW_ldynsym and dynsym sections 1999 * is supposed to be adjacent with SUNW_ldynsym coming 2000 * first. Check, and issue a warning if it isn't so. 2001 */ 2002 if (((ldynsym_state.sym + ldynsym_state.symn) 2003 != dynsym_state.sym) && 2004 ((flags & FLG_CTL_FAKESHDR) == 0)) 2005 (void) fprintf(stderr, 2006 MSG_INTL(MSG_ERR_LDYNNOTADJ), file, 2007 ldynsym_state.secname, 2008 dynsym_state.secname); 2009 } else { 2010 dbg_print(0, MSG_INTL(MSG_ELF_SCN_SYMSORT1), 2011 sortcache->c_name, dynsym_state.secname); 2012 } 2013 Elf_syms_table_title(0, ELF_DBG_ELFDUMP); 2014 2015 /* If not first one, insert a line of whitespace */ 2016 if (output_cnt++ > 0) 2017 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 2018 2019 /* 2020 * SUNW_dynsymsort and SUNW_dyntlssort are arrays of 2021 * symbol indices. Iterate over the array entries, 2022 * dispaying the referenced symbols. 2023 */ 2024 ndxn = sortshdr->sh_size / sortshdr->sh_entsize; 2025 ndx = (Word *)sortcache->c_data->d_buf; 2026 for (; ndxn-- > 0; ndx++) { 2027 if (*ndx >= ldynsym_cnt) { 2028 Word sec_ndx = *ndx - ldynsym_cnt; 2029 2030 output_symbol(&dynsym_state, sec_ndx, 0, 2031 *ndx, dynsym_state.sym + sec_ndx); 2032 } else { 2033 output_symbol(&ldynsym_state, *ndx, 0, 2034 *ndx, ldynsym_state.sym + *ndx); 2035 } 2036 } 2037 } 2038 } 2039 2040 /* 2041 * Search for and process any relocation sections. 2042 */ 2043 static void 2044 reloc(Cache *cache, Word shnum, Ehdr *ehdr, const char *file) 2045 { 2046 Word cnt; 2047 2048 for (cnt = 1; cnt < shnum; cnt++) { 2049 Word type, symnum; 2050 Xword relndx, relnum, relsize; 2051 void *rels; 2052 Sym *syms; 2053 Cache *symsec, *strsec; 2054 Cache *_cache = &cache[cnt]; 2055 Shdr *shdr = _cache->c_shdr; 2056 char *relname = _cache->c_name; 2057 Conv_inv_buf_t inv_buf; 2058 2059 if (((type = shdr->sh_type) != SHT_RELA) && 2060 (type != SHT_REL)) 2061 continue; 2062 if (!match(MATCH_F_ALL, relname, cnt, type)) 2063 continue; 2064 2065 /* 2066 * Decide entry size. 2067 */ 2068 if (((relsize = shdr->sh_entsize) == 0) || 2069 (relsize > shdr->sh_size)) { 2070 if (type == SHT_RELA) 2071 relsize = sizeof (Rela); 2072 else 2073 relsize = sizeof (Rel); 2074 } 2075 2076 /* 2077 * Determine the number of relocations available. 2078 */ 2079 if (shdr->sh_size == 0) { 2080 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 2081 file, relname); 2082 continue; 2083 } 2084 if (_cache->c_data == NULL) 2085 continue; 2086 2087 rels = _cache->c_data->d_buf; 2088 relnum = shdr->sh_size / relsize; 2089 2090 /* 2091 * Get the data buffer for the associated symbol table and 2092 * string table. 2093 */ 2094 if (stringtbl(cache, 1, cnt, shnum, file, 2095 &symnum, &symsec, &strsec) == 0) 2096 continue; 2097 2098 syms = symsec->c_data->d_buf; 2099 2100 /* 2101 * Loop through the relocation entries. 2102 */ 2103 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 2104 dbg_print(0, MSG_INTL(MSG_ELF_SCN_RELOC), _cache->c_name); 2105 Elf_reloc_title(0, ELF_DBG_ELFDUMP, type); 2106 2107 for (relndx = 0; relndx < relnum; relndx++, 2108 rels = (void *)((char *)rels + relsize)) { 2109 Half mach = ehdr->e_machine; 2110 char section[BUFSIZ]; 2111 const char *symname; 2112 Word symndx, reltype; 2113 Rela *rela; 2114 Rel *rel; 2115 2116 /* 2117 * Unravel the relocation and determine the symbol with 2118 * which this relocation is associated. 2119 */ 2120 if (type == SHT_RELA) { 2121 rela = (Rela *)rels; 2122 symndx = ELF_R_SYM(rela->r_info); 2123 reltype = ELF_R_TYPE(rela->r_info, mach); 2124 } else { 2125 rel = (Rel *)rels; 2126 symndx = ELF_R_SYM(rel->r_info); 2127 reltype = ELF_R_TYPE(rel->r_info, mach); 2128 } 2129 2130 symname = relsymname(cache, _cache, strsec, symndx, 2131 symnum, relndx, syms, section, BUFSIZ, file); 2132 2133 /* 2134 * A zero symbol index is only valid for a few 2135 * relocations. 2136 */ 2137 if (symndx == 0) { 2138 int badrel = 0; 2139 2140 if ((mach == EM_SPARC) || 2141 (mach == EM_SPARC32PLUS) || 2142 (mach == EM_SPARCV9)) { 2143 if ((reltype != R_SPARC_NONE) && 2144 (reltype != R_SPARC_REGISTER) && 2145 (reltype != R_SPARC_RELATIVE)) 2146 badrel++; 2147 } else if (mach == EM_386) { 2148 if ((reltype != R_386_NONE) && 2149 (reltype != R_386_RELATIVE)) 2150 badrel++; 2151 } else if (mach == EM_AMD64) { 2152 if ((reltype != R_AMD64_NONE) && 2153 (reltype != R_AMD64_RELATIVE)) 2154 badrel++; 2155 } 2156 2157 if (badrel) { 2158 (void) fprintf(stderr, 2159 MSG_INTL(MSG_ERR_BADREL1), file, 2160 conv_reloc_type(mach, reltype, 2161 0, &inv_buf)); 2162 } 2163 } 2164 2165 Elf_reloc_entry_1(0, ELF_DBG_ELFDUMP, 2166 MSG_ORIG(MSG_STR_EMPTY), ehdr->e_machine, type, 2167 rels, relname, symname, 0); 2168 } 2169 } 2170 } 2171 2172 2173 /* 2174 * This value controls which test dyn_test() performs. 2175 */ 2176 typedef enum { DYN_TEST_ADDR, DYN_TEST_SIZE, DYN_TEST_ENTSIZE } dyn_test_t; 2177 2178 /* 2179 * Used by dynamic() to compare the value of a dynamic element against 2180 * the starting address of the section it references. 2181 * 2182 * entry: 2183 * test_type - Specify which dyn item is being tested. 2184 * sh_type - SHT_* type value for required section. 2185 * sec_cache - Cache entry for section, or NULL if the object lacks 2186 * a section of this type. 2187 * dyn - Dyn entry to be tested 2188 * dynsec_cnt - # of dynamic section being examined. The first 2189 * dynamic section is 1, the next is 2, and so on... 2190 * ehdr - ELF header for file 2191 * file - Name of file 2192 */ 2193 static void 2194 dyn_test(dyn_test_t test_type, Word sh_type, Cache *sec_cache, Dyn *dyn, 2195 Word dynsec_cnt, Ehdr *ehdr, uchar_t osabi, const char *file) 2196 { 2197 Conv_inv_buf_t buf1, buf2; 2198 2199 /* 2200 * These tests are based around the implicit assumption that 2201 * there is only one dynamic section in an object, and also only 2202 * one of the sections it references. We have therefore gathered 2203 * all of the necessary information to test this in a single pass 2204 * over the section headers, which is very efficient. We are not 2205 * aware of any case where more than one dynamic section would 2206 * be meaningful in an ELF object, so this is a reasonable solution. 2207 * 2208 * To test multiple dynamic sections correctly would be more 2209 * expensive in code and time. We would have to build a data structure 2210 * containing all the dynamic elements. Then, we would use the address 2211 * to locate the section it references and ensure the section is of 2212 * the right type and that the address in the dynamic element is 2213 * to the start of the section. Then, we could check the size and 2214 * entsize values against those same sections. This is O(n^2), and 2215 * also complicated. 2216 * 2217 * In the highly unlikely case that there is more than one dynamic 2218 * section, we only test the first one, and simply allow the values 2219 * of the subsequent one to be displayed unchallenged. 2220 */ 2221 if (dynsec_cnt != 1) 2222 return; 2223 2224 /* 2225 * A DT_ item that references a section address should always find 2226 * the section in the file. 2227 */ 2228 if (sec_cache == NULL) { 2229 const char *name; 2230 2231 /* 2232 * Supply section names instead of section types for 2233 * things that reference progbits so that the error 2234 * message will make more sense. 2235 */ 2236 switch (dyn->d_tag) { 2237 case DT_INIT: 2238 name = MSG_ORIG(MSG_ELF_INIT); 2239 break; 2240 case DT_FINI: 2241 name = MSG_ORIG(MSG_ELF_FINI); 2242 break; 2243 default: 2244 name = conv_sec_type(osabi, ehdr->e_machine, 2245 sh_type, 0, &buf1); 2246 break; 2247 } 2248 (void) fprintf(stderr, MSG_INTL(MSG_ERR_DYNNOBCKSEC), file, 2249 name, conv_dyn_tag(dyn->d_tag, osabi, ehdr->e_machine, 2250 0, &buf2)); 2251 return; 2252 } 2253 2254 2255 switch (test_type) { 2256 case DYN_TEST_ADDR: 2257 /* The section address should match the DT_ item value */ 2258 if (dyn->d_un.d_val != sec_cache->c_shdr->sh_addr) 2259 (void) fprintf(stderr, 2260 MSG_INTL(MSG_ERR_DYNBADADDR), file, 2261 conv_dyn_tag(dyn->d_tag, osabi, ehdr->e_machine, 2262 0, &buf1), EC_ADDR(dyn->d_un.d_val), 2263 sec_cache->c_ndx, sec_cache->c_name, 2264 EC_ADDR(sec_cache->c_shdr->sh_addr)); 2265 break; 2266 2267 case DYN_TEST_SIZE: 2268 /* The section size should match the DT_ item value */ 2269 if (dyn->d_un.d_val != sec_cache->c_shdr->sh_size) 2270 (void) fprintf(stderr, 2271 MSG_INTL(MSG_ERR_DYNBADSIZE), file, 2272 conv_dyn_tag(dyn->d_tag, osabi, ehdr->e_machine, 2273 0, &buf1), EC_XWORD(dyn->d_un.d_val), 2274 sec_cache->c_ndx, sec_cache->c_name, 2275 EC_XWORD(sec_cache->c_shdr->sh_size)); 2276 break; 2277 2278 case DYN_TEST_ENTSIZE: 2279 /* The sh_entsize value should match the DT_ item value */ 2280 if (dyn->d_un.d_val != sec_cache->c_shdr->sh_entsize) 2281 (void) fprintf(stderr, 2282 MSG_INTL(MSG_ERR_DYNBADENTSIZE), file, 2283 conv_dyn_tag(dyn->d_tag, osabi, ehdr->e_machine, 2284 0, &buf1), EC_XWORD(dyn->d_un.d_val), 2285 sec_cache->c_ndx, sec_cache->c_name, 2286 EC_XWORD(sec_cache->c_shdr->sh_entsize)); 2287 break; 2288 } 2289 } 2290 2291 2292 /* 2293 * There are some DT_ entries that have corresponding symbols 2294 * (e.g. DT_INIT and _init). It is expected that these items will 2295 * both have the same value if both are present. This routine 2296 * examines the well known symbol tables for such symbols and 2297 * issues warnings for any that don't match. 2298 * 2299 * entry: 2300 * dyn - Dyn entry to be tested 2301 * symname - Name of symbol that corresponds to dyn 2302 * symtab_cache, dynsym_cache, ldynsym_cache - Symbol tables to check 2303 * cache - Cache of all section headers 2304 * shnum - # of sections in cache 2305 * ehdr - ELF header for file 2306 * file - Name of file 2307 */ 2308 static void 2309 dyn_symtest(Dyn *dyn, const char *symname, Cache *symtab_cache, 2310 Cache *dynsym_cache, Cache *ldynsym_cache, Cache *cache, 2311 Word shnum, Ehdr *ehdr, uchar_t osabi, const char *file) 2312 { 2313 Conv_inv_buf_t buf; 2314 int i; 2315 Sym *sym; 2316 Cache *_cache; 2317 2318 for (i = 0; i < 3; i++) { 2319 switch (i) { 2320 case 0: 2321 _cache = symtab_cache; 2322 break; 2323 case 1: 2324 _cache = dynsym_cache; 2325 break; 2326 case 2: 2327 _cache = ldynsym_cache; 2328 break; 2329 } 2330 2331 if ((_cache != NULL) && 2332 symlookup(symname, cache, shnum, &sym, _cache, file) && 2333 (sym->st_value != dyn->d_un.d_val)) 2334 (void) fprintf(stderr, MSG_INTL(MSG_ERR_DYNSYMVAL), 2335 file, _cache->c_name, conv_dyn_tag(dyn->d_tag, 2336 osabi, ehdr->e_machine, 0, &buf), 2337 symname, EC_ADDR(sym->st_value)); 2338 } 2339 } 2340 2341 2342 /* 2343 * Search for and process a .dynamic section. 2344 */ 2345 static void 2346 dynamic(Cache *cache, Word shnum, Ehdr *ehdr, uchar_t osabi, const char *file) 2347 { 2348 struct { 2349 Cache *symtab; 2350 Cache *dynstr; 2351 Cache *dynsym; 2352 Cache *hash; 2353 Cache *fini; 2354 Cache *fini_array; 2355 Cache *init; 2356 Cache *init_array; 2357 Cache *preinit_array; 2358 Cache *rel; 2359 Cache *rela; 2360 Cache *sunw_cap; 2361 Cache *sunw_ldynsym; 2362 Cache *sunw_move; 2363 Cache *sunw_syminfo; 2364 Cache *sunw_symsort; 2365 Cache *sunw_tlssort; 2366 Cache *sunw_verdef; 2367 Cache *sunw_verneed; 2368 Cache *sunw_versym; 2369 } sec; 2370 Word dynsec_ndx; 2371 Word dynsec_num; 2372 int dynsec_cnt; 2373 Word cnt; 2374 int osabi_solaris = osabi == ELFOSABI_SOLARIS; 2375 2376 /* 2377 * Make a pass over all the sections, gathering section information 2378 * we'll need below. 2379 */ 2380 dynsec_num = 0; 2381 bzero(&sec, sizeof (sec)); 2382 for (cnt = 1; cnt < shnum; cnt++) { 2383 Cache *_cache = &cache[cnt]; 2384 2385 switch (_cache->c_shdr->sh_type) { 2386 case SHT_DYNAMIC: 2387 if (dynsec_num == 0) { 2388 dynsec_ndx = cnt; 2389 2390 /* Does it have a valid string table? */ 2391 (void) stringtbl(cache, 0, cnt, shnum, file, 2392 0, 0, &sec.dynstr); 2393 } 2394 dynsec_num++; 2395 break; 2396 2397 2398 case SHT_PROGBITS: 2399 /* 2400 * We want to detect the .init and .fini sections, 2401 * if present. These are SHT_PROGBITS, so all we 2402 * have to go on is the section name. Normally comparing 2403 * names is a bad idea, but there are some special 2404 * names (i.e. .init/.fini/.interp) that are very 2405 * difficult to use in any other context, and for 2406 * these symbols, we do the heuristic match. 2407 */ 2408 if (strcmp(_cache->c_name, 2409 MSG_ORIG(MSG_ELF_INIT)) == 0) { 2410 if (sec.init == NULL) 2411 sec.init = _cache; 2412 } else if (strcmp(_cache->c_name, 2413 MSG_ORIG(MSG_ELF_FINI)) == 0) { 2414 if (sec.fini == NULL) 2415 sec.fini = _cache; 2416 } 2417 break; 2418 2419 case SHT_REL: 2420 /* 2421 * We want the SHT_REL section with the lowest 2422 * offset. The linker gathers them together, 2423 * and puts the address of the first one 2424 * into the DT_REL dynamic element. 2425 */ 2426 if ((sec.rel == NULL) || 2427 (_cache->c_shdr->sh_offset < 2428 sec.rel->c_shdr->sh_offset)) 2429 sec.rel = _cache; 2430 break; 2431 2432 case SHT_RELA: 2433 /* RELA is handled just like RELA above */ 2434 if ((sec.rela == NULL) || 2435 (_cache->c_shdr->sh_offset < 2436 sec.rela->c_shdr->sh_offset)) 2437 sec.rela = _cache; 2438 break; 2439 2440 /* 2441 * The GRAB macro is used for the simple case in which 2442 * we simply grab the first section of the desired type. 2443 */ 2444 #define GRAB(_sec_type, _sec_field) \ 2445 case _sec_type: \ 2446 if (sec._sec_field == NULL) \ 2447 sec._sec_field = _cache; \ 2448 break 2449 GRAB(SHT_SYMTAB, symtab); 2450 GRAB(SHT_DYNSYM, dynsym); 2451 GRAB(SHT_FINI_ARRAY, fini_array); 2452 GRAB(SHT_HASH, hash); 2453 GRAB(SHT_INIT_ARRAY, init_array); 2454 GRAB(SHT_SUNW_move, sunw_move); 2455 GRAB(SHT_PREINIT_ARRAY, preinit_array); 2456 GRAB(SHT_SUNW_cap, sunw_cap); 2457 GRAB(SHT_SUNW_LDYNSYM, sunw_ldynsym); 2458 GRAB(SHT_SUNW_syminfo, sunw_syminfo); 2459 GRAB(SHT_SUNW_symsort, sunw_symsort); 2460 GRAB(SHT_SUNW_tlssort, sunw_tlssort); 2461 GRAB(SHT_SUNW_verdef, sunw_verdef); 2462 GRAB(SHT_SUNW_verneed, sunw_verneed); 2463 GRAB(SHT_SUNW_versym, sunw_versym); 2464 #undef GRAB 2465 } 2466 } 2467 2468 /* 2469 * If no dynamic section, return immediately. If more than one 2470 * dynamic section, then something odd is going on and an error 2471 * is in order, but then continue on and display them all. 2472 */ 2473 if (dynsec_num == 0) 2474 return; 2475 if (dynsec_num > 1) 2476 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MULTDYN), 2477 file, EC_WORD(dynsec_num)); 2478 2479 2480 dynsec_cnt = 0; 2481 for (cnt = dynsec_ndx; (cnt < shnum) && (dynsec_cnt < dynsec_num); 2482 cnt++) { 2483 Dyn *dyn; 2484 ulong_t numdyn; 2485 int ndx, end_ndx; 2486 Cache *_cache = &cache[cnt], *strsec; 2487 Shdr *shdr = _cache->c_shdr; 2488 int dumped = 0; 2489 2490 if (shdr->sh_type != SHT_DYNAMIC) 2491 continue; 2492 dynsec_cnt++; 2493 2494 /* 2495 * Verify the associated string table section. 2496 */ 2497 if (stringtbl(cache, 0, cnt, shnum, file, 0, 0, &strsec) == 0) 2498 continue; 2499 2500 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0)) { 2501 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 2502 file, _cache->c_name); 2503 continue; 2504 } 2505 if (_cache->c_data == NULL) 2506 continue; 2507 2508 numdyn = shdr->sh_size / shdr->sh_entsize; 2509 dyn = (Dyn *)_cache->c_data->d_buf; 2510 2511 /* 2512 * We expect the REL/RELA entries to reference the reloc 2513 * section with the lowest address. However, this is 2514 * not true for dumped objects. Detect if this object has 2515 * been dumped so that we can skip the reloc address test 2516 * in that case. 2517 */ 2518 for (ndx = 0; ndx < numdyn; dyn++, ndx++) { 2519 if (dyn->d_tag == DT_FLAGS_1) { 2520 dumped = (dyn->d_un.d_val & DF_1_CONFALT) != 0; 2521 break; 2522 } 2523 } 2524 dyn = (Dyn *)_cache->c_data->d_buf; 2525 2526 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 2527 dbg_print(0, MSG_INTL(MSG_ELF_SCN_DYNAMIC), _cache->c_name); 2528 2529 Elf_dyn_title(0); 2530 2531 for (ndx = 0; ndx < numdyn; dyn++, ndx++) { 2532 union { 2533 Conv_inv_buf_t inv; 2534 Conv_dyn_flag_buf_t flag; 2535 Conv_dyn_flag1_buf_t flag1; 2536 Conv_dyn_posflag1_buf_t posflag1; 2537 Conv_dyn_feature1_buf_t feature1; 2538 } c_buf; 2539 const char *name = NULL; 2540 2541 /* 2542 * Print the information numerically, and if possible 2543 * as a string. If a string is available, name is 2544 * set to reference it. 2545 * 2546 * Also, take this opportunity to sanity check 2547 * the values of DT elements. In the code above, 2548 * we gathered information on sections that are 2549 * referenced by the dynamic section. Here, we 2550 * compare the attributes of those sections to 2551 * the DT_ items that reference them and report 2552 * on inconsistencies. 2553 * 2554 * Things not currently tested that could be improved 2555 * in later revisions include: 2556 * - We don't check PLT or GOT related items 2557 * - We don't handle computing the lengths of 2558 * relocation arrays. To handle this 2559 * requires examining data that spans 2560 * across sections, in a contiguous span 2561 * within a single segment. 2562 * - DT_VERDEFNUM and DT_VERNEEDNUM can't be 2563 * verified without parsing the sections. 2564 * - We don't handle DT_SUNW_SYMSZ, which would 2565 * be the sum of the lengths of .dynsym and 2566 * .SUNW_ldynsym 2567 * - DT_SUNW_STRPAD can't be verified other than 2568 * to check that it's not larger than 2569 * the string table. 2570 * - Some items come in "all or none" clusters 2571 * that give an address, element size, 2572 * and data length in bytes. We don't 2573 * verify that there are no missing items 2574 * in such groups. 2575 */ 2576 switch (dyn->d_tag) { 2577 case DT_NULL: 2578 /* 2579 * Special case: DT_NULLs can come in groups 2580 * that we prefer to reduce to a single line. 2581 */ 2582 end_ndx = ndx; 2583 while ((end_ndx < (numdyn - 1)) && 2584 ((dyn + 1)->d_tag == DT_NULL)) { 2585 dyn++; 2586 end_ndx++; 2587 } 2588 Elf_dyn_null_entry(0, dyn, ndx, end_ndx); 2589 ndx = end_ndx; 2590 continue; 2591 2592 /* 2593 * String items all reference the dynstr. The string() 2594 * function does the necessary sanity checking. 2595 */ 2596 case DT_NEEDED: 2597 case DT_SONAME: 2598 case DT_FILTER: 2599 case DT_AUXILIARY: 2600 case DT_CONFIG: 2601 case DT_RPATH: 2602 case DT_RUNPATH: 2603 case DT_USED: 2604 case DT_DEPAUDIT: 2605 case DT_AUDIT: 2606 name = string(_cache, ndx, strsec, 2607 file, dyn->d_un.d_ptr); 2608 break; 2609 2610 case DT_SUNW_AUXILIARY: 2611 case DT_SUNW_FILTER: 2612 if (osabi_solaris) 2613 name = string(_cache, ndx, strsec, 2614 file, dyn->d_un.d_ptr); 2615 break; 2616 2617 case DT_FLAGS: 2618 name = conv_dyn_flag(dyn->d_un.d_val, 2619 0, &c_buf.flag); 2620 break; 2621 case DT_FLAGS_1: 2622 name = conv_dyn_flag1(dyn->d_un.d_val, 0, 2623 &c_buf.flag1); 2624 break; 2625 case DT_POSFLAG_1: 2626 name = conv_dyn_posflag1(dyn->d_un.d_val, 0, 2627 &c_buf.posflag1); 2628 break; 2629 case DT_FEATURE_1: 2630 name = conv_dyn_feature1(dyn->d_un.d_val, 0, 2631 &c_buf.feature1); 2632 break; 2633 case DT_DEPRECATED_SPARC_REGISTER: 2634 name = MSG_INTL(MSG_STR_DEPRECATED); 2635 break; 2636 2637 case DT_SUNW_LDMACH: 2638 if (!osabi_solaris) 2639 break; 2640 name = conv_ehdr_mach((Half)dyn->d_un.d_val, 2641 0, &c_buf.inv); 2642 break; 2643 2644 /* 2645 * Cases below this point are strictly sanity checking, 2646 * and do not generate a name string. The TEST_ macros 2647 * are used to hide the boilerplate arguments neeeded 2648 * by dyn_test(). 2649 */ 2650 #define TEST_ADDR(_sh_type, _sec_field) \ 2651 dyn_test(DYN_TEST_ADDR, _sh_type, \ 2652 sec._sec_field, dyn, dynsec_cnt, ehdr, \ 2653 osabi, file) 2654 #define TEST_SIZE(_sh_type, _sec_field) \ 2655 dyn_test(DYN_TEST_SIZE, _sh_type, \ 2656 sec._sec_field, dyn, dynsec_cnt, ehdr, \ 2657 osabi, file) 2658 #define TEST_ENTSIZE(_sh_type, _sec_field) \ 2659 dyn_test(DYN_TEST_ENTSIZE, _sh_type, \ 2660 sec._sec_field, dyn, dynsec_cnt, ehdr, \ 2661 osabi, file) 2662 2663 case DT_FINI: 2664 dyn_symtest(dyn, MSG_ORIG(MSG_SYM_FINI), 2665 sec.symtab, sec.dynsym, sec.sunw_ldynsym, 2666 cache, shnum, ehdr, osabi, file); 2667 TEST_ADDR(SHT_PROGBITS, fini); 2668 break; 2669 2670 case DT_FINI_ARRAY: 2671 TEST_ADDR(SHT_FINI_ARRAY, fini_array); 2672 break; 2673 2674 case DT_FINI_ARRAYSZ: 2675 TEST_SIZE(SHT_FINI_ARRAY, fini_array); 2676 break; 2677 2678 case DT_HASH: 2679 TEST_ADDR(SHT_HASH, hash); 2680 break; 2681 2682 case DT_INIT: 2683 dyn_symtest(dyn, MSG_ORIG(MSG_SYM_INIT), 2684 sec.symtab, sec.dynsym, sec.sunw_ldynsym, 2685 cache, shnum, ehdr, osabi, file); 2686 TEST_ADDR(SHT_PROGBITS, init); 2687 break; 2688 2689 case DT_INIT_ARRAY: 2690 TEST_ADDR(SHT_INIT_ARRAY, init_array); 2691 break; 2692 2693 case DT_INIT_ARRAYSZ: 2694 TEST_SIZE(SHT_INIT_ARRAY, init_array); 2695 break; 2696 2697 case DT_MOVEENT: 2698 TEST_ENTSIZE(SHT_SUNW_move, sunw_move); 2699 break; 2700 2701 case DT_MOVESZ: 2702 TEST_SIZE(SHT_SUNW_move, sunw_move); 2703 break; 2704 2705 case DT_MOVETAB: 2706 TEST_ADDR(SHT_SUNW_move, sunw_move); 2707 break; 2708 2709 case DT_PREINIT_ARRAY: 2710 TEST_ADDR(SHT_PREINIT_ARRAY, preinit_array); 2711 break; 2712 2713 case DT_PREINIT_ARRAYSZ: 2714 TEST_SIZE(SHT_PREINIT_ARRAY, preinit_array); 2715 break; 2716 2717 case DT_REL: 2718 if (!dumped) 2719 TEST_ADDR(SHT_REL, rel); 2720 break; 2721 2722 case DT_RELENT: 2723 TEST_ENTSIZE(SHT_REL, rel); 2724 break; 2725 2726 case DT_RELA: 2727 if (!dumped) 2728 TEST_ADDR(SHT_RELA, rela); 2729 break; 2730 2731 case DT_RELAENT: 2732 TEST_ENTSIZE(SHT_RELA, rela); 2733 break; 2734 2735 case DT_STRTAB: 2736 TEST_ADDR(SHT_STRTAB, dynstr); 2737 break; 2738 2739 case DT_STRSZ: 2740 TEST_SIZE(SHT_STRTAB, dynstr); 2741 break; 2742 2743 case DT_SUNW_CAP: 2744 TEST_ADDR(SHT_SUNW_cap, sunw_cap); 2745 break; 2746 2747 case DT_SUNW_SYMTAB: 2748 TEST_ADDR(SHT_SUNW_LDYNSYM, sunw_ldynsym); 2749 break; 2750 2751 case DT_SYMENT: 2752 TEST_ENTSIZE(SHT_DYNSYM, dynsym); 2753 break; 2754 2755 case DT_SYMINENT: 2756 TEST_ENTSIZE(SHT_SUNW_syminfo, sunw_syminfo); 2757 break; 2758 2759 case DT_SYMINFO: 2760 TEST_ADDR(SHT_SUNW_syminfo, sunw_syminfo); 2761 break; 2762 2763 case DT_SYMINSZ: 2764 TEST_SIZE(SHT_SUNW_syminfo, sunw_syminfo); 2765 break; 2766 2767 case DT_SYMTAB: 2768 TEST_ADDR(SHT_DYNSYM, dynsym); 2769 break; 2770 2771 case DT_SUNW_SORTENT: 2772 /* 2773 * This entry is related to both the symsort and 2774 * tlssort sections. 2775 */ 2776 if (osabi_solaris) { 2777 int test_tls = 2778 (sec.sunw_tlssort != NULL); 2779 int test_sym = 2780 (sec.sunw_symsort != NULL) || 2781 !test_tls; 2782 if (test_sym) 2783 TEST_ENTSIZE(SHT_SUNW_symsort, 2784 sunw_symsort); 2785 if (test_tls) 2786 TEST_ENTSIZE(SHT_SUNW_tlssort, 2787 sunw_tlssort); 2788 } 2789 break; 2790 2791 2792 case DT_SUNW_SYMSORT: 2793 if (osabi_solaris) 2794 TEST_ADDR(SHT_SUNW_symsort, 2795 sunw_symsort); 2796 break; 2797 2798 case DT_SUNW_SYMSORTSZ: 2799 if (osabi_solaris) 2800 TEST_SIZE(SHT_SUNW_symsort, 2801 sunw_symsort); 2802 break; 2803 2804 case DT_SUNW_TLSSORT: 2805 if (osabi_solaris) 2806 TEST_ADDR(SHT_SUNW_tlssort, 2807 sunw_tlssort); 2808 break; 2809 2810 case DT_SUNW_TLSSORTSZ: 2811 if (osabi_solaris) 2812 TEST_SIZE(SHT_SUNW_tlssort, 2813 sunw_tlssort); 2814 break; 2815 2816 case DT_VERDEF: 2817 TEST_ADDR(SHT_SUNW_verdef, sunw_verdef); 2818 break; 2819 2820 case DT_VERNEED: 2821 TEST_ADDR(SHT_SUNW_verneed, sunw_verneed); 2822 break; 2823 2824 case DT_VERSYM: 2825 TEST_ADDR(SHT_SUNW_versym, sunw_versym); 2826 break; 2827 #undef TEST_ADDR 2828 #undef TEST_SIZE 2829 #undef TEST_ENTSIZE 2830 } 2831 2832 if (name == NULL) 2833 name = MSG_ORIG(MSG_STR_EMPTY); 2834 Elf_dyn_entry(0, dyn, ndx, name, 2835 osabi, ehdr->e_machine); 2836 } 2837 } 2838 } 2839 2840 /* 2841 * Search for and process a MOVE section. 2842 */ 2843 static void 2844 move(Cache *cache, Word shnum, const char *file, uint_t flags) 2845 { 2846 Word cnt; 2847 const char *fmt = NULL; 2848 2849 for (cnt = 1; cnt < shnum; cnt++) { 2850 Word movenum, symnum, ndx; 2851 Sym *syms; 2852 Cache *_cache = &cache[cnt]; 2853 Shdr *shdr = _cache->c_shdr; 2854 Cache *symsec, *strsec; 2855 Move *move; 2856 2857 if (shdr->sh_type != SHT_SUNW_move) 2858 continue; 2859 if (!match(MATCH_F_ALL, _cache->c_name, cnt, shdr->sh_type)) 2860 continue; 2861 2862 /* 2863 * Determine the move data and number. 2864 */ 2865 if ((shdr->sh_entsize == 0) || (shdr->sh_size == 0)) { 2866 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 2867 file, _cache->c_name); 2868 continue; 2869 } 2870 if (_cache->c_data == NULL) 2871 continue; 2872 2873 move = (Move *)_cache->c_data->d_buf; 2874 movenum = shdr->sh_size / shdr->sh_entsize; 2875 2876 /* 2877 * Get the data buffer for the associated symbol table and 2878 * string table. 2879 */ 2880 if (stringtbl(cache, 1, cnt, shnum, file, 2881 &symnum, &symsec, &strsec) == 0) 2882 return; 2883 2884 syms = (Sym *)symsec->c_data->d_buf; 2885 2886 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 2887 dbg_print(0, MSG_INTL(MSG_ELF_SCN_MOVE), _cache->c_name); 2888 dbg_print(0, MSG_INTL(MSG_MOVE_TITLE)); 2889 2890 if (fmt == NULL) 2891 fmt = MSG_INTL(MSG_MOVE_ENTRY); 2892 2893 for (ndx = 0; ndx < movenum; move++, ndx++) { 2894 const char *symname; 2895 char index[MAXNDXSIZE], section[BUFSIZ]; 2896 Word symndx, shndx; 2897 Sym *sym; 2898 2899 /* 2900 * Check for null entries 2901 */ 2902 if ((move->m_info == 0) && (move->m_value == 0) && 2903 (move->m_poffset == 0) && (move->m_repeat == 0) && 2904 (move->m_stride == 0)) { 2905 dbg_print(0, fmt, MSG_ORIG(MSG_STR_EMPTY), 2906 EC_XWORD(move->m_poffset), 0, 0, 0, 2907 EC_LWORD(0), MSG_ORIG(MSG_STR_EMPTY)); 2908 continue; 2909 } 2910 if (((symndx = ELF_M_SYM(move->m_info)) == 0) || 2911 (symndx >= symnum)) { 2912 (void) fprintf(stderr, 2913 MSG_INTL(MSG_ERR_BADMINFO), file, 2914 _cache->c_name, EC_XWORD(move->m_info)); 2915 2916 (void) snprintf(index, MAXNDXSIZE, 2917 MSG_ORIG(MSG_FMT_INDEX), EC_XWORD(symndx)); 2918 dbg_print(0, fmt, index, 2919 EC_XWORD(move->m_poffset), 2920 ELF_M_SIZE(move->m_info), move->m_repeat, 2921 move->m_stride, move->m_value, 2922 MSG_INTL(MSG_STR_UNKNOWN)); 2923 continue; 2924 } 2925 2926 symname = relsymname(cache, _cache, strsec, 2927 symndx, symnum, ndx, syms, section, BUFSIZ, file); 2928 sym = (Sym *)(syms + symndx); 2929 2930 /* 2931 * Additional sanity check. 2932 */ 2933 shndx = sym->st_shndx; 2934 if (!((shndx == SHN_COMMON) || 2935 (((shndx >= 1) && (shndx <= shnum)) && 2936 (cache[shndx].c_shdr)->sh_type == SHT_NOBITS))) { 2937 (void) fprintf(stderr, 2938 MSG_INTL(MSG_ERR_BADSYM2), file, 2939 _cache->c_name, EC_WORD(symndx), 2940 demangle(symname, flags)); 2941 } 2942 2943 (void) snprintf(index, MAXNDXSIZE, 2944 MSG_ORIG(MSG_FMT_INDEX), EC_XWORD(symndx)); 2945 dbg_print(0, fmt, index, EC_XWORD(move->m_poffset), 2946 ELF_M_SIZE(move->m_info), move->m_repeat, 2947 move->m_stride, move->m_value, 2948 demangle(symname, flags)); 2949 } 2950 } 2951 } 2952 2953 /* 2954 * parse_note_t is used to track the state used by parse_note_entry() 2955 * between calls, and also to return the results of each call. 2956 */ 2957 typedef struct { 2958 /* pns_ fields track progress through the data */ 2959 const char *pns_file; /* File name */ 2960 Cache *pns_cache; /* Note section cache entry */ 2961 size_t pns_size; /* # unprocessed data bytes */ 2962 Word *pns_data; /* # to next unused data byte */ 2963 2964 /* pn_ fields return the results for a single call */ 2965 Word pn_namesz; /* Value of note namesz field */ 2966 Word pn_descsz; /* Value of note descsz field */ 2967 Word pn_type; /* Value of note type field */ 2968 const char *pn_name; /* if (namesz > 0) ptr to name bytes */ 2969 const char *pn_desc; /* if (descsx > 0) ptr to data bytes */ 2970 } parse_note_t; 2971 2972 /* 2973 * Extract the various sub-parts of a note entry, and advance the 2974 * data pointer past it. 2975 * 2976 * entry: 2977 * The state pns_ fields contain current values for the Note section 2978 * 2979 * exit: 2980 * On success, True (1) is returned, the state pns_ fields have been 2981 * advanced to point at the start of the next entry, and the information 2982 * for the recovered note entry is found in the state pn_ fields. 2983 * 2984 * On failure, False (0) is returned. The values contained in state 2985 * are undefined. 2986 */ 2987 static int 2988 parse_note_entry(parse_note_t *state) 2989 { 2990 size_t pad, noteoff; 2991 2992 noteoff = (Word)state->pns_cache->c_data->d_size - state->pns_size; 2993 /* 2994 * Make sure we can at least reference the 3 initial entries 2995 * (4-byte words) of the note information block. 2996 */ 2997 if (state->pns_size >= (sizeof (Word) * 3)) { 2998 state->pns_size -= (sizeof (Word) * 3); 2999 } else { 3000 (void) fprintf(stderr, MSG_INTL(MSG_NOTE_BADDATASZ), 3001 state->pns_file, state->pns_cache->c_name, 3002 EC_WORD(noteoff)); 3003 return (0); 3004 } 3005 3006 /* 3007 * Make sure any specified name string can be referenced. 3008 */ 3009 if ((state->pn_namesz = *state->pns_data++) != 0) { 3010 if (state->pns_size >= state->pn_namesz) { 3011 state->pns_size -= state->pn_namesz; 3012 } else { 3013 (void) fprintf(stderr, MSG_INTL(MSG_NOTE_BADNMSZ), 3014 state->pns_file, state->pns_cache->c_name, 3015 EC_WORD(noteoff), EC_WORD(state->pn_namesz)); 3016 return (0); 3017 } 3018 } 3019 3020 /* 3021 * Make sure any specified descriptor can be referenced. 3022 */ 3023 if ((state->pn_descsz = *state->pns_data++) != 0) { 3024 /* 3025 * If namesz isn't a 4-byte multiple, account for any 3026 * padding that must exist before the descriptor. 3027 */ 3028 if ((pad = (state->pn_namesz & (sizeof (Word) - 1))) != 0) { 3029 pad = sizeof (Word) - pad; 3030 state->pns_size -= pad; 3031 } 3032 if (state->pns_size >= state->pn_descsz) { 3033 state->pns_size -= state->pn_descsz; 3034 } else { 3035 (void) fprintf(stderr, MSG_INTL(MSG_NOTE_BADDESZ), 3036 state->pns_file, state->pns_cache->c_name, 3037 EC_WORD(noteoff), EC_WORD(state->pn_namesz)); 3038 return (0); 3039 } 3040 } 3041 3042 state->pn_type = *state->pns_data++; 3043 3044 /* Name */ 3045 if (state->pn_namesz) { 3046 state->pn_name = (char *)state->pns_data; 3047 pad = (state->pn_namesz + 3048 (sizeof (Word) - 1)) & ~(sizeof (Word) - 1); 3049 /* LINTED */ 3050 state->pns_data = (Word *)(state->pn_name + pad); 3051 } 3052 3053 /* 3054 * If multiple information blocks exist within a .note section 3055 * account for any padding that must exist before the next 3056 * information block. 3057 */ 3058 if ((pad = (state->pn_descsz & (sizeof (Word) - 1))) != 0) { 3059 pad = sizeof (Word) - pad; 3060 if (state->pns_size > pad) 3061 state->pns_size -= pad; 3062 } 3063 3064 /* Data */ 3065 if (state->pn_descsz) { 3066 state->pn_desc = (const char *)state->pns_data; 3067 /* LINTED */ 3068 state->pns_data = (Word *)(state->pn_desc + 3069 state->pn_descsz + pad); 3070 } 3071 3072 return (1); 3073 } 3074 3075 /* 3076 * Callback function for use with conv_str_to_c_literal() below. 3077 */ 3078 /*ARGSUSED2*/ 3079 static void 3080 c_literal_cb(const void *ptr, size_t size, void *uvalue) 3081 { 3082 (void) fwrite(ptr, size, 1, stdout); 3083 } 3084 3085 /* 3086 * Traverse a note section analyzing each note information block. 3087 * The data buffers size is used to validate references before they are made, 3088 * and is decremented as each element is processed. 3089 */ 3090 void 3091 note_entry(Cache *cache, Word *data, size_t size, Ehdr *ehdr, const char *file) 3092 { 3093 int cnt = 0; 3094 int is_corenote; 3095 int do_swap; 3096 Conv_inv_buf_t inv_buf; 3097 parse_note_t pnstate; 3098 3099 pnstate.pns_file = file; 3100 pnstate.pns_cache = cache; 3101 pnstate.pns_size = size; 3102 pnstate.pns_data = data; 3103 do_swap = _elf_sys_encoding() != ehdr->e_ident[EI_DATA]; 3104 3105 /* 3106 * Print out a single `note' information block. 3107 */ 3108 while (pnstate.pns_size > 0) { 3109 3110 if (parse_note_entry(&pnstate) == 0) 3111 return; 3112 3113 /* 3114 * Is this a Solaris core note? Such notes all have 3115 * the name "CORE". 3116 */ 3117 is_corenote = (ehdr->e_type == ET_CORE) && 3118 (pnstate.pn_namesz == (MSG_STR_CORE_SIZE + 1)) && 3119 (strncmp(MSG_ORIG(MSG_STR_CORE), pnstate.pn_name, 3120 MSG_STR_CORE_SIZE + 1) == 0); 3121 3122 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3123 dbg_print(0, MSG_INTL(MSG_FMT_NOTEENTNDX), EC_WORD(cnt)); 3124 cnt++; 3125 dbg_print(0, MSG_ORIG(MSG_NOTE_NAMESZ), 3126 EC_WORD(pnstate.pn_namesz)); 3127 dbg_print(0, MSG_ORIG(MSG_NOTE_DESCSZ), 3128 EC_WORD(pnstate.pn_descsz)); 3129 3130 if (is_corenote) 3131 dbg_print(0, MSG_ORIG(MSG_NOTE_TYPE_STR), 3132 conv_cnote_type(pnstate.pn_type, 0, &inv_buf)); 3133 else 3134 dbg_print(0, MSG_ORIG(MSG_NOTE_TYPE), 3135 EC_WORD(pnstate.pn_type)); 3136 if (pnstate.pn_namesz) { 3137 dbg_print(0, MSG_ORIG(MSG_NOTE_NAME)); 3138 /* 3139 * The name string can contain embedded 'null' 3140 * bytes and/or unprintable characters. Also, 3141 * the final NULL is documented in the ELF ABI 3142 * as being included in the namesz. So, display 3143 * the name using C literal string notation, and 3144 * include the terminating NULL in the output. 3145 * We don't show surrounding double quotes, as 3146 * that implies the termination that we are showing 3147 * explicitly. 3148 */ 3149 (void) fwrite(MSG_ORIG(MSG_STR_8SP), 3150 MSG_STR_8SP_SIZE, 1, stdout); 3151 conv_str_to_c_literal(pnstate.pn_name, 3152 pnstate.pn_namesz, c_literal_cb, NULL); 3153 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3154 } 3155 3156 if (pnstate.pn_descsz) { 3157 int hexdump = 1; 3158 3159 /* 3160 * If this is a core note, let the corenote() 3161 * function handle it. 3162 */ 3163 if (is_corenote) { 3164 /* We only issue the bad arch error once */ 3165 static int badnote_done = 0; 3166 corenote_ret_t corenote_ret; 3167 3168 corenote_ret = corenote(ehdr->e_machine, 3169 do_swap, pnstate.pn_type, pnstate.pn_desc, 3170 pnstate.pn_descsz); 3171 switch (corenote_ret) { 3172 case CORENOTE_R_OK: 3173 hexdump = 0; 3174 break; 3175 case CORENOTE_R_BADDATA: 3176 (void) fprintf(stderr, 3177 MSG_INTL(MSG_NOTE_BADCOREDATA), 3178 file); 3179 break; 3180 case CORENOTE_R_BADARCH: 3181 if (badnote_done) 3182 break; 3183 (void) fprintf(stderr, 3184 MSG_INTL(MSG_NOTE_BADCOREARCH), 3185 file, 3186 conv_ehdr_mach(ehdr->e_machine, 3187 0, &inv_buf)); 3188 break; 3189 } 3190 } 3191 3192 /* 3193 * The default thing when we don't understand 3194 * the note data is to display it as hex bytes. 3195 */ 3196 if (hexdump) { 3197 dbg_print(0, MSG_ORIG(MSG_NOTE_DESC)); 3198 dump_hex_bytes(pnstate.pn_desc, 3199 pnstate.pn_descsz, 8, 4, 4); 3200 } 3201 } 3202 } 3203 } 3204 3205 /* 3206 * Search for and process .note sections. 3207 * 3208 * Returns the number of note sections seen. 3209 */ 3210 static Word 3211 note(Cache *cache, Word shnum, Ehdr *ehdr, const char *file) 3212 { 3213 Word cnt, note_cnt = 0; 3214 3215 /* 3216 * Otherwise look for any .note sections. 3217 */ 3218 for (cnt = 1; cnt < shnum; cnt++) { 3219 Cache *_cache = &cache[cnt]; 3220 Shdr *shdr = _cache->c_shdr; 3221 3222 if (shdr->sh_type != SHT_NOTE) 3223 continue; 3224 note_cnt++; 3225 if (!match(MATCH_F_ALL, _cache->c_name, cnt, shdr->sh_type)) 3226 continue; 3227 3228 /* 3229 * As these sections are often hand rolled, make sure they're 3230 * properly aligned before proceeding, and issue an error 3231 * as necessary. 3232 * 3233 * Note that we will continue on to display the note even 3234 * if it has bad alignment. We can do this safely, because 3235 * libelf knows the alignment required for SHT_NOTE, and 3236 * takes steps to deliver a properly aligned buffer to us 3237 * even if the actual file is misaligned. 3238 */ 3239 if (shdr->sh_offset & (sizeof (Word) - 1)) 3240 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADALIGN), 3241 file, _cache->c_name); 3242 3243 if (_cache->c_data == NULL) 3244 continue; 3245 3246 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3247 dbg_print(0, MSG_INTL(MSG_ELF_SCN_NOTE), _cache->c_name); 3248 note_entry(_cache, (Word *)_cache->c_data->d_buf, 3249 /* LINTED */ 3250 (Word)_cache->c_data->d_size, ehdr, file); 3251 } 3252 3253 return (note_cnt); 3254 } 3255 3256 /* 3257 * The Linux Standard Base defines a special note named .note.ABI-tag 3258 * that is used to maintain Linux ABI information. Presence of this section 3259 * is a strong indication that the object should be considered to be 3260 * ELFOSABI_LINUX. 3261 * 3262 * This function returns True (1) if such a note is seen, and False (0) 3263 * otherwise. 3264 */ 3265 static int 3266 has_linux_abi_note(Cache *cache, Word shnum, const char *file) 3267 { 3268 Word cnt; 3269 3270 for (cnt = 1; cnt < shnum; cnt++) { 3271 parse_note_t pnstate; 3272 Cache *_cache = &cache[cnt]; 3273 Shdr *shdr = _cache->c_shdr; 3274 3275 /* 3276 * Section must be SHT_NOTE, must have the name 3277 * .note.ABI-tag, and must have data. 3278 */ 3279 if ((shdr->sh_type != SHT_NOTE) || 3280 (strcmp(MSG_ORIG(MSG_STR_NOTEABITAG), 3281 _cache->c_name) != 0) || (_cache->c_data == NULL)) 3282 continue; 3283 3284 pnstate.pns_file = file; 3285 pnstate.pns_cache = _cache; 3286 pnstate.pns_size = _cache->c_data->d_size; 3287 pnstate.pns_data = (Word *)_cache->c_data->d_buf; 3288 3289 while (pnstate.pns_size > 0) { 3290 Word *w; 3291 3292 if (parse_note_entry(&pnstate) == 0) 3293 break; 3294 3295 /* 3296 * The type must be 1, and the name must be "GNU". 3297 * The descsz must be at least 16 bytes. 3298 */ 3299 if ((pnstate.pn_type != 1) || 3300 (pnstate.pn_namesz != (MSG_STR_GNU_SIZE + 1)) || 3301 (strncmp(MSG_ORIG(MSG_STR_GNU), pnstate.pn_name, 3302 MSG_STR_CORE_SIZE + 1) != 0) || 3303 (pnstate.pn_descsz < 16)) 3304 continue; 3305 3306 /* 3307 * desc contains 4 32-bit fields. Field 0 must be 0, 3308 * indicating Linux. The second, third, and fourth 3309 * fields represent the earliest Linux kernel 3310 * version compatible with this object. 3311 */ 3312 /*LINTED*/ 3313 w = (Word *) pnstate.pn_desc; 3314 if (*w == 0) 3315 return (1); 3316 } 3317 } 3318 3319 return (0); 3320 } 3321 3322 /* 3323 * Determine an individual hash entry. This may be the initial hash entry, 3324 * or an associated chain entry. 3325 */ 3326 static void 3327 hash_entry(Cache *refsec, Cache *strsec, const char *hsecname, Word hashndx, 3328 Word symndx, Word symn, Sym *syms, const char *file, ulong_t bkts, 3329 uint_t flags, int chain) 3330 { 3331 Sym *sym; 3332 const char *symname, *str; 3333 char _bucket[MAXNDXSIZE], _symndx[MAXNDXSIZE]; 3334 ulong_t nbkt, nhash; 3335 3336 if (symndx > symn) { 3337 (void) fprintf(stderr, MSG_INTL(MSG_ERR_HSBADSYMNDX), file, 3338 EC_WORD(symndx), EC_WORD(hashndx)); 3339 symname = MSG_INTL(MSG_STR_UNKNOWN); 3340 } else { 3341 sym = (Sym *)(syms + symndx); 3342 symname = string(refsec, symndx, strsec, file, sym->st_name); 3343 } 3344 3345 if (chain == 0) { 3346 (void) snprintf(_bucket, MAXNDXSIZE, MSG_ORIG(MSG_FMT_INTEGER), 3347 hashndx); 3348 str = (const char *)_bucket; 3349 } else 3350 str = MSG_ORIG(MSG_STR_EMPTY); 3351 3352 (void) snprintf(_symndx, MAXNDXSIZE, MSG_ORIG(MSG_FMT_INDEX2), 3353 EC_WORD(symndx)); 3354 dbg_print(0, MSG_ORIG(MSG_FMT_HASH_INFO), str, _symndx, 3355 demangle(symname, flags)); 3356 3357 /* 3358 * Determine if this string is in the correct bucket. 3359 */ 3360 nhash = elf_hash(symname); 3361 nbkt = nhash % bkts; 3362 3363 if (nbkt != hashndx) { 3364 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADHASH), file, 3365 hsecname, symname, EC_WORD(hashndx), nbkt); 3366 } 3367 } 3368 3369 #define MAXCOUNT 500 3370 3371 static void 3372 hash(Cache *cache, Word shnum, const char *file, uint_t flags) 3373 { 3374 static int count[MAXCOUNT]; 3375 Word cnt; 3376 ulong_t ndx, bkts; 3377 char number[MAXNDXSIZE]; 3378 3379 for (cnt = 1; cnt < shnum; cnt++) { 3380 uint_t *hash, *chain; 3381 Cache *_cache = &cache[cnt]; 3382 Shdr *sshdr, *hshdr = _cache->c_shdr; 3383 char *ssecname, *hsecname = _cache->c_name; 3384 Sym *syms; 3385 Word symn; 3386 3387 if (hshdr->sh_type != SHT_HASH) 3388 continue; 3389 3390 /* 3391 * Determine the hash table data and size. 3392 */ 3393 if ((hshdr->sh_entsize == 0) || (hshdr->sh_size == 0)) { 3394 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 3395 file, hsecname); 3396 continue; 3397 } 3398 if (_cache->c_data == NULL) 3399 continue; 3400 3401 hash = (uint_t *)_cache->c_data->d_buf; 3402 bkts = *hash; 3403 chain = hash + 2 + bkts; 3404 hash += 2; 3405 3406 /* 3407 * Get the data buffer for the associated symbol table. 3408 */ 3409 if ((hshdr->sh_link == 0) || (hshdr->sh_link >= shnum)) { 3410 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 3411 file, hsecname, EC_WORD(hshdr->sh_link)); 3412 continue; 3413 } 3414 3415 _cache = &cache[hshdr->sh_link]; 3416 ssecname = _cache->c_name; 3417 3418 if (_cache->c_data == NULL) 3419 continue; 3420 3421 if ((syms = (Sym *)_cache->c_data->d_buf) == NULL) { 3422 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 3423 file, ssecname); 3424 continue; 3425 } 3426 3427 sshdr = _cache->c_shdr; 3428 /* LINTED */ 3429 symn = (Word)(sshdr->sh_size / sshdr->sh_entsize); 3430 3431 /* 3432 * Get the associated string table section. 3433 */ 3434 if ((sshdr->sh_link == 0) || (sshdr->sh_link >= shnum)) { 3435 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHLINK), 3436 file, ssecname, EC_WORD(sshdr->sh_link)); 3437 continue; 3438 } 3439 3440 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3441 dbg_print(0, MSG_INTL(MSG_ELF_SCN_HASH), hsecname); 3442 dbg_print(0, MSG_INTL(MSG_ELF_HASH_INFO)); 3443 3444 /* 3445 * Loop through the hash buckets, printing the appropriate 3446 * symbols. 3447 */ 3448 for (ndx = 0; ndx < bkts; ndx++, hash++) { 3449 Word _ndx, _cnt; 3450 3451 if (*hash == 0) { 3452 count[0]++; 3453 continue; 3454 } 3455 3456 hash_entry(_cache, &cache[sshdr->sh_link], hsecname, 3457 ndx, *hash, symn, syms, file, bkts, flags, 0); 3458 3459 /* 3460 * Determine if any other symbols are chained to this 3461 * bucket. 3462 */ 3463 _ndx = chain[*hash]; 3464 _cnt = 1; 3465 while (_ndx) { 3466 hash_entry(_cache, &cache[sshdr->sh_link], 3467 hsecname, ndx, _ndx, symn, syms, file, 3468 bkts, flags, 1); 3469 _ndx = chain[_ndx]; 3470 _cnt++; 3471 } 3472 3473 if (_cnt >= MAXCOUNT) { 3474 (void) fprintf(stderr, 3475 MSG_INTL(MSG_HASH_OVERFLW), file, 3476 _cache->c_name, EC_WORD(ndx), 3477 EC_WORD(_cnt)); 3478 } else 3479 count[_cnt]++; 3480 } 3481 break; 3482 } 3483 3484 /* 3485 * Print out the count information. 3486 */ 3487 bkts = cnt = 0; 3488 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3489 3490 for (ndx = 0; ndx < MAXCOUNT; ndx++) { 3491 Word _cnt; 3492 3493 if ((_cnt = count[ndx]) == 0) 3494 continue; 3495 3496 (void) snprintf(number, MAXNDXSIZE, 3497 MSG_ORIG(MSG_FMT_INTEGER), _cnt); 3498 dbg_print(0, MSG_INTL(MSG_ELF_HASH_BKTS1), number, 3499 EC_WORD(ndx)); 3500 bkts += _cnt; 3501 cnt += (Word)(ndx * _cnt); 3502 } 3503 if (cnt) { 3504 (void) snprintf(number, MAXNDXSIZE, MSG_ORIG(MSG_FMT_INTEGER), 3505 bkts); 3506 dbg_print(0, MSG_INTL(MSG_ELF_HASH_BKTS2), number, 3507 EC_WORD(cnt)); 3508 } 3509 } 3510 3511 static void 3512 group(Cache *cache, Word shnum, const char *file, uint_t flags) 3513 { 3514 Word scnt; 3515 3516 for (scnt = 1; scnt < shnum; scnt++) { 3517 Cache *_cache = &cache[scnt]; 3518 Shdr *shdr = _cache->c_shdr; 3519 Word *grpdata, gcnt, grpcnt, symnum, unknown; 3520 Cache *symsec, *strsec; 3521 Sym *syms, *sym; 3522 char flgstrbuf[MSG_GRP_COMDAT_SIZE + 10]; 3523 3524 if (shdr->sh_type != SHT_GROUP) 3525 continue; 3526 if (!match(MATCH_F_ALL, _cache->c_name, scnt, shdr->sh_type)) 3527 continue; 3528 if ((_cache->c_data == NULL) || 3529 ((grpdata = (Word *)_cache->c_data->d_buf) == NULL)) 3530 continue; 3531 grpcnt = shdr->sh_size / sizeof (Word); 3532 3533 /* 3534 * Get the data buffer for the associated symbol table and 3535 * string table. 3536 */ 3537 if (stringtbl(cache, 1, scnt, shnum, file, 3538 &symnum, &symsec, &strsec) == 0) 3539 return; 3540 3541 syms = symsec->c_data->d_buf; 3542 3543 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3544 dbg_print(0, MSG_INTL(MSG_ELF_SCN_GRP), _cache->c_name); 3545 dbg_print(0, MSG_INTL(MSG_GRP_TITLE)); 3546 3547 /* 3548 * The first element of the group defines the group. The 3549 * associated symbol is defined by the sh_link field. 3550 */ 3551 if ((shdr->sh_info == SHN_UNDEF) || (shdr->sh_info > symnum)) { 3552 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHINFO), 3553 file, _cache->c_name, EC_WORD(shdr->sh_info)); 3554 return; 3555 } 3556 3557 (void) strcpy(flgstrbuf, MSG_ORIG(MSG_STR_OSQBRKT)); 3558 if (grpdata[0] & GRP_COMDAT) { 3559 (void) strcat(flgstrbuf, MSG_ORIG(MSG_GRP_COMDAT)); 3560 } 3561 if ((unknown = (grpdata[0] & ~GRP_COMDAT)) != 0) { 3562 size_t len = strlen(flgstrbuf); 3563 3564 (void) snprintf(&flgstrbuf[len], 3565 (MSG_GRP_COMDAT_SIZE + 10 - len), 3566 MSG_ORIG(MSG_GRP_UNKNOWN), unknown); 3567 } 3568 (void) strcat(flgstrbuf, MSG_ORIG(MSG_STR_CSQBRKT)); 3569 sym = (Sym *)(syms + shdr->sh_info); 3570 3571 dbg_print(0, MSG_INTL(MSG_GRP_SIGNATURE), flgstrbuf, 3572 demangle(string(_cache, 0, strsec, file, sym->st_name), 3573 flags)); 3574 3575 for (gcnt = 1; gcnt < grpcnt; gcnt++) { 3576 char index[MAXNDXSIZE]; 3577 const char *name; 3578 3579 (void) snprintf(index, MAXNDXSIZE, 3580 MSG_ORIG(MSG_FMT_INDEX), EC_XWORD(gcnt)); 3581 3582 if (grpdata[gcnt] >= shnum) 3583 name = MSG_INTL(MSG_GRP_INVALSCN); 3584 else 3585 name = cache[grpdata[gcnt]].c_name; 3586 3587 (void) printf(MSG_ORIG(MSG_GRP_ENTRY), index, name, 3588 EC_XWORD(grpdata[gcnt])); 3589 } 3590 } 3591 } 3592 3593 static void 3594 got(Cache *cache, Word shnum, Ehdr *ehdr, const char *file) 3595 { 3596 Cache *gotcache = NULL, *symtab = NULL; 3597 Addr gotbgn, gotend; 3598 Shdr *gotshdr; 3599 Word cnt, gotents, gotndx; 3600 size_t gentsize; 3601 Got_info *gottable; 3602 char *gotdata; 3603 Sym *gotsym; 3604 Xword gotsymaddr; 3605 uint_t sys_encoding; 3606 3607 /* 3608 * First, find the got. 3609 */ 3610 for (cnt = 1; cnt < shnum; cnt++) { 3611 if (strncmp(cache[cnt].c_name, MSG_ORIG(MSG_ELF_GOT), 3612 MSG_ELF_GOT_SIZE) == 0) { 3613 gotcache = &cache[cnt]; 3614 break; 3615 } 3616 } 3617 if (gotcache == NULL) 3618 return; 3619 3620 /* 3621 * A got section within a relocatable object is suspicious. 3622 */ 3623 if (ehdr->e_type == ET_REL) { 3624 (void) fprintf(stderr, MSG_INTL(MSG_GOT_UNEXPECTED), file, 3625 gotcache->c_name); 3626 } 3627 3628 gotshdr = gotcache->c_shdr; 3629 if (gotshdr->sh_size == 0) { 3630 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 3631 file, gotcache->c_name); 3632 return; 3633 } 3634 3635 gotbgn = gotshdr->sh_addr; 3636 gotend = gotbgn + gotshdr->sh_size; 3637 3638 /* 3639 * Some architectures don't properly set the sh_entsize for the GOT 3640 * table. If it's not set, default to a size of a pointer. 3641 */ 3642 if ((gentsize = gotshdr->sh_entsize) == 0) 3643 gentsize = sizeof (Xword); 3644 3645 if (gotcache->c_data == NULL) 3646 return; 3647 3648 /* LINTED */ 3649 gotents = (Word)(gotshdr->sh_size / gentsize); 3650 gotdata = gotcache->c_data->d_buf; 3651 3652 if ((gottable = calloc(gotents, sizeof (Got_info))) == 0) { 3653 int err = errno; 3654 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MALLOC), file, 3655 strerror(err)); 3656 return; 3657 } 3658 3659 /* 3660 * Now we scan through all the sections looking for any relocations 3661 * that may be against the GOT. Since these may not be isolated to a 3662 * .rel[a].got section we check them all. 3663 * While scanning sections save the symbol table entry (a symtab 3664 * overriding a dynsym) so that we can lookup _GLOBAL_OFFSET_TABLE_. 3665 */ 3666 for (cnt = 1; cnt < shnum; cnt++) { 3667 Word type, symnum; 3668 Xword relndx, relnum, relsize; 3669 void *rels; 3670 Sym *syms; 3671 Cache *symsec, *strsec; 3672 Cache *_cache = &cache[cnt]; 3673 Shdr *shdr; 3674 3675 shdr = _cache->c_shdr; 3676 type = shdr->sh_type; 3677 3678 if ((symtab == 0) && (type == SHT_DYNSYM)) { 3679 symtab = _cache; 3680 continue; 3681 } 3682 if (type == SHT_SYMTAB) { 3683 symtab = _cache; 3684 continue; 3685 } 3686 if ((type != SHT_RELA) && (type != SHT_REL)) 3687 continue; 3688 3689 /* 3690 * Decide entry size. 3691 */ 3692 if (((relsize = shdr->sh_entsize) == 0) || 3693 (relsize > shdr->sh_size)) { 3694 if (type == SHT_RELA) 3695 relsize = sizeof (Rela); 3696 else 3697 relsize = sizeof (Rel); 3698 } 3699 3700 /* 3701 * Determine the number of relocations available. 3702 */ 3703 if (shdr->sh_size == 0) { 3704 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSZ), 3705 file, _cache->c_name); 3706 continue; 3707 } 3708 if (_cache->c_data == NULL) 3709 continue; 3710 3711 rels = _cache->c_data->d_buf; 3712 relnum = shdr->sh_size / relsize; 3713 3714 /* 3715 * Get the data buffer for the associated symbol table and 3716 * string table. 3717 */ 3718 if (stringtbl(cache, 1, cnt, shnum, file, 3719 &symnum, &symsec, &strsec) == 0) 3720 continue; 3721 3722 syms = symsec->c_data->d_buf; 3723 3724 /* 3725 * Loop through the relocation entries. 3726 */ 3727 for (relndx = 0; relndx < relnum; relndx++, 3728 rels = (void *)((char *)rels + relsize)) { 3729 char section[BUFSIZ]; 3730 Addr offset; 3731 Got_info *gip; 3732 Word symndx, reltype; 3733 Rela *rela; 3734 Rel *rel; 3735 3736 /* 3737 * Unravel the relocation. 3738 */ 3739 if (type == SHT_RELA) { 3740 rela = (Rela *)rels; 3741 symndx = ELF_R_SYM(rela->r_info); 3742 reltype = ELF_R_TYPE(rela->r_info, 3743 ehdr->e_machine); 3744 offset = rela->r_offset; 3745 } else { 3746 rel = (Rel *)rels; 3747 symndx = ELF_R_SYM(rel->r_info); 3748 reltype = ELF_R_TYPE(rel->r_info, 3749 ehdr->e_machine); 3750 offset = rel->r_offset; 3751 } 3752 3753 /* 3754 * Only pay attention to relocations against the GOT. 3755 */ 3756 if ((offset < gotbgn) || (offset >= gotend)) 3757 continue; 3758 3759 /* LINTED */ 3760 gotndx = (Word)((offset - gotbgn) / 3761 gotshdr->sh_entsize); 3762 gip = &gottable[gotndx]; 3763 3764 if (gip->g_reltype != 0) { 3765 (void) fprintf(stderr, 3766 MSG_INTL(MSG_GOT_MULTIPLE), file, 3767 EC_WORD(gotndx), EC_ADDR(offset)); 3768 continue; 3769 } 3770 3771 if (symndx) 3772 gip->g_symname = relsymname(cache, _cache, 3773 strsec, symndx, symnum, relndx, syms, 3774 section, BUFSIZ, file); 3775 gip->g_reltype = reltype; 3776 gip->g_rel = rels; 3777 } 3778 } 3779 3780 if (symlookup(MSG_ORIG(MSG_SYM_GOT), cache, shnum, &gotsym, symtab, 3781 file)) 3782 gotsymaddr = gotsym->st_value; 3783 else 3784 gotsymaddr = gotbgn; 3785 3786 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3787 dbg_print(0, MSG_INTL(MSG_ELF_SCN_GOT), gotcache->c_name); 3788 Elf_got_title(0); 3789 3790 sys_encoding = _elf_sys_encoding(); 3791 for (gotndx = 0; gotndx < gotents; gotndx++) { 3792 Got_info *gip; 3793 Sword gindex; 3794 Addr gaddr; 3795 Xword gotentry; 3796 3797 gip = &gottable[gotndx]; 3798 3799 gaddr = gotbgn + (gotndx * gentsize); 3800 gindex = (Sword)(gaddr - gotsymaddr) / (Sword)gentsize; 3801 3802 if (gentsize == sizeof (Word)) 3803 /* LINTED */ 3804 gotentry = (Xword)(*((Word *)(gotdata) + gotndx)); 3805 else 3806 /* LINTED */ 3807 gotentry = *((Xword *)(gotdata) + gotndx); 3808 3809 Elf_got_entry(0, gindex, gaddr, gotentry, ehdr->e_machine, 3810 ehdr->e_ident[EI_DATA], sys_encoding, 3811 gip->g_reltype, gip->g_rel, gip->g_symname); 3812 } 3813 free(gottable); 3814 } 3815 3816 void 3817 checksum(Elf *elf) 3818 { 3819 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 3820 dbg_print(0, MSG_INTL(MSG_STR_CHECKSUM), elf_checksum(elf)); 3821 } 3822 3823 /* 3824 * This variable is used by regular() to communicate the address of 3825 * the section header cache to sort_shdr_ndx_arr(). Unfortunately, 3826 * the qsort() interface does not include a userdata argument by which 3827 * such arbitrary data can be passed, so we are stuck using global data. 3828 */ 3829 static Cache *sort_shdr_ndx_arr_cache; 3830 3831 3832 /* 3833 * Used with qsort() to sort the section indices so that they can be 3834 * used to access the section headers in order of increasing data offset. 3835 * 3836 * entry: 3837 * sort_shdr_ndx_arr_cache - Contains address of 3838 * section header cache. 3839 * v1, v2 - Point at elements of sort_shdr_bits array to be compared. 3840 * 3841 * exit: 3842 * Returns -1 (less than), 0 (equal) or 1 (greater than). 3843 */ 3844 static int 3845 sort_shdr_ndx_arr(const void *v1, const void *v2) 3846 { 3847 Cache *cache1 = sort_shdr_ndx_arr_cache + *((size_t *)v1); 3848 Cache *cache2 = sort_shdr_ndx_arr_cache + *((size_t *)v2); 3849 3850 if (cache1->c_shdr->sh_offset < cache2->c_shdr->sh_offset) 3851 return (-1); 3852 3853 if (cache1->c_shdr->sh_offset > cache2->c_shdr->sh_offset) 3854 return (1); 3855 3856 return (0); 3857 } 3858 3859 3860 static int 3861 shdr_cache(const char *file, Elf *elf, Ehdr *ehdr, size_t shstrndx, 3862 size_t shnum, Cache **cache_ret, Word flags) 3863 { 3864 Elf_Scn *scn; 3865 Elf_Data *data; 3866 size_t ndx; 3867 Shdr *nameshdr; 3868 char *names = NULL; 3869 Cache *cache, *_cache; 3870 size_t *shdr_ndx_arr, shdr_ndx_arr_cnt; 3871 3872 3873 /* 3874 * Obtain the .shstrtab data buffer to provide the required section 3875 * name strings. 3876 */ 3877 if (shstrndx == SHN_UNDEF) { 3878 /* 3879 * It is rare, but legal, for an object to lack a 3880 * header string table section. 3881 */ 3882 names = NULL; 3883 (void) fprintf(stderr, MSG_INTL(MSG_ERR_NOSHSTRSEC), file); 3884 } else if ((scn = elf_getscn(elf, shstrndx)) == NULL) { 3885 failure(file, MSG_ORIG(MSG_ELF_GETSCN)); 3886 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_SHDR), 3887 EC_XWORD(shstrndx)); 3888 3889 } else if ((data = elf_getdata(scn, NULL)) == NULL) { 3890 failure(file, MSG_ORIG(MSG_ELF_GETDATA)); 3891 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_DATA), 3892 EC_XWORD(shstrndx)); 3893 3894 } else if ((nameshdr = elf_getshdr(scn)) == NULL) { 3895 failure(file, MSG_ORIG(MSG_ELF_GETSHDR)); 3896 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_SCN), 3897 EC_WORD(elf_ndxscn(scn))); 3898 3899 } else if ((names = data->d_buf) == NULL) 3900 (void) fprintf(stderr, MSG_INTL(MSG_ERR_SHSTRNULL), file); 3901 3902 /* 3903 * Allocate a cache to maintain a descriptor for each section. 3904 */ 3905 if ((*cache_ret = cache = malloc(shnum * sizeof (Cache))) == NULL) { 3906 int err = errno; 3907 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MALLOC), 3908 file, strerror(err)); 3909 return (0); 3910 } 3911 3912 *cache = cache_init; 3913 _cache = cache; 3914 _cache++; 3915 3916 /* 3917 * Allocate an array that will hold the section index for 3918 * each section that has data in the ELF file: 3919 * 3920 * - Is not a NOBITS section 3921 * - Data has non-zero length 3922 * 3923 * Note that shnum is an upper bound on the size required. It 3924 * is likely that we won't use a few of these array elements. 3925 * Allocating a modest amount of extra memory in this case means 3926 * that we can avoid an extra loop to count the number of needed 3927 * items, and can fill this array immediately in the first loop 3928 * below. 3929 */ 3930 if ((shdr_ndx_arr = malloc(shnum * sizeof (*shdr_ndx_arr))) == NULL) { 3931 int err = errno; 3932 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MALLOC), 3933 file, strerror(err)); 3934 return (0); 3935 } 3936 shdr_ndx_arr_cnt = 0; 3937 3938 /* 3939 * Traverse the sections of the file. This gathering of data is 3940 * carried out in two passes. First, the section headers are captured 3941 * and the section header names are evaluated. A verification pass is 3942 * then carried out over the section information. Files have been 3943 * known to exhibit overlapping (and hence erroneous) section header 3944 * information. 3945 * 3946 * Finally, the data for each section is obtained. This processing is 3947 * carried out after section verification because should any section 3948 * header overlap occur, and a file needs translating (ie. xlate'ing 3949 * information from a non-native architecture file), then the process 3950 * of translation can corrupt the section header information. Of 3951 * course, if there is any section overlap, the data related to the 3952 * sections is going to be compromised. However, it is the translation 3953 * of this data that has caused problems with elfdump()'s ability to 3954 * extract the data. 3955 */ 3956 for (ndx = 1, scn = NULL; scn = elf_nextscn(elf, scn); 3957 ndx++, _cache++) { 3958 char scnndxnm[100]; 3959 3960 _cache->c_ndx = ndx; 3961 _cache->c_scn = scn; 3962 3963 if ((_cache->c_shdr = elf_getshdr(scn)) == NULL) { 3964 failure(file, MSG_ORIG(MSG_ELF_GETSHDR)); 3965 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_SCN), 3966 EC_WORD(elf_ndxscn(scn))); 3967 } 3968 3969 /* 3970 * If this section has data in the file, include it in 3971 * the array of sections to check for address overlap. 3972 */ 3973 if ((_cache->c_shdr->sh_size != 0) && 3974 (_cache->c_shdr->sh_type != SHT_NOBITS)) 3975 shdr_ndx_arr[shdr_ndx_arr_cnt++] = ndx; 3976 3977 /* 3978 * If a shstrtab exists, assign the section name. 3979 */ 3980 if (names && _cache->c_shdr) { 3981 if (_cache->c_shdr->sh_name && 3982 /* LINTED */ 3983 (nameshdr->sh_size > _cache->c_shdr->sh_name)) { 3984 const char *symname; 3985 char *secname; 3986 3987 secname = names + _cache->c_shdr->sh_name; 3988 3989 /* 3990 * A SUN naming convention employs a "%" within 3991 * a section name to indicate a section/symbol 3992 * name. This originated from the compilers 3993 * -xF option, that places functions into their 3994 * own sections. This convention (which has no 3995 * formal standard) has also been followed for 3996 * COMDAT sections. To demangle the symbol 3997 * name, the name must be separated from the 3998 * section name. 3999 */ 4000 if (((flags & FLG_CTL_DEMANGLE) == 0) || 4001 ((symname = strchr(secname, '%')) == NULL)) 4002 _cache->c_name = secname; 4003 else { 4004 size_t secsz = ++symname - secname; 4005 size_t strsz; 4006 4007 symname = demangle(symname, flags); 4008 strsz = secsz + strlen(symname) + 1; 4009 4010 if ((_cache->c_name = 4011 malloc(strsz)) == NULL) { 4012 int err = errno; 4013 (void) fprintf(stderr, 4014 MSG_INTL(MSG_ERR_MALLOC), 4015 file, strerror(err)); 4016 return (0); 4017 } 4018 (void) snprintf(_cache->c_name, strsz, 4019 MSG_ORIG(MSG_FMT_SECSYM), 4020 EC_WORD(secsz), secname, symname); 4021 } 4022 4023 continue; 4024 } 4025 4026 /* 4027 * Generate an error if the section name index is zero 4028 * or exceeds the shstrtab data. Fall through to 4029 * fabricate a section name. 4030 */ 4031 if ((_cache->c_shdr->sh_name == 0) || 4032 /* LINTED */ 4033 (nameshdr->sh_size <= _cache->c_shdr->sh_name)) { 4034 (void) fprintf(stderr, 4035 MSG_INTL(MSG_ERR_BADSHNAME), file, 4036 EC_WORD(ndx), 4037 EC_XWORD(_cache->c_shdr->sh_name)); 4038 } 4039 } 4040 4041 /* 4042 * If there exists no shstrtab data, or a section header has no 4043 * name (an invalid index of 0), then compose a name for the 4044 * section. 4045 */ 4046 (void) snprintf(scnndxnm, sizeof (scnndxnm), 4047 MSG_INTL(MSG_FMT_SCNNDX), ndx); 4048 4049 if ((_cache->c_name = malloc(strlen(scnndxnm) + 1)) == NULL) { 4050 int err = errno; 4051 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MALLOC), 4052 file, strerror(err)); 4053 return (0); 4054 } 4055 (void) strcpy(_cache->c_name, scnndxnm); 4056 } 4057 4058 /* 4059 * Having collected all the sections, validate their address range. 4060 * Cases have existed where the section information has been invalid. 4061 * This can lead to all sorts of other, hard to diagnose errors, as 4062 * each section is processed individually (ie. with elf_getdata()). 4063 * Here, we carry out some address comparisons to catch a family of 4064 * overlapping memory issues we have observed (likely, there are others 4065 * that we have yet to discover). 4066 * 4067 * Note, should any memory overlap occur, obtaining any additional 4068 * data from the file is questionable. However, it might still be 4069 * possible to inspect the ELF header, Programs headers, or individual 4070 * sections, so rather than bailing on an error condition, continue 4071 * processing to see if any data can be salvaged. 4072 */ 4073 if (shdr_ndx_arr_cnt > 1) { 4074 sort_shdr_ndx_arr_cache = cache; 4075 qsort(shdr_ndx_arr, shdr_ndx_arr_cnt, 4076 sizeof (*shdr_ndx_arr), sort_shdr_ndx_arr); 4077 } 4078 for (ndx = 0; ndx < shdr_ndx_arr_cnt; ndx++) { 4079 Cache *_cache = cache + shdr_ndx_arr[ndx]; 4080 Shdr *shdr = _cache->c_shdr; 4081 Off bgn1, bgn = shdr->sh_offset; 4082 Off end1, end = shdr->sh_offset + shdr->sh_size; 4083 size_t ndx1; 4084 4085 /* 4086 * Check the section against all following ones, reporting 4087 * any overlaps. Since we've sorted the sections by offset, 4088 * we can stop after the first comparison that fails. There 4089 * are no overlaps in a properly formed ELF file, in which 4090 * case this algorithm runs in O(n) time. This will degenerate 4091 * to O(n^2) for a completely broken file. Such a file is 4092 * (1) highly unlikely, and (2) unusable, so it is reasonable 4093 * for the analysis to take longer. 4094 */ 4095 for (ndx1 = ndx + 1; ndx1 < shdr_ndx_arr_cnt; ndx1++) { 4096 Cache *_cache1 = cache + shdr_ndx_arr[ndx1]; 4097 Shdr *shdr1 = _cache1->c_shdr; 4098 4099 bgn1 = shdr1->sh_offset; 4100 end1 = shdr1->sh_offset + shdr1->sh_size; 4101 4102 if (((bgn1 <= bgn) && (end1 > bgn)) || 4103 ((bgn1 < end) && (end1 >= end))) { 4104 (void) fprintf(stderr, 4105 MSG_INTL(MSG_ERR_SECMEMOVER), file, 4106 EC_WORD(elf_ndxscn(_cache->c_scn)), 4107 _cache->c_name, EC_OFF(bgn), EC_OFF(end), 4108 EC_WORD(elf_ndxscn(_cache1->c_scn)), 4109 _cache1->c_name, EC_OFF(bgn1), 4110 EC_OFF(end1)); 4111 } else { /* No overlap, so can stop */ 4112 break; 4113 } 4114 } 4115 4116 /* 4117 * In addition to checking for sections overlapping 4118 * each other (done above), we should also make sure 4119 * the section doesn't overlap the section header array. 4120 */ 4121 bgn1 = ehdr->e_shoff; 4122 end1 = ehdr->e_shoff + (ehdr->e_shentsize * ehdr->e_shnum); 4123 4124 if (((bgn1 <= bgn) && (end1 > bgn)) || 4125 ((bgn1 < end) && (end1 >= end))) { 4126 (void) fprintf(stderr, 4127 MSG_INTL(MSG_ERR_SHDRMEMOVER), file, EC_OFF(bgn1), 4128 EC_OFF(end1), 4129 EC_WORD(elf_ndxscn(_cache->c_scn)), 4130 _cache->c_name, EC_OFF(bgn), EC_OFF(end)); 4131 } 4132 } 4133 4134 /* 4135 * Obtain the data for each section. 4136 */ 4137 for (ndx = 1; ndx < shnum; ndx++) { 4138 Cache *_cache = &cache[ndx]; 4139 Elf_Scn *scn = _cache->c_scn; 4140 4141 if ((_cache->c_data = elf_getdata(scn, NULL)) == NULL) { 4142 failure(file, MSG_ORIG(MSG_ELF_GETDATA)); 4143 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_SCNDATA), 4144 EC_WORD(elf_ndxscn(scn))); 4145 } 4146 4147 /* 4148 * If a string table, verify that it has NULL first and 4149 * final bytes. 4150 */ 4151 if ((_cache->c_shdr->sh_type == SHT_STRTAB) && 4152 (_cache->c_data->d_buf != NULL) && 4153 (_cache->c_data->d_size > 0)) { 4154 const char *s = _cache->c_data->d_buf; 4155 4156 if ((*s != '\0') || 4157 (*(s + _cache->c_data->d_size - 1) != '\0')) 4158 (void) fprintf(stderr, MSG_INTL(MSG_ERR_MALSTR), 4159 file, _cache->c_name); 4160 } 4161 } 4162 4163 return (1); 4164 } 4165 4166 4167 4168 /* 4169 * Generate a cache of section headers and related information 4170 * for use by the rest of elfdump. If requested (or the file 4171 * contains no section headers), we generate a fake set of 4172 * headers from the information accessible from the program headers. 4173 * Otherwise, we use the real section headers contained in the file. 4174 */ 4175 static int 4176 create_cache(const char *file, int fd, Elf *elf, Ehdr *ehdr, Cache **cache, 4177 size_t shstrndx, size_t *shnum, uint_t *flags) 4178 { 4179 /* 4180 * If there are no section headers, then resort to synthesizing 4181 * section headers from the program headers. This is normally 4182 * only done by explicit request, but in this case there's no 4183 * reason not to go ahead, since the alternative is simply to quit. 4184 */ 4185 if ((*shnum <= 1) && ((*flags & FLG_CTL_FAKESHDR) == 0)) { 4186 (void) fprintf(stderr, MSG_INTL(MSG_ERR_NOSHDR), file); 4187 *flags |= FLG_CTL_FAKESHDR; 4188 } 4189 4190 if (*flags & FLG_CTL_FAKESHDR) { 4191 if (fake_shdr_cache(file, fd, elf, ehdr, cache, shnum) == 0) 4192 return (0); 4193 } else { 4194 if (shdr_cache(file, elf, ehdr, shstrndx, *shnum, 4195 cache, *flags) == 0) 4196 return (0); 4197 } 4198 4199 return (1); 4200 } 4201 4202 int 4203 regular(const char *file, int fd, Elf *elf, uint_t flags, 4204 const char *wname, int wfd, uchar_t osabi) 4205 { 4206 enum { CACHE_NEEDED, CACHE_OK, CACHE_FAIL} cache_state = CACHE_NEEDED; 4207 Elf_Scn *scn; 4208 Ehdr *ehdr; 4209 size_t ndx, shstrndx, shnum, phnum; 4210 Shdr *shdr; 4211 Cache *cache; 4212 VERSYM_STATE versym; 4213 int ret = 0; 4214 int addr_align; 4215 4216 if ((ehdr = elf_getehdr(elf)) == NULL) { 4217 failure(file, MSG_ORIG(MSG_ELF_GETEHDR)); 4218 return (ret); 4219 } 4220 4221 if (elf_getshnum(elf, &shnum) == 0) { 4222 failure(file, MSG_ORIG(MSG_ELF_GETSHNUM)); 4223 return (ret); 4224 } 4225 4226 if (elf_getshstrndx(elf, &shstrndx) == 0) { 4227 failure(file, MSG_ORIG(MSG_ELF_GETSHSTRNDX)); 4228 return (ret); 4229 } 4230 4231 if (elf_getphnum(elf, &phnum) == 0) { 4232 failure(file, MSG_ORIG(MSG_ELF_GETPHNUM)); 4233 return (ret); 4234 } 4235 /* 4236 * If the user requested section headers derived from the 4237 * program headers (-P option) and this file doesn't have 4238 * any program headers (i.e. ET_REL), then we can't do it. 4239 */ 4240 if ((phnum == 0) && (flags & FLG_CTL_FAKESHDR)) { 4241 (void) fprintf(stderr, MSG_INTL(MSG_ERR_PNEEDSPH), file); 4242 return (ret); 4243 } 4244 4245 4246 if ((scn = elf_getscn(elf, 0)) != NULL) { 4247 if ((shdr = elf_getshdr(scn)) == NULL) { 4248 failure(file, MSG_ORIG(MSG_ELF_GETSHDR)); 4249 (void) fprintf(stderr, MSG_INTL(MSG_ELF_ERR_SCN), 0); 4250 return (ret); 4251 } 4252 } else 4253 shdr = NULL; 4254 4255 /* 4256 * Print the elf header. 4257 */ 4258 if (flags & FLG_SHOW_EHDR) 4259 Elf_ehdr(0, ehdr, shdr); 4260 4261 /* 4262 * If the section headers or program headers have inadequate 4263 * alignment for the class of object, print a warning. libelf 4264 * can handle such files, but programs that use them can crash 4265 * when they dereference unaligned items. 4266 * 4267 * Note that the AMD64 ABI, although it is a 64-bit architecture, 4268 * allows access to data types smaller than 128-bits to be on 4269 * word alignment. 4270 */ 4271 if (ehdr->e_machine == EM_AMD64) 4272 addr_align = sizeof (Word); 4273 else 4274 addr_align = sizeof (Addr); 4275 4276 if (ehdr->e_phoff & (addr_align - 1)) 4277 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADPHDRALIGN), file); 4278 if (ehdr->e_shoff & (addr_align - 1)) 4279 (void) fprintf(stderr, MSG_INTL(MSG_ERR_BADSHDRALIGN), file); 4280 4281 4282 /* 4283 * Determine the Operating System ABI (osabi) we will use to 4284 * interpret the object. 4285 */ 4286 if (flags & FLG_CTL_OSABI) { 4287 /* 4288 * If the user explicitly specifies '-O none', we need 4289 * to display a completely generic view of the file. 4290 * However, libconv is written to assume that ELFOSABI_NONE 4291 * is equivalent to ELFOSABI_SOLARIS. To get the desired 4292 * effect, we use an osabi that libconv has no knowledge of. 4293 */ 4294 if (osabi == ELFOSABI_NONE) 4295 osabi = ELFOSABI_UNKNOWN4; 4296 } else { 4297 /* Determine osabi from file */ 4298 osabi = ehdr->e_ident[EI_OSABI]; 4299 if (osabi == ELFOSABI_NONE) { 4300 /* 4301 * Chicken/Egg scenario: 4302 * 4303 * Ideally, we wait to create the section header cache 4304 * until after the program headers are printed. If we 4305 * only output program headers, we can skip building 4306 * the cache entirely. 4307 * 4308 * Proper interpretation of program headers requires 4309 * the osabi, which is supposed to be in the ELF header. 4310 * However, many systems (Solaris and Linux included) 4311 * have a history of setting the osabi to the generic 4312 * SysV ABI (ELFOSABI_NONE). We assume ELFOSABI_SOLARIS 4313 * in such cases, but would like to check the object 4314 * to see if it has a Linux .note.ABI-tag section, 4315 * which implies ELFOSABI_LINUX. This requires a 4316 * section header cache. 4317 * 4318 * To break the cycle, we create section headers now 4319 * if osabi is ELFOSABI_NONE, and later otherwise. 4320 * If it succeeds, we use them, if not, we defer 4321 * exiting until after the program headers are out. 4322 */ 4323 if (create_cache(file, fd, elf, ehdr, &cache, 4324 shstrndx, &shnum, &flags) == 0) { 4325 cache_state = CACHE_FAIL; 4326 } else { 4327 cache_state = CACHE_OK; 4328 if (has_linux_abi_note(cache, shnum, file)) { 4329 Conv_inv_buf_t ibuf1, ibuf2; 4330 4331 (void) fprintf(stderr, 4332 MSG_INTL(MSG_INFO_LINUXOSABI), file, 4333 conv_ehdr_osabi(osabi, 0, &ibuf1), 4334 conv_ehdr_osabi(ELFOSABI_LINUX, 4335 0, &ibuf2)); 4336 osabi = ELFOSABI_LINUX; 4337 } 4338 } 4339 } 4340 /* 4341 * We treat ELFOSABI_NONE identically to ELFOSABI_SOLARIS. 4342 * Mapping NONE to SOLARIS simplifies the required test. 4343 */ 4344 if (osabi == ELFOSABI_NONE) 4345 osabi = ELFOSABI_SOLARIS; 4346 } 4347 4348 /* 4349 * Print the program headers. 4350 */ 4351 if ((flags & FLG_SHOW_PHDR) && (phnum != 0)) { 4352 Phdr *phdr; 4353 4354 if ((phdr = elf_getphdr(elf)) == NULL) { 4355 failure(file, MSG_ORIG(MSG_ELF_GETPHDR)); 4356 return (ret); 4357 } 4358 4359 for (ndx = 0; ndx < phnum; phdr++, ndx++) { 4360 if (!match(MATCH_F_PHDR| MATCH_F_NDX | MATCH_F_TYPE, 4361 NULL, ndx, phdr->p_type)) 4362 continue; 4363 4364 dbg_print(0, MSG_ORIG(MSG_STR_EMPTY)); 4365 dbg_print(0, MSG_INTL(MSG_ELF_PHDR), EC_WORD(ndx)); 4366 Elf_phdr(0, osabi, ehdr->e_machine, phdr); 4367 } 4368 } 4369 4370 /* 4371 * If we have flag bits set that explicitly require a show or calc 4372 * operation, but none of them require the section headers, then 4373 * we are done and can return now. 4374 */ 4375 if (((flags & (FLG_MASK_SHOW | FLG_MASK_CALC)) != 0) && 4376 ((flags & (FLG_MASK_SHOW_SHDR | FLG_MASK_CALC_SHDR)) == 0)) 4377 return (ret); 4378 4379 /* 4380 * Everything from this point on requires section headers. 4381 * If we have no section headers, there is no reason to continue. 4382 * 4383 * If we tried above to create the section header cache and failed, 4384 * it is time to exit. Otherwise, create it if needed. 4385 */ 4386 switch (cache_state) { 4387 case CACHE_NEEDED: 4388 if (create_cache(file, fd, elf, ehdr, &cache, shstrndx, 4389 &shnum, &flags) == 0) 4390 return (ret); 4391 break; 4392 case CACHE_FAIL: 4393 return (ret); 4394 } 4395 if (shnum <= 1) 4396 goto done; 4397 4398 /* 4399 * If -w was specified, find and write out the section(s) data. 4400 */ 4401 if (wfd) { 4402 for (ndx = 1; ndx < shnum; ndx++) { 4403 Cache *_cache = &cache[ndx]; 4404 4405 if (match(MATCH_F_STRICT | MATCH_F_ALL, _cache->c_name, 4406 ndx, _cache->c_shdr->sh_type) && 4407 _cache->c_data && _cache->c_data->d_buf) { 4408 if (write(wfd, _cache->c_data->d_buf, 4409 _cache->c_data->d_size) != 4410 _cache->c_data->d_size) { 4411 int err = errno; 4412 (void) fprintf(stderr, 4413 MSG_INTL(MSG_ERR_WRITE), wname, 4414 strerror(err)); 4415 /* 4416 * Return an exit status of 1, because 4417 * the failure is not related to the 4418 * ELF file, but by system resources. 4419 */ 4420 ret = 1; 4421 goto done; 4422 } 4423 } 4424 } 4425 } 4426 4427 /* 4428 * If we have no flag bits set that explicitly require a show or calc 4429 * operation, but match options (-I, -N, -T) were used, then run 4430 * through the section headers and see if we can't deduce show flags 4431 * from the match options given. 4432 * 4433 * We don't do this if -w was specified, because (-I, -N, -T) used 4434 * with -w in lieu of some other option is supposed to be quiet. 4435 */ 4436 if ((wfd == 0) && (flags & FLG_CTL_MATCH) && 4437 ((flags & (FLG_MASK_SHOW | FLG_MASK_CALC)) == 0)) { 4438 for (ndx = 1; ndx < shnum; ndx++) { 4439 Cache *_cache = &cache[ndx]; 4440 4441 if (!match(MATCH_F_STRICT | MATCH_F_ALL, _cache->c_name, 4442 ndx, _cache->c_shdr->sh_type)) 4443 continue; 4444 4445 switch (_cache->c_shdr->sh_type) { 4446 case SHT_PROGBITS: 4447 /* 4448 * Heuristic time: It is usually bad form 4449 * to assume the meaning/format of a PROGBITS 4450 * section based on its name. However, there 4451 * are ABI mandated exceptions. Check for 4452 * these special names. 4453 */ 4454 4455 /* The ELF ABI specifies .interp and .got */ 4456 if (strcmp(_cache->c_name, 4457 MSG_ORIG(MSG_ELF_INTERP)) == 0) { 4458 flags |= FLG_SHOW_INTERP; 4459 break; 4460 } 4461 if (strcmp(_cache->c_name, 4462 MSG_ORIG(MSG_ELF_GOT)) == 0) { 4463 flags |= FLG_SHOW_GOT; 4464 break; 4465 } 4466 /* 4467 * The GNU compilers, and amd64 ABI, define 4468 * .eh_frame and .eh_frame_hdr. The Sun 4469 * C++ ABI defines .exception_ranges. 4470 */ 4471 if ((strncmp(_cache->c_name, 4472 MSG_ORIG(MSG_SCN_FRM), 4473 MSG_SCN_FRM_SIZE) == 0) || 4474 (strncmp(_cache->c_name, 4475 MSG_ORIG(MSG_SCN_EXRANGE), 4476 MSG_SCN_EXRANGE_SIZE) == 0)) { 4477 flags |= FLG_SHOW_UNWIND; 4478 break; 4479 } 4480 break; 4481 4482 case SHT_SYMTAB: 4483 case SHT_DYNSYM: 4484 case SHT_SUNW_LDYNSYM: 4485 case SHT_SUNW_versym: 4486 case SHT_SYMTAB_SHNDX: 4487 flags |= FLG_SHOW_SYMBOLS; 4488 break; 4489 4490 case SHT_RELA: 4491 case SHT_REL: 4492 flags |= FLG_SHOW_RELOC; 4493 break; 4494 4495 case SHT_HASH: 4496 flags |= FLG_SHOW_HASH; 4497 break; 4498 4499 case SHT_DYNAMIC: 4500 flags |= FLG_SHOW_DYNAMIC; 4501 break; 4502 4503 case SHT_NOTE: 4504 flags |= FLG_SHOW_NOTE; 4505 break; 4506 4507 case SHT_GROUP: 4508 flags |= FLG_SHOW_GROUP; 4509 break; 4510 4511 case SHT_SUNW_symsort: 4512 case SHT_SUNW_tlssort: 4513 flags |= FLG_SHOW_SORT; 4514 break; 4515 4516 case SHT_SUNW_cap: 4517 flags |= FLG_SHOW_CAP; 4518 break; 4519 4520 case SHT_SUNW_move: 4521 flags |= FLG_SHOW_MOVE; 4522 break; 4523 4524 case SHT_SUNW_syminfo: 4525 flags |= FLG_SHOW_SYMINFO; 4526 break; 4527 4528 case SHT_SUNW_verdef: 4529 case SHT_SUNW_verneed: 4530 flags |= FLG_SHOW_VERSIONS; 4531 break; 4532 4533 case SHT_AMD64_UNWIND: 4534 flags |= FLG_SHOW_UNWIND; 4535 break; 4536 } 4537 } 4538 } 4539 4540 4541 if (flags & FLG_SHOW_SHDR) 4542 sections(file, cache, shnum, ehdr, osabi); 4543 4544 if (flags & FLG_SHOW_INTERP) 4545 interp(file, cache, shnum, phnum, elf); 4546 4547 if ((osabi == ELFOSABI_SOLARIS) || (osabi == ELFOSABI_LINUX)) 4548 versions(cache, shnum, file, flags, &versym); 4549 4550 if (flags & FLG_SHOW_SYMBOLS) 4551 symbols(cache, shnum, ehdr, osabi, &versym, file, flags); 4552 4553 if ((flags & FLG_SHOW_SORT) && (osabi == ELFOSABI_SOLARIS)) 4554 sunw_sort(cache, shnum, ehdr, osabi, &versym, file, flags); 4555 4556 if (flags & FLG_SHOW_HASH) 4557 hash(cache, shnum, file, flags); 4558 4559 if (flags & FLG_SHOW_GOT) 4560 got(cache, shnum, ehdr, file); 4561 4562 if (flags & FLG_SHOW_GROUP) 4563 group(cache, shnum, file, flags); 4564 4565 if (flags & FLG_SHOW_SYMINFO) 4566 syminfo(cache, shnum, file); 4567 4568 if (flags & FLG_SHOW_RELOC) 4569 reloc(cache, shnum, ehdr, file); 4570 4571 if (flags & FLG_SHOW_DYNAMIC) 4572 dynamic(cache, shnum, ehdr, osabi, file); 4573 4574 if (flags & FLG_SHOW_NOTE) { 4575 Word note_cnt; 4576 size_t note_shnum; 4577 Cache *note_cache; 4578 4579 note_cnt = note(cache, shnum, ehdr, file); 4580 4581 /* 4582 * Solaris core files have section headers, but these 4583 * headers do not include SHT_NOTE sections that reference 4584 * the core note sections. This means that note() won't 4585 * find the core notes. Fake section headers (-P option) 4586 * recover these sections, but it is inconvenient to require 4587 * users to specify -P in this situation. If the following 4588 * are all true: 4589 * 4590 * - No note sections were found 4591 * - This is a core file 4592 * - We are not already using fake section headers 4593 * 4594 * then we will automatically generate fake section headers 4595 * and then process them in a second call to note(). 4596 */ 4597 if ((note_cnt == 0) && (ehdr->e_type == ET_CORE) && 4598 !(flags & FLG_CTL_FAKESHDR) && 4599 (fake_shdr_cache(file, fd, elf, ehdr, 4600 ¬e_cache, ¬e_shnum) != 0)) { 4601 (void) note(note_cache, note_shnum, ehdr, file); 4602 fake_shdr_cache_free(note_cache, note_shnum); 4603 } 4604 } 4605 4606 if ((flags & FLG_SHOW_MOVE) && (osabi == ELFOSABI_SOLARIS)) 4607 move(cache, shnum, file, flags); 4608 4609 if (flags & FLG_CALC_CHECKSUM) 4610 checksum(elf); 4611 4612 if ((flags & FLG_SHOW_CAP) && (osabi == ELFOSABI_SOLARIS)) 4613 cap(file, cache, shnum, phnum, ehdr, elf); 4614 4615 if ((flags & FLG_SHOW_UNWIND) && 4616 ((osabi == ELFOSABI_SOLARIS) || (osabi == ELFOSABI_LINUX))) 4617 unwind(cache, shnum, phnum, ehdr, osabi, file, elf, flags); 4618 4619 4620 /* Release the memory used to cache section headers */ 4621 done: 4622 if (flags & FLG_CTL_FAKESHDR) 4623 fake_shdr_cache_free(cache, shnum); 4624 else 4625 free(cache); 4626 4627 return (ret); 4628 } 4629