libgcov-util.c revision 1.1.1.7
1 1.1 mrg /* Utility functions for reading gcda files into in-memory 2 1.1 mrg gcov_info structures and offline profile processing. */ 3 1.1.1.7 mrg /* Copyright (C) 2014-2019 Free Software Foundation, Inc. 4 1.1 mrg Contributed by Rong Xu <xur (at) google.com>. 5 1.1 mrg 6 1.1 mrg This file is part of GCC. 7 1.1 mrg 8 1.1 mrg GCC is free software; you can redistribute it and/or modify it under 9 1.1 mrg the terms of the GNU General Public License as published by the Free 10 1.1 mrg Software Foundation; either version 3, or (at your option) any later 11 1.1 mrg version. 12 1.1 mrg 13 1.1 mrg GCC is distributed in the hope that it will be useful, but WITHOUT ANY 14 1.1 mrg WARRANTY; without even the implied warranty of MERCHANTABILITY or 15 1.1 mrg FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 16 1.1 mrg for more details. 17 1.1 mrg 18 1.1 mrg Under Section 7 of GPL version 3, you are granted additional 19 1.1 mrg permissions described in the GCC Runtime Library Exception, version 20 1.1 mrg 3.1, as published by the Free Software Foundation. 21 1.1 mrg 22 1.1 mrg You should have received a copy of the GNU General Public License and 23 1.1 mrg a copy of the GCC Runtime Library Exception along with this program; 24 1.1 mrg see the files COPYING3 and COPYING.RUNTIME respectively. If not, see 25 1.1 mrg <http://www.gnu.org/licenses/>. */ 26 1.1 mrg 27 1.1 mrg 28 1.1 mrg #define IN_GCOV_TOOL 1 29 1.1 mrg 30 1.1 mrg #include "libgcov.h" 31 1.1 mrg #include "intl.h" 32 1.1 mrg #include "diagnostic.h" 33 1.1 mrg #include "version.h" 34 1.1 mrg #include "demangle.h" 35 1.1.1.7 mrg #include "gcov-io.h" 36 1.1 mrg 37 1.1 mrg /* Borrowed from basic-block.h. */ 38 1.1 mrg #define RDIV(X,Y) (((X) + (Y) / 2) / (Y)) 39 1.1 mrg 40 1.1 mrg extern gcov_position_t gcov_position(); 41 1.1 mrg extern int gcov_is_error(); 42 1.1 mrg 43 1.1 mrg /* Verbose mode for debug. */ 44 1.1 mrg static int verbose; 45 1.1 mrg 46 1.1 mrg /* Set verbose flag. */ 47 1.1 mrg void gcov_set_verbose (void) 48 1.1 mrg { 49 1.1 mrg verbose = 1; 50 1.1 mrg } 51 1.1 mrg 52 1.1 mrg /* The following part is to read Gcda and reconstruct GCOV_INFO. */ 53 1.1 mrg 54 1.1 mrg #include "obstack.h" 55 1.1 mrg #include <unistd.h> 56 1.1 mrg #ifdef HAVE_FTW_H 57 1.1 mrg #include <ftw.h> 58 1.1 mrg #endif 59 1.1 mrg 60 1.1 mrg static void tag_function (unsigned, unsigned); 61 1.1 mrg static void tag_blocks (unsigned, unsigned); 62 1.1 mrg static void tag_arcs (unsigned, unsigned); 63 1.1 mrg static void tag_lines (unsigned, unsigned); 64 1.1 mrg static void tag_counters (unsigned, unsigned); 65 1.1 mrg static void tag_summary (unsigned, unsigned); 66 1.1 mrg 67 1.1 mrg /* The gcov_info for the first module. */ 68 1.1 mrg static struct gcov_info *curr_gcov_info; 69 1.1 mrg /* The gcov_info being processed. */ 70 1.1 mrg static struct gcov_info *gcov_info_head; 71 1.1 mrg /* This variable contains all the functions in current module. */ 72 1.1 mrg static struct obstack fn_info; 73 1.1 mrg /* The function being processed. */ 74 1.1 mrg static struct gcov_fn_info *curr_fn_info; 75 1.1 mrg /* The number of functions seen so far. */ 76 1.1 mrg static unsigned num_fn_info; 77 1.1 mrg /* This variable contains all the counters for current module. */ 78 1.1 mrg static int k_ctrs_mask[GCOV_COUNTERS]; 79 1.1 mrg /* The kind of counters that have been seen. */ 80 1.1 mrg static struct gcov_ctr_info k_ctrs[GCOV_COUNTERS]; 81 1.1 mrg /* Number of kind of counters that have been seen. */ 82 1.1 mrg static int k_ctrs_types; 83 1.1.1.7 mrg /* The object summary being processed. */ 84 1.1.1.7 mrg static struct gcov_summary *curr_object_summary; 85 1.1 mrg 86 1.1 mrg /* Merge functions for counters. */ 87 1.1 mrg #define DEF_GCOV_COUNTER(COUNTER, NAME, FN_TYPE) __gcov_merge ## FN_TYPE, 88 1.1 mrg static gcov_merge_fn ctr_merge_functions[GCOV_COUNTERS] = { 89 1.1 mrg #include "gcov-counter.def" 90 1.1 mrg }; 91 1.1 mrg #undef DEF_GCOV_COUNTER 92 1.1 mrg 93 1.1 mrg /* Set the ctrs field in gcov_fn_info object FN_INFO. */ 94 1.1 mrg 95 1.1 mrg static void 96 1.1 mrg set_fn_ctrs (struct gcov_fn_info *fn_info) 97 1.1 mrg { 98 1.1 mrg int j = 0, i; 99 1.1 mrg 100 1.1 mrg for (i = 0; i < GCOV_COUNTERS; i++) 101 1.1 mrg { 102 1.1 mrg if (k_ctrs_mask[i] == 0) 103 1.1 mrg continue; 104 1.1 mrg fn_info->ctrs[j].num = k_ctrs[i].num; 105 1.1 mrg fn_info->ctrs[j].values = k_ctrs[i].values; 106 1.1 mrg j++; 107 1.1 mrg } 108 1.1 mrg if (k_ctrs_types == 0) 109 1.1 mrg k_ctrs_types = j; 110 1.1 mrg else 111 1.1 mrg gcc_assert (j == k_ctrs_types); 112 1.1 mrg } 113 1.1 mrg 114 1.1 mrg /* For each tag in gcda file, we have an entry here. 115 1.1 mrg TAG is the tag value; NAME is the tag name; and 116 1.1 mrg PROC is the handler function. */ 117 1.1 mrg 118 1.1 mrg typedef struct tag_format 119 1.1 mrg { 120 1.1 mrg unsigned tag; 121 1.1 mrg char const *name; 122 1.1 mrg void (*proc) (unsigned, unsigned); 123 1.1 mrg } tag_format_t; 124 1.1 mrg 125 1.1 mrg /* Handler table for various Tags. */ 126 1.1 mrg 127 1.1 mrg static const tag_format_t tag_table[] = 128 1.1 mrg { 129 1.1 mrg {0, "NOP", NULL}, 130 1.1 mrg {0, "UNKNOWN", NULL}, 131 1.1 mrg {0, "COUNTERS", tag_counters}, 132 1.1 mrg {GCOV_TAG_FUNCTION, "FUNCTION", tag_function}, 133 1.1 mrg {GCOV_TAG_BLOCKS, "BLOCKS", tag_blocks}, 134 1.1 mrg {GCOV_TAG_ARCS, "ARCS", tag_arcs}, 135 1.1 mrg {GCOV_TAG_LINES, "LINES", tag_lines}, 136 1.1 mrg {GCOV_TAG_OBJECT_SUMMARY, "OBJECT_SUMMARY", tag_summary}, 137 1.1 mrg {0, NULL, NULL} 138 1.1 mrg }; 139 1.1 mrg 140 1.1 mrg /* Handler for reading function tag. */ 141 1.1 mrg 142 1.1 mrg static void 143 1.1 mrg tag_function (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED) 144 1.1 mrg { 145 1.1 mrg int i; 146 1.1 mrg 147 1.1 mrg /* write out previous fn_info. */ 148 1.1 mrg if (num_fn_info) 149 1.1 mrg { 150 1.1 mrg set_fn_ctrs (curr_fn_info); 151 1.1 mrg obstack_ptr_grow (&fn_info, curr_fn_info); 152 1.1 mrg } 153 1.1 mrg 154 1.1 mrg /* Here we over allocate a bit, using GCOV_COUNTERS instead of the actual active 155 1.1 mrg counter types. */ 156 1.1 mrg curr_fn_info = (struct gcov_fn_info *) xcalloc (sizeof (struct gcov_fn_info) 157 1.1 mrg + GCOV_COUNTERS * sizeof (struct gcov_ctr_info), 1); 158 1.1 mrg 159 1.1 mrg for (i = 0; i < GCOV_COUNTERS; i++) 160 1.1 mrg k_ctrs[i].num = 0; 161 1.1 mrg k_ctrs_types = 0; 162 1.1 mrg 163 1.1 mrg curr_fn_info->key = curr_gcov_info; 164 1.1 mrg curr_fn_info->ident = gcov_read_unsigned (); 165 1.1 mrg curr_fn_info->lineno_checksum = gcov_read_unsigned (); 166 1.1 mrg curr_fn_info->cfg_checksum = gcov_read_unsigned (); 167 1.1 mrg num_fn_info++; 168 1.1 mrg 169 1.1 mrg if (verbose) 170 1.1 mrg fnotice (stdout, "tag one function id=%d\n", curr_fn_info->ident); 171 1.1 mrg } 172 1.1 mrg 173 1.1 mrg /* Handler for reading block tag. */ 174 1.1 mrg 175 1.1 mrg static void 176 1.1 mrg tag_blocks (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED) 177 1.1 mrg { 178 1.1 mrg /* TBD: gcov-tool currently does not handle gcno files. Assert here. */ 179 1.1 mrg gcc_unreachable (); 180 1.1 mrg } 181 1.1 mrg 182 1.1 mrg /* Handler for reading flow arc tag. */ 183 1.1 mrg 184 1.1 mrg static void 185 1.1 mrg tag_arcs (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED) 186 1.1 mrg { 187 1.1 mrg /* TBD: gcov-tool currently does not handle gcno files. Assert here. */ 188 1.1 mrg gcc_unreachable (); 189 1.1 mrg } 190 1.1 mrg 191 1.1 mrg /* Handler for reading line tag. */ 192 1.1 mrg 193 1.1 mrg static void 194 1.1 mrg tag_lines (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED) 195 1.1 mrg { 196 1.1 mrg /* TBD: gcov-tool currently does not handle gcno files. Assert here. */ 197 1.1 mrg gcc_unreachable (); 198 1.1 mrg } 199 1.1 mrg 200 1.1 mrg /* Handler for reading counters array tag with value as TAG and length of LENGTH. */ 201 1.1 mrg 202 1.1 mrg static void 203 1.1 mrg tag_counters (unsigned tag, unsigned length) 204 1.1 mrg { 205 1.1 mrg unsigned n_counts = GCOV_TAG_COUNTER_NUM (length); 206 1.1 mrg gcov_type *values; 207 1.1 mrg unsigned ix; 208 1.1 mrg unsigned tag_ix; 209 1.1 mrg 210 1.1 mrg tag_ix = GCOV_COUNTER_FOR_TAG (tag); 211 1.1 mrg gcc_assert (tag_ix < GCOV_COUNTERS); 212 1.1 mrg k_ctrs_mask [tag_ix] = 1; 213 1.1 mrg gcc_assert (k_ctrs[tag_ix].num == 0); 214 1.1 mrg k_ctrs[tag_ix].num = n_counts; 215 1.1 mrg 216 1.1 mrg k_ctrs[tag_ix].values = values = (gcov_type *) xmalloc (n_counts * sizeof (gcov_type)); 217 1.1 mrg gcc_assert (values); 218 1.1 mrg 219 1.1 mrg for (ix = 0; ix != n_counts; ix++) 220 1.1 mrg values[ix] = gcov_read_counter (); 221 1.1 mrg } 222 1.1 mrg 223 1.1 mrg /* Handler for reading summary tag. */ 224 1.1 mrg 225 1.1 mrg static void 226 1.1 mrg tag_summary (unsigned tag ATTRIBUTE_UNUSED, unsigned length ATTRIBUTE_UNUSED) 227 1.1 mrg { 228 1.1.1.7 mrg curr_object_summary = (gcov_summary *) xcalloc (sizeof (gcov_summary), 1); 229 1.1.1.7 mrg gcov_read_summary (curr_object_summary); 230 1.1 mrg } 231 1.1 mrg 232 1.1 mrg /* This function is called at the end of reading a gcda file. 233 1.1 mrg It flushes the contents in curr_fn_info to gcov_info object OBJ_INFO. */ 234 1.1 mrg 235 1.1 mrg static void 236 1.1 mrg read_gcda_finalize (struct gcov_info *obj_info) 237 1.1 mrg { 238 1.1 mrg int i; 239 1.1 mrg 240 1.1 mrg set_fn_ctrs (curr_fn_info); 241 1.1 mrg obstack_ptr_grow (&fn_info, curr_fn_info); 242 1.1 mrg 243 1.1.1.7 mrg /* We set the following fields: merge, n_functions, functions 244 1.1.1.7 mrg and summary. */ 245 1.1 mrg obj_info->n_functions = num_fn_info; 246 1.1 mrg obj_info->functions = (const struct gcov_fn_info**) obstack_finish (&fn_info); 247 1.1 mrg 248 1.1 mrg /* wrap all the counter array. */ 249 1.1 mrg for (i=0; i< GCOV_COUNTERS; i++) 250 1.1 mrg { 251 1.1 mrg if (k_ctrs_mask[i]) 252 1.1 mrg obj_info->merge[i] = ctr_merge_functions[i]; 253 1.1 mrg } 254 1.1 mrg } 255 1.1 mrg 256 1.1 mrg /* Read the content of a gcda file FILENAME, and return a gcov_info data structure. 257 1.1 mrg Program level summary CURRENT_SUMMARY will also be updated. */ 258 1.1 mrg 259 1.1 mrg static struct gcov_info * 260 1.1 mrg read_gcda_file (const char *filename) 261 1.1 mrg { 262 1.1 mrg unsigned tags[4]; 263 1.1 mrg unsigned depth = 0; 264 1.1 mrg unsigned magic, version; 265 1.1 mrg struct gcov_info *obj_info; 266 1.1 mrg int i; 267 1.1 mrg 268 1.1 mrg for (i=0; i< GCOV_COUNTERS; i++) 269 1.1 mrg k_ctrs_mask[i] = 0; 270 1.1 mrg k_ctrs_types = 0; 271 1.1 mrg 272 1.1 mrg if (!gcov_open (filename)) 273 1.1 mrg { 274 1.1 mrg fnotice (stderr, "%s:cannot open\n", filename); 275 1.1 mrg return NULL; 276 1.1 mrg } 277 1.1 mrg 278 1.1 mrg /* Read magic. */ 279 1.1 mrg magic = gcov_read_unsigned (); 280 1.1 mrg if (magic != GCOV_DATA_MAGIC) 281 1.1 mrg { 282 1.1 mrg fnotice (stderr, "%s:not a gcov data file\n", filename); 283 1.1 mrg gcov_close (); 284 1.1 mrg return NULL; 285 1.1 mrg } 286 1.1 mrg 287 1.1 mrg /* Read version. */ 288 1.1 mrg version = gcov_read_unsigned (); 289 1.1 mrg if (version != GCOV_VERSION) 290 1.1 mrg { 291 1.1 mrg fnotice (stderr, "%s:incorrect gcov version %d vs %d \n", filename, version, GCOV_VERSION); 292 1.1 mrg gcov_close (); 293 1.1 mrg return NULL; 294 1.1 mrg } 295 1.1 mrg 296 1.1 mrg /* Instantiate a gcov_info object. */ 297 1.1 mrg curr_gcov_info = obj_info = (struct gcov_info *) xcalloc (sizeof (struct gcov_info) + 298 1.1 mrg sizeof (struct gcov_ctr_info) * GCOV_COUNTERS, 1); 299 1.1 mrg 300 1.1 mrg obj_info->version = version; 301 1.1 mrg obstack_init (&fn_info); 302 1.1 mrg num_fn_info = 0; 303 1.1 mrg curr_fn_info = 0; 304 1.1.1.7 mrg curr_object_summary = NULL; 305 1.1 mrg { 306 1.1 mrg size_t len = strlen (filename) + 1; 307 1.1 mrg char *str_dup = (char*) xmalloc (len); 308 1.1 mrg 309 1.1 mrg memcpy (str_dup, filename, len); 310 1.1 mrg obj_info->filename = str_dup; 311 1.1 mrg } 312 1.1 mrg 313 1.1 mrg /* Read stamp. */ 314 1.1 mrg obj_info->stamp = gcov_read_unsigned (); 315 1.1 mrg 316 1.1 mrg while (1) 317 1.1 mrg { 318 1.1 mrg gcov_position_t base; 319 1.1 mrg unsigned tag, length; 320 1.1 mrg tag_format_t const *format; 321 1.1 mrg unsigned tag_depth; 322 1.1 mrg int error; 323 1.1 mrg unsigned mask; 324 1.1 mrg 325 1.1 mrg tag = gcov_read_unsigned (); 326 1.1 mrg if (!tag) 327 1.1 mrg break; 328 1.1 mrg length = gcov_read_unsigned (); 329 1.1 mrg base = gcov_position (); 330 1.1 mrg mask = GCOV_TAG_MASK (tag) >> 1; 331 1.1 mrg for (tag_depth = 4; mask; mask >>= 8) 332 1.1 mrg { 333 1.1 mrg if (((mask & 0xff) != 0xff)) 334 1.1 mrg { 335 1.1 mrg warning (0, "%s:tag `%x' is invalid\n", filename, tag); 336 1.1 mrg break; 337 1.1 mrg } 338 1.1 mrg tag_depth--; 339 1.1 mrg } 340 1.1 mrg for (format = tag_table; format->name; format++) 341 1.1 mrg if (format->tag == tag) 342 1.1 mrg goto found; 343 1.1 mrg format = &tag_table[GCOV_TAG_IS_COUNTER (tag) ? 2 : 1]; 344 1.1 mrg found:; 345 1.1 mrg if (tag) 346 1.1 mrg { 347 1.1 mrg if (depth && depth < tag_depth) 348 1.1 mrg { 349 1.1 mrg if (!GCOV_TAG_IS_SUBTAG (tags[depth - 1], tag)) 350 1.1 mrg warning (0, "%s:tag `%x' is incorrectly nested\n", 351 1.1 mrg filename, tag); 352 1.1 mrg } 353 1.1 mrg depth = tag_depth; 354 1.1 mrg tags[depth - 1] = tag; 355 1.1 mrg } 356 1.1 mrg 357 1.1 mrg if (format->proc) 358 1.1 mrg { 359 1.1 mrg unsigned long actual_length; 360 1.1 mrg 361 1.1 mrg (*format->proc) (tag, length); 362 1.1 mrg 363 1.1 mrg actual_length = gcov_position () - base; 364 1.1 mrg if (actual_length > length) 365 1.1 mrg warning (0, "%s:record size mismatch %lu bytes overread\n", 366 1.1 mrg filename, actual_length - length); 367 1.1 mrg else if (length > actual_length) 368 1.1 mrg warning (0, "%s:record size mismatch %lu bytes unread\n", 369 1.1 mrg filename, length - actual_length); 370 1.1 mrg } 371 1.1 mrg 372 1.1 mrg gcov_sync (base, length); 373 1.1 mrg if ((error = gcov_is_error ())) 374 1.1 mrg { 375 1.1 mrg warning (0, error < 0 ? "%s:counter overflow at %lu\n" : 376 1.1 mrg "%s:read error at %lu\n", filename, 377 1.1 mrg (long unsigned) gcov_position ()); 378 1.1 mrg break; 379 1.1 mrg } 380 1.1 mrg } 381 1.1 mrg 382 1.1 mrg read_gcda_finalize (obj_info); 383 1.1 mrg gcov_close (); 384 1.1 mrg 385 1.1 mrg return obj_info; 386 1.1 mrg } 387 1.1 mrg 388 1.1 mrg #ifdef HAVE_FTW_H 389 1.1 mrg /* This will be called by ftw(). It opens and read a gcda file FILENAME. 390 1.1 mrg Return a non-zero value to stop the tree walk. */ 391 1.1 mrg 392 1.1 mrg static int 393 1.1 mrg ftw_read_file (const char *filename, 394 1.1 mrg const struct stat *status ATTRIBUTE_UNUSED, 395 1.1 mrg int type) 396 1.1 mrg { 397 1.1 mrg int filename_len; 398 1.1 mrg int suffix_len; 399 1.1 mrg struct gcov_info *obj_info; 400 1.1 mrg 401 1.1 mrg /* Only read regular files. */ 402 1.1 mrg if (type != FTW_F) 403 1.1 mrg return 0; 404 1.1 mrg 405 1.1 mrg filename_len = strlen (filename); 406 1.1 mrg suffix_len = strlen (GCOV_DATA_SUFFIX); 407 1.1 mrg 408 1.1 mrg if (filename_len <= suffix_len) 409 1.1 mrg return 0; 410 1.1 mrg 411 1.1 mrg if (strcmp(filename + filename_len - suffix_len, GCOV_DATA_SUFFIX)) 412 1.1 mrg return 0; 413 1.1 mrg 414 1.1 mrg if (verbose) 415 1.1 mrg fnotice (stderr, "reading file: %s\n", filename); 416 1.1 mrg 417 1.1 mrg obj_info = read_gcda_file (filename); 418 1.1 mrg if (!obj_info) 419 1.1 mrg return 0; 420 1.1 mrg 421 1.1 mrg obj_info->next = gcov_info_head; 422 1.1 mrg gcov_info_head = obj_info; 423 1.1 mrg 424 1.1 mrg return 0; 425 1.1 mrg } 426 1.1 mrg #endif 427 1.1 mrg 428 1.1 mrg /* Initializer for reading a profile dir. */ 429 1.1 mrg 430 1.1 mrg static inline void 431 1.1 mrg read_profile_dir_init (void) 432 1.1 mrg { 433 1.1 mrg gcov_info_head = 0; 434 1.1 mrg } 435 1.1 mrg 436 1.1 mrg /* Driver for read a profile directory and convert into gcov_info list in memory. 437 1.1 mrg Return NULL on error, 438 1.1 mrg Return the head of gcov_info list on success. */ 439 1.1 mrg 440 1.1 mrg struct gcov_info * 441 1.1 mrg gcov_read_profile_dir (const char* dir_name, int recompute_summary ATTRIBUTE_UNUSED) 442 1.1 mrg { 443 1.1 mrg char *pwd; 444 1.1 mrg int ret; 445 1.1 mrg 446 1.1 mrg read_profile_dir_init (); 447 1.1 mrg 448 1.1 mrg if (access (dir_name, R_OK) != 0) 449 1.1 mrg { 450 1.1 mrg fnotice (stderr, "cannot access directory %s\n", dir_name); 451 1.1 mrg return NULL; 452 1.1 mrg } 453 1.1 mrg pwd = getcwd (NULL, 0); 454 1.1 mrg gcc_assert (pwd); 455 1.1 mrg ret = chdir (dir_name); 456 1.1 mrg if (ret !=0) 457 1.1 mrg { 458 1.1 mrg fnotice (stderr, "%s is not a directory\n", dir_name); 459 1.1 mrg return NULL; 460 1.1 mrg } 461 1.1 mrg #ifdef HAVE_FTW_H 462 1.1 mrg ftw (".", ftw_read_file, 50); 463 1.1 mrg #endif 464 1.1 mrg ret = chdir (pwd); 465 1.1 mrg free (pwd); 466 1.1 mrg 467 1.1 mrg 468 1.1 mrg return gcov_info_head;; 469 1.1 mrg } 470 1.1 mrg 471 1.1 mrg /* This part of the code is to merge profile counters. These 472 1.1 mrg variables are set in merge_wrapper and to be used by 473 1.1 mrg global function gcov_read_counter_mem() and gcov_get_merge_weight. */ 474 1.1 mrg 475 1.1 mrg /* We save the counter value address to this variable. */ 476 1.1 mrg static gcov_type *gcov_value_buf; 477 1.1 mrg 478 1.1 mrg /* The number of counter values to be read by current merging. */ 479 1.1 mrg static gcov_unsigned_t gcov_value_buf_size; 480 1.1 mrg 481 1.1 mrg /* The index of counter values being read. */ 482 1.1 mrg static gcov_unsigned_t gcov_value_buf_pos; 483 1.1 mrg 484 1.1 mrg /* The weight of current merging. */ 485 1.1 mrg static unsigned gcov_merge_weight; 486 1.1 mrg 487 1.1 mrg /* Read a counter value from gcov_value_buf array. */ 488 1.1 mrg 489 1.1 mrg gcov_type 490 1.1 mrg gcov_read_counter_mem (void) 491 1.1 mrg { 492 1.1 mrg gcov_type ret; 493 1.1 mrg gcc_assert (gcov_value_buf_pos < gcov_value_buf_size); 494 1.1 mrg ret = *(gcov_value_buf + gcov_value_buf_pos); 495 1.1 mrg ++gcov_value_buf_pos; 496 1.1 mrg return ret; 497 1.1 mrg } 498 1.1 mrg 499 1.1 mrg /* Return the recorded merge weight. */ 500 1.1 mrg 501 1.1 mrg unsigned 502 1.1 mrg gcov_get_merge_weight (void) 503 1.1 mrg { 504 1.1 mrg return gcov_merge_weight; 505 1.1 mrg } 506 1.1 mrg 507 1.1 mrg /* A wrapper function for merge functions. It sets up the 508 1.1 mrg value buffer and weights and then calls the merge function. */ 509 1.1 mrg 510 1.1 mrg static void 511 1.1 mrg merge_wrapper (gcov_merge_fn f, gcov_type *v1, gcov_unsigned_t n, 512 1.1 mrg gcov_type *v2, unsigned w) 513 1.1 mrg { 514 1.1 mrg gcov_value_buf = v2; 515 1.1 mrg gcov_value_buf_pos = 0; 516 1.1 mrg gcov_value_buf_size = n; 517 1.1 mrg gcov_merge_weight = w; 518 1.1 mrg (*f) (v1, n); 519 1.1 mrg } 520 1.1 mrg 521 1.1 mrg /* Offline tool to manipulate profile data. 522 1.1 mrg This tool targets on matched profiles. But it has some tolerance on 523 1.1 mrg unmatched profiles. 524 1.1 mrg When merging p1 to p2 (p2 is the dst), 525 1.1 mrg * m.gcda in p1 but not in p2: append m.gcda to p2 with specified weight; 526 1.1 mrg emit warning 527 1.1 mrg * m.gcda in p2 but not in p1: keep m.gcda in p2 and multiply by 528 1.1 mrg specified weight; emit warning. 529 1.1 mrg * m.gcda in both p1 and p2: 530 1.1 mrg ** p1->m.gcda->f checksum matches p2->m.gcda->f: simple merge. 531 1.1 mrg ** p1->m.gcda->f checksum does not matches p2->m.gcda->f: keep 532 1.1 mrg p2->m.gcda->f and 533 1.1 mrg drop p1->m.gcda->f. A warning is emitted. */ 534 1.1 mrg 535 1.1 mrg /* Add INFO2's counter to INFO1, multiplying by weight W. */ 536 1.1 mrg 537 1.1 mrg static int 538 1.1 mrg gcov_merge (struct gcov_info *info1, struct gcov_info *info2, int w) 539 1.1 mrg { 540 1.1 mrg unsigned f_ix; 541 1.1 mrg unsigned n_functions = info1->n_functions; 542 1.1 mrg int has_mismatch = 0; 543 1.1 mrg 544 1.1 mrg gcc_assert (info2->n_functions == n_functions); 545 1.1 mrg for (f_ix = 0; f_ix < n_functions; f_ix++) 546 1.1 mrg { 547 1.1 mrg unsigned t_ix; 548 1.1 mrg const struct gcov_fn_info *gfi_ptr1 = info1->functions[f_ix]; 549 1.1 mrg const struct gcov_fn_info *gfi_ptr2 = info2->functions[f_ix]; 550 1.1 mrg const struct gcov_ctr_info *ci_ptr1, *ci_ptr2; 551 1.1 mrg 552 1.1 mrg if (!gfi_ptr1 || gfi_ptr1->key != info1) 553 1.1 mrg continue; 554 1.1 mrg if (!gfi_ptr2 || gfi_ptr2->key != info2) 555 1.1 mrg continue; 556 1.1 mrg 557 1.1 mrg if (gfi_ptr1->cfg_checksum != gfi_ptr2->cfg_checksum) 558 1.1 mrg { 559 1.1 mrg fnotice (stderr, "in %s, cfg_checksum mismatch, skipping\n", 560 1.1 mrg info1->filename); 561 1.1 mrg has_mismatch = 1; 562 1.1 mrg continue; 563 1.1 mrg } 564 1.1 mrg ci_ptr1 = gfi_ptr1->ctrs; 565 1.1 mrg ci_ptr2 = gfi_ptr2->ctrs; 566 1.1 mrg for (t_ix = 0; t_ix != GCOV_COUNTERS; t_ix++) 567 1.1 mrg { 568 1.1 mrg gcov_merge_fn merge1 = info1->merge[t_ix]; 569 1.1 mrg gcov_merge_fn merge2 = info2->merge[t_ix]; 570 1.1 mrg 571 1.1 mrg gcc_assert (merge1 == merge2); 572 1.1 mrg if (!merge1) 573 1.1 mrg continue; 574 1.1 mrg gcc_assert (ci_ptr1->num == ci_ptr2->num); 575 1.1 mrg merge_wrapper (merge1, ci_ptr1->values, ci_ptr1->num, ci_ptr2->values, w); 576 1.1 mrg ci_ptr1++; 577 1.1 mrg ci_ptr2++; 578 1.1 mrg } 579 1.1 mrg } 580 1.1 mrg 581 1.1 mrg return has_mismatch; 582 1.1 mrg } 583 1.1 mrg 584 1.1 mrg /* Find and return the match gcov_info object for INFO from ARRAY. 585 1.1 mrg SIZE is the length of ARRAY. 586 1.1 mrg Return NULL if there is no match. */ 587 1.1 mrg 588 1.1 mrg static struct gcov_info * 589 1.1 mrg find_match_gcov_info (struct gcov_info **array, int size, 590 1.1 mrg struct gcov_info *info) 591 1.1 mrg { 592 1.1 mrg struct gcov_info *gi_ptr; 593 1.1 mrg struct gcov_info *ret = NULL; 594 1.1 mrg int i; 595 1.1 mrg 596 1.1 mrg for (i = 0; i < size; i++) 597 1.1 mrg { 598 1.1 mrg gi_ptr = array[i]; 599 1.1 mrg if (gi_ptr == 0) 600 1.1 mrg continue; 601 1.1 mrg if (!strcmp (gi_ptr->filename, info->filename)) 602 1.1 mrg { 603 1.1 mrg ret = gi_ptr; 604 1.1 mrg array[i] = 0; 605 1.1 mrg break; 606 1.1 mrg } 607 1.1 mrg } 608 1.1 mrg 609 1.1 mrg if (ret && ret->n_functions != info->n_functions) 610 1.1 mrg { 611 1.1 mrg fnotice (stderr, "mismatched profiles in %s (%d functions" 612 1.1 mrg " vs %d functions)\n", 613 1.1 mrg ret->filename, 614 1.1 mrg ret->n_functions, 615 1.1 mrg info->n_functions); 616 1.1 mrg ret = NULL; 617 1.1 mrg } 618 1.1 mrg return ret; 619 1.1 mrg } 620 1.1 mrg 621 1.1 mrg /* Merge the list of gcov_info objects from SRC_PROFILE to TGT_PROFILE. 622 1.1 mrg Return 0 on success: without mismatch. 623 1.1 mrg Reutrn 1 on error. */ 624 1.1 mrg 625 1.1 mrg int 626 1.1 mrg gcov_profile_merge (struct gcov_info *tgt_profile, struct gcov_info *src_profile, 627 1.1 mrg int w1, int w2) 628 1.1 mrg { 629 1.1 mrg struct gcov_info *gi_ptr; 630 1.1 mrg struct gcov_info **tgt_infos; 631 1.1 mrg struct gcov_info *tgt_tail; 632 1.1 mrg struct gcov_info **in_src_not_tgt; 633 1.1 mrg unsigned tgt_cnt = 0, src_cnt = 0; 634 1.1 mrg unsigned unmatch_info_cnt = 0; 635 1.1 mrg unsigned int i; 636 1.1 mrg 637 1.1 mrg for (gi_ptr = tgt_profile; gi_ptr; gi_ptr = gi_ptr->next) 638 1.1 mrg tgt_cnt++; 639 1.1 mrg for (gi_ptr = src_profile; gi_ptr; gi_ptr = gi_ptr->next) 640 1.1 mrg src_cnt++; 641 1.1 mrg tgt_infos = (struct gcov_info **) xmalloc (sizeof (struct gcov_info *) 642 1.1 mrg * tgt_cnt); 643 1.1 mrg gcc_assert (tgt_infos); 644 1.1 mrg in_src_not_tgt = (struct gcov_info **) xmalloc (sizeof (struct gcov_info *) 645 1.1 mrg * src_cnt); 646 1.1 mrg gcc_assert (in_src_not_tgt); 647 1.1 mrg 648 1.1 mrg for (gi_ptr = tgt_profile, i = 0; gi_ptr; gi_ptr = gi_ptr->next, i++) 649 1.1 mrg tgt_infos[i] = gi_ptr; 650 1.1 mrg 651 1.1 mrg tgt_tail = tgt_infos[tgt_cnt - 1]; 652 1.1 mrg 653 1.1 mrg /* First pass on tgt_profile, we multiply w1 to all counters. */ 654 1.1 mrg if (w1 > 1) 655 1.1 mrg { 656 1.1 mrg for (i = 0; i < tgt_cnt; i++) 657 1.1 mrg gcov_merge (tgt_infos[i], tgt_infos[i], w1-1); 658 1.1 mrg } 659 1.1 mrg 660 1.1 mrg /* Second pass, add src_profile to the tgt_profile. */ 661 1.1 mrg for (gi_ptr = src_profile; gi_ptr; gi_ptr = gi_ptr->next) 662 1.1 mrg { 663 1.1 mrg struct gcov_info *gi_ptr1; 664 1.1 mrg 665 1.1 mrg gi_ptr1 = find_match_gcov_info (tgt_infos, tgt_cnt, gi_ptr); 666 1.1 mrg if (gi_ptr1 == NULL) 667 1.1 mrg { 668 1.1 mrg in_src_not_tgt[unmatch_info_cnt++] = gi_ptr; 669 1.1 mrg continue; 670 1.1 mrg } 671 1.1 mrg gcov_merge (gi_ptr1, gi_ptr, w2); 672 1.1 mrg } 673 1.1 mrg 674 1.1 mrg /* For modules in src but not in tgt. We adjust the counter and append. */ 675 1.1 mrg for (i = 0; i < unmatch_info_cnt; i++) 676 1.1 mrg { 677 1.1 mrg gi_ptr = in_src_not_tgt[i]; 678 1.1 mrg gcov_merge (gi_ptr, gi_ptr, w2 - 1); 679 1.1.1.3 mrg gi_ptr->next = NULL; 680 1.1 mrg tgt_tail->next = gi_ptr; 681 1.1 mrg tgt_tail = gi_ptr; 682 1.1 mrg } 683 1.1 mrg 684 1.1 mrg return 0; 685 1.1 mrg } 686 1.1 mrg 687 1.1 mrg typedef gcov_type (*counter_op_fn) (gcov_type, void*, void*); 688 1.1 mrg 689 1.1 mrg /* Performing FN upon arc counters. */ 690 1.1 mrg 691 1.1 mrg static void 692 1.1 mrg __gcov_add_counter_op (gcov_type *counters, unsigned n_counters, 693 1.1 mrg counter_op_fn fn, void *data1, void *data2) 694 1.1 mrg { 695 1.1 mrg for (; n_counters; counters++, n_counters--) 696 1.1 mrg { 697 1.1 mrg gcov_type val = *counters; 698 1.1 mrg *counters = fn(val, data1, data2); 699 1.1 mrg } 700 1.1 mrg } 701 1.1 mrg 702 1.1 mrg /* Performing FN upon ior counters. */ 703 1.1 mrg 704 1.1 mrg static void 705 1.1 mrg __gcov_ior_counter_op (gcov_type *counters ATTRIBUTE_UNUSED, 706 1.1 mrg unsigned n_counters ATTRIBUTE_UNUSED, 707 1.1 mrg counter_op_fn fn ATTRIBUTE_UNUSED, 708 1.1 mrg void *data1 ATTRIBUTE_UNUSED, 709 1.1 mrg void *data2 ATTRIBUTE_UNUSED) 710 1.1 mrg { 711 1.1 mrg /* Do nothing. */ 712 1.1 mrg } 713 1.1 mrg 714 1.1 mrg /* Performing FN upon time-profile counters. */ 715 1.1 mrg 716 1.1 mrg static void 717 1.1 mrg __gcov_time_profile_counter_op (gcov_type *counters ATTRIBUTE_UNUSED, 718 1.1 mrg unsigned n_counters ATTRIBUTE_UNUSED, 719 1.1 mrg counter_op_fn fn ATTRIBUTE_UNUSED, 720 1.1 mrg void *data1 ATTRIBUTE_UNUSED, 721 1.1 mrg void *data2 ATTRIBUTE_UNUSED) 722 1.1 mrg { 723 1.1 mrg /* Do nothing. */ 724 1.1 mrg } 725 1.1 mrg 726 1.1 mrg /* Performing FN upon single counters. */ 727 1.1 mrg 728 1.1 mrg static void 729 1.1 mrg __gcov_single_counter_op (gcov_type *counters, unsigned n_counters, 730 1.1 mrg counter_op_fn fn, void *data1, void *data2) 731 1.1 mrg { 732 1.1 mrg unsigned i, n_measures; 733 1.1 mrg 734 1.1 mrg gcc_assert (!(n_counters % 3)); 735 1.1 mrg n_measures = n_counters / 3; 736 1.1 mrg for (i = 0; i < n_measures; i++, counters += 3) 737 1.1 mrg { 738 1.1 mrg counters[1] = fn (counters[1], data1, data2); 739 1.1 mrg counters[2] = fn (counters[2], data1, data2); 740 1.1 mrg } 741 1.1 mrg } 742 1.1 mrg 743 1.1 mrg /* Performing FN upon indirect-call profile counters. */ 744 1.1 mrg 745 1.1 mrg static void 746 1.1 mrg __gcov_icall_topn_counter_op (gcov_type *counters, unsigned n_counters, 747 1.1 mrg counter_op_fn fn, void *data1, void *data2) 748 1.1 mrg { 749 1.1 mrg unsigned i; 750 1.1 mrg 751 1.1 mrg gcc_assert (!(n_counters % GCOV_ICALL_TOPN_NCOUNTS)); 752 1.1 mrg for (i = 0; i < n_counters; i += GCOV_ICALL_TOPN_NCOUNTS) 753 1.1 mrg { 754 1.1 mrg unsigned j; 755 1.1 mrg gcov_type *value_array = &counters[i + 1]; 756 1.1 mrg 757 1.1 mrg for (j = 0; j < GCOV_ICALL_TOPN_NCOUNTS - 1; j += 2) 758 1.1 mrg value_array[j + 1] = fn (value_array[j + 1], data1, data2); 759 1.1 mrg } 760 1.1 mrg } 761 1.1 mrg 762 1.1 mrg /* Scaling the counter value V by multiplying *(float*) DATA1. */ 763 1.1 mrg 764 1.1 mrg static gcov_type 765 1.1 mrg fp_scale (gcov_type v, void *data1, void *data2 ATTRIBUTE_UNUSED) 766 1.1 mrg { 767 1.1 mrg float f = *(float *) data1; 768 1.1 mrg return (gcov_type) (v * f); 769 1.1 mrg } 770 1.1 mrg 771 1.1 mrg /* Scaling the counter value V by multiplying DATA2/DATA1. */ 772 1.1 mrg 773 1.1 mrg static gcov_type 774 1.1 mrg int_scale (gcov_type v, void *data1, void *data2) 775 1.1 mrg { 776 1.1 mrg int n = *(int *) data1; 777 1.1 mrg int d = *(int *) data2; 778 1.1 mrg return (gcov_type) ( RDIV (v,d) * n); 779 1.1 mrg } 780 1.1 mrg 781 1.1 mrg /* Type of function used to process counters. */ 782 1.1 mrg typedef void (*gcov_counter_fn) (gcov_type *, gcov_unsigned_t, 783 1.1 mrg counter_op_fn, void *, void *); 784 1.1 mrg 785 1.1 mrg /* Function array to process profile counters. */ 786 1.1 mrg #define DEF_GCOV_COUNTER(COUNTER, NAME, FN_TYPE) \ 787 1.1 mrg __gcov ## FN_TYPE ## _counter_op, 788 1.1 mrg static gcov_counter_fn ctr_functions[GCOV_COUNTERS] = { 789 1.1 mrg #include "gcov-counter.def" 790 1.1 mrg }; 791 1.1 mrg #undef DEF_GCOV_COUNTER 792 1.1 mrg 793 1.1 mrg /* Driver for scaling profile counters. */ 794 1.1 mrg 795 1.1 mrg int 796 1.1 mrg gcov_profile_scale (struct gcov_info *profile, float scale_factor, int n, int d) 797 1.1 mrg { 798 1.1 mrg struct gcov_info *gi_ptr; 799 1.1 mrg unsigned f_ix; 800 1.1 mrg 801 1.1 mrg if (verbose) 802 1.1 mrg fnotice (stdout, "scale_factor is %f or %d/%d\n", scale_factor, n, d); 803 1.1 mrg 804 1.1 mrg /* Scaling the counters. */ 805 1.1 mrg for (gi_ptr = profile; gi_ptr; gi_ptr = gi_ptr->next) 806 1.1 mrg for (f_ix = 0; f_ix < gi_ptr->n_functions; f_ix++) 807 1.1 mrg { 808 1.1 mrg unsigned t_ix; 809 1.1 mrg const struct gcov_fn_info *gfi_ptr = gi_ptr->functions[f_ix]; 810 1.1 mrg const struct gcov_ctr_info *ci_ptr; 811 1.1 mrg 812 1.1 mrg if (!gfi_ptr || gfi_ptr->key != gi_ptr) 813 1.1 mrg continue; 814 1.1 mrg 815 1.1 mrg ci_ptr = gfi_ptr->ctrs; 816 1.1 mrg for (t_ix = 0; t_ix != GCOV_COUNTERS; t_ix++) 817 1.1 mrg { 818 1.1 mrg gcov_merge_fn merge = gi_ptr->merge[t_ix]; 819 1.1 mrg 820 1.1 mrg if (!merge) 821 1.1 mrg continue; 822 1.1 mrg if (d == 0) 823 1.1 mrg (*ctr_functions[t_ix]) (ci_ptr->values, ci_ptr->num, 824 1.1 mrg fp_scale, &scale_factor, NULL); 825 1.1 mrg else 826 1.1 mrg (*ctr_functions[t_ix]) (ci_ptr->values, ci_ptr->num, 827 1.1 mrg int_scale, &n, &d); 828 1.1 mrg ci_ptr++; 829 1.1 mrg } 830 1.1 mrg } 831 1.1 mrg 832 1.1 mrg return 0; 833 1.1 mrg } 834 1.1 mrg 835 1.1 mrg /* Driver to normalize profile counters. */ 836 1.1 mrg 837 1.1 mrg int 838 1.1 mrg gcov_profile_normalize (struct gcov_info *profile, gcov_type max_val) 839 1.1 mrg { 840 1.1 mrg struct gcov_info *gi_ptr; 841 1.1 mrg gcov_type curr_max_val = 0; 842 1.1 mrg unsigned f_ix; 843 1.1 mrg unsigned int i; 844 1.1 mrg float scale_factor; 845 1.1 mrg 846 1.1 mrg /* Find the largest count value. */ 847 1.1 mrg for (gi_ptr = profile; gi_ptr; gi_ptr = gi_ptr->next) 848 1.1 mrg for (f_ix = 0; f_ix < gi_ptr->n_functions; f_ix++) 849 1.1 mrg { 850 1.1 mrg unsigned t_ix; 851 1.1 mrg const struct gcov_fn_info *gfi_ptr = gi_ptr->functions[f_ix]; 852 1.1 mrg const struct gcov_ctr_info *ci_ptr; 853 1.1 mrg 854 1.1 mrg if (!gfi_ptr || gfi_ptr->key != gi_ptr) 855 1.1 mrg continue; 856 1.1 mrg 857 1.1 mrg ci_ptr = gfi_ptr->ctrs; 858 1.1 mrg for (t_ix = 0; t_ix < 1; t_ix++) 859 1.1 mrg { 860 1.1 mrg for (i = 0; i < ci_ptr->num; i++) 861 1.1 mrg if (ci_ptr->values[i] > curr_max_val) 862 1.1 mrg curr_max_val = ci_ptr->values[i]; 863 1.1 mrg ci_ptr++; 864 1.1 mrg } 865 1.1 mrg } 866 1.1 mrg 867 1.1 mrg scale_factor = (float)max_val / curr_max_val; 868 1.1 mrg if (verbose) 869 1.1.1.2 mrg fnotice (stdout, "max_val is %" PRId64 "\n", curr_max_val); 870 1.1 mrg 871 1.1 mrg return gcov_profile_scale (profile, scale_factor, 0, 0); 872 1.1 mrg } 873 1.1 mrg 874 1.1 mrg /* The following variables are defined in gcc/gcov-tool.c. */ 875 1.1 mrg extern int overlap_func_level; 876 1.1 mrg extern int overlap_obj_level; 877 1.1 mrg extern int overlap_hot_only; 878 1.1 mrg extern int overlap_use_fullname; 879 1.1 mrg extern double overlap_hot_threshold; 880 1.1 mrg 881 1.1 mrg /* Compute the overlap score of two values. The score is defined as: 882 1.1 mrg min (V1/SUM_1, V2/SUM_2) */ 883 1.1 mrg 884 1.1 mrg static double 885 1.1 mrg calculate_2_entries (const unsigned long v1, const unsigned long v2, 886 1.1 mrg const double sum_1, const double sum_2) 887 1.1 mrg { 888 1.1 mrg double val1 = (sum_1 == 0.0 ? 0.0 : v1/sum_1); 889 1.1 mrg double val2 = (sum_2 == 0.0 ? 0.0 : v2/sum_2); 890 1.1 mrg 891 1.1 mrg if (val2 < val1) 892 1.1 mrg val1 = val2; 893 1.1 mrg 894 1.1 mrg return val1; 895 1.1 mrg } 896 1.1 mrg 897 1.1 mrg /* Compute the overlap score between GCOV_INFO1 and GCOV_INFO2. 898 1.1 mrg This function also updates cumulative score CUM_1_RESULT and 899 1.1 mrg CUM_2_RESULT. */ 900 1.1 mrg 901 1.1 mrg static double 902 1.1 mrg compute_one_gcov (const struct gcov_info *gcov_info1, 903 1.1 mrg const struct gcov_info *gcov_info2, 904 1.1 mrg const double sum_1, const double sum_2, 905 1.1 mrg double *cum_1_result, double *cum_2_result) 906 1.1 mrg { 907 1.1 mrg unsigned f_ix; 908 1.1 mrg double ret = 0; 909 1.1 mrg double cum_1 = 0, cum_2 = 0; 910 1.1 mrg const struct gcov_info *gcov_info = 0; 911 1.1 mrg double *cum_p; 912 1.1 mrg double sum; 913 1.1 mrg 914 1.1 mrg gcc_assert (gcov_info1 || gcov_info2); 915 1.1 mrg if (!gcov_info1) 916 1.1 mrg { 917 1.1 mrg gcov_info = gcov_info2; 918 1.1 mrg cum_p = cum_2_result; 919 1.1 mrg sum = sum_2; 920 1.1 mrg *cum_1_result = 0; 921 1.1 mrg } else 922 1.1 mrg if (!gcov_info2) 923 1.1 mrg { 924 1.1 mrg gcov_info = gcov_info1; 925 1.1 mrg cum_p = cum_1_result; 926 1.1 mrg sum = sum_1; 927 1.1 mrg *cum_2_result = 0; 928 1.1 mrg } 929 1.1 mrg 930 1.1 mrg if (gcov_info) 931 1.1 mrg { 932 1.1 mrg for (f_ix = 0; f_ix < gcov_info->n_functions; f_ix++) 933 1.1 mrg { 934 1.1 mrg const struct gcov_fn_info *gfi_ptr = gcov_info->functions[f_ix]; 935 1.1 mrg if (!gfi_ptr || gfi_ptr->key != gcov_info) 936 1.1 mrg continue; 937 1.1 mrg const struct gcov_ctr_info *ci_ptr = gfi_ptr->ctrs; 938 1.1.1.7 mrg unsigned c_num; 939 1.1.1.7 mrg for (c_num = 0; c_num < ci_ptr->num; c_num++) 940 1.1.1.7 mrg cum_1 += ci_ptr->values[c_num] / sum; 941 1.1 mrg } 942 1.1 mrg *cum_p = cum_1; 943 1.1 mrg return 0.0; 944 1.1 mrg } 945 1.1 mrg 946 1.1 mrg for (f_ix = 0; f_ix < gcov_info1->n_functions; f_ix++) 947 1.1 mrg { 948 1.1 mrg double func_cum_1 = 0.0; 949 1.1 mrg double func_cum_2 = 0.0; 950 1.1 mrg double func_val = 0.0; 951 1.1 mrg int nonzero = 0; 952 1.1 mrg int hot = 0; 953 1.1 mrg const struct gcov_fn_info *gfi_ptr1 = gcov_info1->functions[f_ix]; 954 1.1 mrg const struct gcov_fn_info *gfi_ptr2 = gcov_info2->functions[f_ix]; 955 1.1 mrg 956 1.1 mrg if (!gfi_ptr1 || gfi_ptr1->key != gcov_info1) 957 1.1 mrg continue; 958 1.1 mrg if (!gfi_ptr2 || gfi_ptr2->key != gcov_info2) 959 1.1 mrg continue; 960 1.1 mrg 961 1.1 mrg const struct gcov_ctr_info *ci_ptr1 = gfi_ptr1->ctrs; 962 1.1 mrg const struct gcov_ctr_info *ci_ptr2 = gfi_ptr2->ctrs; 963 1.1.1.7 mrg unsigned c_num; 964 1.1.1.7 mrg for (c_num = 0; c_num < ci_ptr1->num; c_num++) 965 1.1.1.7 mrg { 966 1.1.1.7 mrg if (ci_ptr1->values[c_num] | ci_ptr2->values[c_num]) 967 1.1.1.7 mrg { 968 1.1.1.7 mrg func_val += calculate_2_entries (ci_ptr1->values[c_num], 969 1.1.1.7 mrg ci_ptr2->values[c_num], 970 1.1.1.7 mrg sum_1, sum_2); 971 1.1.1.7 mrg 972 1.1.1.7 mrg func_cum_1 += ci_ptr1->values[c_num] / sum_1; 973 1.1.1.7 mrg func_cum_2 += ci_ptr2->values[c_num] / sum_2; 974 1.1.1.7 mrg nonzero = 1; 975 1.1.1.7 mrg if (ci_ptr1->values[c_num] / sum_1 >= overlap_hot_threshold 976 1.1.1.7 mrg || ci_ptr2->values[c_num] / sum_2 >= overlap_hot_threshold) 977 1.1.1.7 mrg hot = 1; 978 1.1.1.7 mrg } 979 1.1.1.7 mrg } 980 1.1 mrg 981 1.1 mrg ret += func_val; 982 1.1 mrg cum_1 += func_cum_1; 983 1.1 mrg cum_2 += func_cum_2; 984 1.1 mrg if (overlap_func_level && nonzero && (!overlap_hot_only || hot)) 985 1.1 mrg { 986 1.1 mrg printf(" \tfunc_id=%10d \toverlap =%6.5f%% (%5.5f%% %5.5f%%)\n", 987 1.1 mrg gfi_ptr1->ident, func_val*100, func_cum_1*100, func_cum_2*100); 988 1.1 mrg } 989 1.1 mrg } 990 1.1 mrg *cum_1_result = cum_1; 991 1.1 mrg *cum_2_result = cum_2; 992 1.1 mrg return ret; 993 1.1 mrg } 994 1.1 mrg 995 1.1 mrg /* Test if all counter values in this GCOV_INFO are cold. 996 1.1 mrg "Cold" is defined as the counter value being less than 997 1.1 mrg or equal to THRESHOLD. */ 998 1.1 mrg 999 1.1 mrg static bool 1000 1.1 mrg gcov_info_count_all_cold (const struct gcov_info *gcov_info, 1001 1.1 mrg gcov_type threshold) 1002 1.1 mrg { 1003 1.1 mrg unsigned f_ix; 1004 1.1 mrg 1005 1.1 mrg for (f_ix = 0; f_ix < gcov_info->n_functions; f_ix++) 1006 1.1 mrg { 1007 1.1 mrg const struct gcov_fn_info *gfi_ptr = gcov_info->functions[f_ix]; 1008 1.1 mrg 1009 1.1 mrg if (!gfi_ptr || gfi_ptr->key != gcov_info) 1010 1.1 mrg continue; 1011 1.1 mrg const struct gcov_ctr_info *ci_ptr = gfi_ptr->ctrs; 1012 1.1.1.7 mrg for (unsigned c_num = 0; c_num < ci_ptr->num; c_num++) 1013 1.1.1.7 mrg if (ci_ptr->values[c_num] > threshold) 1014 1.1.1.7 mrg return false; 1015 1.1 mrg } 1016 1.1 mrg 1017 1.1 mrg return true; 1018 1.1 mrg } 1019 1.1 mrg 1020 1.1 mrg /* Test if all counter values in this GCOV_INFO are 0. */ 1021 1.1 mrg 1022 1.1 mrg static bool 1023 1.1 mrg gcov_info_count_all_zero (const struct gcov_info *gcov_info) 1024 1.1 mrg { 1025 1.1 mrg return gcov_info_count_all_cold (gcov_info, 0); 1026 1.1 mrg } 1027 1.1 mrg 1028 1.1 mrg /* A pair of matched GCOV_INFO. 1029 1.1 mrg The flag is a bitvector: 1030 1.1 mrg b0: obj1's all counts are 0; 1031 1.1 mrg b1: obj1's all counts are cold (but no 0); 1032 1.1 mrg b2: obj1 is hot; 1033 1.1 mrg b3: no obj1 to match obj2; 1034 1.1 mrg b4: obj2's all counts are 0; 1035 1.1 mrg b5: obj2's all counts are cold (but no 0); 1036 1.1 mrg b6: obj2 is hot; 1037 1.1 mrg b7: no obj2 to match obj1; 1038 1.1 mrg */ 1039 1.1 mrg struct overlap_t { 1040 1.1 mrg const struct gcov_info *obj1; 1041 1.1 mrg const struct gcov_info *obj2; 1042 1.1 mrg char flag; 1043 1.1 mrg }; 1044 1.1 mrg 1045 1.1 mrg #define FLAG_BOTH_ZERO(flag) ((flag & 0x1) && (flag & 0x10)) 1046 1.1 mrg #define FLAG_BOTH_COLD(flag) ((flag & 0x2) && (flag & 0x20)) 1047 1.1 mrg #define FLAG_ONE_HOT(flag) ((flag & 0x4) || (flag & 0x40)) 1048 1.1 mrg 1049 1.1 mrg /* Cumlative overlap dscore for profile1 and profile2. */ 1050 1.1 mrg static double overlap_sum_1, overlap_sum_2; 1051 1.1 mrg 1052 1.1 mrg /* The number of gcda files in the profiles. */ 1053 1.1 mrg static unsigned gcda_files[2]; 1054 1.1 mrg 1055 1.1 mrg /* The number of unique gcda files in the profiles 1056 1.1 mrg (not existing in the other profile). */ 1057 1.1 mrg static unsigned unique_gcda_files[2]; 1058 1.1 mrg 1059 1.1 mrg /* The number of gcda files that all counter values are 0. */ 1060 1.1 mrg static unsigned zero_gcda_files[2]; 1061 1.1 mrg 1062 1.1 mrg /* The number of gcda files that all counter values are cold (but not 0). */ 1063 1.1 mrg static unsigned cold_gcda_files[2]; 1064 1.1 mrg 1065 1.1 mrg /* The number of gcda files that includes hot counter values. */ 1066 1.1 mrg static unsigned hot_gcda_files[2]; 1067 1.1 mrg 1068 1.1 mrg /* The number of gcda files with hot count value in either profiles. */ 1069 1.1 mrg static unsigned both_hot_cnt; 1070 1.1 mrg 1071 1.1 mrg /* The number of gcda files with all counts cold (but not 0) in 1072 1.1 mrg both profiles. */ 1073 1.1 mrg static unsigned both_cold_cnt; 1074 1.1 mrg 1075 1.1 mrg /* The number of gcda files with all counts 0 in both profiles. */ 1076 1.1 mrg static unsigned both_zero_cnt; 1077 1.1 mrg 1078 1.1 mrg /* Extract the basename of the filename NAME. */ 1079 1.1 mrg 1080 1.1 mrg static char * 1081 1.1 mrg extract_file_basename (const char *name) 1082 1.1 mrg { 1083 1.1 mrg char *str; 1084 1.1 mrg int len = 0; 1085 1.1 mrg char *path = xstrdup (name); 1086 1.1 mrg char sep_str[2]; 1087 1.1 mrg 1088 1.1 mrg sep_str[0] = DIR_SEPARATOR; 1089 1.1 mrg sep_str[1] = 0; 1090 1.1 mrg str = strstr(path, sep_str); 1091 1.1 mrg do{ 1092 1.1 mrg len = strlen(str) + 1; 1093 1.1 mrg path = &path[strlen(path) - len + 2]; 1094 1.1 mrg str = strstr(path, sep_str); 1095 1.1 mrg } while(str); 1096 1.1 mrg 1097 1.1 mrg return path; 1098 1.1 mrg } 1099 1.1 mrg 1100 1.1 mrg /* Utility function to get the filename. */ 1101 1.1 mrg 1102 1.1 mrg static const char * 1103 1.1 mrg get_file_basename (const char *name) 1104 1.1 mrg { 1105 1.1 mrg if (overlap_use_fullname) 1106 1.1 mrg return name; 1107 1.1 mrg return extract_file_basename (name); 1108 1.1 mrg } 1109 1.1 mrg 1110 1.1 mrg /* A utility function to set the flag for the gcda files. */ 1111 1.1 mrg 1112 1.1 mrg static void 1113 1.1 mrg set_flag (struct overlap_t *e) 1114 1.1 mrg { 1115 1.1 mrg char flag = 0; 1116 1.1 mrg 1117 1.1 mrg if (!e->obj1) 1118 1.1 mrg { 1119 1.1 mrg unique_gcda_files[1]++; 1120 1.1 mrg flag = 0x8; 1121 1.1 mrg } 1122 1.1 mrg else 1123 1.1 mrg { 1124 1.1 mrg gcda_files[0]++; 1125 1.1 mrg if (gcov_info_count_all_zero (e->obj1)) 1126 1.1 mrg { 1127 1.1 mrg zero_gcda_files[0]++; 1128 1.1 mrg flag = 0x1; 1129 1.1 mrg } 1130 1.1 mrg else 1131 1.1 mrg if (gcov_info_count_all_cold (e->obj1, overlap_sum_1 1132 1.1 mrg * overlap_hot_threshold)) 1133 1.1 mrg { 1134 1.1 mrg cold_gcda_files[0]++; 1135 1.1 mrg flag = 0x2; 1136 1.1 mrg } 1137 1.1 mrg else 1138 1.1 mrg { 1139 1.1 mrg hot_gcda_files[0]++; 1140 1.1 mrg flag = 0x4; 1141 1.1 mrg } 1142 1.1 mrg } 1143 1.1 mrg 1144 1.1 mrg if (!e->obj2) 1145 1.1 mrg { 1146 1.1 mrg unique_gcda_files[0]++; 1147 1.1 mrg flag |= (0x8 << 4); 1148 1.1 mrg } 1149 1.1 mrg else 1150 1.1 mrg { 1151 1.1 mrg gcda_files[1]++; 1152 1.1 mrg if (gcov_info_count_all_zero (e->obj2)) 1153 1.1 mrg { 1154 1.1 mrg zero_gcda_files[1]++; 1155 1.1 mrg flag |= (0x1 << 4); 1156 1.1 mrg } 1157 1.1 mrg else 1158 1.1 mrg if (gcov_info_count_all_cold (e->obj2, overlap_sum_2 1159 1.1 mrg * overlap_hot_threshold)) 1160 1.1 mrg { 1161 1.1 mrg cold_gcda_files[1]++; 1162 1.1 mrg flag |= (0x2 << 4); 1163 1.1 mrg } 1164 1.1 mrg else 1165 1.1 mrg { 1166 1.1 mrg hot_gcda_files[1]++; 1167 1.1 mrg flag |= (0x4 << 4); 1168 1.1 mrg } 1169 1.1 mrg } 1170 1.1 mrg 1171 1.1 mrg gcc_assert (flag); 1172 1.1 mrg e->flag = flag; 1173 1.1 mrg } 1174 1.1 mrg 1175 1.1 mrg /* Test if INFO1 and INFO2 are from the matched source file. 1176 1.1 mrg Return 1 if they match; return 0 otherwise. */ 1177 1.1 mrg 1178 1.1 mrg static int 1179 1.1 mrg matched_gcov_info (const struct gcov_info *info1, const struct gcov_info *info2) 1180 1.1 mrg { 1181 1.1 mrg /* For FDO, we have to match the name. This can be expensive. 1182 1.1 mrg Maybe we should use hash here. */ 1183 1.1 mrg if (strcmp (info1->filename, info2->filename)) 1184 1.1 mrg return 0; 1185 1.1 mrg 1186 1.1 mrg if (info1->n_functions != info2->n_functions) 1187 1.1 mrg { 1188 1.1 mrg fnotice (stderr, "mismatched profiles in %s (%d functions" 1189 1.1 mrg " vs %d functions)\n", 1190 1.1 mrg info1->filename, 1191 1.1 mrg info1->n_functions, 1192 1.1 mrg info2->n_functions); 1193 1.1 mrg return 0; 1194 1.1 mrg } 1195 1.1 mrg return 1; 1196 1.1 mrg } 1197 1.1 mrg 1198 1.1 mrg /* Compute the overlap score of two profiles with the head of GCOV_LIST1 and 1199 1.1 mrg GCOV_LIST1. Return a number ranging from [0.0, 1.0], with 0.0 meaning no 1200 1.1 mrg match and 1.0 meaning a perfect match. */ 1201 1.1 mrg 1202 1.1 mrg static double 1203 1.1 mrg calculate_overlap (struct gcov_info *gcov_list1, 1204 1.1 mrg struct gcov_info *gcov_list2) 1205 1.1 mrg { 1206 1.1 mrg unsigned list1_cnt = 0, list2_cnt= 0, all_cnt; 1207 1.1 mrg unsigned int i, j; 1208 1.1 mrg const struct gcov_info *gi_ptr; 1209 1.1 mrg struct overlap_t *all_infos; 1210 1.1 mrg 1211 1.1 mrg for (gi_ptr = gcov_list1; gi_ptr; gi_ptr = gi_ptr->next) 1212 1.1 mrg list1_cnt++; 1213 1.1 mrg for (gi_ptr = gcov_list2; gi_ptr; gi_ptr = gi_ptr->next) 1214 1.1 mrg list2_cnt++; 1215 1.1 mrg all_cnt = list1_cnt + list2_cnt; 1216 1.1 mrg all_infos = (struct overlap_t *) xmalloc (sizeof (struct overlap_t) 1217 1.1 mrg * all_cnt * 2); 1218 1.1 mrg gcc_assert (all_infos); 1219 1.1 mrg 1220 1.1 mrg i = 0; 1221 1.1 mrg for (gi_ptr = gcov_list1; gi_ptr; gi_ptr = gi_ptr->next, i++) 1222 1.1 mrg { 1223 1.1 mrg all_infos[i].obj1 = gi_ptr; 1224 1.1 mrg all_infos[i].obj2 = 0; 1225 1.1 mrg } 1226 1.1 mrg 1227 1.1 mrg for (gi_ptr = gcov_list2; gi_ptr; gi_ptr = gi_ptr->next, i++) 1228 1.1 mrg { 1229 1.1 mrg all_infos[i].obj1 = 0; 1230 1.1 mrg all_infos[i].obj2 = gi_ptr; 1231 1.1 mrg } 1232 1.1 mrg 1233 1.1 mrg for (i = list1_cnt; i < all_cnt; i++) 1234 1.1 mrg { 1235 1.1 mrg if (all_infos[i].obj2 == 0) 1236 1.1 mrg continue; 1237 1.1 mrg for (j = 0; j < list1_cnt; j++) 1238 1.1 mrg { 1239 1.1 mrg if (all_infos[j].obj2 != 0) 1240 1.1 mrg continue; 1241 1.1 mrg if (matched_gcov_info (all_infos[i].obj2, all_infos[j].obj1)) 1242 1.1 mrg { 1243 1.1 mrg all_infos[j].obj2 = all_infos[i].obj2; 1244 1.1 mrg all_infos[i].obj2 = 0; 1245 1.1 mrg break; 1246 1.1 mrg } 1247 1.1 mrg } 1248 1.1 mrg } 1249 1.1 mrg 1250 1.1 mrg for (i = 0; i < all_cnt; i++) 1251 1.1 mrg if (all_infos[i].obj1 || all_infos[i].obj2) 1252 1.1 mrg { 1253 1.1 mrg set_flag (all_infos + i); 1254 1.1 mrg if (FLAG_ONE_HOT (all_infos[i].flag)) 1255 1.1 mrg both_hot_cnt++; 1256 1.1 mrg if (FLAG_BOTH_COLD(all_infos[i].flag)) 1257 1.1 mrg both_cold_cnt++; 1258 1.1 mrg if (FLAG_BOTH_ZERO(all_infos[i].flag)) 1259 1.1 mrg both_zero_cnt++; 1260 1.1 mrg } 1261 1.1 mrg 1262 1.1 mrg double prg_val = 0; 1263 1.1 mrg double sum_val = 0; 1264 1.1 mrg double sum_cum_1 = 0; 1265 1.1 mrg double sum_cum_2 = 0; 1266 1.1 mrg 1267 1.1 mrg for (i = 0; i < all_cnt; i++) 1268 1.1 mrg { 1269 1.1 mrg double val; 1270 1.1 mrg double cum_1, cum_2; 1271 1.1 mrg const char *filename; 1272 1.1 mrg 1273 1.1 mrg if (all_infos[i].obj1 == 0 && all_infos[i].obj2 == 0) 1274 1.1 mrg continue; 1275 1.1 mrg if (FLAG_BOTH_ZERO (all_infos[i].flag)) 1276 1.1 mrg continue; 1277 1.1 mrg 1278 1.1 mrg if (all_infos[i].obj1) 1279 1.1 mrg filename = get_file_basename (all_infos[i].obj1->filename); 1280 1.1 mrg else 1281 1.1 mrg filename = get_file_basename (all_infos[i].obj2->filename); 1282 1.1 mrg 1283 1.1 mrg if (overlap_func_level) 1284 1.1 mrg printf("\n processing %36s:\n", filename); 1285 1.1 mrg 1286 1.1 mrg val = compute_one_gcov (all_infos[i].obj1, all_infos[i].obj2, 1287 1.1 mrg overlap_sum_1, overlap_sum_2, &cum_1, &cum_2); 1288 1.1 mrg 1289 1.1 mrg if (overlap_obj_level && (!overlap_hot_only || FLAG_ONE_HOT (all_infos[i].flag))) 1290 1.1 mrg { 1291 1.1 mrg printf(" obj=%36s overlap = %6.2f%% (%5.2f%% %5.2f%%)\n", 1292 1.1 mrg filename, val*100, cum_1*100, cum_2*100); 1293 1.1 mrg sum_val += val; 1294 1.1 mrg sum_cum_1 += cum_1; 1295 1.1 mrg sum_cum_2 += cum_2; 1296 1.1 mrg } 1297 1.1 mrg 1298 1.1 mrg prg_val += val; 1299 1.1 mrg 1300 1.1 mrg } 1301 1.1 mrg 1302 1.1 mrg if (overlap_obj_level) 1303 1.1 mrg printf(" SUM:%36s overlap = %6.2f%% (%5.2f%% %5.2f%%)\n", 1304 1.1 mrg "", sum_val*100, sum_cum_1*100, sum_cum_2*100); 1305 1.1 mrg 1306 1.1 mrg printf (" Statistics:\n" 1307 1.1 mrg " profile1_# profile2_# overlap_#\n"); 1308 1.1 mrg printf (" gcda files: %12u\t%12u\t%12u\n", gcda_files[0], gcda_files[1], 1309 1.1.1.2 mrg gcda_files[0]-unique_gcda_files[0]); 1310 1.1 mrg printf (" unique files: %12u\t%12u\n", unique_gcda_files[0], 1311 1.1.1.2 mrg unique_gcda_files[1]); 1312 1.1 mrg printf (" hot files: %12u\t%12u\t%12u\n", hot_gcda_files[0], 1313 1.1.1.2 mrg hot_gcda_files[1], both_hot_cnt); 1314 1.1 mrg printf (" cold files: %12u\t%12u\t%12u\n", cold_gcda_files[0], 1315 1.1.1.2 mrg cold_gcda_files[1], both_cold_cnt); 1316 1.1 mrg printf (" zero files: %12u\t%12u\t%12u\n", zero_gcda_files[0], 1317 1.1.1.2 mrg zero_gcda_files[1], both_zero_cnt); 1318 1.1 mrg 1319 1.1 mrg return prg_val; 1320 1.1 mrg } 1321 1.1 mrg 1322 1.1.1.3 mrg /* Compute the overlap score of two lists of gcov_info objects PROFILE1 and 1323 1.1.1.3 mrg PROFILE2. 1324 1.1 mrg Return 0 on success: without mismatch. Reutrn 1 on error. */ 1325 1.1 mrg 1326 1.1 mrg int 1327 1.1 mrg gcov_profile_overlap (struct gcov_info *profile1, struct gcov_info *profile2) 1328 1.1 mrg { 1329 1.1 mrg double result; 1330 1.1 mrg 1331 1.1 mrg result = calculate_overlap (profile1, profile2); 1332 1.1 mrg 1333 1.1 mrg if (result > 0) 1334 1.1 mrg { 1335 1.1 mrg printf("\nProgram level overlap result is %3.2f%%\n\n", result*100); 1336 1.1 mrg return 0; 1337 1.1 mrg } 1338 1.1 mrg return 1; 1339 1.1 mrg } 1340
Indexes created Sun Mar 29 00:23:15 UTC 2026