dwarf.c revision 1.1.1.3
1 1.1 mrg /* dwarf.c -- Get file/line information from DWARF for backtraces. 2 1.1.1.3 mrg Copyright (C) 2012-2016 Free Software Foundation, Inc. 3 1.1 mrg Written by Ian Lance Taylor, Google. 4 1.1 mrg 5 1.1 mrg Redistribution and use in source and binary forms, with or without 6 1.1 mrg modification, are permitted provided that the following conditions are 7 1.1 mrg met: 8 1.1 mrg 9 1.1 mrg (1) Redistributions of source code must retain the above copyright 10 1.1 mrg notice, this list of conditions and the following disclaimer. 11 1.1 mrg 12 1.1 mrg (2) Redistributions in binary form must reproduce the above copyright 13 1.1 mrg notice, this list of conditions and the following disclaimer in 14 1.1 mrg the documentation and/or other materials provided with the 15 1.1 mrg distribution. 16 1.1 mrg 17 1.1 mrg (3) The name of the author may not be used to 18 1.1 mrg endorse or promote products derived from this software without 19 1.1 mrg specific prior written permission. 20 1.1 mrg 21 1.1 mrg THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 22 1.1 mrg IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED 23 1.1 mrg WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE 24 1.1 mrg DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, 25 1.1 mrg INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 26 1.1 mrg (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR 27 1.1 mrg SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 28 1.1 mrg HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, 29 1.1 mrg STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING 30 1.1 mrg IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 31 1.1 mrg POSSIBILITY OF SUCH DAMAGE. */ 32 1.1 mrg 33 1.1 mrg #include "config.h" 34 1.1 mrg 35 1.1 mrg #include <errno.h> 36 1.1 mrg #include <stdlib.h> 37 1.1 mrg #include <string.h> 38 1.1 mrg #include <sys/types.h> 39 1.1 mrg 40 1.1 mrg #include "dwarf2.h" 41 1.1 mrg #include "filenames.h" 42 1.1 mrg 43 1.1 mrg #include "backtrace.h" 44 1.1 mrg #include "internal.h" 45 1.1 mrg 46 1.1 mrg #if !defined(HAVE_DECL_STRNLEN) || !HAVE_DECL_STRNLEN 47 1.1 mrg 48 1.1 mrg /* If strnlen is not declared, provide our own version. */ 49 1.1 mrg 50 1.1 mrg static size_t 51 1.1 mrg xstrnlen (const char *s, size_t maxlen) 52 1.1 mrg { 53 1.1 mrg size_t i; 54 1.1 mrg 55 1.1 mrg for (i = 0; i < maxlen; ++i) 56 1.1 mrg if (s[i] == '\0') 57 1.1 mrg break; 58 1.1 mrg return i; 59 1.1 mrg } 60 1.1 mrg 61 1.1 mrg #define strnlen xstrnlen 62 1.1 mrg 63 1.1 mrg #endif 64 1.1 mrg 65 1.1 mrg /* A buffer to read DWARF info. */ 66 1.1 mrg 67 1.1 mrg struct dwarf_buf 68 1.1 mrg { 69 1.1 mrg /* Buffer name for error messages. */ 70 1.1 mrg const char *name; 71 1.1 mrg /* Start of the buffer. */ 72 1.1 mrg const unsigned char *start; 73 1.1 mrg /* Next byte to read. */ 74 1.1 mrg const unsigned char *buf; 75 1.1 mrg /* The number of bytes remaining. */ 76 1.1 mrg size_t left; 77 1.1 mrg /* Whether the data is big-endian. */ 78 1.1 mrg int is_bigendian; 79 1.1 mrg /* Error callback routine. */ 80 1.1 mrg backtrace_error_callback error_callback; 81 1.1 mrg /* Data for error_callback. */ 82 1.1 mrg void *data; 83 1.1 mrg /* Non-zero if we've reported an underflow error. */ 84 1.1 mrg int reported_underflow; 85 1.1 mrg }; 86 1.1 mrg 87 1.1 mrg /* A single attribute in a DWARF abbreviation. */ 88 1.1 mrg 89 1.1 mrg struct attr 90 1.1 mrg { 91 1.1 mrg /* The attribute name. */ 92 1.1 mrg enum dwarf_attribute name; 93 1.1 mrg /* The attribute form. */ 94 1.1 mrg enum dwarf_form form; 95 1.1 mrg }; 96 1.1 mrg 97 1.1 mrg /* A single DWARF abbreviation. */ 98 1.1 mrg 99 1.1 mrg struct abbrev 100 1.1 mrg { 101 1.1 mrg /* The abbrev code--the number used to refer to the abbrev. */ 102 1.1 mrg uint64_t code; 103 1.1 mrg /* The entry tag. */ 104 1.1 mrg enum dwarf_tag tag; 105 1.1 mrg /* Non-zero if this abbrev has child entries. */ 106 1.1 mrg int has_children; 107 1.1 mrg /* The number of attributes. */ 108 1.1 mrg size_t num_attrs; 109 1.1 mrg /* The attributes. */ 110 1.1 mrg struct attr *attrs; 111 1.1 mrg }; 112 1.1 mrg 113 1.1 mrg /* The DWARF abbreviations for a compilation unit. This structure 114 1.1 mrg only exists while reading the compilation unit. Most DWARF readers 115 1.1 mrg seem to a hash table to map abbrev ID's to abbrev entries. 116 1.1 mrg However, we primarily care about GCC, and GCC simply issues ID's in 117 1.1 mrg numerical order starting at 1. So we simply keep a sorted vector, 118 1.1 mrg and try to just look up the code. */ 119 1.1 mrg 120 1.1 mrg struct abbrevs 121 1.1 mrg { 122 1.1 mrg /* The number of abbrevs in the vector. */ 123 1.1 mrg size_t num_abbrevs; 124 1.1 mrg /* The abbrevs, sorted by the code field. */ 125 1.1 mrg struct abbrev *abbrevs; 126 1.1 mrg }; 127 1.1 mrg 128 1.1 mrg /* The different kinds of attribute values. */ 129 1.1 mrg 130 1.1 mrg enum attr_val_encoding 131 1.1 mrg { 132 1.1 mrg /* An address. */ 133 1.1 mrg ATTR_VAL_ADDRESS, 134 1.1 mrg /* A unsigned integer. */ 135 1.1 mrg ATTR_VAL_UINT, 136 1.1 mrg /* A sigd integer. */ 137 1.1 mrg ATTR_VAL_SINT, 138 1.1 mrg /* A string. */ 139 1.1 mrg ATTR_VAL_STRING, 140 1.1 mrg /* An offset to other data in the containing unit. */ 141 1.1 mrg ATTR_VAL_REF_UNIT, 142 1.1 mrg /* An offset to other data within the .dwarf_info section. */ 143 1.1 mrg ATTR_VAL_REF_INFO, 144 1.1 mrg /* An offset to data in some other section. */ 145 1.1 mrg ATTR_VAL_REF_SECTION, 146 1.1 mrg /* A type signature. */ 147 1.1 mrg ATTR_VAL_REF_TYPE, 148 1.1 mrg /* A block of data (not represented). */ 149 1.1 mrg ATTR_VAL_BLOCK, 150 1.1 mrg /* An expression (not represented). */ 151 1.1 mrg ATTR_VAL_EXPR, 152 1.1 mrg }; 153 1.1 mrg 154 1.1 mrg /* An attribute value. */ 155 1.1 mrg 156 1.1 mrg struct attr_val 157 1.1 mrg { 158 1.1 mrg /* How the value is stored in the field u. */ 159 1.1 mrg enum attr_val_encoding encoding; 160 1.1 mrg union 161 1.1 mrg { 162 1.1 mrg /* ATTR_VAL_ADDRESS, ATTR_VAL_UINT, ATTR_VAL_REF*. */ 163 1.1 mrg uint64_t uint; 164 1.1 mrg /* ATTR_VAL_SINT. */ 165 1.1 mrg int64_t sint; 166 1.1 mrg /* ATTR_VAL_STRING. */ 167 1.1 mrg const char *string; 168 1.1 mrg /* ATTR_VAL_BLOCK not stored. */ 169 1.1 mrg } u; 170 1.1 mrg }; 171 1.1 mrg 172 1.1 mrg /* The line number program header. */ 173 1.1 mrg 174 1.1 mrg struct line_header 175 1.1 mrg { 176 1.1 mrg /* The version of the line number information. */ 177 1.1 mrg int version; 178 1.1 mrg /* The minimum instruction length. */ 179 1.1 mrg unsigned int min_insn_len; 180 1.1 mrg /* The maximum number of ops per instruction. */ 181 1.1 mrg unsigned int max_ops_per_insn; 182 1.1 mrg /* The line base for special opcodes. */ 183 1.1 mrg int line_base; 184 1.1 mrg /* The line range for special opcodes. */ 185 1.1 mrg unsigned int line_range; 186 1.1 mrg /* The opcode base--the first special opcode. */ 187 1.1 mrg unsigned int opcode_base; 188 1.1 mrg /* Opcode lengths, indexed by opcode - 1. */ 189 1.1 mrg const unsigned char *opcode_lengths; 190 1.1 mrg /* The number of directory entries. */ 191 1.1 mrg size_t dirs_count; 192 1.1 mrg /* The directory entries. */ 193 1.1 mrg const char **dirs; 194 1.1 mrg /* The number of filenames. */ 195 1.1 mrg size_t filenames_count; 196 1.1 mrg /* The filenames. */ 197 1.1 mrg const char **filenames; 198 1.1 mrg }; 199 1.1 mrg 200 1.1 mrg /* Map a single PC value to a file/line. We will keep a vector of 201 1.1 mrg these sorted by PC value. Each file/line will be correct from the 202 1.1 mrg PC up to the PC of the next entry if there is one. We allocate one 203 1.1 mrg extra entry at the end so that we can use bsearch. */ 204 1.1 mrg 205 1.1 mrg struct line 206 1.1 mrg { 207 1.1 mrg /* PC. */ 208 1.1 mrg uintptr_t pc; 209 1.1 mrg /* File name. Many entries in the array are expected to point to 210 1.1 mrg the same file name. */ 211 1.1 mrg const char *filename; 212 1.1 mrg /* Line number. */ 213 1.1 mrg int lineno; 214 1.1.1.3 mrg /* Index of the object in the original array read from the DWARF 215 1.1.1.3 mrg section, before it has been sorted. The index makes it possible 216 1.1.1.3 mrg to use Quicksort and maintain stability. */ 217 1.1.1.3 mrg int idx; 218 1.1 mrg }; 219 1.1 mrg 220 1.1 mrg /* A growable vector of line number information. This is used while 221 1.1 mrg reading the line numbers. */ 222 1.1 mrg 223 1.1 mrg struct line_vector 224 1.1 mrg { 225 1.1 mrg /* Memory. This is an array of struct line. */ 226 1.1 mrg struct backtrace_vector vec; 227 1.1 mrg /* Number of valid mappings. */ 228 1.1 mrg size_t count; 229 1.1 mrg }; 230 1.1 mrg 231 1.1 mrg /* A function described in the debug info. */ 232 1.1 mrg 233 1.1 mrg struct function 234 1.1 mrg { 235 1.1 mrg /* The name of the function. */ 236 1.1 mrg const char *name; 237 1.1 mrg /* If this is an inlined function, the filename of the call 238 1.1 mrg site. */ 239 1.1 mrg const char *caller_filename; 240 1.1 mrg /* If this is an inlined function, the line number of the call 241 1.1 mrg site. */ 242 1.1 mrg int caller_lineno; 243 1.1 mrg /* Map PC ranges to inlined functions. */ 244 1.1 mrg struct function_addrs *function_addrs; 245 1.1 mrg size_t function_addrs_count; 246 1.1 mrg }; 247 1.1 mrg 248 1.1 mrg /* An address range for a function. This maps a PC value to a 249 1.1 mrg specific function. */ 250 1.1 mrg 251 1.1 mrg struct function_addrs 252 1.1 mrg { 253 1.1 mrg /* Range is LOW <= PC < HIGH. */ 254 1.1 mrg uint64_t low; 255 1.1 mrg uint64_t high; 256 1.1 mrg /* Function for this address range. */ 257 1.1 mrg struct function *function; 258 1.1 mrg }; 259 1.1 mrg 260 1.1 mrg /* A growable vector of function address ranges. */ 261 1.1 mrg 262 1.1 mrg struct function_vector 263 1.1 mrg { 264 1.1 mrg /* Memory. This is an array of struct function_addrs. */ 265 1.1 mrg struct backtrace_vector vec; 266 1.1 mrg /* Number of address ranges present. */ 267 1.1 mrg size_t count; 268 1.1 mrg }; 269 1.1 mrg 270 1.1 mrg /* A DWARF compilation unit. This only holds the information we need 271 1.1 mrg to map a PC to a file and line. */ 272 1.1 mrg 273 1.1 mrg struct unit 274 1.1 mrg { 275 1.1 mrg /* The first entry for this compilation unit. */ 276 1.1 mrg const unsigned char *unit_data; 277 1.1 mrg /* The length of the data for this compilation unit. */ 278 1.1 mrg size_t unit_data_len; 279 1.1 mrg /* The offset of UNIT_DATA from the start of the information for 280 1.1 mrg this compilation unit. */ 281 1.1 mrg size_t unit_data_offset; 282 1.1 mrg /* DWARF version. */ 283 1.1 mrg int version; 284 1.1 mrg /* Whether unit is DWARF64. */ 285 1.1 mrg int is_dwarf64; 286 1.1 mrg /* Address size. */ 287 1.1 mrg int addrsize; 288 1.1 mrg /* Offset into line number information. */ 289 1.1 mrg off_t lineoff; 290 1.1 mrg /* Primary source file. */ 291 1.1 mrg const char *filename; 292 1.1 mrg /* Compilation command working directory. */ 293 1.1 mrg const char *comp_dir; 294 1.1 mrg /* Absolute file name, only set if needed. */ 295 1.1 mrg const char *abs_filename; 296 1.1 mrg /* The abbreviations for this unit. */ 297 1.1 mrg struct abbrevs abbrevs; 298 1.1 mrg 299 1.1 mrg /* The fields above this point are read in during initialization and 300 1.1 mrg may be accessed freely. The fields below this point are read in 301 1.1 mrg as needed, and therefore require care, as different threads may 302 1.1 mrg try to initialize them simultaneously. */ 303 1.1 mrg 304 1.1 mrg /* PC to line number mapping. This is NULL if the values have not 305 1.1 mrg been read. This is (struct line *) -1 if there was an error 306 1.1 mrg reading the values. */ 307 1.1 mrg struct line *lines; 308 1.1 mrg /* Number of entries in lines. */ 309 1.1 mrg size_t lines_count; 310 1.1 mrg /* PC ranges to function. */ 311 1.1 mrg struct function_addrs *function_addrs; 312 1.1 mrg size_t function_addrs_count; 313 1.1 mrg }; 314 1.1 mrg 315 1.1 mrg /* An address range for a compilation unit. This maps a PC value to a 316 1.1 mrg specific compilation unit. Note that we invert the representation 317 1.1 mrg in DWARF: instead of listing the units and attaching a list of 318 1.1 mrg ranges, we list the ranges and have each one point to the unit. 319 1.1 mrg This lets us do a binary search to find the unit. */ 320 1.1 mrg 321 1.1 mrg struct unit_addrs 322 1.1 mrg { 323 1.1 mrg /* Range is LOW <= PC < HIGH. */ 324 1.1 mrg uint64_t low; 325 1.1 mrg uint64_t high; 326 1.1 mrg /* Compilation unit for this address range. */ 327 1.1 mrg struct unit *u; 328 1.1 mrg }; 329 1.1 mrg 330 1.1 mrg /* A growable vector of compilation unit address ranges. */ 331 1.1 mrg 332 1.1 mrg struct unit_addrs_vector 333 1.1 mrg { 334 1.1 mrg /* Memory. This is an array of struct unit_addrs. */ 335 1.1 mrg struct backtrace_vector vec; 336 1.1 mrg /* Number of address ranges present. */ 337 1.1 mrg size_t count; 338 1.1 mrg }; 339 1.1 mrg 340 1.1 mrg /* The information we need to map a PC to a file and line. */ 341 1.1 mrg 342 1.1 mrg struct dwarf_data 343 1.1 mrg { 344 1.1 mrg /* The data for the next file we know about. */ 345 1.1 mrg struct dwarf_data *next; 346 1.1 mrg /* The base address for this file. */ 347 1.1 mrg uintptr_t base_address; 348 1.1 mrg /* A sorted list of address ranges. */ 349 1.1 mrg struct unit_addrs *addrs; 350 1.1 mrg /* Number of address ranges in list. */ 351 1.1 mrg size_t addrs_count; 352 1.1 mrg /* The unparsed .debug_info section. */ 353 1.1 mrg const unsigned char *dwarf_info; 354 1.1 mrg size_t dwarf_info_size; 355 1.1 mrg /* The unparsed .debug_line section. */ 356 1.1 mrg const unsigned char *dwarf_line; 357 1.1 mrg size_t dwarf_line_size; 358 1.1 mrg /* The unparsed .debug_ranges section. */ 359 1.1 mrg const unsigned char *dwarf_ranges; 360 1.1 mrg size_t dwarf_ranges_size; 361 1.1 mrg /* The unparsed .debug_str section. */ 362 1.1 mrg const unsigned char *dwarf_str; 363 1.1 mrg size_t dwarf_str_size; 364 1.1 mrg /* Whether the data is big-endian or not. */ 365 1.1 mrg int is_bigendian; 366 1.1 mrg /* A vector used for function addresses. We keep this here so that 367 1.1 mrg we can grow the vector as we read more functions. */ 368 1.1 mrg struct function_vector fvec; 369 1.1 mrg }; 370 1.1 mrg 371 1.1 mrg /* Report an error for a DWARF buffer. */ 372 1.1 mrg 373 1.1 mrg static void 374 1.1 mrg dwarf_buf_error (struct dwarf_buf *buf, const char *msg) 375 1.1 mrg { 376 1.1 mrg char b[200]; 377 1.1 mrg 378 1.1 mrg snprintf (b, sizeof b, "%s in %s at %d", 379 1.1 mrg msg, buf->name, (int) (buf->buf - buf->start)); 380 1.1 mrg buf->error_callback (buf->data, b, 0); 381 1.1 mrg } 382 1.1 mrg 383 1.1 mrg /* Require at least COUNT bytes in BUF. Return 1 if all is well, 0 on 384 1.1 mrg error. */ 385 1.1 mrg 386 1.1 mrg static int 387 1.1 mrg require (struct dwarf_buf *buf, size_t count) 388 1.1 mrg { 389 1.1 mrg if (buf->left >= count) 390 1.1 mrg return 1; 391 1.1 mrg 392 1.1 mrg if (!buf->reported_underflow) 393 1.1 mrg { 394 1.1 mrg dwarf_buf_error (buf, "DWARF underflow"); 395 1.1 mrg buf->reported_underflow = 1; 396 1.1 mrg } 397 1.1 mrg 398 1.1 mrg return 0; 399 1.1 mrg } 400 1.1 mrg 401 1.1 mrg /* Advance COUNT bytes in BUF. Return 1 if all is well, 0 on 402 1.1 mrg error. */ 403 1.1 mrg 404 1.1 mrg static int 405 1.1 mrg advance (struct dwarf_buf *buf, size_t count) 406 1.1 mrg { 407 1.1 mrg if (!require (buf, count)) 408 1.1 mrg return 0; 409 1.1 mrg buf->buf += count; 410 1.1 mrg buf->left -= count; 411 1.1 mrg return 1; 412 1.1 mrg } 413 1.1 mrg 414 1.1 mrg /* Read one byte from BUF and advance 1 byte. */ 415 1.1 mrg 416 1.1 mrg static unsigned char 417 1.1 mrg read_byte (struct dwarf_buf *buf) 418 1.1 mrg { 419 1.1 mrg const unsigned char *p = buf->buf; 420 1.1 mrg 421 1.1 mrg if (!advance (buf, 1)) 422 1.1 mrg return 0; 423 1.1 mrg return p[0]; 424 1.1 mrg } 425 1.1 mrg 426 1.1 mrg /* Read a signed char from BUF and advance 1 byte. */ 427 1.1 mrg 428 1.1 mrg static signed char 429 1.1 mrg read_sbyte (struct dwarf_buf *buf) 430 1.1 mrg { 431 1.1 mrg const unsigned char *p = buf->buf; 432 1.1 mrg 433 1.1 mrg if (!advance (buf, 1)) 434 1.1 mrg return 0; 435 1.1 mrg return (*p ^ 0x80) - 0x80; 436 1.1 mrg } 437 1.1 mrg 438 1.1 mrg /* Read a uint16 from BUF and advance 2 bytes. */ 439 1.1 mrg 440 1.1 mrg static uint16_t 441 1.1 mrg read_uint16 (struct dwarf_buf *buf) 442 1.1 mrg { 443 1.1 mrg const unsigned char *p = buf->buf; 444 1.1 mrg 445 1.1 mrg if (!advance (buf, 2)) 446 1.1 mrg return 0; 447 1.1 mrg if (buf->is_bigendian) 448 1.1 mrg return ((uint16_t) p[0] << 8) | (uint16_t) p[1]; 449 1.1 mrg else 450 1.1 mrg return ((uint16_t) p[1] << 8) | (uint16_t) p[0]; 451 1.1 mrg } 452 1.1 mrg 453 1.1 mrg /* Read a uint32 from BUF and advance 4 bytes. */ 454 1.1 mrg 455 1.1 mrg static uint32_t 456 1.1 mrg read_uint32 (struct dwarf_buf *buf) 457 1.1 mrg { 458 1.1 mrg const unsigned char *p = buf->buf; 459 1.1 mrg 460 1.1 mrg if (!advance (buf, 4)) 461 1.1 mrg return 0; 462 1.1 mrg if (buf->is_bigendian) 463 1.1 mrg return (((uint32_t) p[0] << 24) | ((uint32_t) p[1] << 16) 464 1.1 mrg | ((uint32_t) p[2] << 8) | (uint32_t) p[3]); 465 1.1 mrg else 466 1.1 mrg return (((uint32_t) p[3] << 24) | ((uint32_t) p[2] << 16) 467 1.1 mrg | ((uint32_t) p[1] << 8) | (uint32_t) p[0]); 468 1.1 mrg } 469 1.1 mrg 470 1.1 mrg /* Read a uint64 from BUF and advance 8 bytes. */ 471 1.1 mrg 472 1.1 mrg static uint64_t 473 1.1 mrg read_uint64 (struct dwarf_buf *buf) 474 1.1 mrg { 475 1.1 mrg const unsigned char *p = buf->buf; 476 1.1 mrg 477 1.1 mrg if (!advance (buf, 8)) 478 1.1 mrg return 0; 479 1.1 mrg if (buf->is_bigendian) 480 1.1 mrg return (((uint64_t) p[0] << 56) | ((uint64_t) p[1] << 48) 481 1.1 mrg | ((uint64_t) p[2] << 40) | ((uint64_t) p[3] << 32) 482 1.1 mrg | ((uint64_t) p[4] << 24) | ((uint64_t) p[5] << 16) 483 1.1 mrg | ((uint64_t) p[6] << 8) | (uint64_t) p[7]); 484 1.1 mrg else 485 1.1 mrg return (((uint64_t) p[7] << 56) | ((uint64_t) p[6] << 48) 486 1.1 mrg | ((uint64_t) p[5] << 40) | ((uint64_t) p[4] << 32) 487 1.1 mrg | ((uint64_t) p[3] << 24) | ((uint64_t) p[2] << 16) 488 1.1 mrg | ((uint64_t) p[1] << 8) | (uint64_t) p[0]); 489 1.1 mrg } 490 1.1 mrg 491 1.1 mrg /* Read an offset from BUF and advance the appropriate number of 492 1.1 mrg bytes. */ 493 1.1 mrg 494 1.1 mrg static uint64_t 495 1.1 mrg read_offset (struct dwarf_buf *buf, int is_dwarf64) 496 1.1 mrg { 497 1.1 mrg if (is_dwarf64) 498 1.1 mrg return read_uint64 (buf); 499 1.1 mrg else 500 1.1 mrg return read_uint32 (buf); 501 1.1 mrg } 502 1.1 mrg 503 1.1 mrg /* Read an address from BUF and advance the appropriate number of 504 1.1 mrg bytes. */ 505 1.1 mrg 506 1.1 mrg static uint64_t 507 1.1 mrg read_address (struct dwarf_buf *buf, int addrsize) 508 1.1 mrg { 509 1.1 mrg switch (addrsize) 510 1.1 mrg { 511 1.1 mrg case 1: 512 1.1 mrg return read_byte (buf); 513 1.1 mrg case 2: 514 1.1 mrg return read_uint16 (buf); 515 1.1 mrg case 4: 516 1.1 mrg return read_uint32 (buf); 517 1.1 mrg case 8: 518 1.1 mrg return read_uint64 (buf); 519 1.1 mrg default: 520 1.1 mrg dwarf_buf_error (buf, "unrecognized address size"); 521 1.1 mrg return 0; 522 1.1 mrg } 523 1.1 mrg } 524 1.1 mrg 525 1.1 mrg /* Return whether a value is the highest possible address, given the 526 1.1 mrg address size. */ 527 1.1 mrg 528 1.1 mrg static int 529 1.1 mrg is_highest_address (uint64_t address, int addrsize) 530 1.1 mrg { 531 1.1 mrg switch (addrsize) 532 1.1 mrg { 533 1.1 mrg case 1: 534 1.1 mrg return address == (unsigned char) -1; 535 1.1 mrg case 2: 536 1.1 mrg return address == (uint16_t) -1; 537 1.1 mrg case 4: 538 1.1 mrg return address == (uint32_t) -1; 539 1.1 mrg case 8: 540 1.1 mrg return address == (uint64_t) -1; 541 1.1 mrg default: 542 1.1 mrg return 0; 543 1.1 mrg } 544 1.1 mrg } 545 1.1 mrg 546 1.1 mrg /* Read an unsigned LEB128 number. */ 547 1.1 mrg 548 1.1 mrg static uint64_t 549 1.1 mrg read_uleb128 (struct dwarf_buf *buf) 550 1.1 mrg { 551 1.1 mrg uint64_t ret; 552 1.1 mrg unsigned int shift; 553 1.1 mrg int overflow; 554 1.1 mrg unsigned char b; 555 1.1 mrg 556 1.1 mrg ret = 0; 557 1.1 mrg shift = 0; 558 1.1 mrg overflow = 0; 559 1.1 mrg do 560 1.1 mrg { 561 1.1 mrg const unsigned char *p; 562 1.1 mrg 563 1.1 mrg p = buf->buf; 564 1.1 mrg if (!advance (buf, 1)) 565 1.1 mrg return 0; 566 1.1 mrg b = *p; 567 1.1 mrg if (shift < 64) 568 1.1 mrg ret |= ((uint64_t) (b & 0x7f)) << shift; 569 1.1 mrg else if (!overflow) 570 1.1 mrg { 571 1.1 mrg dwarf_buf_error (buf, "LEB128 overflows uint64_t"); 572 1.1 mrg overflow = 1; 573 1.1 mrg } 574 1.1 mrg shift += 7; 575 1.1 mrg } 576 1.1 mrg while ((b & 0x80) != 0); 577 1.1 mrg 578 1.1 mrg return ret; 579 1.1 mrg } 580 1.1 mrg 581 1.1 mrg /* Read a signed LEB128 number. */ 582 1.1 mrg 583 1.1 mrg static int64_t 584 1.1 mrg read_sleb128 (struct dwarf_buf *buf) 585 1.1 mrg { 586 1.1 mrg uint64_t val; 587 1.1 mrg unsigned int shift; 588 1.1 mrg int overflow; 589 1.1 mrg unsigned char b; 590 1.1 mrg 591 1.1 mrg val = 0; 592 1.1 mrg shift = 0; 593 1.1 mrg overflow = 0; 594 1.1 mrg do 595 1.1 mrg { 596 1.1 mrg const unsigned char *p; 597 1.1 mrg 598 1.1 mrg p = buf->buf; 599 1.1 mrg if (!advance (buf, 1)) 600 1.1 mrg return 0; 601 1.1 mrg b = *p; 602 1.1 mrg if (shift < 64) 603 1.1 mrg val |= ((uint64_t) (b & 0x7f)) << shift; 604 1.1 mrg else if (!overflow) 605 1.1 mrg { 606 1.1 mrg dwarf_buf_error (buf, "signed LEB128 overflows uint64_t"); 607 1.1 mrg overflow = 1; 608 1.1 mrg } 609 1.1 mrg shift += 7; 610 1.1 mrg } 611 1.1 mrg while ((b & 0x80) != 0); 612 1.1 mrg 613 1.1 mrg if ((b & 0x40) != 0 && shift < 64) 614 1.1 mrg val |= ((uint64_t) -1) << shift; 615 1.1 mrg 616 1.1 mrg return (int64_t) val; 617 1.1 mrg } 618 1.1 mrg 619 1.1 mrg /* Return the length of an LEB128 number. */ 620 1.1 mrg 621 1.1 mrg static size_t 622 1.1 mrg leb128_len (const unsigned char *p) 623 1.1 mrg { 624 1.1 mrg size_t ret; 625 1.1 mrg 626 1.1 mrg ret = 1; 627 1.1 mrg while ((*p & 0x80) != 0) 628 1.1 mrg { 629 1.1 mrg ++p; 630 1.1 mrg ++ret; 631 1.1 mrg } 632 1.1 mrg return ret; 633 1.1 mrg } 634 1.1 mrg 635 1.1 mrg /* Free an abbreviations structure. */ 636 1.1 mrg 637 1.1 mrg static void 638 1.1 mrg free_abbrevs (struct backtrace_state *state, struct abbrevs *abbrevs, 639 1.1 mrg backtrace_error_callback error_callback, void *data) 640 1.1 mrg { 641 1.1 mrg size_t i; 642 1.1 mrg 643 1.1 mrg for (i = 0; i < abbrevs->num_abbrevs; ++i) 644 1.1 mrg backtrace_free (state, abbrevs->abbrevs[i].attrs, 645 1.1 mrg abbrevs->abbrevs[i].num_attrs * sizeof (struct attr), 646 1.1 mrg error_callback, data); 647 1.1 mrg backtrace_free (state, abbrevs->abbrevs, 648 1.1 mrg abbrevs->num_abbrevs * sizeof (struct abbrev), 649 1.1 mrg error_callback, data); 650 1.1 mrg abbrevs->num_abbrevs = 0; 651 1.1 mrg abbrevs->abbrevs = NULL; 652 1.1 mrg } 653 1.1 mrg 654 1.1 mrg /* Read an attribute value. Returns 1 on success, 0 on failure. If 655 1.1 mrg the value can be represented as a uint64_t, sets *VAL and sets 656 1.1 mrg *IS_VALID to 1. We don't try to store the value of other attribute 657 1.1 mrg forms, because we don't care about them. */ 658 1.1 mrg 659 1.1 mrg static int 660 1.1 mrg read_attribute (enum dwarf_form form, struct dwarf_buf *buf, 661 1.1 mrg int is_dwarf64, int version, int addrsize, 662 1.1 mrg const unsigned char *dwarf_str, size_t dwarf_str_size, 663 1.1 mrg struct attr_val *val) 664 1.1 mrg { 665 1.1 mrg /* Avoid warnings about val.u.FIELD may be used uninitialized if 666 1.1 mrg this function is inlined. The warnings aren't valid but can 667 1.1 mrg occur because the different fields are set and used 668 1.1 mrg conditionally. */ 669 1.1 mrg memset (val, 0, sizeof *val); 670 1.1 mrg 671 1.1 mrg switch (form) 672 1.1 mrg { 673 1.1 mrg case DW_FORM_addr: 674 1.1 mrg val->encoding = ATTR_VAL_ADDRESS; 675 1.1 mrg val->u.uint = read_address (buf, addrsize); 676 1.1 mrg return 1; 677 1.1 mrg case DW_FORM_block2: 678 1.1 mrg val->encoding = ATTR_VAL_BLOCK; 679 1.1 mrg return advance (buf, read_uint16 (buf)); 680 1.1 mrg case DW_FORM_block4: 681 1.1 mrg val->encoding = ATTR_VAL_BLOCK; 682 1.1 mrg return advance (buf, read_uint32 (buf)); 683 1.1 mrg case DW_FORM_data2: 684 1.1 mrg val->encoding = ATTR_VAL_UINT; 685 1.1 mrg val->u.uint = read_uint16 (buf); 686 1.1 mrg return 1; 687 1.1 mrg case DW_FORM_data4: 688 1.1 mrg val->encoding = ATTR_VAL_UINT; 689 1.1 mrg val->u.uint = read_uint32 (buf); 690 1.1 mrg return 1; 691 1.1 mrg case DW_FORM_data8: 692 1.1 mrg val->encoding = ATTR_VAL_UINT; 693 1.1 mrg val->u.uint = read_uint64 (buf); 694 1.1 mrg return 1; 695 1.1 mrg case DW_FORM_string: 696 1.1 mrg val->encoding = ATTR_VAL_STRING; 697 1.1 mrg val->u.string = (const char *) buf->buf; 698 1.1 mrg return advance (buf, strnlen ((const char *) buf->buf, buf->left) + 1); 699 1.1 mrg case DW_FORM_block: 700 1.1 mrg val->encoding = ATTR_VAL_BLOCK; 701 1.1 mrg return advance (buf, read_uleb128 (buf)); 702 1.1 mrg case DW_FORM_block1: 703 1.1 mrg val->encoding = ATTR_VAL_BLOCK; 704 1.1 mrg return advance (buf, read_byte (buf)); 705 1.1 mrg case DW_FORM_data1: 706 1.1 mrg val->encoding = ATTR_VAL_UINT; 707 1.1 mrg val->u.uint = read_byte (buf); 708 1.1 mrg return 1; 709 1.1 mrg case DW_FORM_flag: 710 1.1 mrg val->encoding = ATTR_VAL_UINT; 711 1.1 mrg val->u.uint = read_byte (buf); 712 1.1 mrg return 1; 713 1.1 mrg case DW_FORM_sdata: 714 1.1 mrg val->encoding = ATTR_VAL_SINT; 715 1.1 mrg val->u.sint = read_sleb128 (buf); 716 1.1 mrg return 1; 717 1.1 mrg case DW_FORM_strp: 718 1.1 mrg { 719 1.1 mrg uint64_t offset; 720 1.1 mrg 721 1.1 mrg offset = read_offset (buf, is_dwarf64); 722 1.1 mrg if (offset >= dwarf_str_size) 723 1.1 mrg { 724 1.1 mrg dwarf_buf_error (buf, "DW_FORM_strp out of range"); 725 1.1 mrg return 0; 726 1.1 mrg } 727 1.1 mrg val->encoding = ATTR_VAL_STRING; 728 1.1 mrg val->u.string = (const char *) dwarf_str + offset; 729 1.1 mrg return 1; 730 1.1 mrg } 731 1.1 mrg case DW_FORM_udata: 732 1.1 mrg val->encoding = ATTR_VAL_UINT; 733 1.1 mrg val->u.uint = read_uleb128 (buf); 734 1.1 mrg return 1; 735 1.1 mrg case DW_FORM_ref_addr: 736 1.1 mrg val->encoding = ATTR_VAL_REF_INFO; 737 1.1 mrg if (version == 2) 738 1.1 mrg val->u.uint = read_address (buf, addrsize); 739 1.1 mrg else 740 1.1 mrg val->u.uint = read_offset (buf, is_dwarf64); 741 1.1 mrg return 1; 742 1.1 mrg case DW_FORM_ref1: 743 1.1 mrg val->encoding = ATTR_VAL_REF_UNIT; 744 1.1 mrg val->u.uint = read_byte (buf); 745 1.1 mrg return 1; 746 1.1 mrg case DW_FORM_ref2: 747 1.1 mrg val->encoding = ATTR_VAL_REF_UNIT; 748 1.1 mrg val->u.uint = read_uint16 (buf); 749 1.1 mrg return 1; 750 1.1 mrg case DW_FORM_ref4: 751 1.1 mrg val->encoding = ATTR_VAL_REF_UNIT; 752 1.1 mrg val->u.uint = read_uint32 (buf); 753 1.1 mrg return 1; 754 1.1 mrg case DW_FORM_ref8: 755 1.1 mrg val->encoding = ATTR_VAL_REF_UNIT; 756 1.1 mrg val->u.uint = read_uint64 (buf); 757 1.1 mrg return 1; 758 1.1 mrg case DW_FORM_ref_udata: 759 1.1 mrg val->encoding = ATTR_VAL_REF_UNIT; 760 1.1 mrg val->u.uint = read_uleb128 (buf); 761 1.1 mrg return 1; 762 1.1 mrg case DW_FORM_indirect: 763 1.1 mrg { 764 1.1 mrg uint64_t form; 765 1.1 mrg 766 1.1 mrg form = read_uleb128 (buf); 767 1.1 mrg return read_attribute ((enum dwarf_form) form, buf, is_dwarf64, 768 1.1 mrg version, addrsize, dwarf_str, dwarf_str_size, 769 1.1 mrg val); 770 1.1 mrg } 771 1.1 mrg case DW_FORM_sec_offset: 772 1.1 mrg val->encoding = ATTR_VAL_REF_SECTION; 773 1.1 mrg val->u.uint = read_offset (buf, is_dwarf64); 774 1.1 mrg return 1; 775 1.1 mrg case DW_FORM_exprloc: 776 1.1 mrg val->encoding = ATTR_VAL_EXPR; 777 1.1 mrg return advance (buf, read_uleb128 (buf)); 778 1.1 mrg case DW_FORM_flag_present: 779 1.1 mrg val->encoding = ATTR_VAL_UINT; 780 1.1 mrg val->u.uint = 1; 781 1.1 mrg return 1; 782 1.1 mrg case DW_FORM_ref_sig8: 783 1.1 mrg val->encoding = ATTR_VAL_REF_TYPE; 784 1.1 mrg val->u.uint = read_uint64 (buf); 785 1.1 mrg return 1; 786 1.1 mrg case DW_FORM_GNU_addr_index: 787 1.1 mrg val->encoding = ATTR_VAL_REF_SECTION; 788 1.1 mrg val->u.uint = read_uleb128 (buf); 789 1.1 mrg return 1; 790 1.1 mrg case DW_FORM_GNU_str_index: 791 1.1 mrg val->encoding = ATTR_VAL_REF_SECTION; 792 1.1 mrg val->u.uint = read_uleb128 (buf); 793 1.1 mrg return 1; 794 1.1 mrg case DW_FORM_GNU_ref_alt: 795 1.1 mrg val->encoding = ATTR_VAL_REF_SECTION; 796 1.1 mrg val->u.uint = read_offset (buf, is_dwarf64); 797 1.1 mrg return 1; 798 1.1 mrg case DW_FORM_GNU_strp_alt: 799 1.1 mrg val->encoding = ATTR_VAL_REF_SECTION; 800 1.1 mrg val->u.uint = read_offset (buf, is_dwarf64); 801 1.1 mrg return 1; 802 1.1 mrg default: 803 1.1 mrg dwarf_buf_error (buf, "unrecognized DWARF form"); 804 1.1 mrg return 0; 805 1.1 mrg } 806 1.1 mrg } 807 1.1 mrg 808 1.1 mrg /* Compare function_addrs for qsort. When ranges are nested, make the 809 1.1 mrg smallest one sort last. */ 810 1.1 mrg 811 1.1 mrg static int 812 1.1 mrg function_addrs_compare (const void *v1, const void *v2) 813 1.1 mrg { 814 1.1 mrg const struct function_addrs *a1 = (const struct function_addrs *) v1; 815 1.1 mrg const struct function_addrs *a2 = (const struct function_addrs *) v2; 816 1.1 mrg 817 1.1 mrg if (a1->low < a2->low) 818 1.1 mrg return -1; 819 1.1 mrg if (a1->low > a2->low) 820 1.1 mrg return 1; 821 1.1 mrg if (a1->high < a2->high) 822 1.1 mrg return 1; 823 1.1 mrg if (a1->high > a2->high) 824 1.1 mrg return -1; 825 1.1 mrg return strcmp (a1->function->name, a2->function->name); 826 1.1 mrg } 827 1.1 mrg 828 1.1 mrg /* Compare a PC against a function_addrs for bsearch. Note that if 829 1.1 mrg there are multiple ranges containing PC, which one will be returned 830 1.1 mrg is unpredictable. We compensate for that in dwarf_fileline. */ 831 1.1 mrg 832 1.1 mrg static int 833 1.1 mrg function_addrs_search (const void *vkey, const void *ventry) 834 1.1 mrg { 835 1.1 mrg const uintptr_t *key = (const uintptr_t *) vkey; 836 1.1 mrg const struct function_addrs *entry = (const struct function_addrs *) ventry; 837 1.1 mrg uintptr_t pc; 838 1.1 mrg 839 1.1 mrg pc = *key; 840 1.1 mrg if (pc < entry->low) 841 1.1 mrg return -1; 842 1.1 mrg else if (pc >= entry->high) 843 1.1 mrg return 1; 844 1.1 mrg else 845 1.1 mrg return 0; 846 1.1 mrg } 847 1.1 mrg 848 1.1 mrg /* Add a new compilation unit address range to a vector. Returns 1 on 849 1.1 mrg success, 0 on failure. */ 850 1.1 mrg 851 1.1 mrg static int 852 1.1 mrg add_unit_addr (struct backtrace_state *state, uintptr_t base_address, 853 1.1 mrg struct unit_addrs addrs, 854 1.1 mrg backtrace_error_callback error_callback, void *data, 855 1.1 mrg struct unit_addrs_vector *vec) 856 1.1 mrg { 857 1.1 mrg struct unit_addrs *p; 858 1.1 mrg 859 1.1 mrg /* Add in the base address of the module here, so that we can look 860 1.1 mrg up the PC directly. */ 861 1.1 mrg addrs.low += base_address; 862 1.1 mrg addrs.high += base_address; 863 1.1 mrg 864 1.1 mrg /* Try to merge with the last entry. */ 865 1.1 mrg if (vec->count > 0) 866 1.1 mrg { 867 1.1 mrg p = (struct unit_addrs *) vec->vec.base + (vec->count - 1); 868 1.1 mrg if ((addrs.low == p->high || addrs.low == p->high + 1) 869 1.1 mrg && addrs.u == p->u) 870 1.1 mrg { 871 1.1 mrg if (addrs.high > p->high) 872 1.1 mrg p->high = addrs.high; 873 1.1 mrg return 1; 874 1.1 mrg } 875 1.1 mrg } 876 1.1 mrg 877 1.1 mrg p = ((struct unit_addrs *) 878 1.1 mrg backtrace_vector_grow (state, sizeof (struct unit_addrs), 879 1.1 mrg error_callback, data, &vec->vec)); 880 1.1 mrg if (p == NULL) 881 1.1 mrg return 0; 882 1.1 mrg 883 1.1 mrg *p = addrs; 884 1.1 mrg ++vec->count; 885 1.1 mrg return 1; 886 1.1 mrg } 887 1.1 mrg 888 1.1 mrg /* Free a unit address vector. */ 889 1.1 mrg 890 1.1 mrg static void 891 1.1 mrg free_unit_addrs_vector (struct backtrace_state *state, 892 1.1 mrg struct unit_addrs_vector *vec, 893 1.1 mrg backtrace_error_callback error_callback, void *data) 894 1.1 mrg { 895 1.1 mrg struct unit_addrs *addrs; 896 1.1 mrg size_t i; 897 1.1 mrg 898 1.1 mrg addrs = (struct unit_addrs *) vec->vec.base; 899 1.1 mrg for (i = 0; i < vec->count; ++i) 900 1.1 mrg free_abbrevs (state, &addrs[i].u->abbrevs, error_callback, data); 901 1.1 mrg } 902 1.1 mrg 903 1.1 mrg /* Compare unit_addrs for qsort. When ranges are nested, make the 904 1.1 mrg smallest one sort last. */ 905 1.1 mrg 906 1.1 mrg static int 907 1.1 mrg unit_addrs_compare (const void *v1, const void *v2) 908 1.1 mrg { 909 1.1 mrg const struct unit_addrs *a1 = (const struct unit_addrs *) v1; 910 1.1 mrg const struct unit_addrs *a2 = (const struct unit_addrs *) v2; 911 1.1 mrg 912 1.1 mrg if (a1->low < a2->low) 913 1.1 mrg return -1; 914 1.1 mrg if (a1->low > a2->low) 915 1.1 mrg return 1; 916 1.1 mrg if (a1->high < a2->high) 917 1.1 mrg return 1; 918 1.1 mrg if (a1->high > a2->high) 919 1.1 mrg return -1; 920 1.1 mrg if (a1->u->lineoff < a2->u->lineoff) 921 1.1 mrg return -1; 922 1.1 mrg if (a1->u->lineoff > a2->u->lineoff) 923 1.1 mrg return 1; 924 1.1 mrg return 0; 925 1.1 mrg } 926 1.1 mrg 927 1.1 mrg /* Compare a PC against a unit_addrs for bsearch. Note that if there 928 1.1 mrg are multiple ranges containing PC, which one will be returned is 929 1.1 mrg unpredictable. We compensate for that in dwarf_fileline. */ 930 1.1 mrg 931 1.1 mrg static int 932 1.1 mrg unit_addrs_search (const void *vkey, const void *ventry) 933 1.1 mrg { 934 1.1 mrg const uintptr_t *key = (const uintptr_t *) vkey; 935 1.1 mrg const struct unit_addrs *entry = (const struct unit_addrs *) ventry; 936 1.1 mrg uintptr_t pc; 937 1.1 mrg 938 1.1 mrg pc = *key; 939 1.1 mrg if (pc < entry->low) 940 1.1 mrg return -1; 941 1.1 mrg else if (pc >= entry->high) 942 1.1 mrg return 1; 943 1.1 mrg else 944 1.1 mrg return 0; 945 1.1 mrg } 946 1.1 mrg 947 1.1.1.3 mrg /* Sort the line vector by PC. We want a stable sort here to maintain 948 1.1.1.3 mrg the order of lines for the same PC values. Since the sequence is 949 1.1.1.3 mrg being sorted in place, their addresses cannot be relied on to 950 1.1.1.3 mrg maintain stability. That is the purpose of the index member. */ 951 1.1 mrg 952 1.1 mrg static int 953 1.1 mrg line_compare (const void *v1, const void *v2) 954 1.1 mrg { 955 1.1 mrg const struct line *ln1 = (const struct line *) v1; 956 1.1 mrg const struct line *ln2 = (const struct line *) v2; 957 1.1 mrg 958 1.1 mrg if (ln1->pc < ln2->pc) 959 1.1 mrg return -1; 960 1.1 mrg else if (ln1->pc > ln2->pc) 961 1.1 mrg return 1; 962 1.1.1.3 mrg else if (ln1->idx < ln2->idx) 963 1.1 mrg return -1; 964 1.1.1.3 mrg else if (ln1->idx > ln2->idx) 965 1.1 mrg return 1; 966 1.1 mrg else 967 1.1 mrg return 0; 968 1.1 mrg } 969 1.1 mrg 970 1.1 mrg /* Find a PC in a line vector. We always allocate an extra entry at 971 1.1 mrg the end of the lines vector, so that this routine can safely look 972 1.1 mrg at the next entry. Note that when there are multiple mappings for 973 1.1 mrg the same PC value, this will return the last one. */ 974 1.1 mrg 975 1.1 mrg static int 976 1.1 mrg line_search (const void *vkey, const void *ventry) 977 1.1 mrg { 978 1.1 mrg const uintptr_t *key = (const uintptr_t *) vkey; 979 1.1 mrg const struct line *entry = (const struct line *) ventry; 980 1.1 mrg uintptr_t pc; 981 1.1 mrg 982 1.1 mrg pc = *key; 983 1.1 mrg if (pc < entry->pc) 984 1.1 mrg return -1; 985 1.1 mrg else if (pc >= (entry + 1)->pc) 986 1.1 mrg return 1; 987 1.1 mrg else 988 1.1 mrg return 0; 989 1.1 mrg } 990 1.1 mrg 991 1.1 mrg /* Sort the abbrevs by the abbrev code. This function is passed to 992 1.1 mrg both qsort and bsearch. */ 993 1.1 mrg 994 1.1 mrg static int 995 1.1 mrg abbrev_compare (const void *v1, const void *v2) 996 1.1 mrg { 997 1.1 mrg const struct abbrev *a1 = (const struct abbrev *) v1; 998 1.1 mrg const struct abbrev *a2 = (const struct abbrev *) v2; 999 1.1 mrg 1000 1.1 mrg if (a1->code < a2->code) 1001 1.1 mrg return -1; 1002 1.1 mrg else if (a1->code > a2->code) 1003 1.1 mrg return 1; 1004 1.1 mrg else 1005 1.1 mrg { 1006 1.1 mrg /* This really shouldn't happen. It means there are two 1007 1.1 mrg different abbrevs with the same code, and that means we don't 1008 1.1 mrg know which one lookup_abbrev should return. */ 1009 1.1 mrg return 0; 1010 1.1 mrg } 1011 1.1 mrg } 1012 1.1 mrg 1013 1.1 mrg /* Read the abbreviation table for a compilation unit. Returns 1 on 1014 1.1 mrg success, 0 on failure. */ 1015 1.1 mrg 1016 1.1 mrg static int 1017 1.1 mrg read_abbrevs (struct backtrace_state *state, uint64_t abbrev_offset, 1018 1.1 mrg const unsigned char *dwarf_abbrev, size_t dwarf_abbrev_size, 1019 1.1 mrg int is_bigendian, backtrace_error_callback error_callback, 1020 1.1 mrg void *data, struct abbrevs *abbrevs) 1021 1.1 mrg { 1022 1.1 mrg struct dwarf_buf abbrev_buf; 1023 1.1 mrg struct dwarf_buf count_buf; 1024 1.1 mrg size_t num_abbrevs; 1025 1.1 mrg 1026 1.1 mrg abbrevs->num_abbrevs = 0; 1027 1.1 mrg abbrevs->abbrevs = NULL; 1028 1.1 mrg 1029 1.1 mrg if (abbrev_offset >= dwarf_abbrev_size) 1030 1.1 mrg { 1031 1.1 mrg error_callback (data, "abbrev offset out of range", 0); 1032 1.1 mrg return 0; 1033 1.1 mrg } 1034 1.1 mrg 1035 1.1 mrg abbrev_buf.name = ".debug_abbrev"; 1036 1.1 mrg abbrev_buf.start = dwarf_abbrev; 1037 1.1 mrg abbrev_buf.buf = dwarf_abbrev + abbrev_offset; 1038 1.1 mrg abbrev_buf.left = dwarf_abbrev_size - abbrev_offset; 1039 1.1 mrg abbrev_buf.is_bigendian = is_bigendian; 1040 1.1 mrg abbrev_buf.error_callback = error_callback; 1041 1.1 mrg abbrev_buf.data = data; 1042 1.1 mrg abbrev_buf.reported_underflow = 0; 1043 1.1 mrg 1044 1.1 mrg /* Count the number of abbrevs in this list. */ 1045 1.1 mrg 1046 1.1 mrg count_buf = abbrev_buf; 1047 1.1 mrg num_abbrevs = 0; 1048 1.1 mrg while (read_uleb128 (&count_buf) != 0) 1049 1.1 mrg { 1050 1.1 mrg if (count_buf.reported_underflow) 1051 1.1 mrg return 0; 1052 1.1 mrg ++num_abbrevs; 1053 1.1 mrg // Skip tag. 1054 1.1 mrg read_uleb128 (&count_buf); 1055 1.1 mrg // Skip has_children. 1056 1.1 mrg read_byte (&count_buf); 1057 1.1 mrg // Skip attributes. 1058 1.1 mrg while (read_uleb128 (&count_buf) != 0) 1059 1.1 mrg read_uleb128 (&count_buf); 1060 1.1 mrg // Skip form of last attribute. 1061 1.1 mrg read_uleb128 (&count_buf); 1062 1.1 mrg } 1063 1.1 mrg 1064 1.1 mrg if (count_buf.reported_underflow) 1065 1.1 mrg return 0; 1066 1.1 mrg 1067 1.1 mrg if (num_abbrevs == 0) 1068 1.1 mrg return 1; 1069 1.1 mrg 1070 1.1 mrg abbrevs->num_abbrevs = num_abbrevs; 1071 1.1 mrg abbrevs->abbrevs = ((struct abbrev *) 1072 1.1 mrg backtrace_alloc (state, 1073 1.1 mrg num_abbrevs * sizeof (struct abbrev), 1074 1.1 mrg error_callback, data)); 1075 1.1 mrg if (abbrevs->abbrevs == NULL) 1076 1.1 mrg return 0; 1077 1.1 mrg memset (abbrevs->abbrevs, 0, num_abbrevs * sizeof (struct abbrev)); 1078 1.1 mrg 1079 1.1 mrg num_abbrevs = 0; 1080 1.1 mrg while (1) 1081 1.1 mrg { 1082 1.1 mrg uint64_t code; 1083 1.1 mrg struct abbrev a; 1084 1.1 mrg size_t num_attrs; 1085 1.1 mrg struct attr *attrs; 1086 1.1 mrg 1087 1.1 mrg if (abbrev_buf.reported_underflow) 1088 1.1 mrg goto fail; 1089 1.1 mrg 1090 1.1 mrg code = read_uleb128 (&abbrev_buf); 1091 1.1 mrg if (code == 0) 1092 1.1 mrg break; 1093 1.1 mrg 1094 1.1 mrg a.code = code; 1095 1.1 mrg a.tag = (enum dwarf_tag) read_uleb128 (&abbrev_buf); 1096 1.1 mrg a.has_children = read_byte (&abbrev_buf); 1097 1.1 mrg 1098 1.1 mrg count_buf = abbrev_buf; 1099 1.1 mrg num_attrs = 0; 1100 1.1 mrg while (read_uleb128 (&count_buf) != 0) 1101 1.1 mrg { 1102 1.1 mrg ++num_attrs; 1103 1.1 mrg read_uleb128 (&count_buf); 1104 1.1 mrg } 1105 1.1 mrg 1106 1.1 mrg if (num_attrs == 0) 1107 1.1 mrg { 1108 1.1 mrg attrs = NULL; 1109 1.1 mrg read_uleb128 (&abbrev_buf); 1110 1.1 mrg read_uleb128 (&abbrev_buf); 1111 1.1 mrg } 1112 1.1 mrg else 1113 1.1 mrg { 1114 1.1 mrg attrs = ((struct attr *) 1115 1.1 mrg backtrace_alloc (state, num_attrs * sizeof *attrs, 1116 1.1 mrg error_callback, data)); 1117 1.1 mrg if (attrs == NULL) 1118 1.1 mrg goto fail; 1119 1.1 mrg num_attrs = 0; 1120 1.1 mrg while (1) 1121 1.1 mrg { 1122 1.1 mrg uint64_t name; 1123 1.1 mrg uint64_t form; 1124 1.1 mrg 1125 1.1 mrg name = read_uleb128 (&abbrev_buf); 1126 1.1 mrg form = read_uleb128 (&abbrev_buf); 1127 1.1 mrg if (name == 0) 1128 1.1 mrg break; 1129 1.1 mrg attrs[num_attrs].name = (enum dwarf_attribute) name; 1130 1.1 mrg attrs[num_attrs].form = (enum dwarf_form) form; 1131 1.1 mrg ++num_attrs; 1132 1.1 mrg } 1133 1.1 mrg } 1134 1.1 mrg 1135 1.1 mrg a.num_attrs = num_attrs; 1136 1.1 mrg a.attrs = attrs; 1137 1.1 mrg 1138 1.1 mrg abbrevs->abbrevs[num_abbrevs] = a; 1139 1.1 mrg ++num_abbrevs; 1140 1.1 mrg } 1141 1.1 mrg 1142 1.1.1.2 mrg backtrace_qsort (abbrevs->abbrevs, abbrevs->num_abbrevs, 1143 1.1.1.2 mrg sizeof (struct abbrev), abbrev_compare); 1144 1.1 mrg 1145 1.1 mrg return 1; 1146 1.1 mrg 1147 1.1 mrg fail: 1148 1.1 mrg free_abbrevs (state, abbrevs, error_callback, data); 1149 1.1 mrg return 0; 1150 1.1 mrg } 1151 1.1 mrg 1152 1.1 mrg /* Return the abbrev information for an abbrev code. */ 1153 1.1 mrg 1154 1.1 mrg static const struct abbrev * 1155 1.1 mrg lookup_abbrev (struct abbrevs *abbrevs, uint64_t code, 1156 1.1 mrg backtrace_error_callback error_callback, void *data) 1157 1.1 mrg { 1158 1.1 mrg struct abbrev key; 1159 1.1 mrg void *p; 1160 1.1 mrg 1161 1.1 mrg /* With GCC, where abbrevs are simply numbered in order, we should 1162 1.1 mrg be able to just look up the entry. */ 1163 1.1 mrg if (code - 1 < abbrevs->num_abbrevs 1164 1.1 mrg && abbrevs->abbrevs[code - 1].code == code) 1165 1.1 mrg return &abbrevs->abbrevs[code - 1]; 1166 1.1 mrg 1167 1.1 mrg /* Otherwise we have to search. */ 1168 1.1 mrg memset (&key, 0, sizeof key); 1169 1.1 mrg key.code = code; 1170 1.1 mrg p = bsearch (&key, abbrevs->abbrevs, abbrevs->num_abbrevs, 1171 1.1 mrg sizeof (struct abbrev), abbrev_compare); 1172 1.1 mrg if (p == NULL) 1173 1.1 mrg { 1174 1.1 mrg error_callback (data, "invalid abbreviation code", 0); 1175 1.1 mrg return NULL; 1176 1.1 mrg } 1177 1.1 mrg return (const struct abbrev *) p; 1178 1.1 mrg } 1179 1.1 mrg 1180 1.1 mrg /* Add non-contiguous address ranges for a compilation unit. Returns 1181 1.1 mrg 1 on success, 0 on failure. */ 1182 1.1 mrg 1183 1.1 mrg static int 1184 1.1 mrg add_unit_ranges (struct backtrace_state *state, uintptr_t base_address, 1185 1.1 mrg struct unit *u, uint64_t ranges, uint64_t base, 1186 1.1 mrg int is_bigendian, const unsigned char *dwarf_ranges, 1187 1.1 mrg size_t dwarf_ranges_size, 1188 1.1 mrg backtrace_error_callback error_callback, void *data, 1189 1.1 mrg struct unit_addrs_vector *addrs) 1190 1.1 mrg { 1191 1.1 mrg struct dwarf_buf ranges_buf; 1192 1.1 mrg 1193 1.1 mrg if (ranges >= dwarf_ranges_size) 1194 1.1 mrg { 1195 1.1 mrg error_callback (data, "ranges offset out of range", 0); 1196 1.1 mrg return 0; 1197 1.1 mrg } 1198 1.1 mrg 1199 1.1 mrg ranges_buf.name = ".debug_ranges"; 1200 1.1 mrg ranges_buf.start = dwarf_ranges; 1201 1.1 mrg ranges_buf.buf = dwarf_ranges + ranges; 1202 1.1 mrg ranges_buf.left = dwarf_ranges_size - ranges; 1203 1.1 mrg ranges_buf.is_bigendian = is_bigendian; 1204 1.1 mrg ranges_buf.error_callback = error_callback; 1205 1.1 mrg ranges_buf.data = data; 1206 1.1 mrg ranges_buf.reported_underflow = 0; 1207 1.1 mrg 1208 1.1 mrg while (1) 1209 1.1 mrg { 1210 1.1 mrg uint64_t low; 1211 1.1 mrg uint64_t high; 1212 1.1 mrg 1213 1.1 mrg if (ranges_buf.reported_underflow) 1214 1.1 mrg return 0; 1215 1.1 mrg 1216 1.1 mrg low = read_address (&ranges_buf, u->addrsize); 1217 1.1 mrg high = read_address (&ranges_buf, u->addrsize); 1218 1.1 mrg 1219 1.1 mrg if (low == 0 && high == 0) 1220 1.1 mrg break; 1221 1.1 mrg 1222 1.1 mrg if (is_highest_address (low, u->addrsize)) 1223 1.1 mrg base = high; 1224 1.1 mrg else 1225 1.1 mrg { 1226 1.1 mrg struct unit_addrs a; 1227 1.1 mrg 1228 1.1 mrg a.low = low + base; 1229 1.1 mrg a.high = high + base; 1230 1.1 mrg a.u = u; 1231 1.1 mrg if (!add_unit_addr (state, base_address, a, error_callback, data, 1232 1.1 mrg addrs)) 1233 1.1 mrg return 0; 1234 1.1 mrg } 1235 1.1 mrg } 1236 1.1 mrg 1237 1.1 mrg if (ranges_buf.reported_underflow) 1238 1.1 mrg return 0; 1239 1.1 mrg 1240 1.1 mrg return 1; 1241 1.1 mrg } 1242 1.1 mrg 1243 1.1.1.2 mrg /* Find the address range covered by a compilation unit, reading from 1244 1.1.1.2 mrg UNIT_BUF and adding values to U. Returns 1 if all data could be 1245 1.1.1.2 mrg read, 0 if there is some error. */ 1246 1.1 mrg 1247 1.1 mrg static int 1248 1.1.1.2 mrg find_address_ranges (struct backtrace_state *state, uintptr_t base_address, 1249 1.1.1.2 mrg struct dwarf_buf *unit_buf, 1250 1.1.1.2 mrg const unsigned char *dwarf_str, size_t dwarf_str_size, 1251 1.1.1.2 mrg const unsigned char *dwarf_ranges, 1252 1.1.1.2 mrg size_t dwarf_ranges_size, 1253 1.1.1.2 mrg int is_bigendian, backtrace_error_callback error_callback, 1254 1.1.1.2 mrg void *data, struct unit *u, 1255 1.1.1.2 mrg struct unit_addrs_vector *addrs) 1256 1.1 mrg { 1257 1.1.1.2 mrg while (unit_buf->left > 0) 1258 1.1 mrg { 1259 1.1 mrg uint64_t code; 1260 1.1.1.2 mrg const struct abbrev *abbrev; 1261 1.1 mrg uint64_t lowpc; 1262 1.1 mrg int have_lowpc; 1263 1.1 mrg uint64_t highpc; 1264 1.1 mrg int have_highpc; 1265 1.1 mrg int highpc_is_relative; 1266 1.1 mrg uint64_t ranges; 1267 1.1 mrg int have_ranges; 1268 1.1.1.2 mrg size_t i; 1269 1.1 mrg 1270 1.1.1.2 mrg code = read_uleb128 (unit_buf); 1271 1.1.1.2 mrg if (code == 0) 1272 1.1.1.2 mrg return 1; 1273 1.1 mrg 1274 1.1.1.2 mrg abbrev = lookup_abbrev (&u->abbrevs, code, error_callback, data); 1275 1.1 mrg if (abbrev == NULL) 1276 1.1.1.2 mrg return 0; 1277 1.1 mrg 1278 1.1 mrg lowpc = 0; 1279 1.1 mrg have_lowpc = 0; 1280 1.1 mrg highpc = 0; 1281 1.1 mrg have_highpc = 0; 1282 1.1 mrg highpc_is_relative = 0; 1283 1.1 mrg ranges = 0; 1284 1.1 mrg have_ranges = 0; 1285 1.1 mrg for (i = 0; i < abbrev->num_attrs; ++i) 1286 1.1 mrg { 1287 1.1 mrg struct attr_val val; 1288 1.1 mrg 1289 1.1.1.2 mrg if (!read_attribute (abbrev->attrs[i].form, unit_buf, 1290 1.1.1.2 mrg u->is_dwarf64, u->version, u->addrsize, 1291 1.1.1.2 mrg dwarf_str, dwarf_str_size, &val)) 1292 1.1.1.2 mrg return 0; 1293 1.1 mrg 1294 1.1 mrg switch (abbrev->attrs[i].name) 1295 1.1 mrg { 1296 1.1 mrg case DW_AT_low_pc: 1297 1.1 mrg if (val.encoding == ATTR_VAL_ADDRESS) 1298 1.1 mrg { 1299 1.1 mrg lowpc = val.u.uint; 1300 1.1 mrg have_lowpc = 1; 1301 1.1 mrg } 1302 1.1 mrg break; 1303 1.1.1.2 mrg 1304 1.1 mrg case DW_AT_high_pc: 1305 1.1 mrg if (val.encoding == ATTR_VAL_ADDRESS) 1306 1.1 mrg { 1307 1.1 mrg highpc = val.u.uint; 1308 1.1 mrg have_highpc = 1; 1309 1.1 mrg } 1310 1.1 mrg else if (val.encoding == ATTR_VAL_UINT) 1311 1.1 mrg { 1312 1.1 mrg highpc = val.u.uint; 1313 1.1 mrg have_highpc = 1; 1314 1.1 mrg highpc_is_relative = 1; 1315 1.1 mrg } 1316 1.1 mrg break; 1317 1.1.1.2 mrg 1318 1.1 mrg case DW_AT_ranges: 1319 1.1 mrg if (val.encoding == ATTR_VAL_UINT 1320 1.1 mrg || val.encoding == ATTR_VAL_REF_SECTION) 1321 1.1 mrg { 1322 1.1 mrg ranges = val.u.uint; 1323 1.1 mrg have_ranges = 1; 1324 1.1 mrg } 1325 1.1 mrg break; 1326 1.1.1.2 mrg 1327 1.1 mrg case DW_AT_stmt_list: 1328 1.1.1.2 mrg if (abbrev->tag == DW_TAG_compile_unit 1329 1.1.1.2 mrg && (val.encoding == ATTR_VAL_UINT 1330 1.1.1.2 mrg || val.encoding == ATTR_VAL_REF_SECTION)) 1331 1.1.1.2 mrg u->lineoff = val.u.uint; 1332 1.1 mrg break; 1333 1.1.1.2 mrg 1334 1.1 mrg case DW_AT_name: 1335 1.1.1.2 mrg if (abbrev->tag == DW_TAG_compile_unit 1336 1.1.1.2 mrg && val.encoding == ATTR_VAL_STRING) 1337 1.1.1.2 mrg u->filename = val.u.string; 1338 1.1 mrg break; 1339 1.1.1.2 mrg 1340 1.1 mrg case DW_AT_comp_dir: 1341 1.1.1.2 mrg if (abbrev->tag == DW_TAG_compile_unit 1342 1.1.1.2 mrg && val.encoding == ATTR_VAL_STRING) 1343 1.1.1.2 mrg u->comp_dir = val.u.string; 1344 1.1 mrg break; 1345 1.1.1.2 mrg 1346 1.1 mrg default: 1347 1.1 mrg break; 1348 1.1 mrg } 1349 1.1 mrg } 1350 1.1 mrg 1351 1.1.1.2 mrg if (abbrev->tag == DW_TAG_compile_unit 1352 1.1.1.2 mrg || abbrev->tag == DW_TAG_subprogram) 1353 1.1 mrg { 1354 1.1 mrg if (have_ranges) 1355 1.1 mrg { 1356 1.1 mrg if (!add_unit_ranges (state, base_address, u, ranges, lowpc, 1357 1.1 mrg is_bigendian, dwarf_ranges, 1358 1.1.1.2 mrg dwarf_ranges_size, error_callback, 1359 1.1.1.2 mrg data, addrs)) 1360 1.1.1.2 mrg return 0; 1361 1.1 mrg } 1362 1.1.1.2 mrg else if (have_lowpc && have_highpc) 1363 1.1 mrg { 1364 1.1.1.2 mrg struct unit_addrs a; 1365 1.1.1.2 mrg 1366 1.1 mrg if (highpc_is_relative) 1367 1.1 mrg highpc += lowpc; 1368 1.1 mrg a.low = lowpc; 1369 1.1 mrg a.high = highpc; 1370 1.1 mrg a.u = u; 1371 1.1 mrg 1372 1.1 mrg if (!add_unit_addr (state, base_address, a, error_callback, data, 1373 1.1 mrg addrs)) 1374 1.1.1.2 mrg return 0; 1375 1.1 mrg } 1376 1.1.1.2 mrg 1377 1.1.1.2 mrg /* If we found the PC range in the DW_TAG_compile_unit, we 1378 1.1.1.2 mrg can stop now. */ 1379 1.1.1.2 mrg if (abbrev->tag == DW_TAG_compile_unit 1380 1.1.1.2 mrg && (have_ranges || (have_lowpc && have_highpc))) 1381 1.1.1.2 mrg return 1; 1382 1.1 mrg } 1383 1.1.1.2 mrg 1384 1.1.1.2 mrg if (abbrev->has_children) 1385 1.1 mrg { 1386 1.1.1.2 mrg if (!find_address_ranges (state, base_address, unit_buf, 1387 1.1.1.2 mrg dwarf_str, dwarf_str_size, 1388 1.1.1.2 mrg dwarf_ranges, dwarf_ranges_size, 1389 1.1.1.2 mrg is_bigendian, error_callback, data, 1390 1.1.1.2 mrg u, addrs)) 1391 1.1.1.2 mrg return 0; 1392 1.1.1.2 mrg } 1393 1.1.1.2 mrg } 1394 1.1.1.2 mrg 1395 1.1.1.2 mrg return 1; 1396 1.1.1.2 mrg } 1397 1.1.1.2 mrg 1398 1.1.1.2 mrg /* Build a mapping from address ranges to the compilation units where 1399 1.1.1.2 mrg the line number information for that range can be found. Returns 1 1400 1.1.1.2 mrg on success, 0 on failure. */ 1401 1.1.1.2 mrg 1402 1.1.1.2 mrg static int 1403 1.1.1.2 mrg build_address_map (struct backtrace_state *state, uintptr_t base_address, 1404 1.1.1.2 mrg const unsigned char *dwarf_info, size_t dwarf_info_size, 1405 1.1.1.2 mrg const unsigned char *dwarf_abbrev, size_t dwarf_abbrev_size, 1406 1.1.1.2 mrg const unsigned char *dwarf_ranges, size_t dwarf_ranges_size, 1407 1.1.1.2 mrg const unsigned char *dwarf_str, size_t dwarf_str_size, 1408 1.1.1.2 mrg int is_bigendian, backtrace_error_callback error_callback, 1409 1.1.1.2 mrg void *data, struct unit_addrs_vector *addrs) 1410 1.1.1.2 mrg { 1411 1.1.1.2 mrg struct dwarf_buf info; 1412 1.1.1.2 mrg struct abbrevs abbrevs; 1413 1.1.1.2 mrg 1414 1.1.1.2 mrg memset (&addrs->vec, 0, sizeof addrs->vec); 1415 1.1.1.2 mrg addrs->count = 0; 1416 1.1.1.2 mrg 1417 1.1.1.2 mrg /* Read through the .debug_info section. FIXME: Should we use the 1418 1.1.1.2 mrg .debug_aranges section? gdb and addr2line don't use it, but I'm 1419 1.1.1.2 mrg not sure why. */ 1420 1.1.1.2 mrg 1421 1.1.1.2 mrg info.name = ".debug_info"; 1422 1.1.1.2 mrg info.start = dwarf_info; 1423 1.1.1.2 mrg info.buf = dwarf_info; 1424 1.1.1.2 mrg info.left = dwarf_info_size; 1425 1.1.1.2 mrg info.is_bigendian = is_bigendian; 1426 1.1.1.2 mrg info.error_callback = error_callback; 1427 1.1.1.2 mrg info.data = data; 1428 1.1.1.2 mrg info.reported_underflow = 0; 1429 1.1.1.2 mrg 1430 1.1.1.2 mrg memset (&abbrevs, 0, sizeof abbrevs); 1431 1.1.1.2 mrg while (info.left > 0) 1432 1.1.1.2 mrg { 1433 1.1.1.2 mrg const unsigned char *unit_data_start; 1434 1.1.1.2 mrg uint64_t len; 1435 1.1.1.2 mrg int is_dwarf64; 1436 1.1.1.2 mrg struct dwarf_buf unit_buf; 1437 1.1.1.2 mrg int version; 1438 1.1.1.2 mrg uint64_t abbrev_offset; 1439 1.1.1.2 mrg int addrsize; 1440 1.1.1.2 mrg struct unit *u; 1441 1.1.1.2 mrg 1442 1.1.1.2 mrg if (info.reported_underflow) 1443 1.1.1.2 mrg goto fail; 1444 1.1.1.2 mrg 1445 1.1.1.2 mrg unit_data_start = info.buf; 1446 1.1.1.2 mrg 1447 1.1.1.2 mrg is_dwarf64 = 0; 1448 1.1.1.2 mrg len = read_uint32 (&info); 1449 1.1.1.2 mrg if (len == 0xffffffff) 1450 1.1.1.2 mrg { 1451 1.1.1.2 mrg len = read_uint64 (&info); 1452 1.1.1.2 mrg is_dwarf64 = 1; 1453 1.1.1.2 mrg } 1454 1.1.1.2 mrg 1455 1.1.1.2 mrg unit_buf = info; 1456 1.1.1.2 mrg unit_buf.left = len; 1457 1.1.1.2 mrg 1458 1.1.1.2 mrg if (!advance (&info, len)) 1459 1.1.1.2 mrg goto fail; 1460 1.1.1.2 mrg 1461 1.1.1.2 mrg version = read_uint16 (&unit_buf); 1462 1.1.1.2 mrg if (version < 2 || version > 4) 1463 1.1.1.2 mrg { 1464 1.1.1.2 mrg dwarf_buf_error (&unit_buf, "unrecognized DWARF version"); 1465 1.1.1.2 mrg goto fail; 1466 1.1.1.2 mrg } 1467 1.1.1.2 mrg 1468 1.1.1.2 mrg abbrev_offset = read_offset (&unit_buf, is_dwarf64); 1469 1.1.1.2 mrg if (!read_abbrevs (state, abbrev_offset, dwarf_abbrev, dwarf_abbrev_size, 1470 1.1.1.2 mrg is_bigendian, error_callback, data, &abbrevs)) 1471 1.1.1.2 mrg goto fail; 1472 1.1.1.2 mrg 1473 1.1.1.2 mrg addrsize = read_byte (&unit_buf); 1474 1.1.1.2 mrg 1475 1.1.1.2 mrg u = ((struct unit *) 1476 1.1.1.2 mrg backtrace_alloc (state, sizeof *u, error_callback, data)); 1477 1.1.1.2 mrg if (u == NULL) 1478 1.1.1.2 mrg goto fail; 1479 1.1.1.2 mrg u->unit_data = unit_buf.buf; 1480 1.1.1.2 mrg u->unit_data_len = unit_buf.left; 1481 1.1.1.2 mrg u->unit_data_offset = unit_buf.buf - unit_data_start; 1482 1.1.1.2 mrg u->version = version; 1483 1.1.1.2 mrg u->is_dwarf64 = is_dwarf64; 1484 1.1.1.2 mrg u->addrsize = addrsize; 1485 1.1.1.2 mrg u->filename = NULL; 1486 1.1.1.2 mrg u->comp_dir = NULL; 1487 1.1.1.2 mrg u->abs_filename = NULL; 1488 1.1.1.2 mrg u->lineoff = 0; 1489 1.1.1.2 mrg u->abbrevs = abbrevs; 1490 1.1.1.2 mrg memset (&abbrevs, 0, sizeof abbrevs); 1491 1.1.1.2 mrg 1492 1.1.1.2 mrg /* The actual line number mappings will be read as needed. */ 1493 1.1.1.2 mrg u->lines = NULL; 1494 1.1.1.2 mrg u->lines_count = 0; 1495 1.1.1.2 mrg u->function_addrs = NULL; 1496 1.1.1.2 mrg u->function_addrs_count = 0; 1497 1.1.1.2 mrg 1498 1.1.1.2 mrg if (!find_address_ranges (state, base_address, &unit_buf, 1499 1.1.1.2 mrg dwarf_str, dwarf_str_size, 1500 1.1.1.2 mrg dwarf_ranges, dwarf_ranges_size, 1501 1.1.1.2 mrg is_bigendian, error_callback, data, 1502 1.1.1.2 mrg u, addrs)) 1503 1.1.1.2 mrg { 1504 1.1.1.2 mrg free_abbrevs (state, &u->abbrevs, error_callback, data); 1505 1.1.1.2 mrg backtrace_free (state, u, sizeof *u, error_callback, data); 1506 1.1.1.2 mrg goto fail; 1507 1.1.1.2 mrg } 1508 1.1.1.2 mrg 1509 1.1.1.2 mrg if (unit_buf.reported_underflow) 1510 1.1.1.2 mrg { 1511 1.1.1.2 mrg free_abbrevs (state, &u->abbrevs, error_callback, data); 1512 1.1.1.2 mrg backtrace_free (state, u, sizeof *u, error_callback, data); 1513 1.1.1.2 mrg goto fail; 1514 1.1 mrg } 1515 1.1 mrg } 1516 1.1 mrg if (info.reported_underflow) 1517 1.1 mrg goto fail; 1518 1.1 mrg 1519 1.1 mrg return 1; 1520 1.1 mrg 1521 1.1 mrg fail: 1522 1.1 mrg free_abbrevs (state, &abbrevs, error_callback, data); 1523 1.1 mrg free_unit_addrs_vector (state, addrs, error_callback, data); 1524 1.1 mrg return 0; 1525 1.1 mrg } 1526 1.1 mrg 1527 1.1 mrg /* Add a new mapping to the vector of line mappings that we are 1528 1.1 mrg building. Returns 1 on success, 0 on failure. */ 1529 1.1 mrg 1530 1.1 mrg static int 1531 1.1 mrg add_line (struct backtrace_state *state, struct dwarf_data *ddata, 1532 1.1 mrg uintptr_t pc, const char *filename, int lineno, 1533 1.1 mrg backtrace_error_callback error_callback, void *data, 1534 1.1 mrg struct line_vector *vec) 1535 1.1 mrg { 1536 1.1 mrg struct line *ln; 1537 1.1 mrg 1538 1.1 mrg /* If we are adding the same mapping, ignore it. This can happen 1539 1.1 mrg when using discriminators. */ 1540 1.1 mrg if (vec->count > 0) 1541 1.1 mrg { 1542 1.1 mrg ln = (struct line *) vec->vec.base + (vec->count - 1); 1543 1.1 mrg if (pc == ln->pc && filename == ln->filename && lineno == ln->lineno) 1544 1.1 mrg return 1; 1545 1.1 mrg } 1546 1.1 mrg 1547 1.1 mrg ln = ((struct line *) 1548 1.1 mrg backtrace_vector_grow (state, sizeof (struct line), error_callback, 1549 1.1 mrg data, &vec->vec)); 1550 1.1 mrg if (ln == NULL) 1551 1.1 mrg return 0; 1552 1.1 mrg 1553 1.1 mrg /* Add in the base address here, so that we can look up the PC 1554 1.1 mrg directly. */ 1555 1.1 mrg ln->pc = pc + ddata->base_address; 1556 1.1 mrg 1557 1.1 mrg ln->filename = filename; 1558 1.1 mrg ln->lineno = lineno; 1559 1.1.1.3 mrg ln->idx = vec->count; 1560 1.1 mrg 1561 1.1 mrg ++vec->count; 1562 1.1 mrg 1563 1.1 mrg return 1; 1564 1.1 mrg } 1565 1.1 mrg 1566 1.1 mrg /* Free the line header information. If FREE_FILENAMES is true we 1567 1.1 mrg free the file names themselves, otherwise we leave them, as there 1568 1.1 mrg may be line structures pointing to them. */ 1569 1.1 mrg 1570 1.1 mrg static void 1571 1.1 mrg free_line_header (struct backtrace_state *state, struct line_header *hdr, 1572 1.1 mrg backtrace_error_callback error_callback, void *data) 1573 1.1 mrg { 1574 1.1 mrg backtrace_free (state, hdr->dirs, hdr->dirs_count * sizeof (const char *), 1575 1.1 mrg error_callback, data); 1576 1.1 mrg backtrace_free (state, hdr->filenames, 1577 1.1 mrg hdr->filenames_count * sizeof (char *), 1578 1.1 mrg error_callback, data); 1579 1.1 mrg } 1580 1.1 mrg 1581 1.1 mrg /* Read the line header. Return 1 on success, 0 on failure. */ 1582 1.1 mrg 1583 1.1 mrg static int 1584 1.1 mrg read_line_header (struct backtrace_state *state, struct unit *u, 1585 1.1 mrg int is_dwarf64, struct dwarf_buf *line_buf, 1586 1.1 mrg struct line_header *hdr) 1587 1.1 mrg { 1588 1.1 mrg uint64_t hdrlen; 1589 1.1 mrg struct dwarf_buf hdr_buf; 1590 1.1 mrg const unsigned char *p; 1591 1.1 mrg const unsigned char *pend; 1592 1.1 mrg size_t i; 1593 1.1 mrg 1594 1.1 mrg hdr->version = read_uint16 (line_buf); 1595 1.1 mrg if (hdr->version < 2 || hdr->version > 4) 1596 1.1 mrg { 1597 1.1 mrg dwarf_buf_error (line_buf, "unsupported line number version"); 1598 1.1 mrg return 0; 1599 1.1 mrg } 1600 1.1 mrg 1601 1.1 mrg hdrlen = read_offset (line_buf, is_dwarf64); 1602 1.1 mrg 1603 1.1 mrg hdr_buf = *line_buf; 1604 1.1 mrg hdr_buf.left = hdrlen; 1605 1.1 mrg 1606 1.1 mrg if (!advance (line_buf, hdrlen)) 1607 1.1 mrg return 0; 1608 1.1 mrg 1609 1.1 mrg hdr->min_insn_len = read_byte (&hdr_buf); 1610 1.1 mrg if (hdr->version < 4) 1611 1.1 mrg hdr->max_ops_per_insn = 1; 1612 1.1 mrg else 1613 1.1 mrg hdr->max_ops_per_insn = read_byte (&hdr_buf); 1614 1.1 mrg 1615 1.1 mrg /* We don't care about default_is_stmt. */ 1616 1.1 mrg read_byte (&hdr_buf); 1617 1.1 mrg 1618 1.1 mrg hdr->line_base = read_sbyte (&hdr_buf); 1619 1.1 mrg hdr->line_range = read_byte (&hdr_buf); 1620 1.1 mrg 1621 1.1 mrg hdr->opcode_base = read_byte (&hdr_buf); 1622 1.1 mrg hdr->opcode_lengths = hdr_buf.buf; 1623 1.1 mrg if (!advance (&hdr_buf, hdr->opcode_base - 1)) 1624 1.1 mrg return 0; 1625 1.1 mrg 1626 1.1 mrg /* Count the number of directory entries. */ 1627 1.1 mrg hdr->dirs_count = 0; 1628 1.1 mrg p = hdr_buf.buf; 1629 1.1 mrg pend = p + hdr_buf.left; 1630 1.1 mrg while (p < pend && *p != '\0') 1631 1.1 mrg { 1632 1.1 mrg p += strnlen((const char *) p, pend - p) + 1; 1633 1.1 mrg ++hdr->dirs_count; 1634 1.1 mrg } 1635 1.1 mrg 1636 1.1 mrg hdr->dirs = ((const char **) 1637 1.1 mrg backtrace_alloc (state, 1638 1.1 mrg hdr->dirs_count * sizeof (const char *), 1639 1.1 mrg line_buf->error_callback, line_buf->data)); 1640 1.1 mrg if (hdr->dirs == NULL) 1641 1.1 mrg return 0; 1642 1.1 mrg 1643 1.1 mrg i = 0; 1644 1.1 mrg while (*hdr_buf.buf != '\0') 1645 1.1 mrg { 1646 1.1 mrg if (hdr_buf.reported_underflow) 1647 1.1 mrg return 0; 1648 1.1 mrg 1649 1.1 mrg hdr->dirs[i] = (const char *) hdr_buf.buf; 1650 1.1 mrg ++i; 1651 1.1 mrg if (!advance (&hdr_buf, 1652 1.1 mrg strnlen ((const char *) hdr_buf.buf, hdr_buf.left) + 1)) 1653 1.1 mrg return 0; 1654 1.1 mrg } 1655 1.1 mrg if (!advance (&hdr_buf, 1)) 1656 1.1 mrg return 0; 1657 1.1 mrg 1658 1.1 mrg /* Count the number of file entries. */ 1659 1.1 mrg hdr->filenames_count = 0; 1660 1.1 mrg p = hdr_buf.buf; 1661 1.1 mrg pend = p + hdr_buf.left; 1662 1.1 mrg while (p < pend && *p != '\0') 1663 1.1 mrg { 1664 1.1 mrg p += strnlen ((const char *) p, pend - p) + 1; 1665 1.1 mrg p += leb128_len (p); 1666 1.1 mrg p += leb128_len (p); 1667 1.1 mrg p += leb128_len (p); 1668 1.1 mrg ++hdr->filenames_count; 1669 1.1 mrg } 1670 1.1 mrg 1671 1.1 mrg hdr->filenames = ((const char **) 1672 1.1 mrg backtrace_alloc (state, 1673 1.1 mrg hdr->filenames_count * sizeof (char *), 1674 1.1 mrg line_buf->error_callback, 1675 1.1 mrg line_buf->data)); 1676 1.1 mrg if (hdr->filenames == NULL) 1677 1.1 mrg return 0; 1678 1.1 mrg i = 0; 1679 1.1 mrg while (*hdr_buf.buf != '\0') 1680 1.1 mrg { 1681 1.1 mrg const char *filename; 1682 1.1 mrg uint64_t dir_index; 1683 1.1 mrg 1684 1.1 mrg if (hdr_buf.reported_underflow) 1685 1.1 mrg return 0; 1686 1.1 mrg 1687 1.1 mrg filename = (const char *) hdr_buf.buf; 1688 1.1 mrg if (!advance (&hdr_buf, 1689 1.1 mrg strnlen ((const char *) hdr_buf.buf, hdr_buf.left) + 1)) 1690 1.1 mrg return 0; 1691 1.1 mrg dir_index = read_uleb128 (&hdr_buf); 1692 1.1 mrg if (IS_ABSOLUTE_PATH (filename) 1693 1.1 mrg || (dir_index == 0 && u->comp_dir == NULL)) 1694 1.1 mrg hdr->filenames[i] = filename; 1695 1.1 mrg else 1696 1.1 mrg { 1697 1.1 mrg const char *dir; 1698 1.1 mrg size_t dir_len; 1699 1.1 mrg size_t filename_len; 1700 1.1 mrg char *s; 1701 1.1 mrg 1702 1.1 mrg if (dir_index == 0) 1703 1.1 mrg dir = u->comp_dir; 1704 1.1 mrg else if (dir_index - 1 < hdr->dirs_count) 1705 1.1 mrg dir = hdr->dirs[dir_index - 1]; 1706 1.1 mrg else 1707 1.1 mrg { 1708 1.1 mrg dwarf_buf_error (line_buf, 1709 1.1 mrg ("invalid directory index in " 1710 1.1 mrg "line number program header")); 1711 1.1 mrg return 0; 1712 1.1 mrg } 1713 1.1 mrg dir_len = strlen (dir); 1714 1.1 mrg filename_len = strlen (filename); 1715 1.1 mrg s = ((char *) 1716 1.1 mrg backtrace_alloc (state, dir_len + filename_len + 2, 1717 1.1 mrg line_buf->error_callback, line_buf->data)); 1718 1.1 mrg if (s == NULL) 1719 1.1 mrg return 0; 1720 1.1 mrg memcpy (s, dir, dir_len); 1721 1.1 mrg /* FIXME: If we are on a DOS-based file system, and the 1722 1.1 mrg directory or the file name use backslashes, then we 1723 1.1 mrg should use a backslash here. */ 1724 1.1 mrg s[dir_len] = '/'; 1725 1.1 mrg memcpy (s + dir_len + 1, filename, filename_len + 1); 1726 1.1 mrg hdr->filenames[i] = s; 1727 1.1 mrg } 1728 1.1 mrg 1729 1.1 mrg /* Ignore the modification time and size. */ 1730 1.1 mrg read_uleb128 (&hdr_buf); 1731 1.1 mrg read_uleb128 (&hdr_buf); 1732 1.1 mrg 1733 1.1 mrg ++i; 1734 1.1 mrg } 1735 1.1 mrg 1736 1.1 mrg if (hdr_buf.reported_underflow) 1737 1.1 mrg return 0; 1738 1.1 mrg 1739 1.1 mrg return 1; 1740 1.1 mrg } 1741 1.1 mrg 1742 1.1 mrg /* Read the line program, adding line mappings to VEC. Return 1 on 1743 1.1 mrg success, 0 on failure. */ 1744 1.1 mrg 1745 1.1 mrg static int 1746 1.1 mrg read_line_program (struct backtrace_state *state, struct dwarf_data *ddata, 1747 1.1 mrg struct unit *u, const struct line_header *hdr, 1748 1.1 mrg struct dwarf_buf *line_buf, struct line_vector *vec) 1749 1.1 mrg { 1750 1.1 mrg uint64_t address; 1751 1.1 mrg unsigned int op_index; 1752 1.1 mrg const char *reset_filename; 1753 1.1 mrg const char *filename; 1754 1.1 mrg int lineno; 1755 1.1 mrg 1756 1.1 mrg address = 0; 1757 1.1 mrg op_index = 0; 1758 1.1 mrg if (hdr->filenames_count > 0) 1759 1.1 mrg reset_filename = hdr->filenames[0]; 1760 1.1 mrg else 1761 1.1 mrg reset_filename = ""; 1762 1.1 mrg filename = reset_filename; 1763 1.1 mrg lineno = 1; 1764 1.1 mrg while (line_buf->left > 0) 1765 1.1 mrg { 1766 1.1 mrg unsigned int op; 1767 1.1 mrg 1768 1.1 mrg op = read_byte (line_buf); 1769 1.1 mrg if (op >= hdr->opcode_base) 1770 1.1 mrg { 1771 1.1 mrg unsigned int advance; 1772 1.1 mrg 1773 1.1 mrg /* Special opcode. */ 1774 1.1 mrg op -= hdr->opcode_base; 1775 1.1 mrg advance = op / hdr->line_range; 1776 1.1 mrg address += (hdr->min_insn_len * (op_index + advance) 1777 1.1 mrg / hdr->max_ops_per_insn); 1778 1.1 mrg op_index = (op_index + advance) % hdr->max_ops_per_insn; 1779 1.1 mrg lineno += hdr->line_base + (int) (op % hdr->line_range); 1780 1.1 mrg add_line (state, ddata, address, filename, lineno, 1781 1.1 mrg line_buf->error_callback, line_buf->data, vec); 1782 1.1 mrg } 1783 1.1 mrg else if (op == DW_LNS_extended_op) 1784 1.1 mrg { 1785 1.1 mrg uint64_t len; 1786 1.1 mrg 1787 1.1 mrg len = read_uleb128 (line_buf); 1788 1.1 mrg op = read_byte (line_buf); 1789 1.1 mrg switch (op) 1790 1.1 mrg { 1791 1.1 mrg case DW_LNE_end_sequence: 1792 1.1 mrg /* FIXME: Should we mark the high PC here? It seems 1793 1.1 mrg that we already have that information from the 1794 1.1 mrg compilation unit. */ 1795 1.1 mrg address = 0; 1796 1.1 mrg op_index = 0; 1797 1.1 mrg filename = reset_filename; 1798 1.1 mrg lineno = 1; 1799 1.1 mrg break; 1800 1.1 mrg case DW_LNE_set_address: 1801 1.1 mrg address = read_address (line_buf, u->addrsize); 1802 1.1 mrg break; 1803 1.1 mrg case DW_LNE_define_file: 1804 1.1 mrg { 1805 1.1 mrg const char *f; 1806 1.1 mrg unsigned int dir_index; 1807 1.1 mrg 1808 1.1 mrg f = (const char *) line_buf->buf; 1809 1.1 mrg if (!advance (line_buf, strnlen (f, line_buf->left) + 1)) 1810 1.1 mrg return 0; 1811 1.1 mrg dir_index = read_uleb128 (line_buf); 1812 1.1 mrg /* Ignore that time and length. */ 1813 1.1 mrg read_uleb128 (line_buf); 1814 1.1 mrg read_uleb128 (line_buf); 1815 1.1 mrg if (IS_ABSOLUTE_PATH (f)) 1816 1.1 mrg filename = f; 1817 1.1 mrg else 1818 1.1 mrg { 1819 1.1 mrg const char *dir; 1820 1.1 mrg size_t dir_len; 1821 1.1 mrg size_t f_len; 1822 1.1 mrg char *p; 1823 1.1 mrg 1824 1.1 mrg if (dir_index == 0) 1825 1.1 mrg dir = u->comp_dir; 1826 1.1 mrg else if (dir_index - 1 < hdr->dirs_count) 1827 1.1 mrg dir = hdr->dirs[dir_index - 1]; 1828 1.1 mrg else 1829 1.1 mrg { 1830 1.1 mrg dwarf_buf_error (line_buf, 1831 1.1 mrg ("invalid directory index " 1832 1.1 mrg "in line number program")); 1833 1.1 mrg return 0; 1834 1.1 mrg } 1835 1.1 mrg dir_len = strlen (dir); 1836 1.1 mrg f_len = strlen (f); 1837 1.1 mrg p = ((char *) 1838 1.1 mrg backtrace_alloc (state, dir_len + f_len + 2, 1839 1.1 mrg line_buf->error_callback, 1840 1.1 mrg line_buf->data)); 1841 1.1 mrg if (p == NULL) 1842 1.1 mrg return 0; 1843 1.1 mrg memcpy (p, dir, dir_len); 1844 1.1 mrg /* FIXME: If we are on a DOS-based file system, 1845 1.1 mrg and the directory or the file name use 1846 1.1 mrg backslashes, then we should use a backslash 1847 1.1 mrg here. */ 1848 1.1 mrg p[dir_len] = '/'; 1849 1.1 mrg memcpy (p + dir_len + 1, f, f_len + 1); 1850 1.1 mrg filename = p; 1851 1.1 mrg } 1852 1.1 mrg } 1853 1.1 mrg break; 1854 1.1 mrg case DW_LNE_set_discriminator: 1855 1.1 mrg /* We don't care about discriminators. */ 1856 1.1 mrg read_uleb128 (line_buf); 1857 1.1 mrg break; 1858 1.1 mrg default: 1859 1.1 mrg if (!advance (line_buf, len - 1)) 1860 1.1 mrg return 0; 1861 1.1 mrg break; 1862 1.1 mrg } 1863 1.1 mrg } 1864 1.1 mrg else 1865 1.1 mrg { 1866 1.1 mrg switch (op) 1867 1.1 mrg { 1868 1.1 mrg case DW_LNS_copy: 1869 1.1 mrg add_line (state, ddata, address, filename, lineno, 1870 1.1 mrg line_buf->error_callback, line_buf->data, vec); 1871 1.1 mrg break; 1872 1.1 mrg case DW_LNS_advance_pc: 1873 1.1 mrg { 1874 1.1 mrg uint64_t advance; 1875 1.1 mrg 1876 1.1 mrg advance = read_uleb128 (line_buf); 1877 1.1 mrg address += (hdr->min_insn_len * (op_index + advance) 1878 1.1 mrg / hdr->max_ops_per_insn); 1879 1.1 mrg op_index = (op_index + advance) % hdr->max_ops_per_insn; 1880 1.1 mrg } 1881 1.1 mrg break; 1882 1.1 mrg case DW_LNS_advance_line: 1883 1.1 mrg lineno += (int) read_sleb128 (line_buf); 1884 1.1 mrg break; 1885 1.1 mrg case DW_LNS_set_file: 1886 1.1 mrg { 1887 1.1 mrg uint64_t fileno; 1888 1.1 mrg 1889 1.1 mrg fileno = read_uleb128 (line_buf); 1890 1.1 mrg if (fileno == 0) 1891 1.1 mrg filename = ""; 1892 1.1 mrg else 1893 1.1 mrg { 1894 1.1 mrg if (fileno - 1 >= hdr->filenames_count) 1895 1.1 mrg { 1896 1.1 mrg dwarf_buf_error (line_buf, 1897 1.1 mrg ("invalid file number in " 1898 1.1 mrg "line number program")); 1899 1.1 mrg return 0; 1900 1.1 mrg } 1901 1.1 mrg filename = hdr->filenames[fileno - 1]; 1902 1.1 mrg } 1903 1.1 mrg } 1904 1.1 mrg break; 1905 1.1 mrg case DW_LNS_set_column: 1906 1.1 mrg read_uleb128 (line_buf); 1907 1.1 mrg break; 1908 1.1 mrg case DW_LNS_negate_stmt: 1909 1.1 mrg break; 1910 1.1 mrg case DW_LNS_set_basic_block: 1911 1.1 mrg break; 1912 1.1 mrg case DW_LNS_const_add_pc: 1913 1.1 mrg { 1914 1.1 mrg unsigned int advance; 1915 1.1 mrg 1916 1.1 mrg op = 255 - hdr->opcode_base; 1917 1.1 mrg advance = op / hdr->line_range; 1918 1.1 mrg address += (hdr->min_insn_len * (op_index + advance) 1919 1.1 mrg / hdr->max_ops_per_insn); 1920 1.1 mrg op_index = (op_index + advance) % hdr->max_ops_per_insn; 1921 1.1 mrg } 1922 1.1 mrg break; 1923 1.1 mrg case DW_LNS_fixed_advance_pc: 1924 1.1 mrg address += read_uint16 (line_buf); 1925 1.1 mrg op_index = 0; 1926 1.1 mrg break; 1927 1.1 mrg case DW_LNS_set_prologue_end: 1928 1.1 mrg break; 1929 1.1 mrg case DW_LNS_set_epilogue_begin: 1930 1.1 mrg break; 1931 1.1 mrg case DW_LNS_set_isa: 1932 1.1 mrg read_uleb128 (line_buf); 1933 1.1 mrg break; 1934 1.1 mrg default: 1935 1.1 mrg { 1936 1.1 mrg unsigned int i; 1937 1.1 mrg 1938 1.1 mrg for (i = hdr->opcode_lengths[op - 1]; i > 0; --i) 1939 1.1 mrg read_uleb128 (line_buf); 1940 1.1 mrg } 1941 1.1 mrg break; 1942 1.1 mrg } 1943 1.1 mrg } 1944 1.1 mrg } 1945 1.1 mrg 1946 1.1 mrg return 1; 1947 1.1 mrg } 1948 1.1 mrg 1949 1.1 mrg /* Read the line number information for a compilation unit. Returns 1 1950 1.1 mrg on success, 0 on failure. */ 1951 1.1 mrg 1952 1.1 mrg static int 1953 1.1 mrg read_line_info (struct backtrace_state *state, struct dwarf_data *ddata, 1954 1.1 mrg backtrace_error_callback error_callback, void *data, 1955 1.1 mrg struct unit *u, struct line_header *hdr, struct line **lines, 1956 1.1 mrg size_t *lines_count) 1957 1.1 mrg { 1958 1.1 mrg struct line_vector vec; 1959 1.1 mrg struct dwarf_buf line_buf; 1960 1.1 mrg uint64_t len; 1961 1.1 mrg int is_dwarf64; 1962 1.1 mrg struct line *ln; 1963 1.1 mrg 1964 1.1 mrg memset (&vec.vec, 0, sizeof vec.vec); 1965 1.1 mrg vec.count = 0; 1966 1.1 mrg 1967 1.1 mrg memset (hdr, 0, sizeof *hdr); 1968 1.1 mrg 1969 1.1 mrg if (u->lineoff != (off_t) (size_t) u->lineoff 1970 1.1 mrg || (size_t) u->lineoff >= ddata->dwarf_line_size) 1971 1.1 mrg { 1972 1.1 mrg error_callback (data, "unit line offset out of range", 0); 1973 1.1 mrg goto fail; 1974 1.1 mrg } 1975 1.1 mrg 1976 1.1 mrg line_buf.name = ".debug_line"; 1977 1.1 mrg line_buf.start = ddata->dwarf_line; 1978 1.1 mrg line_buf.buf = ddata->dwarf_line + u->lineoff; 1979 1.1 mrg line_buf.left = ddata->dwarf_line_size - u->lineoff; 1980 1.1 mrg line_buf.is_bigendian = ddata->is_bigendian; 1981 1.1 mrg line_buf.error_callback = error_callback; 1982 1.1 mrg line_buf.data = data; 1983 1.1 mrg line_buf.reported_underflow = 0; 1984 1.1 mrg 1985 1.1 mrg is_dwarf64 = 0; 1986 1.1 mrg len = read_uint32 (&line_buf); 1987 1.1 mrg if (len == 0xffffffff) 1988 1.1 mrg { 1989 1.1 mrg len = read_uint64 (&line_buf); 1990 1.1 mrg is_dwarf64 = 1; 1991 1.1 mrg } 1992 1.1 mrg line_buf.left = len; 1993 1.1 mrg 1994 1.1 mrg if (!read_line_header (state, u, is_dwarf64, &line_buf, hdr)) 1995 1.1 mrg goto fail; 1996 1.1 mrg 1997 1.1 mrg if (!read_line_program (state, ddata, u, hdr, &line_buf, &vec)) 1998 1.1 mrg goto fail; 1999 1.1 mrg 2000 1.1 mrg if (line_buf.reported_underflow) 2001 1.1 mrg goto fail; 2002 1.1 mrg 2003 1.1 mrg if (vec.count == 0) 2004 1.1 mrg { 2005 1.1 mrg /* This is not a failure in the sense of a generating an error, 2006 1.1 mrg but it is a failure in that sense that we have no useful 2007 1.1 mrg information. */ 2008 1.1 mrg goto fail; 2009 1.1 mrg } 2010 1.1 mrg 2011 1.1 mrg /* Allocate one extra entry at the end. */ 2012 1.1 mrg ln = ((struct line *) 2013 1.1 mrg backtrace_vector_grow (state, sizeof (struct line), error_callback, 2014 1.1 mrg data, &vec.vec)); 2015 1.1 mrg if (ln == NULL) 2016 1.1 mrg goto fail; 2017 1.1 mrg ln->pc = (uintptr_t) -1; 2018 1.1 mrg ln->filename = NULL; 2019 1.1 mrg ln->lineno = 0; 2020 1.1.1.3 mrg ln->idx = 0; 2021 1.1 mrg 2022 1.1 mrg if (!backtrace_vector_release (state, &vec.vec, error_callback, data)) 2023 1.1 mrg goto fail; 2024 1.1 mrg 2025 1.1 mrg ln = (struct line *) vec.vec.base; 2026 1.1.1.2 mrg backtrace_qsort (ln, vec.count, sizeof (struct line), line_compare); 2027 1.1 mrg 2028 1.1 mrg *lines = ln; 2029 1.1 mrg *lines_count = vec.count; 2030 1.1 mrg 2031 1.1 mrg return 1; 2032 1.1 mrg 2033 1.1 mrg fail: 2034 1.1 mrg vec.vec.alc += vec.vec.size; 2035 1.1 mrg vec.vec.size = 0; 2036 1.1 mrg backtrace_vector_release (state, &vec.vec, error_callback, data); 2037 1.1 mrg free_line_header (state, hdr, error_callback, data); 2038 1.1 mrg *lines = (struct line *) (uintptr_t) -1; 2039 1.1 mrg *lines_count = 0; 2040 1.1 mrg return 0; 2041 1.1 mrg } 2042 1.1 mrg 2043 1.1 mrg /* Read the name of a function from a DIE referenced by a 2044 1.1 mrg DW_AT_abstract_origin or DW_AT_specification tag. OFFSET is within 2045 1.1 mrg the same compilation unit. */ 2046 1.1 mrg 2047 1.1 mrg static const char * 2048 1.1 mrg read_referenced_name (struct dwarf_data *ddata, struct unit *u, 2049 1.1 mrg uint64_t offset, backtrace_error_callback error_callback, 2050 1.1 mrg void *data) 2051 1.1 mrg { 2052 1.1 mrg struct dwarf_buf unit_buf; 2053 1.1 mrg uint64_t code; 2054 1.1 mrg const struct abbrev *abbrev; 2055 1.1 mrg const char *ret; 2056 1.1 mrg size_t i; 2057 1.1 mrg 2058 1.1 mrg /* OFFSET is from the start of the data for this compilation unit. 2059 1.1 mrg U->unit_data is the data, but it starts U->unit_data_offset bytes 2060 1.1 mrg from the beginning. */ 2061 1.1 mrg 2062 1.1 mrg if (offset < u->unit_data_offset 2063 1.1 mrg || offset - u->unit_data_offset >= u->unit_data_len) 2064 1.1 mrg { 2065 1.1 mrg error_callback (data, 2066 1.1 mrg "abstract origin or specification out of range", 2067 1.1 mrg 0); 2068 1.1 mrg return NULL; 2069 1.1 mrg } 2070 1.1 mrg 2071 1.1 mrg offset -= u->unit_data_offset; 2072 1.1 mrg 2073 1.1 mrg unit_buf.name = ".debug_info"; 2074 1.1 mrg unit_buf.start = ddata->dwarf_info; 2075 1.1 mrg unit_buf.buf = u->unit_data + offset; 2076 1.1 mrg unit_buf.left = u->unit_data_len - offset; 2077 1.1 mrg unit_buf.is_bigendian = ddata->is_bigendian; 2078 1.1 mrg unit_buf.error_callback = error_callback; 2079 1.1 mrg unit_buf.data = data; 2080 1.1 mrg unit_buf.reported_underflow = 0; 2081 1.1 mrg 2082 1.1 mrg code = read_uleb128 (&unit_buf); 2083 1.1 mrg if (code == 0) 2084 1.1 mrg { 2085 1.1 mrg dwarf_buf_error (&unit_buf, "invalid abstract origin or specification"); 2086 1.1 mrg return NULL; 2087 1.1 mrg } 2088 1.1 mrg 2089 1.1 mrg abbrev = lookup_abbrev (&u->abbrevs, code, error_callback, data); 2090 1.1 mrg if (abbrev == NULL) 2091 1.1 mrg return NULL; 2092 1.1 mrg 2093 1.1 mrg ret = NULL; 2094 1.1 mrg for (i = 0; i < abbrev->num_attrs; ++i) 2095 1.1 mrg { 2096 1.1 mrg struct attr_val val; 2097 1.1 mrg 2098 1.1 mrg if (!read_attribute (abbrev->attrs[i].form, &unit_buf, 2099 1.1 mrg u->is_dwarf64, u->version, u->addrsize, 2100 1.1 mrg ddata->dwarf_str, ddata->dwarf_str_size, 2101 1.1 mrg &val)) 2102 1.1 mrg return NULL; 2103 1.1 mrg 2104 1.1 mrg switch (abbrev->attrs[i].name) 2105 1.1 mrg { 2106 1.1 mrg case DW_AT_name: 2107 1.1 mrg /* We prefer the linkage name if get one. */ 2108 1.1 mrg if (val.encoding == ATTR_VAL_STRING) 2109 1.1 mrg ret = val.u.string; 2110 1.1 mrg break; 2111 1.1 mrg 2112 1.1 mrg case DW_AT_linkage_name: 2113 1.1 mrg case DW_AT_MIPS_linkage_name: 2114 1.1 mrg if (val.encoding == ATTR_VAL_STRING) 2115 1.1 mrg return val.u.string; 2116 1.1 mrg break; 2117 1.1 mrg 2118 1.1 mrg case DW_AT_specification: 2119 1.1 mrg if (abbrev->attrs[i].form == DW_FORM_ref_addr 2120 1.1 mrg || abbrev->attrs[i].form == DW_FORM_ref_sig8) 2121 1.1 mrg { 2122 1.1 mrg /* This refers to a specification defined in some other 2123 1.1 mrg compilation unit. We can handle this case if we 2124 1.1 mrg must, but it's harder. */ 2125 1.1 mrg break; 2126 1.1 mrg } 2127 1.1 mrg if (val.encoding == ATTR_VAL_UINT 2128 1.1 mrg || val.encoding == ATTR_VAL_REF_UNIT) 2129 1.1 mrg { 2130 1.1 mrg const char *name; 2131 1.1 mrg 2132 1.1 mrg name = read_referenced_name (ddata, u, val.u.uint, 2133 1.1 mrg error_callback, data); 2134 1.1 mrg if (name != NULL) 2135 1.1 mrg ret = name; 2136 1.1 mrg } 2137 1.1 mrg break; 2138 1.1 mrg 2139 1.1 mrg default: 2140 1.1 mrg break; 2141 1.1 mrg } 2142 1.1 mrg } 2143 1.1 mrg 2144 1.1 mrg return ret; 2145 1.1 mrg } 2146 1.1 mrg 2147 1.1 mrg /* Add a single range to U that maps to function. Returns 1 on 2148 1.1 mrg success, 0 on error. */ 2149 1.1 mrg 2150 1.1 mrg static int 2151 1.1 mrg add_function_range (struct backtrace_state *state, struct dwarf_data *ddata, 2152 1.1 mrg struct function *function, uint64_t lowpc, uint64_t highpc, 2153 1.1 mrg backtrace_error_callback error_callback, 2154 1.1 mrg void *data, struct function_vector *vec) 2155 1.1 mrg { 2156 1.1 mrg struct function_addrs *p; 2157 1.1 mrg 2158 1.1 mrg /* Add in the base address here, so that we can look up the PC 2159 1.1 mrg directly. */ 2160 1.1 mrg lowpc += ddata->base_address; 2161 1.1 mrg highpc += ddata->base_address; 2162 1.1 mrg 2163 1.1 mrg if (vec->count > 0) 2164 1.1 mrg { 2165 1.1 mrg p = (struct function_addrs *) vec->vec.base + vec->count - 1; 2166 1.1 mrg if ((lowpc == p->high || lowpc == p->high + 1) 2167 1.1 mrg && function == p->function) 2168 1.1 mrg { 2169 1.1 mrg if (highpc > p->high) 2170 1.1 mrg p->high = highpc; 2171 1.1 mrg return 1; 2172 1.1 mrg } 2173 1.1 mrg } 2174 1.1 mrg 2175 1.1 mrg p = ((struct function_addrs *) 2176 1.1 mrg backtrace_vector_grow (state, sizeof (struct function_addrs), 2177 1.1 mrg error_callback, data, &vec->vec)); 2178 1.1 mrg if (p == NULL) 2179 1.1 mrg return 0; 2180 1.1 mrg 2181 1.1 mrg p->low = lowpc; 2182 1.1 mrg p->high = highpc; 2183 1.1 mrg p->function = function; 2184 1.1 mrg ++vec->count; 2185 1.1 mrg return 1; 2186 1.1 mrg } 2187 1.1 mrg 2188 1.1 mrg /* Add PC ranges to U that map to FUNCTION. Returns 1 on success, 0 2189 1.1 mrg on error. */ 2190 1.1 mrg 2191 1.1 mrg static int 2192 1.1 mrg add_function_ranges (struct backtrace_state *state, struct dwarf_data *ddata, 2193 1.1 mrg struct unit *u, struct function *function, 2194 1.1 mrg uint64_t ranges, uint64_t base, 2195 1.1 mrg backtrace_error_callback error_callback, void *data, 2196 1.1 mrg struct function_vector *vec) 2197 1.1 mrg { 2198 1.1 mrg struct dwarf_buf ranges_buf; 2199 1.1 mrg 2200 1.1 mrg if (ranges >= ddata->dwarf_ranges_size) 2201 1.1 mrg { 2202 1.1 mrg error_callback (data, "function ranges offset out of range", 0); 2203 1.1 mrg return 0; 2204 1.1 mrg } 2205 1.1 mrg 2206 1.1 mrg ranges_buf.name = ".debug_ranges"; 2207 1.1 mrg ranges_buf.start = ddata->dwarf_ranges; 2208 1.1 mrg ranges_buf.buf = ddata->dwarf_ranges + ranges; 2209 1.1 mrg ranges_buf.left = ddata->dwarf_ranges_size - ranges; 2210 1.1 mrg ranges_buf.is_bigendian = ddata->is_bigendian; 2211 1.1 mrg ranges_buf.error_callback = error_callback; 2212 1.1 mrg ranges_buf.data = data; 2213 1.1 mrg ranges_buf.reported_underflow = 0; 2214 1.1 mrg 2215 1.1 mrg while (1) 2216 1.1 mrg { 2217 1.1 mrg uint64_t low; 2218 1.1 mrg uint64_t high; 2219 1.1 mrg 2220 1.1 mrg if (ranges_buf.reported_underflow) 2221 1.1 mrg return 0; 2222 1.1 mrg 2223 1.1 mrg low = read_address (&ranges_buf, u->addrsize); 2224 1.1 mrg high = read_address (&ranges_buf, u->addrsize); 2225 1.1 mrg 2226 1.1 mrg if (low == 0 && high == 0) 2227 1.1 mrg break; 2228 1.1 mrg 2229 1.1 mrg if (is_highest_address (low, u->addrsize)) 2230 1.1 mrg base = high; 2231 1.1 mrg else 2232 1.1 mrg { 2233 1.1 mrg if (!add_function_range (state, ddata, function, low + base, 2234 1.1 mrg high + base, error_callback, data, vec)) 2235 1.1 mrg return 0; 2236 1.1 mrg } 2237 1.1 mrg } 2238 1.1 mrg 2239 1.1 mrg if (ranges_buf.reported_underflow) 2240 1.1 mrg return 0; 2241 1.1 mrg 2242 1.1 mrg return 1; 2243 1.1 mrg } 2244 1.1 mrg 2245 1.1 mrg /* Read one entry plus all its children. Add function addresses to 2246 1.1 mrg VEC. Returns 1 on success, 0 on error. */ 2247 1.1 mrg 2248 1.1 mrg static int 2249 1.1 mrg read_function_entry (struct backtrace_state *state, struct dwarf_data *ddata, 2250 1.1 mrg struct unit *u, uint64_t base, struct dwarf_buf *unit_buf, 2251 1.1 mrg const struct line_header *lhdr, 2252 1.1 mrg backtrace_error_callback error_callback, void *data, 2253 1.1.1.3 mrg struct function_vector *vec_function, 2254 1.1.1.3 mrg struct function_vector *vec_inlined) 2255 1.1 mrg { 2256 1.1 mrg while (unit_buf->left > 0) 2257 1.1 mrg { 2258 1.1 mrg uint64_t code; 2259 1.1 mrg const struct abbrev *abbrev; 2260 1.1 mrg int is_function; 2261 1.1 mrg struct function *function; 2262 1.1.1.3 mrg struct function_vector *vec; 2263 1.1 mrg size_t i; 2264 1.1 mrg uint64_t lowpc; 2265 1.1 mrg int have_lowpc; 2266 1.1 mrg uint64_t highpc; 2267 1.1 mrg int have_highpc; 2268 1.1 mrg int highpc_is_relative; 2269 1.1 mrg uint64_t ranges; 2270 1.1 mrg int have_ranges; 2271 1.1 mrg 2272 1.1 mrg code = read_uleb128 (unit_buf); 2273 1.1 mrg if (code == 0) 2274 1.1 mrg return 1; 2275 1.1 mrg 2276 1.1 mrg abbrev = lookup_abbrev (&u->abbrevs, code, error_callback, data); 2277 1.1 mrg if (abbrev == NULL) 2278 1.1 mrg return 0; 2279 1.1 mrg 2280 1.1 mrg is_function = (abbrev->tag == DW_TAG_subprogram 2281 1.1 mrg || abbrev->tag == DW_TAG_entry_point 2282 1.1 mrg || abbrev->tag == DW_TAG_inlined_subroutine); 2283 1.1 mrg 2284 1.1.1.3 mrg if (abbrev->tag == DW_TAG_inlined_subroutine) 2285 1.1.1.3 mrg vec = vec_inlined; 2286 1.1.1.3 mrg else 2287 1.1.1.3 mrg vec = vec_function; 2288 1.1.1.3 mrg 2289 1.1 mrg function = NULL; 2290 1.1 mrg if (is_function) 2291 1.1 mrg { 2292 1.1 mrg function = ((struct function *) 2293 1.1 mrg backtrace_alloc (state, sizeof *function, 2294 1.1 mrg error_callback, data)); 2295 1.1 mrg if (function == NULL) 2296 1.1 mrg return 0; 2297 1.1 mrg memset (function, 0, sizeof *function); 2298 1.1 mrg } 2299 1.1 mrg 2300 1.1 mrg lowpc = 0; 2301 1.1 mrg have_lowpc = 0; 2302 1.1 mrg highpc = 0; 2303 1.1 mrg have_highpc = 0; 2304 1.1 mrg highpc_is_relative = 0; 2305 1.1 mrg ranges = 0; 2306 1.1 mrg have_ranges = 0; 2307 1.1 mrg for (i = 0; i < abbrev->num_attrs; ++i) 2308 1.1 mrg { 2309 1.1 mrg struct attr_val val; 2310 1.1 mrg 2311 1.1 mrg if (!read_attribute (abbrev->attrs[i].form, unit_buf, 2312 1.1 mrg u->is_dwarf64, u->version, u->addrsize, 2313 1.1 mrg ddata->dwarf_str, ddata->dwarf_str_size, 2314 1.1 mrg &val)) 2315 1.1 mrg return 0; 2316 1.1 mrg 2317 1.1 mrg /* The compile unit sets the base address for any address 2318 1.1 mrg ranges in the function entries. */ 2319 1.1 mrg if (abbrev->tag == DW_TAG_compile_unit 2320 1.1 mrg && abbrev->attrs[i].name == DW_AT_low_pc 2321 1.1 mrg && val.encoding == ATTR_VAL_ADDRESS) 2322 1.1 mrg base = val.u.uint; 2323 1.1 mrg 2324 1.1 mrg if (is_function) 2325 1.1 mrg { 2326 1.1 mrg switch (abbrev->attrs[i].name) 2327 1.1 mrg { 2328 1.1 mrg case DW_AT_call_file: 2329 1.1 mrg if (val.encoding == ATTR_VAL_UINT) 2330 1.1 mrg { 2331 1.1 mrg if (val.u.uint == 0) 2332 1.1 mrg function->caller_filename = ""; 2333 1.1 mrg else 2334 1.1 mrg { 2335 1.1 mrg if (val.u.uint - 1 >= lhdr->filenames_count) 2336 1.1 mrg { 2337 1.1 mrg dwarf_buf_error (unit_buf, 2338 1.1 mrg ("invalid file number in " 2339 1.1 mrg "DW_AT_call_file attribute")); 2340 1.1 mrg return 0; 2341 1.1 mrg } 2342 1.1 mrg function->caller_filename = 2343 1.1 mrg lhdr->filenames[val.u.uint - 1]; 2344 1.1 mrg } 2345 1.1 mrg } 2346 1.1 mrg break; 2347 1.1 mrg 2348 1.1 mrg case DW_AT_call_line: 2349 1.1 mrg if (val.encoding == ATTR_VAL_UINT) 2350 1.1 mrg function->caller_lineno = val.u.uint; 2351 1.1 mrg break; 2352 1.1 mrg 2353 1.1 mrg case DW_AT_abstract_origin: 2354 1.1 mrg case DW_AT_specification: 2355 1.1 mrg if (abbrev->attrs[i].form == DW_FORM_ref_addr 2356 1.1 mrg || abbrev->attrs[i].form == DW_FORM_ref_sig8) 2357 1.1 mrg { 2358 1.1 mrg /* This refers to an abstract origin defined in 2359 1.1 mrg some other compilation unit. We can handle 2360 1.1 mrg this case if we must, but it's harder. */ 2361 1.1 mrg break; 2362 1.1 mrg } 2363 1.1 mrg if (val.encoding == ATTR_VAL_UINT 2364 1.1 mrg || val.encoding == ATTR_VAL_REF_UNIT) 2365 1.1 mrg { 2366 1.1 mrg const char *name; 2367 1.1 mrg 2368 1.1 mrg name = read_referenced_name (ddata, u, val.u.uint, 2369 1.1 mrg error_callback, data); 2370 1.1 mrg if (name != NULL) 2371 1.1 mrg function->name = name; 2372 1.1 mrg } 2373 1.1 mrg break; 2374 1.1 mrg 2375 1.1 mrg case DW_AT_name: 2376 1.1 mrg if (val.encoding == ATTR_VAL_STRING) 2377 1.1 mrg { 2378 1.1 mrg /* Don't override a name we found in some other 2379 1.1 mrg way, as it will normally be more 2380 1.1 mrg useful--e.g., this name is normally not 2381 1.1 mrg mangled. */ 2382 1.1 mrg if (function->name == NULL) 2383 1.1 mrg function->name = val.u.string; 2384 1.1 mrg } 2385 1.1 mrg break; 2386 1.1 mrg 2387 1.1 mrg case DW_AT_linkage_name: 2388 1.1 mrg case DW_AT_MIPS_linkage_name: 2389 1.1 mrg if (val.encoding == ATTR_VAL_STRING) 2390 1.1 mrg function->name = val.u.string; 2391 1.1 mrg break; 2392 1.1 mrg 2393 1.1 mrg case DW_AT_low_pc: 2394 1.1 mrg if (val.encoding == ATTR_VAL_ADDRESS) 2395 1.1 mrg { 2396 1.1 mrg lowpc = val.u.uint; 2397 1.1 mrg have_lowpc = 1; 2398 1.1 mrg } 2399 1.1 mrg break; 2400 1.1 mrg 2401 1.1 mrg case DW_AT_high_pc: 2402 1.1 mrg if (val.encoding == ATTR_VAL_ADDRESS) 2403 1.1 mrg { 2404 1.1 mrg highpc = val.u.uint; 2405 1.1 mrg have_highpc = 1; 2406 1.1 mrg } 2407 1.1 mrg else if (val.encoding == ATTR_VAL_UINT) 2408 1.1 mrg { 2409 1.1 mrg highpc = val.u.uint; 2410 1.1 mrg have_highpc = 1; 2411 1.1 mrg highpc_is_relative = 1; 2412 1.1 mrg } 2413 1.1 mrg break; 2414 1.1 mrg 2415 1.1 mrg case DW_AT_ranges: 2416 1.1 mrg if (val.encoding == ATTR_VAL_UINT 2417 1.1 mrg || val.encoding == ATTR_VAL_REF_SECTION) 2418 1.1 mrg { 2419 1.1 mrg ranges = val.u.uint; 2420 1.1 mrg have_ranges = 1; 2421 1.1 mrg } 2422 1.1 mrg break; 2423 1.1 mrg 2424 1.1 mrg default: 2425 1.1 mrg break; 2426 1.1 mrg } 2427 1.1 mrg } 2428 1.1 mrg } 2429 1.1 mrg 2430 1.1 mrg /* If we couldn't find a name for the function, we have no use 2431 1.1 mrg for it. */ 2432 1.1 mrg if (is_function && function->name == NULL) 2433 1.1 mrg { 2434 1.1 mrg backtrace_free (state, function, sizeof *function, 2435 1.1 mrg error_callback, data); 2436 1.1 mrg is_function = 0; 2437 1.1 mrg } 2438 1.1 mrg 2439 1.1 mrg if (is_function) 2440 1.1 mrg { 2441 1.1 mrg if (have_ranges) 2442 1.1 mrg { 2443 1.1 mrg if (!add_function_ranges (state, ddata, u, function, ranges, 2444 1.1 mrg base, error_callback, data, vec)) 2445 1.1 mrg return 0; 2446 1.1 mrg } 2447 1.1 mrg else if (have_lowpc && have_highpc) 2448 1.1 mrg { 2449 1.1 mrg if (highpc_is_relative) 2450 1.1 mrg highpc += lowpc; 2451 1.1 mrg if (!add_function_range (state, ddata, function, lowpc, highpc, 2452 1.1 mrg error_callback, data, vec)) 2453 1.1 mrg return 0; 2454 1.1 mrg } 2455 1.1 mrg else 2456 1.1 mrg { 2457 1.1 mrg backtrace_free (state, function, sizeof *function, 2458 1.1 mrg error_callback, data); 2459 1.1 mrg is_function = 0; 2460 1.1 mrg } 2461 1.1 mrg } 2462 1.1 mrg 2463 1.1 mrg if (abbrev->has_children) 2464 1.1 mrg { 2465 1.1 mrg if (!is_function) 2466 1.1 mrg { 2467 1.1 mrg if (!read_function_entry (state, ddata, u, base, unit_buf, lhdr, 2468 1.1.1.3 mrg error_callback, data, vec_function, 2469 1.1.1.3 mrg vec_inlined)) 2470 1.1 mrg return 0; 2471 1.1 mrg } 2472 1.1 mrg else 2473 1.1 mrg { 2474 1.1 mrg struct function_vector fvec; 2475 1.1 mrg 2476 1.1 mrg /* Gather any information for inlined functions in 2477 1.1 mrg FVEC. */ 2478 1.1 mrg 2479 1.1 mrg memset (&fvec, 0, sizeof fvec); 2480 1.1 mrg 2481 1.1 mrg if (!read_function_entry (state, ddata, u, base, unit_buf, lhdr, 2482 1.1.1.3 mrg error_callback, data, vec_function, 2483 1.1.1.3 mrg &fvec)) 2484 1.1 mrg return 0; 2485 1.1 mrg 2486 1.1 mrg if (fvec.count > 0) 2487 1.1 mrg { 2488 1.1 mrg struct function_addrs *faddrs; 2489 1.1 mrg 2490 1.1 mrg if (!backtrace_vector_release (state, &fvec.vec, 2491 1.1 mrg error_callback, data)) 2492 1.1 mrg return 0; 2493 1.1 mrg 2494 1.1 mrg faddrs = (struct function_addrs *) fvec.vec.base; 2495 1.1.1.2 mrg backtrace_qsort (faddrs, fvec.count, 2496 1.1.1.2 mrg sizeof (struct function_addrs), 2497 1.1.1.2 mrg function_addrs_compare); 2498 1.1 mrg 2499 1.1 mrg function->function_addrs = faddrs; 2500 1.1 mrg function->function_addrs_count = fvec.count; 2501 1.1 mrg } 2502 1.1 mrg } 2503 1.1 mrg } 2504 1.1 mrg } 2505 1.1 mrg 2506 1.1 mrg return 1; 2507 1.1 mrg } 2508 1.1 mrg 2509 1.1 mrg /* Read function name information for a compilation unit. We look 2510 1.1 mrg through the whole unit looking for function tags. */ 2511 1.1 mrg 2512 1.1 mrg static void 2513 1.1 mrg read_function_info (struct backtrace_state *state, struct dwarf_data *ddata, 2514 1.1 mrg const struct line_header *lhdr, 2515 1.1 mrg backtrace_error_callback error_callback, void *data, 2516 1.1 mrg struct unit *u, struct function_vector *fvec, 2517 1.1 mrg struct function_addrs **ret_addrs, 2518 1.1 mrg size_t *ret_addrs_count) 2519 1.1 mrg { 2520 1.1 mrg struct function_vector lvec; 2521 1.1 mrg struct function_vector *pfvec; 2522 1.1 mrg struct dwarf_buf unit_buf; 2523 1.1 mrg struct function_addrs *addrs; 2524 1.1 mrg size_t addrs_count; 2525 1.1 mrg 2526 1.1 mrg /* Use FVEC if it is not NULL. Otherwise use our own vector. */ 2527 1.1 mrg if (fvec != NULL) 2528 1.1 mrg pfvec = fvec; 2529 1.1 mrg else 2530 1.1 mrg { 2531 1.1 mrg memset (&lvec, 0, sizeof lvec); 2532 1.1 mrg pfvec = &lvec; 2533 1.1 mrg } 2534 1.1 mrg 2535 1.1 mrg unit_buf.name = ".debug_info"; 2536 1.1 mrg unit_buf.start = ddata->dwarf_info; 2537 1.1 mrg unit_buf.buf = u->unit_data; 2538 1.1 mrg unit_buf.left = u->unit_data_len; 2539 1.1 mrg unit_buf.is_bigendian = ddata->is_bigendian; 2540 1.1 mrg unit_buf.error_callback = error_callback; 2541 1.1 mrg unit_buf.data = data; 2542 1.1 mrg unit_buf.reported_underflow = 0; 2543 1.1 mrg 2544 1.1 mrg while (unit_buf.left > 0) 2545 1.1 mrg { 2546 1.1 mrg if (!read_function_entry (state, ddata, u, 0, &unit_buf, lhdr, 2547 1.1.1.3 mrg error_callback, data, pfvec, pfvec)) 2548 1.1 mrg return; 2549 1.1 mrg } 2550 1.1 mrg 2551 1.1 mrg if (pfvec->count == 0) 2552 1.1 mrg return; 2553 1.1 mrg 2554 1.1 mrg addrs_count = pfvec->count; 2555 1.1 mrg 2556 1.1 mrg if (fvec == NULL) 2557 1.1 mrg { 2558 1.1 mrg if (!backtrace_vector_release (state, &lvec.vec, error_callback, data)) 2559 1.1 mrg return; 2560 1.1 mrg addrs = (struct function_addrs *) pfvec->vec.base; 2561 1.1 mrg } 2562 1.1 mrg else 2563 1.1 mrg { 2564 1.1 mrg /* Finish this list of addresses, but leave the remaining space in 2565 1.1 mrg the vector available for the next function unit. */ 2566 1.1 mrg addrs = ((struct function_addrs *) 2567 1.1 mrg backtrace_vector_finish (state, &fvec->vec, 2568 1.1 mrg error_callback, data)); 2569 1.1 mrg if (addrs == NULL) 2570 1.1 mrg return; 2571 1.1 mrg fvec->count = 0; 2572 1.1 mrg } 2573 1.1 mrg 2574 1.1.1.2 mrg backtrace_qsort (addrs, addrs_count, sizeof (struct function_addrs), 2575 1.1.1.2 mrg function_addrs_compare); 2576 1.1 mrg 2577 1.1 mrg *ret_addrs = addrs; 2578 1.1 mrg *ret_addrs_count = addrs_count; 2579 1.1 mrg } 2580 1.1 mrg 2581 1.1 mrg /* See if PC is inlined in FUNCTION. If it is, print out the inlined 2582 1.1 mrg information, and update FILENAME and LINENO for the caller. 2583 1.1 mrg Returns whatever CALLBACK returns, or 0 to keep going. */ 2584 1.1 mrg 2585 1.1 mrg static int 2586 1.1 mrg report_inlined_functions (uintptr_t pc, struct function *function, 2587 1.1 mrg backtrace_full_callback callback, void *data, 2588 1.1 mrg const char **filename, int *lineno) 2589 1.1 mrg { 2590 1.1 mrg struct function_addrs *function_addrs; 2591 1.1 mrg struct function *inlined; 2592 1.1 mrg int ret; 2593 1.1 mrg 2594 1.1 mrg if (function->function_addrs_count == 0) 2595 1.1 mrg return 0; 2596 1.1 mrg 2597 1.1 mrg function_addrs = ((struct function_addrs *) 2598 1.1 mrg bsearch (&pc, function->function_addrs, 2599 1.1 mrg function->function_addrs_count, 2600 1.1 mrg sizeof (struct function_addrs), 2601 1.1 mrg function_addrs_search)); 2602 1.1 mrg if (function_addrs == NULL) 2603 1.1 mrg return 0; 2604 1.1 mrg 2605 1.1 mrg while (((size_t) (function_addrs - function->function_addrs) + 1 2606 1.1 mrg < function->function_addrs_count) 2607 1.1 mrg && pc >= (function_addrs + 1)->low 2608 1.1 mrg && pc < (function_addrs + 1)->high) 2609 1.1 mrg ++function_addrs; 2610 1.1 mrg 2611 1.1 mrg /* We found an inlined call. */ 2612 1.1 mrg 2613 1.1 mrg inlined = function_addrs->function; 2614 1.1 mrg 2615 1.1 mrg /* Report any calls inlined into this one. */ 2616 1.1 mrg ret = report_inlined_functions (pc, inlined, callback, data, 2617 1.1 mrg filename, lineno); 2618 1.1 mrg if (ret != 0) 2619 1.1 mrg return ret; 2620 1.1 mrg 2621 1.1 mrg /* Report this inlined call. */ 2622 1.1 mrg ret = callback (data, pc, *filename, *lineno, inlined->name); 2623 1.1 mrg if (ret != 0) 2624 1.1 mrg return ret; 2625 1.1 mrg 2626 1.1 mrg /* Our caller will report the caller of the inlined function; tell 2627 1.1 mrg it the appropriate filename and line number. */ 2628 1.1 mrg *filename = inlined->caller_filename; 2629 1.1 mrg *lineno = inlined->caller_lineno; 2630 1.1 mrg 2631 1.1 mrg return 0; 2632 1.1 mrg } 2633 1.1 mrg 2634 1.1 mrg /* Look for a PC in the DWARF mapping for one module. On success, 2635 1.1 mrg call CALLBACK and return whatever it returns. On error, call 2636 1.1 mrg ERROR_CALLBACK and return 0. Sets *FOUND to 1 if the PC is found, 2637 1.1 mrg 0 if not. */ 2638 1.1 mrg 2639 1.1 mrg static int 2640 1.1 mrg dwarf_lookup_pc (struct backtrace_state *state, struct dwarf_data *ddata, 2641 1.1 mrg uintptr_t pc, backtrace_full_callback callback, 2642 1.1 mrg backtrace_error_callback error_callback, void *data, 2643 1.1 mrg int *found) 2644 1.1 mrg { 2645 1.1 mrg struct unit_addrs *entry; 2646 1.1 mrg struct unit *u; 2647 1.1 mrg int new_data; 2648 1.1 mrg struct line *lines; 2649 1.1 mrg struct line *ln; 2650 1.1 mrg struct function_addrs *function_addrs; 2651 1.1 mrg struct function *function; 2652 1.1 mrg const char *filename; 2653 1.1 mrg int lineno; 2654 1.1 mrg int ret; 2655 1.1 mrg 2656 1.1 mrg *found = 1; 2657 1.1 mrg 2658 1.1 mrg /* Find an address range that includes PC. */ 2659 1.1 mrg entry = bsearch (&pc, ddata->addrs, ddata->addrs_count, 2660 1.1 mrg sizeof (struct unit_addrs), unit_addrs_search); 2661 1.1 mrg 2662 1.1 mrg if (entry == NULL) 2663 1.1 mrg { 2664 1.1 mrg *found = 0; 2665 1.1 mrg return 0; 2666 1.1 mrg } 2667 1.1 mrg 2668 1.1 mrg /* If there are multiple ranges that contain PC, use the last one, 2669 1.1 mrg in order to produce predictable results. If we assume that all 2670 1.1 mrg ranges are properly nested, then the last range will be the 2671 1.1 mrg smallest one. */ 2672 1.1 mrg while ((size_t) (entry - ddata->addrs) + 1 < ddata->addrs_count 2673 1.1 mrg && pc >= (entry + 1)->low 2674 1.1 mrg && pc < (entry + 1)->high) 2675 1.1 mrg ++entry; 2676 1.1 mrg 2677 1.1 mrg /* We need the lines, lines_count, function_addrs, 2678 1.1 mrg function_addrs_count fields of u. If they are not set, we need 2679 1.1 mrg to set them. When running in threaded mode, we need to allow for 2680 1.1 mrg the possibility that some other thread is setting them 2681 1.1 mrg simultaneously. */ 2682 1.1 mrg 2683 1.1 mrg u = entry->u; 2684 1.1 mrg lines = u->lines; 2685 1.1 mrg 2686 1.1 mrg /* Skip units with no useful line number information by walking 2687 1.1 mrg backward. Useless line number information is marked by setting 2688 1.1 mrg lines == -1. */ 2689 1.1 mrg while (entry > ddata->addrs 2690 1.1 mrg && pc >= (entry - 1)->low 2691 1.1 mrg && pc < (entry - 1)->high) 2692 1.1 mrg { 2693 1.1 mrg if (state->threaded) 2694 1.1.1.2 mrg lines = (struct line *) backtrace_atomic_load_pointer (&u->lines); 2695 1.1 mrg 2696 1.1 mrg if (lines != (struct line *) (uintptr_t) -1) 2697 1.1 mrg break; 2698 1.1 mrg 2699 1.1 mrg --entry; 2700 1.1 mrg 2701 1.1 mrg u = entry->u; 2702 1.1 mrg lines = u->lines; 2703 1.1 mrg } 2704 1.1 mrg 2705 1.1 mrg if (state->threaded) 2706 1.1.1.2 mrg lines = backtrace_atomic_load_pointer (&u->lines); 2707 1.1 mrg 2708 1.1 mrg new_data = 0; 2709 1.1 mrg if (lines == NULL) 2710 1.1 mrg { 2711 1.1 mrg size_t function_addrs_count; 2712 1.1 mrg struct line_header lhdr; 2713 1.1 mrg size_t count; 2714 1.1 mrg 2715 1.1 mrg /* We have never read the line information for this unit. Read 2716 1.1 mrg it now. */ 2717 1.1 mrg 2718 1.1 mrg function_addrs = NULL; 2719 1.1 mrg function_addrs_count = 0; 2720 1.1 mrg if (read_line_info (state, ddata, error_callback, data, entry->u, &lhdr, 2721 1.1 mrg &lines, &count)) 2722 1.1 mrg { 2723 1.1 mrg struct function_vector *pfvec; 2724 1.1 mrg 2725 1.1 mrg /* If not threaded, reuse DDATA->FVEC for better memory 2726 1.1 mrg consumption. */ 2727 1.1 mrg if (state->threaded) 2728 1.1 mrg pfvec = NULL; 2729 1.1 mrg else 2730 1.1 mrg pfvec = &ddata->fvec; 2731 1.1 mrg read_function_info (state, ddata, &lhdr, error_callback, data, 2732 1.1 mrg entry->u, pfvec, &function_addrs, 2733 1.1 mrg &function_addrs_count); 2734 1.1 mrg free_line_header (state, &lhdr, error_callback, data); 2735 1.1 mrg new_data = 1; 2736 1.1 mrg } 2737 1.1 mrg 2738 1.1 mrg /* Atomically store the information we just read into the unit. 2739 1.1 mrg If another thread is simultaneously writing, it presumably 2740 1.1 mrg read the same information, and we don't care which one we 2741 1.1 mrg wind up with; we just leak the other one. We do have to 2742 1.1 mrg write the lines field last, so that the acquire-loads above 2743 1.1 mrg ensure that the other fields are set. */ 2744 1.1 mrg 2745 1.1 mrg if (!state->threaded) 2746 1.1 mrg { 2747 1.1 mrg u->lines_count = count; 2748 1.1 mrg u->function_addrs = function_addrs; 2749 1.1 mrg u->function_addrs_count = function_addrs_count; 2750 1.1 mrg u->lines = lines; 2751 1.1 mrg } 2752 1.1 mrg else 2753 1.1 mrg { 2754 1.1.1.2 mrg backtrace_atomic_store_size_t (&u->lines_count, count); 2755 1.1.1.2 mrg backtrace_atomic_store_pointer (&u->function_addrs, function_addrs); 2756 1.1.1.2 mrg backtrace_atomic_store_size_t (&u->function_addrs_count, 2757 1.1.1.2 mrg function_addrs_count); 2758 1.1.1.2 mrg backtrace_atomic_store_pointer (&u->lines, lines); 2759 1.1 mrg } 2760 1.1 mrg } 2761 1.1 mrg 2762 1.1 mrg /* Now all fields of U have been initialized. */ 2763 1.1 mrg 2764 1.1 mrg if (lines == (struct line *) (uintptr_t) -1) 2765 1.1 mrg { 2766 1.1 mrg /* If reading the line number information failed in some way, 2767 1.1 mrg try again to see if there is a better compilation unit for 2768 1.1 mrg this PC. */ 2769 1.1 mrg if (new_data) 2770 1.1 mrg return dwarf_lookup_pc (state, ddata, pc, callback, error_callback, 2771 1.1 mrg data, found); 2772 1.1 mrg return callback (data, pc, NULL, 0, NULL); 2773 1.1 mrg } 2774 1.1 mrg 2775 1.1 mrg /* Search for PC within this unit. */ 2776 1.1 mrg 2777 1.1 mrg ln = (struct line *) bsearch (&pc, lines, entry->u->lines_count, 2778 1.1 mrg sizeof (struct line), line_search); 2779 1.1 mrg if (ln == NULL) 2780 1.1 mrg { 2781 1.1 mrg /* The PC is between the low_pc and high_pc attributes of the 2782 1.1 mrg compilation unit, but no entry in the line table covers it. 2783 1.1 mrg This implies that the start of the compilation unit has no 2784 1.1 mrg line number information. */ 2785 1.1 mrg 2786 1.1 mrg if (entry->u->abs_filename == NULL) 2787 1.1 mrg { 2788 1.1 mrg const char *filename; 2789 1.1 mrg 2790 1.1 mrg filename = entry->u->filename; 2791 1.1 mrg if (filename != NULL 2792 1.1 mrg && !IS_ABSOLUTE_PATH (filename) 2793 1.1 mrg && entry->u->comp_dir != NULL) 2794 1.1 mrg { 2795 1.1 mrg size_t filename_len; 2796 1.1 mrg const char *dir; 2797 1.1 mrg size_t dir_len; 2798 1.1 mrg char *s; 2799 1.1 mrg 2800 1.1 mrg filename_len = strlen (filename); 2801 1.1 mrg dir = entry->u->comp_dir; 2802 1.1 mrg dir_len = strlen (dir); 2803 1.1 mrg s = (char *) backtrace_alloc (state, dir_len + filename_len + 2, 2804 1.1 mrg error_callback, data); 2805 1.1 mrg if (s == NULL) 2806 1.1 mrg { 2807 1.1 mrg *found = 0; 2808 1.1 mrg return 0; 2809 1.1 mrg } 2810 1.1 mrg memcpy (s, dir, dir_len); 2811 1.1 mrg /* FIXME: Should use backslash if DOS file system. */ 2812 1.1 mrg s[dir_len] = '/'; 2813 1.1 mrg memcpy (s + dir_len + 1, filename, filename_len + 1); 2814 1.1 mrg filename = s; 2815 1.1 mrg } 2816 1.1 mrg entry->u->abs_filename = filename; 2817 1.1 mrg } 2818 1.1 mrg 2819 1.1 mrg return callback (data, pc, entry->u->abs_filename, 0, NULL); 2820 1.1 mrg } 2821 1.1 mrg 2822 1.1 mrg /* Search for function name within this unit. */ 2823 1.1 mrg 2824 1.1 mrg if (entry->u->function_addrs_count == 0) 2825 1.1 mrg return callback (data, pc, ln->filename, ln->lineno, NULL); 2826 1.1 mrg 2827 1.1 mrg function_addrs = ((struct function_addrs *) 2828 1.1 mrg bsearch (&pc, entry->u->function_addrs, 2829 1.1 mrg entry->u->function_addrs_count, 2830 1.1 mrg sizeof (struct function_addrs), 2831 1.1 mrg function_addrs_search)); 2832 1.1 mrg if (function_addrs == NULL) 2833 1.1 mrg return callback (data, pc, ln->filename, ln->lineno, NULL); 2834 1.1 mrg 2835 1.1 mrg /* If there are multiple function ranges that contain PC, use the 2836 1.1 mrg last one, in order to produce predictable results. */ 2837 1.1 mrg 2838 1.1 mrg while (((size_t) (function_addrs - entry->u->function_addrs + 1) 2839 1.1 mrg < entry->u->function_addrs_count) 2840 1.1 mrg && pc >= (function_addrs + 1)->low 2841 1.1 mrg && pc < (function_addrs + 1)->high) 2842 1.1 mrg ++function_addrs; 2843 1.1 mrg 2844 1.1 mrg function = function_addrs->function; 2845 1.1 mrg 2846 1.1 mrg filename = ln->filename; 2847 1.1 mrg lineno = ln->lineno; 2848 1.1 mrg 2849 1.1 mrg ret = report_inlined_functions (pc, function, callback, data, 2850 1.1 mrg &filename, &lineno); 2851 1.1 mrg if (ret != 0) 2852 1.1 mrg return ret; 2853 1.1 mrg 2854 1.1 mrg return callback (data, pc, filename, lineno, function->name); 2855 1.1 mrg } 2856 1.1 mrg 2857 1.1 mrg 2858 1.1 mrg /* Return the file/line information for a PC using the DWARF mapping 2859 1.1 mrg we built earlier. */ 2860 1.1 mrg 2861 1.1 mrg static int 2862 1.1 mrg dwarf_fileline (struct backtrace_state *state, uintptr_t pc, 2863 1.1 mrg backtrace_full_callback callback, 2864 1.1 mrg backtrace_error_callback error_callback, void *data) 2865 1.1 mrg { 2866 1.1 mrg struct dwarf_data *ddata; 2867 1.1 mrg int found; 2868 1.1 mrg int ret; 2869 1.1 mrg 2870 1.1 mrg if (!state->threaded) 2871 1.1 mrg { 2872 1.1 mrg for (ddata = (struct dwarf_data *) state->fileline_data; 2873 1.1 mrg ddata != NULL; 2874 1.1 mrg ddata = ddata->next) 2875 1.1 mrg { 2876 1.1 mrg ret = dwarf_lookup_pc (state, ddata, pc, callback, error_callback, 2877 1.1 mrg data, &found); 2878 1.1 mrg if (ret != 0 || found) 2879 1.1 mrg return ret; 2880 1.1 mrg } 2881 1.1 mrg } 2882 1.1 mrg else 2883 1.1 mrg { 2884 1.1 mrg struct dwarf_data **pp; 2885 1.1 mrg 2886 1.1 mrg pp = (struct dwarf_data **) (void *) &state->fileline_data; 2887 1.1 mrg while (1) 2888 1.1 mrg { 2889 1.1.1.2 mrg ddata = backtrace_atomic_load_pointer (pp); 2890 1.1 mrg if (ddata == NULL) 2891 1.1 mrg break; 2892 1.1 mrg 2893 1.1 mrg ret = dwarf_lookup_pc (state, ddata, pc, callback, error_callback, 2894 1.1 mrg data, &found); 2895 1.1 mrg if (ret != 0 || found) 2896 1.1 mrg return ret; 2897 1.1 mrg 2898 1.1 mrg pp = &ddata->next; 2899 1.1 mrg } 2900 1.1 mrg } 2901 1.1 mrg 2902 1.1 mrg /* FIXME: See if any libraries have been dlopen'ed. */ 2903 1.1 mrg 2904 1.1 mrg return callback (data, pc, NULL, 0, NULL); 2905 1.1 mrg } 2906 1.1 mrg 2907 1.1 mrg /* Initialize our data structures from the DWARF debug info for a 2908 1.1 mrg file. Return NULL on failure. */ 2909 1.1 mrg 2910 1.1 mrg static struct dwarf_data * 2911 1.1 mrg build_dwarf_data (struct backtrace_state *state, 2912 1.1 mrg uintptr_t base_address, 2913 1.1 mrg const unsigned char *dwarf_info, 2914 1.1 mrg size_t dwarf_info_size, 2915 1.1 mrg const unsigned char *dwarf_line, 2916 1.1 mrg size_t dwarf_line_size, 2917 1.1 mrg const unsigned char *dwarf_abbrev, 2918 1.1 mrg size_t dwarf_abbrev_size, 2919 1.1 mrg const unsigned char *dwarf_ranges, 2920 1.1 mrg size_t dwarf_ranges_size, 2921 1.1 mrg const unsigned char *dwarf_str, 2922 1.1 mrg size_t dwarf_str_size, 2923 1.1 mrg int is_bigendian, 2924 1.1 mrg backtrace_error_callback error_callback, 2925 1.1 mrg void *data) 2926 1.1 mrg { 2927 1.1 mrg struct unit_addrs_vector addrs_vec; 2928 1.1 mrg struct unit_addrs *addrs; 2929 1.1 mrg size_t addrs_count; 2930 1.1 mrg struct dwarf_data *fdata; 2931 1.1 mrg 2932 1.1 mrg if (!build_address_map (state, base_address, dwarf_info, dwarf_info_size, 2933 1.1 mrg dwarf_abbrev, dwarf_abbrev_size, dwarf_ranges, 2934 1.1 mrg dwarf_ranges_size, dwarf_str, dwarf_str_size, 2935 1.1 mrg is_bigendian, error_callback, data, &addrs_vec)) 2936 1.1 mrg return NULL; 2937 1.1 mrg 2938 1.1 mrg if (!backtrace_vector_release (state, &addrs_vec.vec, error_callback, data)) 2939 1.1 mrg return NULL; 2940 1.1 mrg addrs = (struct unit_addrs *) addrs_vec.vec.base; 2941 1.1 mrg addrs_count = addrs_vec.count; 2942 1.1.1.2 mrg backtrace_qsort (addrs, addrs_count, sizeof (struct unit_addrs), 2943 1.1.1.2 mrg unit_addrs_compare); 2944 1.1 mrg 2945 1.1 mrg fdata = ((struct dwarf_data *) 2946 1.1 mrg backtrace_alloc (state, sizeof (struct dwarf_data), 2947 1.1 mrg error_callback, data)); 2948 1.1 mrg if (fdata == NULL) 2949 1.1 mrg return NULL; 2950 1.1 mrg 2951 1.1 mrg fdata->next = NULL; 2952 1.1 mrg fdata->base_address = base_address; 2953 1.1 mrg fdata->addrs = addrs; 2954 1.1 mrg fdata->addrs_count = addrs_count; 2955 1.1 mrg fdata->dwarf_info = dwarf_info; 2956 1.1 mrg fdata->dwarf_info_size = dwarf_info_size; 2957 1.1 mrg fdata->dwarf_line = dwarf_line; 2958 1.1 mrg fdata->dwarf_line_size = dwarf_line_size; 2959 1.1 mrg fdata->dwarf_ranges = dwarf_ranges; 2960 1.1 mrg fdata->dwarf_ranges_size = dwarf_ranges_size; 2961 1.1 mrg fdata->dwarf_str = dwarf_str; 2962 1.1 mrg fdata->dwarf_str_size = dwarf_str_size; 2963 1.1 mrg fdata->is_bigendian = is_bigendian; 2964 1.1 mrg memset (&fdata->fvec, 0, sizeof fdata->fvec); 2965 1.1 mrg 2966 1.1 mrg return fdata; 2967 1.1 mrg } 2968 1.1 mrg 2969 1.1 mrg /* Build our data structures from the DWARF sections for a module. 2970 1.1 mrg Set FILELINE_FN and STATE->FILELINE_DATA. Return 1 on success, 0 2971 1.1 mrg on failure. */ 2972 1.1 mrg 2973 1.1 mrg int 2974 1.1 mrg backtrace_dwarf_add (struct backtrace_state *state, 2975 1.1 mrg uintptr_t base_address, 2976 1.1 mrg const unsigned char *dwarf_info, 2977 1.1 mrg size_t dwarf_info_size, 2978 1.1 mrg const unsigned char *dwarf_line, 2979 1.1 mrg size_t dwarf_line_size, 2980 1.1 mrg const unsigned char *dwarf_abbrev, 2981 1.1 mrg size_t dwarf_abbrev_size, 2982 1.1 mrg const unsigned char *dwarf_ranges, 2983 1.1 mrg size_t dwarf_ranges_size, 2984 1.1 mrg const unsigned char *dwarf_str, 2985 1.1 mrg size_t dwarf_str_size, 2986 1.1 mrg int is_bigendian, 2987 1.1 mrg backtrace_error_callback error_callback, 2988 1.1 mrg void *data, fileline *fileline_fn) 2989 1.1 mrg { 2990 1.1 mrg struct dwarf_data *fdata; 2991 1.1 mrg 2992 1.1 mrg fdata = build_dwarf_data (state, base_address, dwarf_info, dwarf_info_size, 2993 1.1 mrg dwarf_line, dwarf_line_size, dwarf_abbrev, 2994 1.1 mrg dwarf_abbrev_size, dwarf_ranges, dwarf_ranges_size, 2995 1.1 mrg dwarf_str, dwarf_str_size, is_bigendian, 2996 1.1 mrg error_callback, data); 2997 1.1 mrg if (fdata == NULL) 2998 1.1 mrg return 0; 2999 1.1 mrg 3000 1.1 mrg if (!state->threaded) 3001 1.1 mrg { 3002 1.1 mrg struct dwarf_data **pp; 3003 1.1 mrg 3004 1.1 mrg for (pp = (struct dwarf_data **) (void *) &state->fileline_data; 3005 1.1 mrg *pp != NULL; 3006 1.1 mrg pp = &(*pp)->next) 3007 1.1 mrg ; 3008 1.1 mrg *pp = fdata; 3009 1.1 mrg } 3010 1.1 mrg else 3011 1.1 mrg { 3012 1.1 mrg while (1) 3013 1.1 mrg { 3014 1.1 mrg struct dwarf_data **pp; 3015 1.1 mrg 3016 1.1 mrg pp = (struct dwarf_data **) (void *) &state->fileline_data; 3017 1.1 mrg 3018 1.1 mrg while (1) 3019 1.1 mrg { 3020 1.1 mrg struct dwarf_data *p; 3021 1.1 mrg 3022 1.1.1.2 mrg p = backtrace_atomic_load_pointer (pp); 3023 1.1 mrg 3024 1.1 mrg if (p == NULL) 3025 1.1 mrg break; 3026 1.1 mrg 3027 1.1 mrg pp = &p->next; 3028 1.1 mrg } 3029 1.1 mrg 3030 1.1 mrg if (__sync_bool_compare_and_swap (pp, NULL, fdata)) 3031 1.1 mrg break; 3032 1.1 mrg } 3033 1.1 mrg } 3034 1.1 mrg 3035 1.1 mrg *fileline_fn = dwarf_fileline; 3036 1.1 mrg 3037 1.1 mrg return 1; 3038 1.1 mrg } 3039
Indexes created Sun Mar 29 00:23:15 UTC 2026