tjh.dev / kernel
Linux kernel mirror (for testing) git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git
kernel os linux
fork atom
kernel / tools / lib / traceevent / event-parse.c
at v4.10-rc5 6837 lines 150 kB view raw
1/* 2 * Copyright (C) 2009, 2010 Red Hat Inc, Steven Rostedt <srostedt@redhat.com> 3 * 4 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 5 * This program is free software; you can redistribute it and/or 6 * modify it under the terms of the GNU Lesser General Public 7 * License as published by the Free Software Foundation; 8 * version 2.1 of the License (not later!) 9 * 10 * This program is distributed in the hope that it will be useful, 11 * but WITHOUT ANY WARRANTY; without even the implied warranty of 12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 13 * GNU Lesser General Public License for more details. 14 * 15 * You should have received a copy of the GNU Lesser General Public 16 * License along with this program; if not, see <http://www.gnu.org/licenses> 17 * 18 * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 19 * 20 * The parts for function graph printing was taken and modified from the 21 * Linux Kernel that were written by 22 * - Copyright (C) 2009 Frederic Weisbecker, 23 * Frederic Weisbecker gave his permission to relicense the code to 24 * the Lesser General Public License. 25 */ 26#include <inttypes.h> 27#include <stdio.h> 28#include <stdlib.h> 29#include <string.h> 30#include <stdarg.h> 31#include <ctype.h> 32#include <errno.h> 33#include <stdint.h> 34#include <limits.h> 35#include <linux/string.h> 36#include <linux/time64.h> 37 38#include <netinet/in.h> 39#include "event-parse.h" 40#include "event-utils.h" 41 42static const char *input_buf; 43static unsigned long long input_buf_ptr; 44static unsigned long long input_buf_siz; 45 46static int is_flag_field; 47static int is_symbolic_field; 48 49static int show_warning = 1; 50 51#define do_warning(fmt, ...) \ 52 do { \ 53 if (show_warning) \ 54 warning(fmt, ##__VA_ARGS__); \ 55 } while (0) 56 57#define do_warning_event(event, fmt, ...) \ 58 do { \ 59 if (!show_warning) \ 60 continue; \ 61 \ 62 if (event) \ 63 warning("[%s:%s] " fmt, event->system, \ 64 event->name, ##__VA_ARGS__); \ 65 else \ 66 warning(fmt, ##__VA_ARGS__); \ 67 } while (0) 68 69static void init_input_buf(const char *buf, unsigned long long size) 70{ 71 input_buf = buf; 72 input_buf_siz = size; 73 input_buf_ptr = 0; 74} 75 76const char *pevent_get_input_buf(void) 77{ 78 return input_buf; 79} 80 81unsigned long long pevent_get_input_buf_ptr(void) 82{ 83 return input_buf_ptr; 84} 85 86struct event_handler { 87 struct event_handler *next; 88 int id; 89 const char *sys_name; 90 const char *event_name; 91 pevent_event_handler_func func; 92 void *context; 93}; 94 95struct pevent_func_params { 96 struct pevent_func_params *next; 97 enum pevent_func_arg_type type; 98}; 99 100struct pevent_function_handler { 101 struct pevent_function_handler *next; 102 enum pevent_func_arg_type ret_type; 103 char *name; 104 pevent_func_handler func; 105 struct pevent_func_params *params; 106 int nr_args; 107}; 108 109static unsigned long long 110process_defined_func(struct trace_seq *s, void *data, int size, 111 struct event_format *event, struct print_arg *arg); 112 113static void free_func_handle(struct pevent_function_handler *func); 114 115/** 116 * pevent_buffer_init - init buffer for parsing 117 * @buf: buffer to parse 118 * @size: the size of the buffer 119 * 120 * For use with pevent_read_token(), this initializes the internal 121 * buffer that pevent_read_token() will parse. 122 */ 123void pevent_buffer_init(const char *buf, unsigned long long size) 124{ 125 init_input_buf(buf, size); 126} 127 128void breakpoint(void) 129{ 130 static int x; 131 x++; 132} 133 134struct print_arg *alloc_arg(void) 135{ 136 return calloc(1, sizeof(struct print_arg)); 137} 138 139struct cmdline { 140 char *comm; 141 int pid; 142}; 143 144static int cmdline_cmp(const void *a, const void *b) 145{ 146 const struct cmdline *ca = a; 147 const struct cmdline *cb = b; 148 149 if (ca->pid < cb->pid) 150 return -1; 151 if (ca->pid > cb->pid) 152 return 1; 153 154 return 0; 155} 156 157struct cmdline_list { 158 struct cmdline_list *next; 159 char *comm; 160 int pid; 161}; 162 163static int cmdline_init(struct pevent *pevent) 164{ 165 struct cmdline_list *cmdlist = pevent->cmdlist; 166 struct cmdline_list *item; 167 struct cmdline *cmdlines; 168 int i; 169 170 cmdlines = malloc(sizeof(*cmdlines) * pevent->cmdline_count); 171 if (!cmdlines) 172 return -1; 173 174 i = 0; 175 while (cmdlist) { 176 cmdlines[i].pid = cmdlist->pid; 177 cmdlines[i].comm = cmdlist->comm; 178 i++; 179 item = cmdlist; 180 cmdlist = cmdlist->next; 181 free(item); 182 } 183 184 qsort(cmdlines, pevent->cmdline_count, sizeof(*cmdlines), cmdline_cmp); 185 186 pevent->cmdlines = cmdlines; 187 pevent->cmdlist = NULL; 188 189 return 0; 190} 191 192static const char *find_cmdline(struct pevent *pevent, int pid) 193{ 194 const struct cmdline *comm; 195 struct cmdline key; 196 197 if (!pid) 198 return "<idle>"; 199 200 if (!pevent->cmdlines && cmdline_init(pevent)) 201 return "<not enough memory for cmdlines!>"; 202 203 key.pid = pid; 204 205 comm = bsearch(&key, pevent->cmdlines, pevent->cmdline_count, 206 sizeof(*pevent->cmdlines), cmdline_cmp); 207 208 if (comm) 209 return comm->comm; 210 return "<...>"; 211} 212 213/** 214 * pevent_pid_is_registered - return if a pid has a cmdline registered 215 * @pevent: handle for the pevent 216 * @pid: The pid to check if it has a cmdline registered with. 217 * 218 * Returns 1 if the pid has a cmdline mapped to it 219 * 0 otherwise. 220 */ 221int pevent_pid_is_registered(struct pevent *pevent, int pid) 222{ 223 const struct cmdline *comm; 224 struct cmdline key; 225 226 if (!pid) 227 return 1; 228 229 if (!pevent->cmdlines && cmdline_init(pevent)) 230 return 0; 231 232 key.pid = pid; 233 234 comm = bsearch(&key, pevent->cmdlines, pevent->cmdline_count, 235 sizeof(*pevent->cmdlines), cmdline_cmp); 236 237 if (comm) 238 return 1; 239 return 0; 240} 241 242/* 243 * If the command lines have been converted to an array, then 244 * we must add this pid. This is much slower than when cmdlines 245 * are added before the array is initialized. 246 */ 247static int add_new_comm(struct pevent *pevent, const char *comm, int pid) 248{ 249 struct cmdline *cmdlines = pevent->cmdlines; 250 const struct cmdline *cmdline; 251 struct cmdline key; 252 253 if (!pid) 254 return 0; 255 256 /* avoid duplicates */ 257 key.pid = pid; 258 259 cmdline = bsearch(&key, pevent->cmdlines, pevent->cmdline_count, 260 sizeof(*pevent->cmdlines), cmdline_cmp); 261 if (cmdline) { 262 errno = EEXIST; 263 return -1; 264 } 265 266 cmdlines = realloc(cmdlines, sizeof(*cmdlines) * (pevent->cmdline_count + 1)); 267 if (!cmdlines) { 268 errno = ENOMEM; 269 return -1; 270 } 271 272 cmdlines[pevent->cmdline_count].comm = strdup(comm); 273 if (!cmdlines[pevent->cmdline_count].comm) { 274 free(cmdlines); 275 errno = ENOMEM; 276 return -1; 277 } 278 279 cmdlines[pevent->cmdline_count].pid = pid; 280 281 if (cmdlines[pevent->cmdline_count].comm) 282 pevent->cmdline_count++; 283 284 qsort(cmdlines, pevent->cmdline_count, sizeof(*cmdlines), cmdline_cmp); 285 pevent->cmdlines = cmdlines; 286 287 return 0; 288} 289 290/** 291 * pevent_register_comm - register a pid / comm mapping 292 * @pevent: handle for the pevent 293 * @comm: the command line to register 294 * @pid: the pid to map the command line to 295 * 296 * This adds a mapping to search for command line names with 297 * a given pid. The comm is duplicated. 298 */ 299int pevent_register_comm(struct pevent *pevent, const char *comm, int pid) 300{ 301 struct cmdline_list *item; 302 303 if (pevent->cmdlines) 304 return add_new_comm(pevent, comm, pid); 305 306 item = malloc(sizeof(*item)); 307 if (!item) 308 return -1; 309 310 if (comm) 311 item->comm = strdup(comm); 312 else 313 item->comm = strdup("<...>"); 314 if (!item->comm) { 315 free(item); 316 return -1; 317 } 318 item->pid = pid; 319 item->next = pevent->cmdlist; 320 321 pevent->cmdlist = item; 322 pevent->cmdline_count++; 323 324 return 0; 325} 326 327int pevent_register_trace_clock(struct pevent *pevent, const char *trace_clock) 328{ 329 pevent->trace_clock = strdup(trace_clock); 330 if (!pevent->trace_clock) { 331 errno = ENOMEM; 332 return -1; 333 } 334 return 0; 335} 336 337struct func_map { 338 unsigned long long addr; 339 char *func; 340 char *mod; 341}; 342 343struct func_list { 344 struct func_list *next; 345 unsigned long long addr; 346 char *func; 347 char *mod; 348}; 349 350static int func_cmp(const void *a, const void *b) 351{ 352 const struct func_map *fa = a; 353 const struct func_map *fb = b; 354 355 if (fa->addr < fb->addr) 356 return -1; 357 if (fa->addr > fb->addr) 358 return 1; 359 360 return 0; 361} 362 363/* 364 * We are searching for a record in between, not an exact 365 * match. 366 */ 367static int func_bcmp(const void *a, const void *b) 368{ 369 const struct func_map *fa = a; 370 const struct func_map *fb = b; 371 372 if ((fa->addr == fb->addr) || 373 374 (fa->addr > fb->addr && 375 fa->addr < (fb+1)->addr)) 376 return 0; 377 378 if (fa->addr < fb->addr) 379 return -1; 380 381 return 1; 382} 383 384static int func_map_init(struct pevent *pevent) 385{ 386 struct func_list *funclist; 387 struct func_list *item; 388 struct func_map *func_map; 389 int i; 390 391 func_map = malloc(sizeof(*func_map) * (pevent->func_count + 1)); 392 if (!func_map) 393 return -1; 394 395 funclist = pevent->funclist; 396 397 i = 0; 398 while (funclist) { 399 func_map[i].func = funclist->func; 400 func_map[i].addr = funclist->addr; 401 func_map[i].mod = funclist->mod; 402 i++; 403 item = funclist; 404 funclist = funclist->next; 405 free(item); 406 } 407 408 qsort(func_map, pevent->func_count, sizeof(*func_map), func_cmp); 409 410 /* 411 * Add a special record at the end. 412 */ 413 func_map[pevent->func_count].func = NULL; 414 func_map[pevent->func_count].addr = 0; 415 func_map[pevent->func_count].mod = NULL; 416 417 pevent->func_map = func_map; 418 pevent->funclist = NULL; 419 420 return 0; 421} 422 423static struct func_map * 424__find_func(struct pevent *pevent, unsigned long long addr) 425{ 426 struct func_map *func; 427 struct func_map key; 428 429 if (!pevent->func_map) 430 func_map_init(pevent); 431 432 key.addr = addr; 433 434 func = bsearch(&key, pevent->func_map, pevent->func_count, 435 sizeof(*pevent->func_map), func_bcmp); 436 437 return func; 438} 439 440struct func_resolver { 441 pevent_func_resolver_t *func; 442 void *priv; 443 struct func_map map; 444}; 445 446/** 447 * pevent_set_function_resolver - set an alternative function resolver 448 * @pevent: handle for the pevent 449 * @resolver: function to be used 450 * @priv: resolver function private state. 451 * 452 * Some tools may have already a way to resolve kernel functions, allow them to 453 * keep using it instead of duplicating all the entries inside 454 * pevent->funclist. 455 */ 456int pevent_set_function_resolver(struct pevent *pevent, 457 pevent_func_resolver_t *func, void *priv) 458{ 459 struct func_resolver *resolver = malloc(sizeof(*resolver)); 460 461 if (resolver == NULL) 462 return -1; 463 464 resolver->func = func; 465 resolver->priv = priv; 466 467 free(pevent->func_resolver); 468 pevent->func_resolver = resolver; 469 470 return 0; 471} 472 473/** 474 * pevent_reset_function_resolver - reset alternative function resolver 475 * @pevent: handle for the pevent 476 * 477 * Stop using whatever alternative resolver was set, use the default 478 * one instead. 479 */ 480void pevent_reset_function_resolver(struct pevent *pevent) 481{ 482 free(pevent->func_resolver); 483 pevent->func_resolver = NULL; 484} 485 486static struct func_map * 487find_func(struct pevent *pevent, unsigned long long addr) 488{ 489 struct func_map *map; 490 491 if (!pevent->func_resolver) 492 return __find_func(pevent, addr); 493 494 map = &pevent->func_resolver->map; 495 map->mod = NULL; 496 map->addr = addr; 497 map->func = pevent->func_resolver->func(pevent->func_resolver->priv, 498 &map->addr, &map->mod); 499 if (map->func == NULL) 500 return NULL; 501 502 return map; 503} 504 505/** 506 * pevent_find_function - find a function by a given address 507 * @pevent: handle for the pevent 508 * @addr: the address to find the function with 509 * 510 * Returns a pointer to the function stored that has the given 511 * address. Note, the address does not have to be exact, it 512 * will select the function that would contain the address. 513 */ 514const char *pevent_find_function(struct pevent *pevent, unsigned long long addr) 515{ 516 struct func_map *map; 517 518 map = find_func(pevent, addr); 519 if (!map) 520 return NULL; 521 522 return map->func; 523} 524 525/** 526 * pevent_find_function_address - find a function address by a given address 527 * @pevent: handle for the pevent 528 * @addr: the address to find the function with 529 * 530 * Returns the address the function starts at. This can be used in 531 * conjunction with pevent_find_function to print both the function 532 * name and the function offset. 533 */ 534unsigned long long 535pevent_find_function_address(struct pevent *pevent, unsigned long long addr) 536{ 537 struct func_map *map; 538 539 map = find_func(pevent, addr); 540 if (!map) 541 return 0; 542 543 return map->addr; 544} 545 546/** 547 * pevent_register_function - register a function with a given address 548 * @pevent: handle for the pevent 549 * @function: the function name to register 550 * @addr: the address the function starts at 551 * @mod: the kernel module the function may be in (NULL for none) 552 * 553 * This registers a function name with an address and module. 554 * The @func passed in is duplicated. 555 */ 556int pevent_register_function(struct pevent *pevent, char *func, 557 unsigned long long addr, char *mod) 558{ 559 struct func_list *item = malloc(sizeof(*item)); 560 561 if (!item) 562 return -1; 563 564 item->next = pevent->funclist; 565 item->func = strdup(func); 566 if (!item->func) 567 goto out_free; 568 569 if (mod) { 570 item->mod = strdup(mod); 571 if (!item->mod) 572 goto out_free_func; 573 } else 574 item->mod = NULL; 575 item->addr = addr; 576 577 pevent->funclist = item; 578 pevent->func_count++; 579 580 return 0; 581 582out_free_func: 583 free(item->func); 584 item->func = NULL; 585out_free: 586 free(item); 587 errno = ENOMEM; 588 return -1; 589} 590 591/** 592 * pevent_print_funcs - print out the stored functions 593 * @pevent: handle for the pevent 594 * 595 * This prints out the stored functions. 596 */ 597void pevent_print_funcs(struct pevent *pevent) 598{ 599 int i; 600 601 if (!pevent->func_map) 602 func_map_init(pevent); 603 604 for (i = 0; i < (int)pevent->func_count; i++) { 605 printf("%016llx %s", 606 pevent->func_map[i].addr, 607 pevent->func_map[i].func); 608 if (pevent->func_map[i].mod) 609 printf(" [%s]\n", pevent->func_map[i].mod); 610 else 611 printf("\n"); 612 } 613} 614 615struct printk_map { 616 unsigned long long addr; 617 char *printk; 618}; 619 620struct printk_list { 621 struct printk_list *next; 622 unsigned long long addr; 623 char *printk; 624}; 625 626static int printk_cmp(const void *a, const void *b) 627{ 628 const struct printk_map *pa = a; 629 const struct printk_map *pb = b; 630 631 if (pa->addr < pb->addr) 632 return -1; 633 if (pa->addr > pb->addr) 634 return 1; 635 636 return 0; 637} 638 639static int printk_map_init(struct pevent *pevent) 640{ 641 struct printk_list *printklist; 642 struct printk_list *item; 643 struct printk_map *printk_map; 644 int i; 645 646 printk_map = malloc(sizeof(*printk_map) * (pevent->printk_count + 1)); 647 if (!printk_map) 648 return -1; 649 650 printklist = pevent->printklist; 651 652 i = 0; 653 while (printklist) { 654 printk_map[i].printk = printklist->printk; 655 printk_map[i].addr = printklist->addr; 656 i++; 657 item = printklist; 658 printklist = printklist->next; 659 free(item); 660 } 661 662 qsort(printk_map, pevent->printk_count, sizeof(*printk_map), printk_cmp); 663 664 pevent->printk_map = printk_map; 665 pevent->printklist = NULL; 666 667 return 0; 668} 669 670static struct printk_map * 671find_printk(struct pevent *pevent, unsigned long long addr) 672{ 673 struct printk_map *printk; 674 struct printk_map key; 675 676 if (!pevent->printk_map && printk_map_init(pevent)) 677 return NULL; 678 679 key.addr = addr; 680 681 printk = bsearch(&key, pevent->printk_map, pevent->printk_count, 682 sizeof(*pevent->printk_map), printk_cmp); 683 684 return printk; 685} 686 687/** 688 * pevent_register_print_string - register a string by its address 689 * @pevent: handle for the pevent 690 * @fmt: the string format to register 691 * @addr: the address the string was located at 692 * 693 * This registers a string by the address it was stored in the kernel. 694 * The @fmt passed in is duplicated. 695 */ 696int pevent_register_print_string(struct pevent *pevent, const char *fmt, 697 unsigned long long addr) 698{ 699 struct printk_list *item = malloc(sizeof(*item)); 700 char *p; 701 702 if (!item) 703 return -1; 704 705 item->next = pevent->printklist; 706 item->addr = addr; 707 708 /* Strip off quotes and '\n' from the end */ 709 if (fmt[0] == '"') 710 fmt++; 711 item->printk = strdup(fmt); 712 if (!item->printk) 713 goto out_free; 714 715 p = item->printk + strlen(item->printk) - 1; 716 if (*p == '"') 717 *p = 0; 718 719 p -= 2; 720 if (strcmp(p, "\\n") == 0) 721 *p = 0; 722 723 pevent->printklist = item; 724 pevent->printk_count++; 725 726 return 0; 727 728out_free: 729 free(item); 730 errno = ENOMEM; 731 return -1; 732} 733 734/** 735 * pevent_print_printk - print out the stored strings 736 * @pevent: handle for the pevent 737 * 738 * This prints the string formats that were stored. 739 */ 740void pevent_print_printk(struct pevent *pevent) 741{ 742 int i; 743 744 if (!pevent->printk_map) 745 printk_map_init(pevent); 746 747 for (i = 0; i < (int)pevent->printk_count; i++) { 748 printf("%016llx %s\n", 749 pevent->printk_map[i].addr, 750 pevent->printk_map[i].printk); 751 } 752} 753 754static struct event_format *alloc_event(void) 755{ 756 return calloc(1, sizeof(struct event_format)); 757} 758 759static int add_event(struct pevent *pevent, struct event_format *event) 760{ 761 int i; 762 struct event_format **events = realloc(pevent->events, sizeof(event) * 763 (pevent->nr_events + 1)); 764 if (!events) 765 return -1; 766 767 pevent->events = events; 768 769 for (i = 0; i < pevent->nr_events; i++) { 770 if (pevent->events[i]->id > event->id) 771 break; 772 } 773 if (i < pevent->nr_events) 774 memmove(&pevent->events[i + 1], 775 &pevent->events[i], 776 sizeof(event) * (pevent->nr_events - i)); 777 778 pevent->events[i] = event; 779 pevent->nr_events++; 780 781 event->pevent = pevent; 782 783 return 0; 784} 785 786static int event_item_type(enum event_type type) 787{ 788 switch (type) { 789 case EVENT_ITEM ... EVENT_SQUOTE: 790 return 1; 791 case EVENT_ERROR ... EVENT_DELIM: 792 default: 793 return 0; 794 } 795} 796 797static void free_flag_sym(struct print_flag_sym *fsym) 798{ 799 struct print_flag_sym *next; 800 801 while (fsym) { 802 next = fsym->next; 803 free(fsym->value); 804 free(fsym->str); 805 free(fsym); 806 fsym = next; 807 } 808} 809 810static void free_arg(struct print_arg *arg) 811{ 812 struct print_arg *farg; 813 814 if (!arg) 815 return; 816 817 switch (arg->type) { 818 case PRINT_ATOM: 819 free(arg->atom.atom); 820 break; 821 case PRINT_FIELD: 822 free(arg->field.name); 823 break; 824 case PRINT_FLAGS: 825 free_arg(arg->flags.field); 826 free(arg->flags.delim); 827 free_flag_sym(arg->flags.flags); 828 break; 829 case PRINT_SYMBOL: 830 free_arg(arg->symbol.field); 831 free_flag_sym(arg->symbol.symbols); 832 break; 833 case PRINT_HEX: 834 free_arg(arg->hex.field); 835 free_arg(arg->hex.size); 836 break; 837 case PRINT_INT_ARRAY: 838 free_arg(arg->int_array.field); 839 free_arg(arg->int_array.count); 840 free_arg(arg->int_array.el_size); 841 break; 842 case PRINT_TYPE: 843 free(arg->typecast.type); 844 free_arg(arg->typecast.item); 845 break; 846 case PRINT_STRING: 847 case PRINT_BSTRING: 848 free(arg->string.string); 849 break; 850 case PRINT_BITMASK: 851 free(arg->bitmask.bitmask); 852 break; 853 case PRINT_DYNAMIC_ARRAY: 854 case PRINT_DYNAMIC_ARRAY_LEN: 855 free(arg->dynarray.index); 856 break; 857 case PRINT_OP: 858 free(arg->op.op); 859 free_arg(arg->op.left); 860 free_arg(arg->op.right); 861 break; 862 case PRINT_FUNC: 863 while (arg->func.args) { 864 farg = arg->func.args; 865 arg->func.args = farg->next; 866 free_arg(farg); 867 } 868 break; 869 870 case PRINT_NULL: 871 default: 872 break; 873 } 874 875 free(arg); 876} 877 878static enum event_type get_type(int ch) 879{ 880 if (ch == '\n') 881 return EVENT_NEWLINE; 882 if (isspace(ch)) 883 return EVENT_SPACE; 884 if (isalnum(ch) || ch == '_') 885 return EVENT_ITEM; 886 if (ch == '\'') 887 return EVENT_SQUOTE; 888 if (ch == '"') 889 return EVENT_DQUOTE; 890 if (!isprint(ch)) 891 return EVENT_NONE; 892 if (ch == '(' || ch == ')' || ch == ',') 893 return EVENT_DELIM; 894 895 return EVENT_OP; 896} 897 898static int __read_char(void) 899{ 900 if (input_buf_ptr >= input_buf_siz) 901 return -1; 902 903 return input_buf[input_buf_ptr++]; 904} 905 906static int __peek_char(void) 907{ 908 if (input_buf_ptr >= input_buf_siz) 909 return -1; 910 911 return input_buf[input_buf_ptr]; 912} 913 914/** 915 * pevent_peek_char - peek at the next character that will be read 916 * 917 * Returns the next character read, or -1 if end of buffer. 918 */ 919int pevent_peek_char(void) 920{ 921 return __peek_char(); 922} 923 924static int extend_token(char **tok, char *buf, int size) 925{ 926 char *newtok = realloc(*tok, size); 927 928 if (!newtok) { 929 free(*tok); 930 *tok = NULL; 931 return -1; 932 } 933 934 if (!*tok) 935 strcpy(newtok, buf); 936 else 937 strcat(newtok, buf); 938 *tok = newtok; 939 940 return 0; 941} 942 943static enum event_type force_token(const char *str, char **tok); 944 945static enum event_type __read_token(char **tok) 946{ 947 char buf[BUFSIZ]; 948 int ch, last_ch, quote_ch, next_ch; 949 int i = 0; 950 int tok_size = 0; 951 enum event_type type; 952 953 *tok = NULL; 954 955 956 ch = __read_char(); 957 if (ch < 0) 958 return EVENT_NONE; 959 960 type = get_type(ch); 961 if (type == EVENT_NONE) 962 return type; 963 964 buf[i++] = ch; 965 966 switch (type) { 967 case EVENT_NEWLINE: 968 case EVENT_DELIM: 969 if (asprintf(tok, "%c", ch) < 0) 970 return EVENT_ERROR; 971 972 return type; 973 974 case EVENT_OP: 975 switch (ch) { 976 case '-': 977 next_ch = __peek_char(); 978 if (next_ch == '>') { 979 buf[i++] = __read_char(); 980 break; 981 } 982 /* fall through */ 983 case '+': 984 case '|': 985 case '&': 986 case '>': 987 case '<': 988 last_ch = ch; 989 ch = __peek_char(); 990 if (ch != last_ch) 991 goto test_equal; 992 buf[i++] = __read_char(); 993 switch (last_ch) { 994 case '>': 995 case '<': 996 goto test_equal; 997 default: 998 break; 999 } 1000 break; 1001 case '!': 1002 case '=': 1003 goto test_equal; 1004 default: /* what should we do instead? */ 1005 break; 1006 } 1007 buf[i] = 0; 1008 *tok = strdup(buf); 1009 return type; 1010 1011 test_equal: 1012 ch = __peek_char(); 1013 if (ch == '=') 1014 buf[i++] = __read_char(); 1015 goto out; 1016 1017 case EVENT_DQUOTE: 1018 case EVENT_SQUOTE: 1019 /* don't keep quotes */ 1020 i--; 1021 quote_ch = ch; 1022 last_ch = 0; 1023 concat: 1024 do { 1025 if (i == (BUFSIZ - 1)) { 1026 buf[i] = 0; 1027 tok_size += BUFSIZ; 1028 1029 if (extend_token(tok, buf, tok_size) < 0) 1030 return EVENT_NONE; 1031 i = 0; 1032 } 1033 last_ch = ch; 1034 ch = __read_char(); 1035 buf[i++] = ch; 1036 /* the '\' '\' will cancel itself */ 1037 if (ch == '\\' && last_ch == '\\') 1038 last_ch = 0; 1039 } while (ch != quote_ch || last_ch == '\\'); 1040 /* remove the last quote */ 1041 i--; 1042 1043 /* 1044 * For strings (double quotes) check the next token. 1045 * If it is another string, concatinate the two. 1046 */ 1047 if (type == EVENT_DQUOTE) { 1048 unsigned long long save_input_buf_ptr = input_buf_ptr; 1049 1050 do { 1051 ch = __read_char(); 1052 } while (isspace(ch)); 1053 if (ch == '"') 1054 goto concat; 1055 input_buf_ptr = save_input_buf_ptr; 1056 } 1057 1058 goto out; 1059 1060 case EVENT_ERROR ... EVENT_SPACE: 1061 case EVENT_ITEM: 1062 default: 1063 break; 1064 } 1065 1066 while (get_type(__peek_char()) == type) { 1067 if (i == (BUFSIZ - 1)) { 1068 buf[i] = 0; 1069 tok_size += BUFSIZ; 1070 1071 if (extend_token(tok, buf, tok_size) < 0) 1072 return EVENT_NONE; 1073 i = 0; 1074 } 1075 ch = __read_char(); 1076 buf[i++] = ch; 1077 } 1078 1079 out: 1080 buf[i] = 0; 1081 if (extend_token(tok, buf, tok_size + i + 1) < 0) 1082 return EVENT_NONE; 1083 1084 if (type == EVENT_ITEM) { 1085 /* 1086 * Older versions of the kernel has a bug that 1087 * creates invalid symbols and will break the mac80211 1088 * parsing. This is a work around to that bug. 1089 * 1090 * See Linux kernel commit: 1091 * 811cb50baf63461ce0bdb234927046131fc7fa8b 1092 */ 1093 if (strcmp(*tok, "LOCAL_PR_FMT") == 0) { 1094 free(*tok); 1095 *tok = NULL; 1096 return force_token("\"\%s\" ", tok); 1097 } else if (strcmp(*tok, "STA_PR_FMT") == 0) { 1098 free(*tok); 1099 *tok = NULL; 1100 return force_token("\" sta:%pM\" ", tok); 1101 } else if (strcmp(*tok, "VIF_PR_FMT") == 0) { 1102 free(*tok); 1103 *tok = NULL; 1104 return force_token("\" vif:%p(%d)\" ", tok); 1105 } 1106 } 1107 1108 return type; 1109} 1110 1111static enum event_type force_token(const char *str, char **tok) 1112{ 1113 const char *save_input_buf; 1114 unsigned long long save_input_buf_ptr; 1115 unsigned long long save_input_buf_siz; 1116 enum event_type type; 1117 1118 /* save off the current input pointers */ 1119 save_input_buf = input_buf; 1120 save_input_buf_ptr = input_buf_ptr; 1121 save_input_buf_siz = input_buf_siz; 1122 1123 init_input_buf(str, strlen(str)); 1124 1125 type = __read_token(tok); 1126 1127 /* reset back to original token */ 1128 input_buf = save_input_buf; 1129 input_buf_ptr = save_input_buf_ptr; 1130 input_buf_siz = save_input_buf_siz; 1131 1132 return type; 1133} 1134 1135static void free_token(char *tok) 1136{ 1137 if (tok) 1138 free(tok); 1139} 1140 1141static enum event_type read_token(char **tok) 1142{ 1143 enum event_type type; 1144 1145 for (;;) { 1146 type = __read_token(tok); 1147 if (type != EVENT_SPACE) 1148 return type; 1149 1150 free_token(*tok); 1151 } 1152 1153 /* not reached */ 1154 *tok = NULL; 1155 return EVENT_NONE; 1156} 1157 1158/** 1159 * pevent_read_token - access to utilites to use the pevent parser 1160 * @tok: The token to return 1161 * 1162 * This will parse tokens from the string given by 1163 * pevent_init_data(). 1164 * 1165 * Returns the token type. 1166 */ 1167enum event_type pevent_read_token(char **tok) 1168{ 1169 return read_token(tok); 1170} 1171 1172/** 1173 * pevent_free_token - free a token returned by pevent_read_token 1174 * @token: the token to free 1175 */ 1176void pevent_free_token(char *token) 1177{ 1178 free_token(token); 1179} 1180 1181/* no newline */ 1182static enum event_type read_token_item(char **tok) 1183{ 1184 enum event_type type; 1185 1186 for (;;) { 1187 type = __read_token(tok); 1188 if (type != EVENT_SPACE && type != EVENT_NEWLINE) 1189 return type; 1190 free_token(*tok); 1191 *tok = NULL; 1192 } 1193 1194 /* not reached */ 1195 *tok = NULL; 1196 return EVENT_NONE; 1197} 1198 1199static int test_type(enum event_type type, enum event_type expect) 1200{ 1201 if (type != expect) { 1202 do_warning("Error: expected type %d but read %d", 1203 expect, type); 1204 return -1; 1205 } 1206 return 0; 1207} 1208 1209static int test_type_token(enum event_type type, const char *token, 1210 enum event_type expect, const char *expect_tok) 1211{ 1212 if (type != expect) { 1213 do_warning("Error: expected type %d but read %d", 1214 expect, type); 1215 return -1; 1216 } 1217 1218 if (strcmp(token, expect_tok) != 0) { 1219 do_warning("Error: expected '%s' but read '%s'", 1220 expect_tok, token); 1221 return -1; 1222 } 1223 return 0; 1224} 1225 1226static int __read_expect_type(enum event_type expect, char **tok, int newline_ok) 1227{ 1228 enum event_type type; 1229 1230 if (newline_ok) 1231 type = read_token(tok); 1232 else 1233 type = read_token_item(tok); 1234 return test_type(type, expect); 1235} 1236 1237static int read_expect_type(enum event_type expect, char **tok) 1238{ 1239 return __read_expect_type(expect, tok, 1); 1240} 1241 1242static int __read_expected(enum event_type expect, const char *str, 1243 int newline_ok) 1244{ 1245 enum event_type type; 1246 char *token; 1247 int ret; 1248 1249 if (newline_ok) 1250 type = read_token(&token); 1251 else 1252 type = read_token_item(&token); 1253 1254 ret = test_type_token(type, token, expect, str); 1255 1256 free_token(token); 1257 1258 return ret; 1259} 1260 1261static int read_expected(enum event_type expect, const char *str) 1262{ 1263 return __read_expected(expect, str, 1); 1264} 1265 1266static int read_expected_item(enum event_type expect, const char *str) 1267{ 1268 return __read_expected(expect, str, 0); 1269} 1270 1271static char *event_read_name(void) 1272{ 1273 char *token; 1274 1275 if (read_expected(EVENT_ITEM, "name") < 0) 1276 return NULL; 1277 1278 if (read_expected(EVENT_OP, ":") < 0) 1279 return NULL; 1280 1281 if (read_expect_type(EVENT_ITEM, &token) < 0) 1282 goto fail; 1283 1284 return token; 1285 1286 fail: 1287 free_token(token); 1288 return NULL; 1289} 1290 1291static int event_read_id(void) 1292{ 1293 char *token; 1294 int id; 1295 1296 if (read_expected_item(EVENT_ITEM, "ID") < 0) 1297 return -1; 1298 1299 if (read_expected(EVENT_OP, ":") < 0) 1300 return -1; 1301 1302 if (read_expect_type(EVENT_ITEM, &token) < 0) 1303 goto fail; 1304 1305 id = strtoul(token, NULL, 0); 1306 free_token(token); 1307 return id; 1308 1309 fail: 1310 free_token(token); 1311 return -1; 1312} 1313 1314static int field_is_string(struct format_field *field) 1315{ 1316 if ((field->flags & FIELD_IS_ARRAY) && 1317 (strstr(field->type, "char") || strstr(field->type, "u8") || 1318 strstr(field->type, "s8"))) 1319 return 1; 1320 1321 return 0; 1322} 1323 1324static int field_is_dynamic(struct format_field *field) 1325{ 1326 if (strncmp(field->type, "__data_loc", 10) == 0) 1327 return 1; 1328 1329 return 0; 1330} 1331 1332static int field_is_long(struct format_field *field) 1333{ 1334 /* includes long long */ 1335 if (strstr(field->type, "long")) 1336 return 1; 1337 1338 return 0; 1339} 1340 1341static unsigned int type_size(const char *name) 1342{ 1343 /* This covers all FIELD_IS_STRING types. */ 1344 static struct { 1345 const char *type; 1346 unsigned int size; 1347 } table[] = { 1348 { "u8", 1 }, 1349 { "u16", 2 }, 1350 { "u32", 4 }, 1351 { "u64", 8 }, 1352 { "s8", 1 }, 1353 { "s16", 2 }, 1354 { "s32", 4 }, 1355 { "s64", 8 }, 1356 { "char", 1 }, 1357 { }, 1358 }; 1359 int i; 1360 1361 for (i = 0; table[i].type; i++) { 1362 if (!strcmp(table[i].type, name)) 1363 return table[i].size; 1364 } 1365 1366 return 0; 1367} 1368 1369static int event_read_fields(struct event_format *event, struct format_field **fields) 1370{ 1371 struct format_field *field = NULL; 1372 enum event_type type; 1373 char *token; 1374 char *last_token; 1375 int count = 0; 1376 1377 do { 1378 unsigned int size_dynamic = 0; 1379 1380 type = read_token(&token); 1381 if (type == EVENT_NEWLINE) { 1382 free_token(token); 1383 return count; 1384 } 1385 1386 count++; 1387 1388 if (test_type_token(type, token, EVENT_ITEM, "field")) 1389 goto fail; 1390 free_token(token); 1391 1392 type = read_token(&token); 1393 /* 1394 * The ftrace fields may still use the "special" name. 1395 * Just ignore it. 1396 */ 1397 if (event->flags & EVENT_FL_ISFTRACE && 1398 type == EVENT_ITEM && strcmp(token, "special") == 0) { 1399 free_token(token); 1400 type = read_token(&token); 1401 } 1402 1403 if (test_type_token(type, token, EVENT_OP, ":") < 0) 1404 goto fail; 1405 1406 free_token(token); 1407 if (read_expect_type(EVENT_ITEM, &token) < 0) 1408 goto fail; 1409 1410 last_token = token; 1411 1412 field = calloc(1, sizeof(*field)); 1413 if (!field) 1414 goto fail; 1415 1416 field->event = event; 1417 1418 /* read the rest of the type */ 1419 for (;;) { 1420 type = read_token(&token); 1421 if (type == EVENT_ITEM || 1422 (type == EVENT_OP && strcmp(token, "*") == 0) || 1423 /* 1424 * Some of the ftrace fields are broken and have 1425 * an illegal "." in them. 1426 */ 1427 (event->flags & EVENT_FL_ISFTRACE && 1428 type == EVENT_OP && strcmp(token, ".") == 0)) { 1429 1430 if (strcmp(token, "*") == 0) 1431 field->flags |= FIELD_IS_POINTER; 1432 1433 if (field->type) { 1434 char *new_type; 1435 new_type = realloc(field->type, 1436 strlen(field->type) + 1437 strlen(last_token) + 2); 1438 if (!new_type) { 1439 free(last_token); 1440 goto fail; 1441 } 1442 field->type = new_type; 1443 strcat(field->type, " "); 1444 strcat(field->type, last_token); 1445 free(last_token); 1446 } else 1447 field->type = last_token; 1448 last_token = token; 1449 continue; 1450 } 1451 1452 break; 1453 } 1454 1455 if (!field->type) { 1456 do_warning_event(event, "%s: no type found", __func__); 1457 goto fail; 1458 } 1459 field->name = field->alias = last_token; 1460 1461 if (test_type(type, EVENT_OP)) 1462 goto fail; 1463 1464 if (strcmp(token, "[") == 0) { 1465 enum event_type last_type = type; 1466 char *brackets = token; 1467 char *new_brackets; 1468 int len; 1469 1470 field->flags |= FIELD_IS_ARRAY; 1471 1472 type = read_token(&token); 1473 1474 if (type == EVENT_ITEM) 1475 field->arraylen = strtoul(token, NULL, 0); 1476 else 1477 field->arraylen = 0; 1478 1479 while (strcmp(token, "]") != 0) { 1480 if (last_type == EVENT_ITEM && 1481 type == EVENT_ITEM) 1482 len = 2; 1483 else 1484 len = 1; 1485 last_type = type; 1486 1487 new_brackets = realloc(brackets, 1488 strlen(brackets) + 1489 strlen(token) + len); 1490 if (!new_brackets) { 1491 free(brackets); 1492 goto fail; 1493 } 1494 brackets = new_brackets; 1495 if (len == 2) 1496 strcat(brackets, " "); 1497 strcat(brackets, token); 1498 /* We only care about the last token */ 1499 field->arraylen = strtoul(token, NULL, 0); 1500 free_token(token); 1501 type = read_token(&token); 1502 if (type == EVENT_NONE) { 1503 do_warning_event(event, "failed to find token"); 1504 goto fail; 1505 } 1506 } 1507 1508 free_token(token); 1509 1510 new_brackets = realloc(brackets, strlen(brackets) + 2); 1511 if (!new_brackets) { 1512 free(brackets); 1513 goto fail; 1514 } 1515 brackets = new_brackets; 1516 strcat(brackets, "]"); 1517 1518 /* add brackets to type */ 1519 1520 type = read_token(&token); 1521 /* 1522 * If the next token is not an OP, then it is of 1523 * the format: type [] item; 1524 */ 1525 if (type == EVENT_ITEM) { 1526 char *new_type; 1527 new_type = realloc(field->type, 1528 strlen(field->type) + 1529 strlen(field->name) + 1530 strlen(brackets) + 2); 1531 if (!new_type) { 1532 free(brackets); 1533 goto fail; 1534 } 1535 field->type = new_type; 1536 strcat(field->type, " "); 1537 strcat(field->type, field->name); 1538 size_dynamic = type_size(field->name); 1539 free_token(field->name); 1540 strcat(field->type, brackets); 1541 field->name = field->alias = token; 1542 type = read_token(&token); 1543 } else { 1544 char *new_type; 1545 new_type = realloc(field->type, 1546 strlen(field->type) + 1547 strlen(brackets) + 1); 1548 if (!new_type) { 1549 free(brackets); 1550 goto fail; 1551 } 1552 field->type = new_type; 1553 strcat(field->type, brackets); 1554 } 1555 free(brackets); 1556 } 1557 1558 if (field_is_string(field)) 1559 field->flags |= FIELD_IS_STRING; 1560 if (field_is_dynamic(field)) 1561 field->flags |= FIELD_IS_DYNAMIC; 1562 if (field_is_long(field)) 1563 field->flags |= FIELD_IS_LONG; 1564 1565 if (test_type_token(type, token, EVENT_OP, ";")) 1566 goto fail; 1567 free_token(token); 1568 1569 if (read_expected(EVENT_ITEM, "offset") < 0) 1570 goto fail_expect; 1571 1572 if (read_expected(EVENT_OP, ":") < 0) 1573 goto fail_expect; 1574 1575 if (read_expect_type(EVENT_ITEM, &token)) 1576 goto fail; 1577 field->offset = strtoul(token, NULL, 0); 1578 free_token(token); 1579 1580 if (read_expected(EVENT_OP, ";") < 0) 1581 goto fail_expect; 1582 1583 if (read_expected(EVENT_ITEM, "size") < 0) 1584 goto fail_expect; 1585 1586 if (read_expected(EVENT_OP, ":") < 0) 1587 goto fail_expect; 1588 1589 if (read_expect_type(EVENT_ITEM, &token)) 1590 goto fail; 1591 field->size = strtoul(token, NULL, 0); 1592 free_token(token); 1593 1594 if (read_expected(EVENT_OP, ";") < 0) 1595 goto fail_expect; 1596 1597 type = read_token(&token); 1598 if (type != EVENT_NEWLINE) { 1599 /* newer versions of the kernel have a "signed" type */ 1600 if (test_type_token(type, token, EVENT_ITEM, "signed")) 1601 goto fail; 1602 1603 free_token(token); 1604 1605 if (read_expected(EVENT_OP, ":") < 0) 1606 goto fail_expect; 1607 1608 if (read_expect_type(EVENT_ITEM, &token)) 1609 goto fail; 1610 1611 if (strtoul(token, NULL, 0)) 1612 field->flags |= FIELD_IS_SIGNED; 1613 1614 free_token(token); 1615 if (read_expected(EVENT_OP, ";") < 0) 1616 goto fail_expect; 1617 1618 if (read_expect_type(EVENT_NEWLINE, &token)) 1619 goto fail; 1620 } 1621 1622 free_token(token); 1623 1624 if (field->flags & FIELD_IS_ARRAY) { 1625 if (field->arraylen) 1626 field->elementsize = field->size / field->arraylen; 1627 else if (field->flags & FIELD_IS_DYNAMIC) 1628 field->elementsize = size_dynamic; 1629 else if (field->flags & FIELD_IS_STRING) 1630 field->elementsize = 1; 1631 else if (field->flags & FIELD_IS_LONG) 1632 field->elementsize = event->pevent ? 1633 event->pevent->long_size : 1634 sizeof(long); 1635 } else 1636 field->elementsize = field->size; 1637 1638 *fields = field; 1639 fields = &field->next; 1640 1641 } while (1); 1642 1643 return 0; 1644 1645fail: 1646 free_token(token); 1647fail_expect: 1648 if (field) { 1649 free(field->type); 1650 free(field->name); 1651 free(field); 1652 } 1653 return -1; 1654} 1655 1656static int event_read_format(struct event_format *event) 1657{ 1658 char *token; 1659 int ret; 1660 1661 if (read_expected_item(EVENT_ITEM, "format") < 0) 1662 return -1; 1663 1664 if (read_expected(EVENT_OP, ":") < 0) 1665 return -1; 1666 1667 if (read_expect_type(EVENT_NEWLINE, &token)) 1668 goto fail; 1669 free_token(token); 1670 1671 ret = event_read_fields(event, &event->format.common_fields); 1672 if (ret < 0) 1673 return ret; 1674 event->format.nr_common = ret; 1675 1676 ret = event_read_fields(event, &event->format.fields); 1677 if (ret < 0) 1678 return ret; 1679 event->format.nr_fields = ret; 1680 1681 return 0; 1682 1683 fail: 1684 free_token(token); 1685 return -1; 1686} 1687 1688static enum event_type 1689process_arg_token(struct event_format *event, struct print_arg *arg, 1690 char **tok, enum event_type type); 1691 1692static enum event_type 1693process_arg(struct event_format *event, struct print_arg *arg, char **tok) 1694{ 1695 enum event_type type; 1696 char *token; 1697 1698 type = read_token(&token); 1699 *tok = token; 1700 1701 return process_arg_token(event, arg, tok, type); 1702} 1703 1704static enum event_type 1705process_op(struct event_format *event, struct print_arg *arg, char **tok); 1706 1707/* 1708 * For __print_symbolic() and __print_flags, we need to completely 1709 * evaluate the first argument, which defines what to print next. 1710 */ 1711static enum event_type 1712process_field_arg(struct event_format *event, struct print_arg *arg, char **tok) 1713{ 1714 enum event_type type; 1715 1716 type = process_arg(event, arg, tok); 1717 1718 while (type == EVENT_OP) { 1719 type = process_op(event, arg, tok); 1720 } 1721 1722 return type; 1723} 1724 1725static enum event_type 1726process_cond(struct event_format *event, struct print_arg *top, char **tok) 1727{ 1728 struct print_arg *arg, *left, *right; 1729 enum event_type type; 1730 char *token = NULL; 1731 1732 arg = alloc_arg(); 1733 left = alloc_arg(); 1734 right = alloc_arg(); 1735 1736 if (!arg || !left || !right) { 1737 do_warning_event(event, "%s: not enough memory!", __func__); 1738 /* arg will be freed at out_free */ 1739 free_arg(left); 1740 free_arg(right); 1741 goto out_free; 1742 } 1743 1744 arg->type = PRINT_OP; 1745 arg->op.left = left; 1746 arg->op.right = right; 1747 1748 *tok = NULL; 1749 type = process_arg(event, left, &token); 1750 1751 again: 1752 if (type == EVENT_ERROR) 1753 goto out_free; 1754 1755 /* Handle other operations in the arguments */ 1756 if (type == EVENT_OP && strcmp(token, ":") != 0) { 1757 type = process_op(event, left, &token); 1758 goto again; 1759 } 1760 1761 if (test_type_token(type, token, EVENT_OP, ":")) 1762 goto out_free; 1763 1764 arg->op.op = token; 1765 1766 type = process_arg(event, right, &token); 1767 1768 top->op.right = arg; 1769 1770 *tok = token; 1771 return type; 1772 1773out_free: 1774 /* Top may point to itself */ 1775 top->op.right = NULL; 1776 free_token(token); 1777 free_arg(arg); 1778 return EVENT_ERROR; 1779} 1780 1781static enum event_type 1782process_array(struct event_format *event, struct print_arg *top, char **tok) 1783{ 1784 struct print_arg *arg; 1785 enum event_type type; 1786 char *token = NULL; 1787 1788 arg = alloc_arg(); 1789 if (!arg) { 1790 do_warning_event(event, "%s: not enough memory!", __func__); 1791 /* '*tok' is set to top->op.op. No need to free. */ 1792 *tok = NULL; 1793 return EVENT_ERROR; 1794 } 1795 1796 *tok = NULL; 1797 type = process_arg(event, arg, &token); 1798 if (test_type_token(type, token, EVENT_OP, "]")) 1799 goto out_free; 1800 1801 top->op.right = arg; 1802 1803 free_token(token); 1804 type = read_token_item(&token); 1805 *tok = token; 1806 1807 return type; 1808 1809out_free: 1810 free_token(token); 1811 free_arg(arg); 1812 return EVENT_ERROR; 1813} 1814 1815static int get_op_prio(char *op) 1816{ 1817 if (!op[1]) { 1818 switch (op[0]) { 1819 case '~': 1820 case '!': 1821 return 4; 1822 case '*': 1823 case '/': 1824 case '%': 1825 return 6; 1826 case '+': 1827 case '-': 1828 return 7; 1829 /* '>>' and '<<' are 8 */ 1830 case '<': 1831 case '>': 1832 return 9; 1833 /* '==' and '!=' are 10 */ 1834 case '&': 1835 return 11; 1836 case '^': 1837 return 12; 1838 case '|': 1839 return 13; 1840 case '?': 1841 return 16; 1842 default: 1843 do_warning("unknown op '%c'", op[0]); 1844 return -1; 1845 } 1846 } else { 1847 if (strcmp(op, "++") == 0 || 1848 strcmp(op, "--") == 0) { 1849 return 3; 1850 } else if (strcmp(op, ">>") == 0 || 1851 strcmp(op, "<<") == 0) { 1852 return 8; 1853 } else if (strcmp(op, ">=") == 0 || 1854 strcmp(op, "<=") == 0) { 1855 return 9; 1856 } else if (strcmp(op, "==") == 0 || 1857 strcmp(op, "!=") == 0) { 1858 return 10; 1859 } else if (strcmp(op, "&&") == 0) { 1860 return 14; 1861 } else if (strcmp(op, "||") == 0) { 1862 return 15; 1863 } else { 1864 do_warning("unknown op '%s'", op); 1865 return -1; 1866 } 1867 } 1868} 1869 1870static int set_op_prio(struct print_arg *arg) 1871{ 1872 1873 /* single ops are the greatest */ 1874 if (!arg->op.left || arg->op.left->type == PRINT_NULL) 1875 arg->op.prio = 0; 1876 else 1877 arg->op.prio = get_op_prio(arg->op.op); 1878 1879 return arg->op.prio; 1880} 1881 1882/* Note, *tok does not get freed, but will most likely be saved */ 1883static enum event_type 1884process_op(struct event_format *event, struct print_arg *arg, char **tok) 1885{ 1886 struct print_arg *left, *right = NULL; 1887 enum event_type type; 1888 char *token; 1889 1890 /* the op is passed in via tok */ 1891 token = *tok; 1892 1893 if (arg->type == PRINT_OP && !arg->op.left) { 1894 /* handle single op */ 1895 if (token[1]) { 1896 do_warning_event(event, "bad op token %s", token); 1897 goto out_free; 1898 } 1899 switch (token[0]) { 1900 case '~': 1901 case '!': 1902 case '+': 1903 case '-': 1904 break; 1905 default: 1906 do_warning_event(event, "bad op token %s", token); 1907 goto out_free; 1908 1909 } 1910 1911 /* make an empty left */ 1912 left = alloc_arg(); 1913 if (!left) 1914 goto out_warn_free; 1915 1916 left->type = PRINT_NULL; 1917 arg->op.left = left; 1918 1919 right = alloc_arg(); 1920 if (!right) 1921 goto out_warn_free; 1922 1923 arg->op.right = right; 1924 1925 /* do not free the token, it belongs to an op */ 1926 *tok = NULL; 1927 type = process_arg(event, right, tok); 1928 1929 } else if (strcmp(token, "?") == 0) { 1930 1931 left = alloc_arg(); 1932 if (!left) 1933 goto out_warn_free; 1934 1935 /* copy the top arg to the left */ 1936 *left = *arg; 1937 1938 arg->type = PRINT_OP; 1939 arg->op.op = token; 1940 arg->op.left = left; 1941 arg->op.prio = 0; 1942 1943 /* it will set arg->op.right */ 1944 type = process_cond(event, arg, tok); 1945 1946 } else if (strcmp(token, ">>") == 0 || 1947 strcmp(token, "<<") == 0 || 1948 strcmp(token, "&") == 0 || 1949 strcmp(token, "|") == 0 || 1950 strcmp(token, "&&") == 0 || 1951 strcmp(token, "||") == 0 || 1952 strcmp(token, "-") == 0 || 1953 strcmp(token, "+") == 0 || 1954 strcmp(token, "*") == 0 || 1955 strcmp(token, "^") == 0 || 1956 strcmp(token, "/") == 0 || 1957 strcmp(token, "%") == 0 || 1958 strcmp(token, "<") == 0 || 1959 strcmp(token, ">") == 0 || 1960 strcmp(token, "<=") == 0 || 1961 strcmp(token, ">=") == 0 || 1962 strcmp(token, "==") == 0 || 1963 strcmp(token, "!=") == 0) { 1964 1965 left = alloc_arg(); 1966 if (!left) 1967 goto out_warn_free; 1968 1969 /* copy the top arg to the left */ 1970 *left = *arg; 1971 1972 arg->type = PRINT_OP; 1973 arg->op.op = token; 1974 arg->op.left = left; 1975 arg->op.right = NULL; 1976 1977 if (set_op_prio(arg) == -1) { 1978 event->flags |= EVENT_FL_FAILED; 1979 /* arg->op.op (= token) will be freed at out_free */ 1980 arg->op.op = NULL; 1981 goto out_free; 1982 } 1983 1984 type = read_token_item(&token); 1985 *tok = token; 1986 1987 /* could just be a type pointer */ 1988 if ((strcmp(arg->op.op, "*") == 0) && 1989 type == EVENT_DELIM && (strcmp(token, ")") == 0)) { 1990 char *new_atom; 1991 1992 if (left->type != PRINT_ATOM) { 1993 do_warning_event(event, "bad pointer type"); 1994 goto out_free; 1995 } 1996 new_atom = realloc(left->atom.atom, 1997 strlen(left->atom.atom) + 3); 1998 if (!new_atom) 1999 goto out_warn_free; 2000 2001 left->atom.atom = new_atom; 2002 strcat(left->atom.atom, " *"); 2003 free(arg->op.op); 2004 *arg = *left; 2005 free(left); 2006 2007 return type; 2008 } 2009 2010 right = alloc_arg(); 2011 if (!right) 2012 goto out_warn_free; 2013 2014 type = process_arg_token(event, right, tok, type); 2015 if (type == EVENT_ERROR) { 2016 free_arg(right); 2017 /* token was freed in process_arg_token() via *tok */ 2018 token = NULL; 2019 goto out_free; 2020 } 2021 2022 if (right->type == PRINT_OP && 2023 get_op_prio(arg->op.op) < get_op_prio(right->op.op)) { 2024 struct print_arg tmp; 2025 2026 /* rotate ops according to the priority */ 2027 arg->op.right = right->op.left; 2028 2029 tmp = *arg; 2030 *arg = *right; 2031 *right = tmp; 2032 2033 arg->op.left = right; 2034 } else { 2035 arg->op.right = right; 2036 } 2037 2038 } else if (strcmp(token, "[") == 0) { 2039 2040 left = alloc_arg(); 2041 if (!left) 2042 goto out_warn_free; 2043 2044 *left = *arg; 2045 2046 arg->type = PRINT_OP; 2047 arg->op.op = token; 2048 arg->op.left = left; 2049 2050 arg->op.prio = 0; 2051 2052 /* it will set arg->op.right */ 2053 type = process_array(event, arg, tok); 2054 2055 } else { 2056 do_warning_event(event, "unknown op '%s'", token); 2057 event->flags |= EVENT_FL_FAILED; 2058 /* the arg is now the left side */ 2059 goto out_free; 2060 } 2061 2062 if (type == EVENT_OP && strcmp(*tok, ":") != 0) { 2063 int prio; 2064 2065 /* higher prios need to be closer to the root */ 2066 prio = get_op_prio(*tok); 2067 2068 if (prio > arg->op.prio) 2069 return process_op(event, arg, tok); 2070 2071 return process_op(event, right, tok); 2072 } 2073 2074 return type; 2075 2076out_warn_free: 2077 do_warning_event(event, "%s: not enough memory!", __func__); 2078out_free: 2079 free_token(token); 2080 *tok = NULL; 2081 return EVENT_ERROR; 2082} 2083 2084static enum event_type 2085process_entry(struct event_format *event __maybe_unused, struct print_arg *arg, 2086 char **tok) 2087{ 2088 enum event_type type; 2089 char *field; 2090 char *token; 2091 2092 if (read_expected(EVENT_OP, "->") < 0) 2093 goto out_err; 2094 2095 if (read_expect_type(EVENT_ITEM, &token) < 0) 2096 goto out_free; 2097 field = token; 2098 2099 arg->type = PRINT_FIELD; 2100 arg->field.name = field; 2101 2102 if (is_flag_field) { 2103 arg->field.field = pevent_find_any_field(event, arg->field.name); 2104 arg->field.field->flags |= FIELD_IS_FLAG; 2105 is_flag_field = 0; 2106 } else if (is_symbolic_field) { 2107 arg->field.field = pevent_find_any_field(event, arg->field.name); 2108 arg->field.field->flags |= FIELD_IS_SYMBOLIC; 2109 is_symbolic_field = 0; 2110 } 2111 2112 type = read_token(&token); 2113 *tok = token; 2114 2115 return type; 2116 2117 out_free: 2118 free_token(token); 2119 out_err: 2120 *tok = NULL; 2121 return EVENT_ERROR; 2122} 2123 2124static int alloc_and_process_delim(struct event_format *event, char *next_token, 2125 struct print_arg **print_arg) 2126{ 2127 struct print_arg *field; 2128 enum event_type type; 2129 char *token; 2130 int ret = 0; 2131 2132 field = alloc_arg(); 2133 if (!field) { 2134 do_warning_event(event, "%s: not enough memory!", __func__); 2135 errno = ENOMEM; 2136 return -1; 2137 } 2138 2139 type = process_arg(event, field, &token); 2140 2141 if (test_type_token(type, token, EVENT_DELIM, next_token)) { 2142 errno = EINVAL; 2143 ret = -1; 2144 free_arg(field); 2145 goto out_free_token; 2146 } 2147 2148 *print_arg = field; 2149 2150out_free_token: 2151 free_token(token); 2152 2153 return ret; 2154} 2155 2156static char *arg_eval (struct print_arg *arg); 2157 2158static unsigned long long 2159eval_type_str(unsigned long long val, const char *type, int pointer) 2160{ 2161 int sign = 0; 2162 char *ref; 2163 int len; 2164 2165 len = strlen(type); 2166 2167 if (pointer) { 2168 2169 if (type[len-1] != '*') { 2170 do_warning("pointer expected with non pointer type"); 2171 return val; 2172 } 2173 2174 ref = malloc(len); 2175 if (!ref) { 2176 do_warning("%s: not enough memory!", __func__); 2177 return val; 2178 } 2179 memcpy(ref, type, len); 2180 2181 /* chop off the " *" */ 2182 ref[len - 2] = 0; 2183 2184 val = eval_type_str(val, ref, 0); 2185 free(ref); 2186 return val; 2187 } 2188 2189 /* check if this is a pointer */ 2190 if (type[len - 1] == '*') 2191 return val; 2192 2193 /* Try to figure out the arg size*/ 2194 if (strncmp(type, "struct", 6) == 0) 2195 /* all bets off */ 2196 return val; 2197 2198 if (strcmp(type, "u8") == 0) 2199 return val & 0xff; 2200 2201 if (strcmp(type, "u16") == 0) 2202 return val & 0xffff; 2203 2204 if (strcmp(type, "u32") == 0) 2205 return val & 0xffffffff; 2206 2207 if (strcmp(type, "u64") == 0 || 2208 strcmp(type, "s64")) 2209 return val; 2210 2211 if (strcmp(type, "s8") == 0) 2212 return (unsigned long long)(char)val & 0xff; 2213 2214 if (strcmp(type, "s16") == 0) 2215 return (unsigned long long)(short)val & 0xffff; 2216 2217 if (strcmp(type, "s32") == 0) 2218 return (unsigned long long)(int)val & 0xffffffff; 2219 2220 if (strncmp(type, "unsigned ", 9) == 0) { 2221 sign = 0; 2222 type += 9; 2223 } 2224 2225 if (strcmp(type, "char") == 0) { 2226 if (sign) 2227 return (unsigned long long)(char)val & 0xff; 2228 else 2229 return val & 0xff; 2230 } 2231 2232 if (strcmp(type, "short") == 0) { 2233 if (sign) 2234 return (unsigned long long)(short)val & 0xffff; 2235 else 2236 return val & 0xffff; 2237 } 2238 2239 if (strcmp(type, "int") == 0) { 2240 if (sign) 2241 return (unsigned long long)(int)val & 0xffffffff; 2242 else 2243 return val & 0xffffffff; 2244 } 2245 2246 return val; 2247} 2248 2249/* 2250 * Try to figure out the type. 2251 */ 2252static unsigned long long 2253eval_type(unsigned long long val, struct print_arg *arg, int pointer) 2254{ 2255 if (arg->type != PRINT_TYPE) { 2256 do_warning("expected type argument"); 2257 return 0; 2258 } 2259 2260 return eval_type_str(val, arg->typecast.type, pointer); 2261} 2262 2263static int arg_num_eval(struct print_arg *arg, long long *val) 2264{ 2265 long long left, right; 2266 int ret = 1; 2267 2268 switch (arg->type) { 2269 case PRINT_ATOM: 2270 *val = strtoll(arg->atom.atom, NULL, 0); 2271 break; 2272 case PRINT_TYPE: 2273 ret = arg_num_eval(arg->typecast.item, val); 2274 if (!ret) 2275 break; 2276 *val = eval_type(*val, arg, 0); 2277 break; 2278 case PRINT_OP: 2279 switch (arg->op.op[0]) { 2280 case '|': 2281 ret = arg_num_eval(arg->op.left, &left); 2282 if (!ret) 2283 break; 2284 ret = arg_num_eval(arg->op.right, &right); 2285 if (!ret) 2286 break; 2287 if (arg->op.op[1]) 2288 *val = left || right; 2289 else 2290 *val = left | right; 2291 break; 2292 case '&': 2293 ret = arg_num_eval(arg->op.left, &left); 2294 if (!ret) 2295 break; 2296 ret = arg_num_eval(arg->op.right, &right); 2297 if (!ret) 2298 break; 2299 if (arg->op.op[1]) 2300 *val = left && right; 2301 else 2302 *val = left & right; 2303 break; 2304 case '<': 2305 ret = arg_num_eval(arg->op.left, &left); 2306 if (!ret) 2307 break; 2308 ret = arg_num_eval(arg->op.right, &right); 2309 if (!ret) 2310 break; 2311 switch (arg->op.op[1]) { 2312 case 0: 2313 *val = left < right; 2314 break; 2315 case '<': 2316 *val = left << right; 2317 break; 2318 case '=': 2319 *val = left <= right; 2320 break; 2321 default: 2322 do_warning("unknown op '%s'", arg->op.op); 2323 ret = 0; 2324 } 2325 break; 2326 case '>': 2327 ret = arg_num_eval(arg->op.left, &left); 2328 if (!ret) 2329 break; 2330 ret = arg_num_eval(arg->op.right, &right); 2331 if (!ret) 2332 break; 2333 switch (arg->op.op[1]) { 2334 case 0: 2335 *val = left > right; 2336 break; 2337 case '>': 2338 *val = left >> right; 2339 break; 2340 case '=': 2341 *val = left >= right; 2342 break; 2343 default: 2344 do_warning("unknown op '%s'", arg->op.op); 2345 ret = 0; 2346 } 2347 break; 2348 case '=': 2349 ret = arg_num_eval(arg->op.left, &left); 2350 if (!ret) 2351 break; 2352 ret = arg_num_eval(arg->op.right, &right); 2353 if (!ret) 2354 break; 2355 2356 if (arg->op.op[1] != '=') { 2357 do_warning("unknown op '%s'", arg->op.op); 2358 ret = 0; 2359 } else 2360 *val = left == right; 2361 break; 2362 case '!': 2363 ret = arg_num_eval(arg->op.left, &left); 2364 if (!ret) 2365 break; 2366 ret = arg_num_eval(arg->op.right, &right); 2367 if (!ret) 2368 break; 2369 2370 switch (arg->op.op[1]) { 2371 case '=': 2372 *val = left != right; 2373 break; 2374 default: 2375 do_warning("unknown op '%s'", arg->op.op); 2376 ret = 0; 2377 } 2378 break; 2379 case '-': 2380 /* check for negative */ 2381 if (arg->op.left->type == PRINT_NULL) 2382 left = 0; 2383 else 2384 ret = arg_num_eval(arg->op.left, &left); 2385 if (!ret) 2386 break; 2387 ret = arg_num_eval(arg->op.right, &right); 2388 if (!ret) 2389 break; 2390 *val = left - right; 2391 break; 2392 case '+': 2393 if (arg->op.left->type == PRINT_NULL) 2394 left = 0; 2395 else 2396 ret = arg_num_eval(arg->op.left, &left); 2397 if (!ret) 2398 break; 2399 ret = arg_num_eval(arg->op.right, &right); 2400 if (!ret) 2401 break; 2402 *val = left + right; 2403 break; 2404 case '~': 2405 ret = arg_num_eval(arg->op.right, &right); 2406 if (!ret) 2407 break; 2408 *val = ~right; 2409 break; 2410 default: 2411 do_warning("unknown op '%s'", arg->op.op); 2412 ret = 0; 2413 } 2414 break; 2415 2416 case PRINT_NULL: 2417 case PRINT_FIELD ... PRINT_SYMBOL: 2418 case PRINT_STRING: 2419 case PRINT_BSTRING: 2420 case PRINT_BITMASK: 2421 default: 2422 do_warning("invalid eval type %d", arg->type); 2423 ret = 0; 2424 2425 } 2426 return ret; 2427} 2428 2429static char *arg_eval (struct print_arg *arg) 2430{ 2431 long long val; 2432 static char buf[20]; 2433 2434 switch (arg->type) { 2435 case PRINT_ATOM: 2436 return arg->atom.atom; 2437 case PRINT_TYPE: 2438 return arg_eval(arg->typecast.item); 2439 case PRINT_OP: 2440 if (!arg_num_eval(arg, &val)) 2441 break; 2442 sprintf(buf, "%lld", val); 2443 return buf; 2444 2445 case PRINT_NULL: 2446 case PRINT_FIELD ... PRINT_SYMBOL: 2447 case PRINT_STRING: 2448 case PRINT_BSTRING: 2449 case PRINT_BITMASK: 2450 default: 2451 do_warning("invalid eval type %d", arg->type); 2452 break; 2453 } 2454 2455 return NULL; 2456} 2457 2458static enum event_type 2459process_fields(struct event_format *event, struct print_flag_sym **list, char **tok) 2460{ 2461 enum event_type type; 2462 struct print_arg *arg = NULL; 2463 struct print_flag_sym *field; 2464 char *token = *tok; 2465 char *value; 2466 2467 do { 2468 free_token(token); 2469 type = read_token_item(&token); 2470 if (test_type_token(type, token, EVENT_OP, "{")) 2471 break; 2472 2473 arg = alloc_arg(); 2474 if (!arg) 2475 goto out_free; 2476 2477 free_token(token); 2478 type = process_arg(event, arg, &token); 2479 2480 if (type == EVENT_OP) 2481 type = process_op(event, arg, &token); 2482 2483 if (type == EVENT_ERROR) 2484 goto out_free; 2485 2486 if (test_type_token(type, token, EVENT_DELIM, ",")) 2487 goto out_free; 2488 2489 field = calloc(1, sizeof(*field)); 2490 if (!field) 2491 goto out_free; 2492 2493 value = arg_eval(arg); 2494 if (value == NULL) 2495 goto out_free_field; 2496 field->value = strdup(value); 2497 if (field->value == NULL) 2498 goto out_free_field; 2499 2500 free_arg(arg); 2501 arg = alloc_arg(); 2502 if (!arg) 2503 goto out_free; 2504 2505 free_token(token); 2506 type = process_arg(event, arg, &token); 2507 if (test_type_token(type, token, EVENT_OP, "}")) 2508 goto out_free_field; 2509 2510 value = arg_eval(arg); 2511 if (value == NULL) 2512 goto out_free_field; 2513 field->str = strdup(value); 2514 if (field->str == NULL) 2515 goto out_free_field; 2516 free_arg(arg); 2517 arg = NULL; 2518 2519 *list = field; 2520 list = &field->next; 2521 2522 free_token(token); 2523 type = read_token_item(&token); 2524 } while (type == EVENT_DELIM && strcmp(token, ",") == 0); 2525 2526 *tok = token; 2527 return type; 2528 2529out_free_field: 2530 free_flag_sym(field); 2531out_free: 2532 free_arg(arg); 2533 free_token(token); 2534 *tok = NULL; 2535 2536 return EVENT_ERROR; 2537} 2538 2539static enum event_type 2540process_flags(struct event_format *event, struct print_arg *arg, char **tok) 2541{ 2542 struct print_arg *field; 2543 enum event_type type; 2544 char *token = NULL; 2545 2546 memset(arg, 0, sizeof(*arg)); 2547 arg->type = PRINT_FLAGS; 2548 2549 field = alloc_arg(); 2550 if (!field) { 2551 do_warning_event(event, "%s: not enough memory!", __func__); 2552 goto out_free; 2553 } 2554 2555 type = process_field_arg(event, field, &token); 2556 2557 /* Handle operations in the first argument */ 2558 while (type == EVENT_OP) 2559 type = process_op(event, field, &token); 2560 2561 if (test_type_token(type, token, EVENT_DELIM, ",")) 2562 goto out_free_field; 2563 free_token(token); 2564 2565 arg->flags.field = field; 2566 2567 type = read_token_item(&token); 2568 if (event_item_type(type)) { 2569 arg->flags.delim = token; 2570 type = read_token_item(&token); 2571 } 2572 2573 if (test_type_token(type, token, EVENT_DELIM, ",")) 2574 goto out_free; 2575 2576 type = process_fields(event, &arg->flags.flags, &token); 2577 if (test_type_token(type, token, EVENT_DELIM, ")")) 2578 goto out_free; 2579 2580 free_token(token); 2581 type = read_token_item(tok); 2582 return type; 2583 2584out_free_field: 2585 free_arg(field); 2586out_free: 2587 free_token(token); 2588 *tok = NULL; 2589 return EVENT_ERROR; 2590} 2591 2592static enum event_type 2593process_symbols(struct event_format *event, struct print_arg *arg, char **tok) 2594{ 2595 struct print_arg *field; 2596 enum event_type type; 2597 char *token = NULL; 2598 2599 memset(arg, 0, sizeof(*arg)); 2600 arg->type = PRINT_SYMBOL; 2601 2602 field = alloc_arg(); 2603 if (!field) { 2604 do_warning_event(event, "%s: not enough memory!", __func__); 2605 goto out_free; 2606 } 2607 2608 type = process_field_arg(event, field, &token); 2609 2610 if (test_type_token(type, token, EVENT_DELIM, ",")) 2611 goto out_free_field; 2612 2613 arg->symbol.field = field; 2614 2615 type = process_fields(event, &arg->symbol.symbols, &token); 2616 if (test_type_token(type, token, EVENT_DELIM, ")")) 2617 goto out_free; 2618 2619 free_token(token); 2620 type = read_token_item(tok); 2621 return type; 2622 2623out_free_field: 2624 free_arg(field); 2625out_free: 2626 free_token(token); 2627 *tok = NULL; 2628 return EVENT_ERROR; 2629} 2630 2631static enum event_type 2632process_hex(struct event_format *event, struct print_arg *arg, char **tok) 2633{ 2634 memset(arg, 0, sizeof(*arg)); 2635 arg->type = PRINT_HEX; 2636 2637 if (alloc_and_process_delim(event, ",", &arg->hex.field)) 2638 goto out; 2639 2640 if (alloc_and_process_delim(event, ")", &arg->hex.size)) 2641 goto free_field; 2642 2643 return read_token_item(tok); 2644 2645free_field: 2646 free_arg(arg->hex.field); 2647 arg->hex.field = NULL; 2648out: 2649 *tok = NULL; 2650 return EVENT_ERROR; 2651} 2652 2653static enum event_type 2654process_int_array(struct event_format *event, struct print_arg *arg, char **tok) 2655{ 2656 memset(arg, 0, sizeof(*arg)); 2657 arg->type = PRINT_INT_ARRAY; 2658 2659 if (alloc_and_process_delim(event, ",", &arg->int_array.field)) 2660 goto out; 2661 2662 if (alloc_and_process_delim(event, ",", &arg->int_array.count)) 2663 goto free_field; 2664 2665 if (alloc_and_process_delim(event, ")", &arg->int_array.el_size)) 2666 goto free_size; 2667 2668 return read_token_item(tok); 2669 2670free_size: 2671 free_arg(arg->int_array.count); 2672 arg->int_array.count = NULL; 2673free_field: 2674 free_arg(arg->int_array.field); 2675 arg->int_array.field = NULL; 2676out: 2677 *tok = NULL; 2678 return EVENT_ERROR; 2679} 2680 2681static enum event_type 2682process_dynamic_array(struct event_format *event, struct print_arg *arg, char **tok) 2683{ 2684 struct format_field *field; 2685 enum event_type type; 2686 char *token; 2687 2688 memset(arg, 0, sizeof(*arg)); 2689 arg->type = PRINT_DYNAMIC_ARRAY; 2690 2691 /* 2692 * The item within the parenthesis is another field that holds 2693 * the index into where the array starts. 2694 */ 2695 type = read_token(&token); 2696 *tok = token; 2697 if (type != EVENT_ITEM) 2698 goto out_free; 2699 2700 /* Find the field */ 2701 2702 field = pevent_find_field(event, token); 2703 if (!field) 2704 goto out_free; 2705 2706 arg->dynarray.field = field; 2707 arg->dynarray.index = 0; 2708 2709 if (read_expected(EVENT_DELIM, ")") < 0) 2710 goto out_free; 2711 2712 free_token(token); 2713 type = read_token_item(&token); 2714 *tok = token; 2715 if (type != EVENT_OP || strcmp(token, "[") != 0) 2716 return type; 2717 2718 free_token(token); 2719 arg = alloc_arg(); 2720 if (!arg) { 2721 do_warning_event(event, "%s: not enough memory!", __func__); 2722 *tok = NULL; 2723 return EVENT_ERROR; 2724 } 2725 2726 type = process_arg(event, arg, &token); 2727 if (type == EVENT_ERROR) 2728 goto out_free_arg; 2729 2730 if (!test_type_token(type, token, EVENT_OP, "]")) 2731 goto out_free_arg; 2732 2733 free_token(token); 2734 type = read_token_item(tok); 2735 return type; 2736 2737 out_free_arg: 2738 free_arg(arg); 2739 out_free: 2740 free_token(token); 2741 *tok = NULL; 2742 return EVENT_ERROR; 2743} 2744 2745static enum event_type 2746process_dynamic_array_len(struct event_format *event, struct print_arg *arg, 2747 char **tok) 2748{ 2749 struct format_field *field; 2750 enum event_type type; 2751 char *token; 2752 2753 if (read_expect_type(EVENT_ITEM, &token) < 0) 2754 goto out_free; 2755 2756 arg->type = PRINT_DYNAMIC_ARRAY_LEN; 2757 2758 /* Find the field */ 2759 field = pevent_find_field(event, token); 2760 if (!field) 2761 goto out_free; 2762 2763 arg->dynarray.field = field; 2764 arg->dynarray.index = 0; 2765 2766 if (read_expected(EVENT_DELIM, ")") < 0) 2767 goto out_err; 2768 2769 type = read_token(&token); 2770 *tok = token; 2771 2772 return type; 2773 2774 out_free: 2775 free_token(token); 2776 out_err: 2777 *tok = NULL; 2778 return EVENT_ERROR; 2779} 2780 2781static enum event_type 2782process_paren(struct event_format *event, struct print_arg *arg, char **tok) 2783{ 2784 struct print_arg *item_arg; 2785 enum event_type type; 2786 char *token; 2787 2788 type = process_arg(event, arg, &token); 2789 2790 if (type == EVENT_ERROR) 2791 goto out_free; 2792 2793 if (type == EVENT_OP) 2794 type = process_op(event, arg, &token); 2795 2796 if (type == EVENT_ERROR) 2797 goto out_free; 2798 2799 if (test_type_token(type, token, EVENT_DELIM, ")")) 2800 goto out_free; 2801 2802 free_token(token); 2803 type = read_token_item(&token); 2804 2805 /* 2806 * If the next token is an item or another open paren, then 2807 * this was a typecast. 2808 */ 2809 if (event_item_type(type) || 2810 (type == EVENT_DELIM && strcmp(token, "(") == 0)) { 2811 2812 /* make this a typecast and contine */ 2813 2814 /* prevous must be an atom */ 2815 if (arg->type != PRINT_ATOM) { 2816 do_warning_event(event, "previous needed to be PRINT_ATOM"); 2817 goto out_free; 2818 } 2819 2820 item_arg = alloc_arg(); 2821 if (!item_arg) { 2822 do_warning_event(event, "%s: not enough memory!", 2823 __func__); 2824 goto out_free; 2825 } 2826 2827 arg->type = PRINT_TYPE; 2828 arg->typecast.type = arg->atom.atom; 2829 arg->typecast.item = item_arg; 2830 type = process_arg_token(event, item_arg, &token, type); 2831 2832 } 2833 2834 *tok = token; 2835 return type; 2836 2837 out_free: 2838 free_token(token); 2839 *tok = NULL; 2840 return EVENT_ERROR; 2841} 2842 2843 2844static enum event_type 2845process_str(struct event_format *event __maybe_unused, struct print_arg *arg, 2846 char **tok) 2847{ 2848 enum event_type type; 2849 char *token; 2850 2851 if (read_expect_type(EVENT_ITEM, &token) < 0) 2852 goto out_free; 2853 2854 arg->type = PRINT_STRING; 2855 arg->string.string = token; 2856 arg->string.offset = -1; 2857 2858 if (read_expected(EVENT_DELIM, ")") < 0) 2859 goto out_err; 2860 2861 type = read_token(&token); 2862 *tok = token; 2863 2864 return type; 2865 2866 out_free: 2867 free_token(token); 2868 out_err: 2869 *tok = NULL; 2870 return EVENT_ERROR; 2871} 2872 2873static enum event_type 2874process_bitmask(struct event_format *event __maybe_unused, struct print_arg *arg, 2875 char **tok) 2876{ 2877 enum event_type type; 2878 char *token; 2879 2880 if (read_expect_type(EVENT_ITEM, &token) < 0) 2881 goto out_free; 2882 2883 arg->type = PRINT_BITMASK; 2884 arg->bitmask.bitmask = token; 2885 arg->bitmask.offset = -1; 2886 2887 if (read_expected(EVENT_DELIM, ")") < 0) 2888 goto out_err; 2889 2890 type = read_token(&token); 2891 *tok = token; 2892 2893 return type; 2894 2895 out_free: 2896 free_token(token); 2897 out_err: 2898 *tok = NULL; 2899 return EVENT_ERROR; 2900} 2901 2902static struct pevent_function_handler * 2903find_func_handler(struct pevent *pevent, char *func_name) 2904{ 2905 struct pevent_function_handler *func; 2906 2907 if (!pevent) 2908 return NULL; 2909 2910 for (func = pevent->func_handlers; func; func = func->next) { 2911 if (strcmp(func->name, func_name) == 0) 2912 break; 2913 } 2914 2915 return func; 2916} 2917 2918static void remove_func_handler(struct pevent *pevent, char *func_name) 2919{ 2920 struct pevent_function_handler *func; 2921 struct pevent_function_handler **next; 2922 2923 next = &pevent->func_handlers; 2924 while ((func = *next)) { 2925 if (strcmp(func->name, func_name) == 0) { 2926 *next = func->next; 2927 free_func_handle(func); 2928 break; 2929 } 2930 next = &func->next; 2931 } 2932} 2933 2934static enum event_type 2935process_func_handler(struct event_format *event, struct pevent_function_handler *func, 2936 struct print_arg *arg, char **tok) 2937{ 2938 struct print_arg **next_arg; 2939 struct print_arg *farg; 2940 enum event_type type; 2941 char *token; 2942 int i; 2943 2944 arg->type = PRINT_FUNC; 2945 arg->func.func = func; 2946 2947 *tok = NULL; 2948 2949 next_arg = &(arg->func.args); 2950 for (i = 0; i < func->nr_args; i++) { 2951 farg = alloc_arg(); 2952 if (!farg) { 2953 do_warning_event(event, "%s: not enough memory!", 2954 __func__); 2955 return EVENT_ERROR; 2956 } 2957 2958 type = process_arg(event, farg, &token); 2959 if (i < (func->nr_args - 1)) { 2960 if (type != EVENT_DELIM || strcmp(token, ",") != 0) { 2961 do_warning_event(event, 2962 "Error: function '%s()' expects %d arguments but event %s only uses %d", 2963 func->name, func->nr_args, 2964 event->name, i + 1); 2965 goto err; 2966 } 2967 } else { 2968 if (type != EVENT_DELIM || strcmp(token, ")") != 0) { 2969 do_warning_event(event, 2970 "Error: function '%s()' only expects %d arguments but event %s has more", 2971 func->name, func->nr_args, event->name); 2972 goto err; 2973 } 2974 } 2975 2976 *next_arg = farg; 2977 next_arg = &(farg->next); 2978 free_token(token); 2979 } 2980 2981 type = read_token(&token); 2982 *tok = token; 2983 2984 return type; 2985 2986err: 2987 free_arg(farg); 2988 free_token(token); 2989 return EVENT_ERROR; 2990} 2991 2992static enum event_type 2993process_function(struct event_format *event, struct print_arg *arg, 2994 char *token, char **tok) 2995{ 2996 struct pevent_function_handler *func; 2997 2998 if (strcmp(token, "__print_flags") == 0) { 2999 free_token(token); 3000 is_flag_field = 1; 3001 return process_flags(event, arg, tok); 3002 } 3003 if (strcmp(token, "__print_symbolic") == 0) { 3004 free_token(token); 3005 is_symbolic_field = 1; 3006 return process_symbols(event, arg, tok); 3007 } 3008 if (strcmp(token, "__print_hex") == 0) { 3009 free_token(token); 3010 return process_hex(event, arg, tok); 3011 } 3012 if (strcmp(token, "__print_array") == 0) { 3013 free_token(token); 3014 return process_int_array(event, arg, tok); 3015 } 3016 if (strcmp(token, "__get_str") == 0) { 3017 free_token(token); 3018 return process_str(event, arg, tok); 3019 } 3020 if (strcmp(token, "__get_bitmask") == 0) { 3021 free_token(token); 3022 return process_bitmask(event, arg, tok); 3023 } 3024 if (strcmp(token, "__get_dynamic_array") == 0) { 3025 free_token(token); 3026 return process_dynamic_array(event, arg, tok); 3027 } 3028 if (strcmp(token, "__get_dynamic_array_len") == 0) { 3029 free_token(token); 3030 return process_dynamic_array_len(event, arg, tok); 3031 } 3032 3033 func = find_func_handler(event->pevent, token); 3034 if (func) { 3035 free_token(token); 3036 return process_func_handler(event, func, arg, tok); 3037 } 3038 3039 do_warning_event(event, "function %s not defined", token); 3040 free_token(token); 3041 return EVENT_ERROR; 3042} 3043 3044static enum event_type 3045process_arg_token(struct event_format *event, struct print_arg *arg, 3046 char **tok, enum event_type type) 3047{ 3048 char *token; 3049 char *atom; 3050 3051 token = *tok; 3052 3053 switch (type) { 3054 case EVENT_ITEM: 3055 if (strcmp(token, "REC") == 0) { 3056 free_token(token); 3057 type = process_entry(event, arg, &token); 3058 break; 3059 } 3060 atom = token; 3061 /* test the next token */ 3062 type = read_token_item(&token); 3063 3064 /* 3065 * If the next token is a parenthesis, then this 3066 * is a function. 3067 */ 3068 if (type == EVENT_DELIM && strcmp(token, "(") == 0) { 3069 free_token(token); 3070 token = NULL; 3071 /* this will free atom. */ 3072 type = process_function(event, arg, atom, &token); 3073 break; 3074 } 3075 /* atoms can be more than one token long */ 3076 while (type == EVENT_ITEM) { 3077 char *new_atom; 3078 new_atom = realloc(atom, 3079 strlen(atom) + strlen(token) + 2); 3080 if (!new_atom) { 3081 free(atom); 3082 *tok = NULL; 3083 free_token(token); 3084 return EVENT_ERROR; 3085 } 3086 atom = new_atom; 3087 strcat(atom, " "); 3088 strcat(atom, token); 3089 free_token(token); 3090 type = read_token_item(&token); 3091 } 3092 3093 arg->type = PRINT_ATOM; 3094 arg->atom.atom = atom; 3095 break; 3096 3097 case EVENT_DQUOTE: 3098 case EVENT_SQUOTE: 3099 arg->type = PRINT_ATOM; 3100 arg->atom.atom = token; 3101 type = read_token_item(&token); 3102 break; 3103 case EVENT_DELIM: 3104 if (strcmp(token, "(") == 0) { 3105 free_token(token); 3106 type = process_paren(event, arg, &token); 3107 break; 3108 } 3109 case EVENT_OP: 3110 /* handle single ops */ 3111 arg->type = PRINT_OP; 3112 arg->op.op = token; 3113 arg->op.left = NULL; 3114 type = process_op(event, arg, &token); 3115 3116 /* On error, the op is freed */ 3117 if (type == EVENT_ERROR) 3118 arg->op.op = NULL; 3119 3120 /* return error type if errored */ 3121 break; 3122 3123 case EVENT_ERROR ... EVENT_NEWLINE: 3124 default: 3125 do_warning_event(event, "unexpected type %d", type); 3126 return EVENT_ERROR; 3127 } 3128 *tok = token; 3129 3130 return type; 3131} 3132 3133static int event_read_print_args(struct event_format *event, struct print_arg **list) 3134{ 3135 enum event_type type = EVENT_ERROR; 3136 struct print_arg *arg; 3137 char *token; 3138 int args = 0; 3139 3140 do { 3141 if (type == EVENT_NEWLINE) { 3142 type = read_token_item(&token); 3143 continue; 3144 } 3145 3146 arg = alloc_arg(); 3147 if (!arg) { 3148 do_warning_event(event, "%s: not enough memory!", 3149 __func__); 3150 return -1; 3151 } 3152 3153 type = process_arg(event, arg, &token); 3154 3155 if (type == EVENT_ERROR) { 3156 free_token(token); 3157 free_arg(arg); 3158 return -1; 3159 } 3160 3161 *list = arg; 3162 args++; 3163 3164 if (type == EVENT_OP) { 3165 type = process_op(event, arg, &token); 3166 free_token(token); 3167 if (type == EVENT_ERROR) { 3168 *list = NULL; 3169 free_arg(arg); 3170 return -1; 3171 } 3172 list = &arg->next; 3173 continue; 3174 } 3175 3176 if (type == EVENT_DELIM && strcmp(token, ",") == 0) { 3177 free_token(token); 3178 *list = arg; 3179 list = &arg->next; 3180 continue; 3181 } 3182 break; 3183 } while (type != EVENT_NONE); 3184 3185 if (type != EVENT_NONE && type != EVENT_ERROR) 3186 free_token(token); 3187 3188 return args; 3189} 3190 3191static int event_read_print(struct event_format *event) 3192{ 3193 enum event_type type; 3194 char *token; 3195 int ret; 3196 3197 if (read_expected_item(EVENT_ITEM, "print") < 0) 3198 return -1; 3199 3200 if (read_expected(EVENT_ITEM, "fmt") < 0) 3201 return -1; 3202 3203 if (read_expected(EVENT_OP, ":") < 0) 3204 return -1; 3205 3206 if (read_expect_type(EVENT_DQUOTE, &token) < 0) 3207 goto fail; 3208 3209 concat: 3210 event->print_fmt.format = token; 3211 event->print_fmt.args = NULL; 3212 3213 /* ok to have no arg */ 3214 type = read_token_item(&token); 3215 3216 if (type == EVENT_NONE) 3217 return 0; 3218 3219 /* Handle concatenation of print lines */ 3220 if (type == EVENT_DQUOTE) { 3221 char *cat; 3222 3223 if (asprintf(&cat, "%s%s", event->print_fmt.format, token) < 0) 3224 goto fail; 3225 free_token(token); 3226 free_token(event->print_fmt.format); 3227 event->print_fmt.format = NULL; 3228 token = cat; 3229 goto concat; 3230 } 3231 3232 if (test_type_token(type, token, EVENT_DELIM, ",")) 3233 goto fail; 3234 3235 free_token(token); 3236 3237 ret = event_read_print_args(event, &event->print_fmt.args); 3238 if (ret < 0) 3239 return -1; 3240 3241 return ret; 3242 3243 fail: 3244 free_token(token); 3245 return -1; 3246} 3247 3248/** 3249 * pevent_find_common_field - return a common field by event 3250 * @event: handle for the event 3251 * @name: the name of the common field to return 3252 * 3253 * Returns a common field from the event by the given @name. 3254 * This only searchs the common fields and not all field. 3255 */ 3256struct format_field * 3257pevent_find_common_field(struct event_format *event, const char *name) 3258{ 3259 struct format_field *format; 3260 3261 for (format = event->format.common_fields; 3262 format; format = format->next) { 3263 if (strcmp(format->name, name) == 0) 3264 break; 3265 } 3266 3267 return format; 3268} 3269 3270/** 3271 * pevent_find_field - find a non-common field 3272 * @event: handle for the event 3273 * @name: the name of the non-common field 3274 * 3275 * Returns a non-common field by the given @name. 3276 * This does not search common fields. 3277 */ 3278struct format_field * 3279pevent_find_field(struct event_format *event, const char *name) 3280{ 3281 struct format_field *format; 3282 3283 for (format = event->format.fields; 3284 format; format = format->next) { 3285 if (strcmp(format->name, name) == 0) 3286 break; 3287 } 3288 3289 return format; 3290} 3291 3292/** 3293 * pevent_find_any_field - find any field by name 3294 * @event: handle for the event 3295 * @name: the name of the field 3296 * 3297 * Returns a field by the given @name. 3298 * This searchs the common field names first, then 3299 * the non-common ones if a common one was not found. 3300 */ 3301struct format_field * 3302pevent_find_any_field(struct event_format *event, const char *name) 3303{ 3304 struct format_field *format; 3305 3306 format = pevent_find_common_field(event, name); 3307 if (format) 3308 return format; 3309 return pevent_find_field(event, name); 3310} 3311 3312/** 3313 * pevent_read_number - read a number from data 3314 * @pevent: handle for the pevent 3315 * @ptr: the raw data 3316 * @size: the size of the data that holds the number 3317 * 3318 * Returns the number (converted to host) from the 3319 * raw data. 3320 */ 3321unsigned long long pevent_read_number(struct pevent *pevent, 3322 const void *ptr, int size) 3323{ 3324 switch (size) { 3325 case 1: 3326 return *(unsigned char *)ptr; 3327 case 2: 3328 return data2host2(pevent, ptr); 3329 case 4: 3330 return data2host4(pevent, ptr); 3331 case 8: 3332 return data2host8(pevent, ptr); 3333 default: 3334 /* BUG! */ 3335 return 0; 3336 } 3337} 3338 3339/** 3340 * pevent_read_number_field - read a number from data 3341 * @field: a handle to the field 3342 * @data: the raw data to read 3343 * @value: the value to place the number in 3344 * 3345 * Reads raw data according to a field offset and size, 3346 * and translates it into @value. 3347 * 3348 * Returns 0 on success, -1 otherwise. 3349 */ 3350int pevent_read_number_field(struct format_field *field, const void *data, 3351 unsigned long long *value) 3352{ 3353 if (!field) 3354 return -1; 3355 switch (field->size) { 3356 case 1: 3357 case 2: 3358 case 4: 3359 case 8: 3360 *value = pevent_read_number(field->event->pevent, 3361 data + field->offset, field->size); 3362 return 0; 3363 default: 3364 return -1; 3365 } 3366} 3367 3368static int get_common_info(struct pevent *pevent, 3369 const char *type, int *offset, int *size) 3370{ 3371 struct event_format *event; 3372 struct format_field *field; 3373 3374 /* 3375 * All events should have the same common elements. 3376 * Pick any event to find where the type is; 3377 */ 3378 if (!pevent->events) { 3379 do_warning("no event_list!"); 3380 return -1; 3381 } 3382 3383 event = pevent->events[0]; 3384 field = pevent_find_common_field(event, type); 3385 if (!field) 3386 return -1; 3387 3388 *offset = field->offset; 3389 *size = field->size; 3390 3391 return 0; 3392} 3393 3394static int __parse_common(struct pevent *pevent, void *data, 3395 int *size, int *offset, const char *name) 3396{ 3397 int ret; 3398 3399 if (!*size) { 3400 ret = get_common_info(pevent, name, offset, size); 3401 if (ret < 0) 3402 return ret; 3403 } 3404 return pevent_read_number(pevent, data + *offset, *size); 3405} 3406 3407static int trace_parse_common_type(struct pevent *pevent, void *data) 3408{ 3409 return __parse_common(pevent, data, 3410 &pevent->type_size, &pevent->type_offset, 3411 "common_type"); 3412} 3413 3414static int parse_common_pid(struct pevent *pevent, void *data) 3415{ 3416 return __parse_common(pevent, data, 3417 &pevent->pid_size, &pevent->pid_offset, 3418 "common_pid"); 3419} 3420 3421static int parse_common_pc(struct pevent *pevent, void *data) 3422{ 3423 return __parse_common(pevent, data, 3424 &pevent->pc_size, &pevent->pc_offset, 3425 "common_preempt_count"); 3426} 3427 3428static int parse_common_flags(struct pevent *pevent, void *data) 3429{ 3430 return __parse_common(pevent, data, 3431 &pevent->flags_size, &pevent->flags_offset, 3432 "common_flags"); 3433} 3434 3435static int parse_common_lock_depth(struct pevent *pevent, void *data) 3436{ 3437 return __parse_common(pevent, data, 3438 &pevent->ld_size, &pevent->ld_offset, 3439 "common_lock_depth"); 3440} 3441 3442static int parse_common_migrate_disable(struct pevent *pevent, void *data) 3443{ 3444 return __parse_common(pevent, data, 3445 &pevent->ld_size, &pevent->ld_offset, 3446 "common_migrate_disable"); 3447} 3448 3449static int events_id_cmp(const void *a, const void *b); 3450 3451/** 3452 * pevent_find_event - find an event by given id 3453 * @pevent: a handle to the pevent 3454 * @id: the id of the event 3455 * 3456 * Returns an event that has a given @id. 3457 */ 3458struct event_format *pevent_find_event(struct pevent *pevent, int id) 3459{ 3460 struct event_format **eventptr; 3461 struct event_format key; 3462 struct event_format *pkey = &key; 3463 3464 /* Check cache first */ 3465 if (pevent->last_event && pevent->last_event->id == id) 3466 return pevent->last_event; 3467 3468 key.id = id; 3469 3470 eventptr = bsearch(&pkey, pevent->events, pevent->nr_events, 3471 sizeof(*pevent->events), events_id_cmp); 3472 3473 if (eventptr) { 3474 pevent->last_event = *eventptr; 3475 return *eventptr; 3476 } 3477 3478 return NULL; 3479} 3480 3481/** 3482 * pevent_find_event_by_name - find an event by given name 3483 * @pevent: a handle to the pevent 3484 * @sys: the system name to search for 3485 * @name: the name of the event to search for 3486 * 3487 * This returns an event with a given @name and under the system 3488 * @sys. If @sys is NULL the first event with @name is returned. 3489 */ 3490struct event_format * 3491pevent_find_event_by_name(struct pevent *pevent, 3492 const char *sys, const char *name) 3493{ 3494 struct event_format *event; 3495 int i; 3496 3497 if (pevent->last_event && 3498 strcmp(pevent->last_event->name, name) == 0 && 3499 (!sys || strcmp(pevent->last_event->system, sys) == 0)) 3500 return pevent->last_event; 3501 3502 for (i = 0; i < pevent->nr_events; i++) { 3503 event = pevent->events[i]; 3504 if (strcmp(event->name, name) == 0) { 3505 if (!sys) 3506 break; 3507 if (strcmp(event->system, sys) == 0) 3508 break; 3509 } 3510 } 3511 if (i == pevent->nr_events) 3512 event = NULL; 3513 3514 pevent->last_event = event; 3515 return event; 3516} 3517 3518static unsigned long long 3519eval_num_arg(void *data, int size, struct event_format *event, struct print_arg *arg) 3520{ 3521 struct pevent *pevent = event->pevent; 3522 unsigned long long val = 0; 3523 unsigned long long left, right; 3524 struct print_arg *typearg = NULL; 3525 struct print_arg *larg; 3526 unsigned long offset; 3527 unsigned int field_size; 3528 3529 switch (arg->type) { 3530 case PRINT_NULL: 3531 /* ?? */ 3532 return 0; 3533 case PRINT_ATOM: 3534 return strtoull(arg->atom.atom, NULL, 0); 3535 case PRINT_FIELD: 3536 if (!arg->field.field) { 3537 arg->field.field = pevent_find_any_field(event, arg->field.name); 3538 if (!arg->field.field) 3539 goto out_warning_field; 3540 3541 } 3542 /* must be a number */ 3543 val = pevent_read_number(pevent, data + arg->field.field->offset, 3544 arg->field.field->size); 3545 break; 3546 case PRINT_FLAGS: 3547 case PRINT_SYMBOL: 3548 case PRINT_INT_ARRAY: 3549 case PRINT_HEX: 3550 break; 3551 case PRINT_TYPE: 3552 val = eval_num_arg(data, size, event, arg->typecast.item); 3553 return eval_type(val, arg, 0); 3554 case PRINT_STRING: 3555 case PRINT_BSTRING: 3556 case PRINT_BITMASK: 3557 return 0; 3558 case PRINT_FUNC: { 3559 struct trace_seq s; 3560 trace_seq_init(&s); 3561 val = process_defined_func(&s, data, size, event, arg); 3562 trace_seq_destroy(&s); 3563 return val; 3564 } 3565 case PRINT_OP: 3566 if (strcmp(arg->op.op, "[") == 0) { 3567 /* 3568 * Arrays are special, since we don't want 3569 * to read the arg as is. 3570 */ 3571 right = eval_num_arg(data, size, event, arg->op.right); 3572 3573 /* handle typecasts */ 3574 larg = arg->op.left; 3575 while (larg->type == PRINT_TYPE) { 3576 if (!typearg) 3577 typearg = larg; 3578 larg = larg->typecast.item; 3579 } 3580 3581 /* Default to long size */ 3582 field_size = pevent->long_size; 3583 3584 switch (larg->type) { 3585 case PRINT_DYNAMIC_ARRAY: 3586 offset = pevent_read_number(pevent, 3587 data + larg->dynarray.field->offset, 3588 larg->dynarray.field->size); 3589 if (larg->dynarray.field->elementsize) 3590 field_size = larg->dynarray.field->elementsize; 3591 /* 3592 * The actual length of the dynamic array is stored 3593 * in the top half of the field, and the offset 3594 * is in the bottom half of the 32 bit field. 3595 */ 3596 offset &= 0xffff; 3597 offset += right; 3598 break; 3599 case PRINT_FIELD: 3600 if (!larg->field.field) { 3601 larg->field.field = 3602 pevent_find_any_field(event, larg->field.name); 3603 if (!larg->field.field) { 3604 arg = larg; 3605 goto out_warning_field; 3606 } 3607 } 3608 field_size = larg->field.field->elementsize; 3609 offset = larg->field.field->offset + 3610 right * larg->field.field->elementsize; 3611 break; 3612 default: 3613 goto default_op; /* oops, all bets off */ 3614 } 3615 val = pevent_read_number(pevent, 3616 data + offset, field_size); 3617 if (typearg) 3618 val = eval_type(val, typearg, 1); 3619 break; 3620 } else if (strcmp(arg->op.op, "?") == 0) { 3621 left = eval_num_arg(data, size, event, arg->op.left); 3622 arg = arg->op.right; 3623 if (left) 3624 val = eval_num_arg(data, size, event, arg->op.left); 3625 else 3626 val = eval_num_arg(data, size, event, arg->op.right); 3627 break; 3628 } 3629 default_op: 3630 left = eval_num_arg(data, size, event, arg->op.left); 3631 right = eval_num_arg(data, size, event, arg->op.right); 3632 switch (arg->op.op[0]) { 3633 case '!': 3634 switch (arg->op.op[1]) { 3635 case 0: 3636 val = !right; 3637 break; 3638 case '=': 3639 val = left != right; 3640 break; 3641 default: 3642 goto out_warning_op; 3643 } 3644 break; 3645 case '~': 3646 val = ~right; 3647 break; 3648 case '|': 3649 if (arg->op.op[1]) 3650 val = left || right; 3651 else 3652 val = left | right; 3653 break; 3654 case '&': 3655 if (arg->op.op[1]) 3656 val = left && right; 3657 else 3658 val = left & right; 3659 break; 3660 case '<': 3661 switch (arg->op.op[1]) { 3662 case 0: 3663 val = left < right; 3664 break; 3665 case '<': 3666 val = left << right; 3667 break; 3668 case '=': 3669 val = left <= right; 3670 break; 3671 default: 3672 goto out_warning_op; 3673 } 3674 break; 3675 case '>': 3676 switch (arg->op.op[1]) { 3677 case 0: 3678 val = left > right; 3679 break; 3680 case '>': 3681 val = left >> right; 3682 break; 3683 case '=': 3684 val = left >= right; 3685 break; 3686 default: 3687 goto out_warning_op; 3688 } 3689 break; 3690 case '=': 3691 if (arg->op.op[1] != '=') 3692 goto out_warning_op; 3693 3694 val = left == right; 3695 break; 3696 case '-': 3697 val = left - right; 3698 break; 3699 case '+': 3700 val = left + right; 3701 break; 3702 case '/': 3703 val = left / right; 3704 break; 3705 case '%': 3706 val = left % right; 3707 break; 3708 case '*': 3709 val = left * right; 3710 break; 3711 default: 3712 goto out_warning_op; 3713 } 3714 break; 3715 case PRINT_DYNAMIC_ARRAY_LEN: 3716 offset = pevent_read_number(pevent, 3717 data + arg->dynarray.field->offset, 3718 arg->dynarray.field->size); 3719 /* 3720 * The total allocated length of the dynamic array is 3721 * stored in the top half of the field, and the offset 3722 * is in the bottom half of the 32 bit field. 3723 */ 3724 val = (unsigned long long)(offset >> 16); 3725 break; 3726 case PRINT_DYNAMIC_ARRAY: 3727 /* Without [], we pass the address to the dynamic data */ 3728 offset = pevent_read_number(pevent, 3729 data + arg->dynarray.field->offset, 3730 arg->dynarray.field->size); 3731 /* 3732 * The total allocated length of the dynamic array is 3733 * stored in the top half of the field, and the offset 3734 * is in the bottom half of the 32 bit field. 3735 */ 3736 offset &= 0xffff; 3737 val = (unsigned long long)((unsigned long)data + offset); 3738 break; 3739 default: /* not sure what to do there */ 3740 return 0; 3741 } 3742 return val; 3743 3744out_warning_op: 3745 do_warning_event(event, "%s: unknown op '%s'", __func__, arg->op.op); 3746 return 0; 3747 3748out_warning_field: 3749 do_warning_event(event, "%s: field %s not found", 3750 __func__, arg->field.name); 3751 return 0; 3752} 3753 3754struct flag { 3755 const char *name; 3756 unsigned long long value; 3757}; 3758 3759static const struct flag flags[] = { 3760 { "HI_SOFTIRQ", 0 }, 3761 { "TIMER_SOFTIRQ", 1 }, 3762 { "NET_TX_SOFTIRQ", 2 }, 3763 { "NET_RX_SOFTIRQ", 3 }, 3764 { "BLOCK_SOFTIRQ", 4 }, 3765 { "IRQ_POLL_SOFTIRQ", 5 }, 3766 { "TASKLET_SOFTIRQ", 6 }, 3767 { "SCHED_SOFTIRQ", 7 }, 3768 { "HRTIMER_SOFTIRQ", 8 }, 3769 { "RCU_SOFTIRQ", 9 }, 3770 3771 { "HRTIMER_NORESTART", 0 }, 3772 { "HRTIMER_RESTART", 1 }, 3773}; 3774 3775static long long eval_flag(const char *flag) 3776{ 3777 int i; 3778 3779 /* 3780 * Some flags in the format files do not get converted. 3781 * If the flag is not numeric, see if it is something that 3782 * we already know about. 3783 */ 3784 if (isdigit(flag[0])) 3785 return strtoull(flag, NULL, 0); 3786 3787 for (i = 0; i < (int)(sizeof(flags)/sizeof(flags[0])); i++) 3788 if (strcmp(flags[i].name, flag) == 0) 3789 return flags[i].value; 3790 3791 return -1LL; 3792} 3793 3794static void print_str_to_seq(struct trace_seq *s, const char *format, 3795 int len_arg, const char *str) 3796{ 3797 if (len_arg >= 0) 3798 trace_seq_printf(s, format, len_arg, str); 3799 else 3800 trace_seq_printf(s, format, str); 3801} 3802 3803static void print_bitmask_to_seq(struct pevent *pevent, 3804 struct trace_seq *s, const char *format, 3805 int len_arg, const void *data, int size) 3806{ 3807 int nr_bits = size * 8; 3808 int str_size = (nr_bits + 3) / 4; 3809 int len = 0; 3810 char buf[3]; 3811 char *str; 3812 int index; 3813 int i; 3814 3815 /* 3816 * The kernel likes to put in commas every 32 bits, we 3817 * can do the same. 3818 */ 3819 str_size += (nr_bits - 1) / 32; 3820 3821 str = malloc(str_size + 1); 3822 if (!str) { 3823 do_warning("%s: not enough memory!", __func__); 3824 return; 3825 } 3826 str[str_size] = 0; 3827 3828 /* Start out with -2 for the two chars per byte */ 3829 for (i = str_size - 2; i >= 0; i -= 2) { 3830 /* 3831 * data points to a bit mask of size bytes. 3832 * In the kernel, this is an array of long words, thus 3833 * endianess is very important. 3834 */ 3835 if (pevent->file_bigendian) 3836 index = size - (len + 1); 3837 else 3838 index = len; 3839 3840 snprintf(buf, 3, "%02x", *((unsigned char *)data + index)); 3841 memcpy(str + i, buf, 2); 3842 len++; 3843 if (!(len & 3) && i > 0) { 3844 i--; 3845 str[i] = ','; 3846 } 3847 } 3848 3849 if (len_arg >= 0) 3850 trace_seq_printf(s, format, len_arg, str); 3851 else 3852 trace_seq_printf(s, format, str); 3853 3854 free(str); 3855} 3856 3857static void print_str_arg(struct trace_seq *s, void *data, int size, 3858 struct event_format *event, const char *format, 3859 int len_arg, struct print_arg *arg) 3860{ 3861 struct pevent *pevent = event->pevent; 3862 struct print_flag_sym *flag; 3863 struct format_field *field; 3864 struct printk_map *printk; 3865 long long val, fval; 3866 unsigned long long addr; 3867 char *str; 3868 unsigned char *hex; 3869 int print; 3870 int i, len; 3871 3872 switch (arg->type) { 3873 case PRINT_NULL: 3874 /* ?? */ 3875 return; 3876 case PRINT_ATOM: 3877 print_str_to_seq(s, format, len_arg, arg->atom.atom); 3878 return; 3879 case PRINT_FIELD: 3880 field = arg->field.field; 3881 if (!field) { 3882 field = pevent_find_any_field(event, arg->field.name); 3883 if (!field) { 3884 str = arg->field.name; 3885 goto out_warning_field; 3886 } 3887 arg->field.field = field; 3888 } 3889 /* Zero sized fields, mean the rest of the data */ 3890 len = field->size ? : size - field->offset; 3891 3892 /* 3893 * Some events pass in pointers. If this is not an array 3894 * and the size is the same as long_size, assume that it 3895 * is a pointer. 3896 */ 3897 if (!(field->flags & FIELD_IS_ARRAY) && 3898 field->size == pevent->long_size) { 3899 3900 /* Handle heterogeneous recording and processing 3901 * architectures 3902 * 3903 * CASE I: 3904 * Traces recorded on 32-bit devices (32-bit 3905 * addressing) and processed on 64-bit devices: 3906 * In this case, only 32 bits should be read. 3907 * 3908 * CASE II: 3909 * Traces recorded on 64 bit devices and processed 3910 * on 32-bit devices: 3911 * In this case, 64 bits must be read. 3912 */ 3913 addr = (pevent->long_size == 8) ? 3914 *(unsigned long long *)(data + field->offset) : 3915 (unsigned long long)*(unsigned int *)(data + field->offset); 3916 3917 /* Check if it matches a print format */ 3918 printk = find_printk(pevent, addr); 3919 if (printk) 3920 trace_seq_puts(s, printk->printk); 3921 else 3922 trace_seq_printf(s, "%llx", addr); 3923 break; 3924 } 3925 str = malloc(len + 1); 3926 if (!str) { 3927 do_warning_event(event, "%s: not enough memory!", 3928 __func__); 3929 return; 3930 } 3931 memcpy(str, data + field->offset, len); 3932 str[len] = 0; 3933 print_str_to_seq(s, format, len_arg, str); 3934 free(str); 3935 break; 3936 case PRINT_FLAGS: 3937 val = eval_num_arg(data, size, event, arg->flags.field); 3938 print = 0; 3939 for (flag = arg->flags.flags; flag; flag = flag->next) { 3940 fval = eval_flag(flag->value); 3941 if (!val && fval < 0) { 3942 print_str_to_seq(s, format, len_arg, flag->str); 3943 break; 3944 } 3945 if (fval > 0 && (val & fval) == fval) { 3946 if (print && arg->flags.delim) 3947 trace_seq_puts(s, arg->flags.delim); 3948 print_str_to_seq(s, format, len_arg, flag->str); 3949 print = 1; 3950 val &= ~fval; 3951 } 3952 } 3953 break; 3954 case PRINT_SYMBOL: 3955 val = eval_num_arg(data, size, event, arg->symbol.field); 3956 for (flag = arg->symbol.symbols; flag; flag = flag->next) { 3957 fval = eval_flag(flag->value); 3958 if (val == fval) { 3959 print_str_to_seq(s, format, len_arg, flag->str); 3960 break; 3961 } 3962 } 3963 break; 3964 case PRINT_HEX: 3965 if (arg->hex.field->type == PRINT_DYNAMIC_ARRAY) { 3966 unsigned long offset; 3967 offset = pevent_read_number(pevent, 3968 data + arg->hex.field->dynarray.field->offset, 3969 arg->hex.field->dynarray.field->size); 3970 hex = data + (offset & 0xffff); 3971 } else { 3972 field = arg->hex.field->field.field; 3973 if (!field) { 3974 str = arg->hex.field->field.name; 3975 field = pevent_find_any_field(event, str); 3976 if (!field) 3977 goto out_warning_field; 3978 arg->hex.field->field.field = field; 3979 } 3980 hex = data + field->offset; 3981 } 3982 len = eval_num_arg(data, size, event, arg->hex.size); 3983 for (i = 0; i < len; i++) { 3984 if (i) 3985 trace_seq_putc(s, ' '); 3986 trace_seq_printf(s, "%02x", hex[i]); 3987 } 3988 break; 3989 3990 case PRINT_INT_ARRAY: { 3991 void *num; 3992 int el_size; 3993 3994 if (arg->int_array.field->type == PRINT_DYNAMIC_ARRAY) { 3995 unsigned long offset; 3996 struct format_field *field = 3997 arg->int_array.field->dynarray.field; 3998 offset = pevent_read_number(pevent, 3999 data + field->offset, 4000 field->size); 4001 num = data + (offset & 0xffff); 4002 } else { 4003 field = arg->int_array.field->field.field; 4004 if (!field) { 4005 str = arg->int_array.field->field.name; 4006 field = pevent_find_any_field(event, str); 4007 if (!field) 4008 goto out_warning_field; 4009 arg->int_array.field->field.field = field; 4010 } 4011 num = data + field->offset; 4012 } 4013 len = eval_num_arg(data, size, event, arg->int_array.count); 4014 el_size = eval_num_arg(data, size, event, 4015 arg->int_array.el_size); 4016 for (i = 0; i < len; i++) { 4017 if (i) 4018 trace_seq_putc(s, ' '); 4019 4020 if (el_size == 1) { 4021 trace_seq_printf(s, "%u", *(uint8_t *)num); 4022 } else if (el_size == 2) { 4023 trace_seq_printf(s, "%u", *(uint16_t *)num); 4024 } else if (el_size == 4) { 4025 trace_seq_printf(s, "%u", *(uint32_t *)num); 4026 } else if (el_size == 8) { 4027 trace_seq_printf(s, "%"PRIu64, *(uint64_t *)num); 4028 } else { 4029 trace_seq_printf(s, "BAD SIZE:%d 0x%x", 4030 el_size, *(uint8_t *)num); 4031 el_size = 1; 4032 } 4033 4034 num += el_size; 4035 } 4036 break; 4037 } 4038 case PRINT_TYPE: 4039 break; 4040 case PRINT_STRING: { 4041 int str_offset; 4042 4043 if (arg->string.offset == -1) { 4044 struct format_field *f; 4045 4046 f = pevent_find_any_field(event, arg->string.string); 4047 arg->string.offset = f->offset; 4048 } 4049 str_offset = data2host4(pevent, data + arg->string.offset); 4050 str_offset &= 0xffff; 4051 print_str_to_seq(s, format, len_arg, ((char *)data) + str_offset); 4052 break; 4053 } 4054 case PRINT_BSTRING: 4055 print_str_to_seq(s, format, len_arg, arg->string.string); 4056 break; 4057 case PRINT_BITMASK: { 4058 int bitmask_offset; 4059 int bitmask_size; 4060 4061 if (arg->bitmask.offset == -1) { 4062 struct format_field *f; 4063 4064 f = pevent_find_any_field(event, arg->bitmask.bitmask); 4065 arg->bitmask.offset = f->offset; 4066 } 4067 bitmask_offset = data2host4(pevent, data + arg->bitmask.offset); 4068 bitmask_size = bitmask_offset >> 16; 4069 bitmask_offset &= 0xffff; 4070 print_bitmask_to_seq(pevent, s, format, len_arg, 4071 data + bitmask_offset, bitmask_size); 4072 break; 4073 } 4074 case PRINT_OP: 4075 /* 4076 * The only op for string should be ? : 4077 */ 4078 if (arg->op.op[0] != '?') 4079 return; 4080 val = eval_num_arg(data, size, event, arg->op.left); 4081 if (val) 4082 print_str_arg(s, data, size, event, 4083 format, len_arg, arg->op.right->op.left); 4084 else 4085 print_str_arg(s, data, size, event, 4086 format, len_arg, arg->op.right->op.right); 4087 break; 4088 case PRINT_FUNC: 4089 process_defined_func(s, data, size, event, arg); 4090 break; 4091 default: 4092 /* well... */ 4093 break; 4094 } 4095 4096 return; 4097 4098out_warning_field: 4099 do_warning_event(event, "%s: field %s not found", 4100 __func__, arg->field.name); 4101} 4102 4103static unsigned long long 4104process_defined_func(struct trace_seq *s, void *data, int size, 4105 struct event_format *event, struct print_arg *arg) 4106{ 4107 struct pevent_function_handler *func_handle = arg->func.func; 4108 struct pevent_func_params *param; 4109 unsigned long long *args; 4110 unsigned long long ret; 4111 struct print_arg *farg; 4112 struct trace_seq str; 4113 struct save_str { 4114 struct save_str *next; 4115 char *str; 4116 } *strings = NULL, *string; 4117 int i; 4118 4119 if (!func_handle->nr_args) { 4120 ret = (*func_handle->func)(s, NULL); 4121 goto out; 4122 } 4123 4124 farg = arg->func.args; 4125 param = func_handle->params; 4126 4127 ret = ULLONG_MAX; 4128 args = malloc(sizeof(*args) * func_handle->nr_args); 4129 if (!args) 4130 goto out; 4131 4132 for (i = 0; i < func_handle->nr_args; i++) { 4133 switch (param->type) { 4134 case PEVENT_FUNC_ARG_INT: 4135 case PEVENT_FUNC_ARG_LONG: 4136 case PEVENT_FUNC_ARG_PTR: 4137 args[i] = eval_num_arg(data, size, event, farg); 4138 break; 4139 case PEVENT_FUNC_ARG_STRING: 4140 trace_seq_init(&str); 4141 print_str_arg(&str, data, size, event, "%s", -1, farg); 4142 trace_seq_terminate(&str); 4143 string = malloc(sizeof(*string)); 4144 if (!string) { 4145 do_warning_event(event, "%s(%d): malloc str", 4146 __func__, __LINE__); 4147 goto out_free; 4148 } 4149 string->next = strings; 4150 string->str = strdup(str.buffer); 4151 if (!string->str) { 4152 free(string); 4153 do_warning_event(event, "%s(%d): malloc str", 4154 __func__, __LINE__); 4155 goto out_free; 4156 } 4157 args[i] = (uintptr_t)string->str; 4158 strings = string; 4159 trace_seq_destroy(&str); 4160 break; 4161 default: 4162 /* 4163 * Something went totally wrong, this is not 4164 * an input error, something in this code broke. 4165 */ 4166 do_warning_event(event, "Unexpected end of arguments\n"); 4167 goto out_free; 4168 } 4169 farg = farg->next; 4170 param = param->next; 4171 } 4172 4173 ret = (*func_handle->func)(s, args); 4174out_free: 4175 free(args); 4176 while (strings) { 4177 string = strings; 4178 strings = string->next; 4179 free(string->str); 4180 free(string); 4181 } 4182 4183 out: 4184 /* TBD : handle return type here */ 4185 return ret; 4186} 4187 4188static void free_args(struct print_arg *args) 4189{ 4190 struct print_arg *next; 4191 4192 while (args) { 4193 next = args->next; 4194 4195 free_arg(args); 4196 args = next; 4197 } 4198} 4199 4200static struct print_arg *make_bprint_args(char *fmt, void *data, int size, struct event_format *event) 4201{ 4202 struct pevent *pevent = event->pevent; 4203 struct format_field *field, *ip_field; 4204 struct print_arg *args, *arg, **next; 4205 unsigned long long ip, val; 4206 char *ptr; 4207 void *bptr; 4208 int vsize; 4209 4210 field = pevent->bprint_buf_field; 4211 ip_field = pevent->bprint_ip_field; 4212 4213 if (!field) { 4214 field = pevent_find_field(event, "buf"); 4215 if (!field) { 4216 do_warning_event(event, "can't find buffer field for binary printk"); 4217 return NULL; 4218 } 4219 ip_field = pevent_find_field(event, "ip"); 4220 if (!ip_field) { 4221 do_warning_event(event, "can't find ip field for binary printk"); 4222 return NULL; 4223 } 4224 pevent->bprint_buf_field = field; 4225 pevent->bprint_ip_field = ip_field; 4226 } 4227 4228 ip = pevent_read_number(pevent, data + ip_field->offset, ip_field->size); 4229 4230 /* 4231 * The first arg is the IP pointer. 4232 */ 4233 args = alloc_arg(); 4234 if (!args) { 4235 do_warning_event(event, "%s(%d): not enough memory!", 4236 __func__, __LINE__); 4237 return NULL; 4238 } 4239 arg = args; 4240 arg->next = NULL; 4241 next = &arg->next; 4242 4243 arg->type = PRINT_ATOM; 4244 4245 if (asprintf(&arg->atom.atom, "%lld", ip) < 0) 4246 goto out_free; 4247 4248 /* skip the first "%ps: " */ 4249 for (ptr = fmt + 5, bptr = data + field->offset; 4250 bptr < data + size && *ptr; ptr++) { 4251 int ls = 0; 4252 4253 if (*ptr == '%') { 4254 process_again: 4255 ptr++; 4256 switch (*ptr) { 4257 case '%': 4258 break; 4259 case 'l': 4260 ls++; 4261 goto process_again; 4262 case 'L': 4263 ls = 2; 4264 goto process_again; 4265 case '0' ... '9': 4266 goto process_again; 4267 case '.': 4268 goto process_again; 4269 case 'z': 4270 case 'Z': 4271 ls = 1; 4272 goto process_again; 4273 case 'p': 4274 ls = 1; 4275 /* fall through */ 4276 case 'd': 4277 case 'u': 4278 case 'x': 4279 case 'i': 4280 switch (ls) { 4281 case 0: 4282 vsize = 4; 4283 break; 4284 case 1: 4285 vsize = pevent->long_size; 4286 break; 4287 case 2: 4288 vsize = 8; 4289 break; 4290 default: 4291 vsize = ls; /* ? */ 4292 break; 4293 } 4294 /* fall through */ 4295 case '*': 4296 if (*ptr == '*') 4297 vsize = 4; 4298 4299 /* the pointers are always 4 bytes aligned */ 4300 bptr = (void *)(((unsigned long)bptr + 3) & 4301 ~3); 4302 val = pevent_read_number(pevent, bptr, vsize); 4303 bptr += vsize; 4304 arg = alloc_arg(); 4305 if (!arg) { 4306 do_warning_event(event, "%s(%d): not enough memory!", 4307 __func__, __LINE__); 4308 goto out_free; 4309 } 4310 arg->next = NULL; 4311 arg->type = PRINT_ATOM; 4312 if (asprintf(&arg->atom.atom, "%lld", val) < 0) { 4313 free(arg); 4314 goto out_free; 4315 } 4316 *next = arg; 4317 next = &arg->next; 4318 /* 4319 * The '*' case means that an arg is used as the length. 4320 * We need to continue to figure out for what. 4321 */ 4322 if (*ptr == '*') 4323 goto process_again; 4324 4325 break; 4326 case 's': 4327 arg = alloc_arg(); 4328 if (!arg) { 4329 do_warning_event(event, "%s(%d): not enough memory!", 4330 __func__, __LINE__); 4331 goto out_free; 4332 } 4333 arg->next = NULL; 4334 arg->type = PRINT_BSTRING; 4335 arg->string.string = strdup(bptr); 4336 if (!arg->string.string) 4337 goto out_free; 4338 bptr += strlen(bptr) + 1; 4339 *next = arg; 4340 next = &arg->next; 4341 default: 4342 break; 4343 } 4344 } 4345 } 4346 4347 return args; 4348 4349out_free: 4350 free_args(args); 4351 return NULL; 4352} 4353 4354static char * 4355get_bprint_format(void *data, int size __maybe_unused, 4356 struct event_format *event) 4357{ 4358 struct pevent *pevent = event->pevent; 4359 unsigned long long addr; 4360 struct format_field *field; 4361 struct printk_map *printk; 4362 char *format; 4363 4364 field = pevent->bprint_fmt_field; 4365 4366 if (!field) { 4367 field = pevent_find_field(event, "fmt"); 4368 if (!field) { 4369 do_warning_event(event, "can't find format field for binary printk"); 4370 return NULL; 4371 } 4372 pevent->bprint_fmt_field = field; 4373 } 4374 4375 addr = pevent_read_number(pevent, data + field->offset, field->size); 4376 4377 printk = find_printk(pevent, addr); 4378 if (!printk) { 4379 if (asprintf(&format, "%%pf: (NO FORMAT FOUND at %llx)\n", addr) < 0) 4380 return NULL; 4381 return format; 4382 } 4383 4384 if (asprintf(&format, "%s: %s", "%pf", printk->printk) < 0) 4385 return NULL; 4386 4387 return format; 4388} 4389 4390static void print_mac_arg(struct trace_seq *s, int mac, void *data, int size, 4391 struct event_format *event, struct print_arg *arg) 4392{ 4393 unsigned char *buf; 4394 const char *fmt = "%.2x:%.2x:%.2x:%.2x:%.2x:%.2x"; 4395 4396 if (arg->type == PRINT_FUNC) { 4397 process_defined_func(s, data, size, event, arg); 4398 return; 4399 } 4400 4401 if (arg->type != PRINT_FIELD) { 4402 trace_seq_printf(s, "ARG TYPE NOT FIELD BUT %d", 4403 arg->type); 4404 return; 4405 } 4406 4407 if (mac == 'm') 4408 fmt = "%.2x%.2x%.2x%.2x%.2x%.2x"; 4409 if (!arg->field.field) { 4410 arg->field.field = 4411 pevent_find_any_field(event, arg->field.name); 4412 if (!arg->field.field) { 4413 do_warning_event(event, "%s: field %s not found", 4414 __func__, arg->field.name); 4415 return; 4416 } 4417 } 4418 if (arg->field.field->size != 6) { 4419 trace_seq_printf(s, "INVALIDMAC"); 4420 return; 4421 } 4422 buf = data + arg->field.field->offset; 4423 trace_seq_printf(s, fmt, buf[0], buf[1], buf[2], buf[3], buf[4], buf[5]); 4424} 4425 4426static void print_ip4_addr(struct trace_seq *s, char i, unsigned char *buf) 4427{ 4428 const char *fmt; 4429 4430 if (i == 'i') 4431 fmt = "%03d.%03d.%03d.%03d"; 4432 else 4433 fmt = "%d.%d.%d.%d"; 4434 4435 trace_seq_printf(s, fmt, buf[0], buf[1], buf[2], buf[3]); 4436} 4437 4438static inline bool ipv6_addr_v4mapped(const struct in6_addr *a) 4439{ 4440 return ((unsigned long)(a->s6_addr32[0] | a->s6_addr32[1]) | 4441 (unsigned long)(a->s6_addr32[2] ^ htonl(0x0000ffff))) == 0UL; 4442} 4443 4444static inline bool ipv6_addr_is_isatap(const struct in6_addr *addr) 4445{ 4446 return (addr->s6_addr32[2] | htonl(0x02000000)) == htonl(0x02005EFE); 4447} 4448 4449static void print_ip6c_addr(struct trace_seq *s, unsigned char *addr) 4450{ 4451 int i, j, range; 4452 unsigned char zerolength[8]; 4453 int longest = 1; 4454 int colonpos = -1; 4455 uint16_t word; 4456 uint8_t hi, lo; 4457 bool needcolon = false; 4458 bool useIPv4; 4459 struct in6_addr in6; 4460 4461 memcpy(&in6, addr, sizeof(struct in6_addr)); 4462 4463 useIPv4 = ipv6_addr_v4mapped(&in6) || ipv6_addr_is_isatap(&in6); 4464 4465 memset(zerolength, 0, sizeof(zerolength)); 4466 4467 if (useIPv4) 4468 range = 6; 4469 else 4470 range = 8; 4471 4472 /* find position of longest 0 run */ 4473 for (i = 0; i < range; i++) { 4474 for (j = i; j < range; j++) { 4475 if (in6.s6_addr16[j] != 0) 4476 break; 4477 zerolength[i]++; 4478 } 4479 } 4480 for (i = 0; i < range; i++) { 4481 if (zerolength[i] > longest) { 4482 longest = zerolength[i]; 4483 colonpos = i; 4484 } 4485 } 4486 if (longest == 1) /* don't compress a single 0 */ 4487 colonpos = -1; 4488 4489 /* emit address */ 4490 for (i = 0; i < range; i++) { 4491 if (i == colonpos) { 4492 if (needcolon || i == 0) 4493 trace_seq_printf(s, ":"); 4494 trace_seq_printf(s, ":"); 4495 needcolon = false; 4496 i += longest - 1; 4497 continue; 4498 } 4499 if (needcolon) { 4500 trace_seq_printf(s, ":"); 4501 needcolon = false; 4502 } 4503 /* hex u16 without leading 0s */ 4504 word = ntohs(in6.s6_addr16[i]); 4505 hi = word >> 8; 4506 lo = word & 0xff; 4507 if (hi) 4508 trace_seq_printf(s, "%x%02x", hi, lo); 4509 else 4510 trace_seq_printf(s, "%x", lo); 4511 4512 needcolon = true; 4513 } 4514 4515 if (useIPv4) { 4516 if (needcolon) 4517 trace_seq_printf(s, ":"); 4518 print_ip4_addr(s, 'I', &in6.s6_addr[12]); 4519 } 4520 4521 return; 4522} 4523 4524static void print_ip6_addr(struct trace_seq *s, char i, unsigned char *buf) 4525{ 4526 int j; 4527 4528 for (j = 0; j < 16; j += 2) { 4529 trace_seq_printf(s, "%02x%02x", buf[j], buf[j+1]); 4530 if (i == 'I' && j < 14) 4531 trace_seq_printf(s, ":"); 4532 } 4533} 4534 4535/* 4536 * %pi4 print an IPv4 address with leading zeros 4537 * %pI4 print an IPv4 address without leading zeros 4538 * %pi6 print an IPv6 address without colons 4539 * %pI6 print an IPv6 address with colons 4540 * %pI6c print an IPv6 address in compressed form with colons 4541 * %pISpc print an IP address based on sockaddr; p adds port. 4542 */ 4543static int print_ipv4_arg(struct trace_seq *s, const char *ptr, char i, 4544 void *data, int size, struct event_format *event, 4545 struct print_arg *arg) 4546{ 4547 unsigned char *buf; 4548 4549 if (arg->type == PRINT_FUNC) { 4550 process_defined_func(s, data, size, event, arg); 4551 return 0; 4552 } 4553 4554 if (arg->type != PRINT_FIELD) { 4555 trace_seq_printf(s, "ARG TYPE NOT FIELD BUT %d", arg->type); 4556 return 0; 4557 } 4558 4559 if (!arg->field.field) { 4560 arg->field.field = 4561 pevent_find_any_field(event, arg->field.name); 4562 if (!arg->field.field) { 4563 do_warning("%s: field %s not found", 4564 __func__, arg->field.name); 4565 return 0; 4566 } 4567 } 4568 4569 buf = data + arg->field.field->offset; 4570 4571 if (arg->field.field->size != 4) { 4572 trace_seq_printf(s, "INVALIDIPv4"); 4573 return 0; 4574 } 4575 print_ip4_addr(s, i, buf); 4576 4577 return 0; 4578} 4579 4580static int print_ipv6_arg(struct trace_seq *s, const char *ptr, char i, 4581 void *data, int size, struct event_format *event, 4582 struct print_arg *arg) 4583{ 4584 char have_c = 0; 4585 unsigned char *buf; 4586 int rc = 0; 4587 4588 /* pI6c */ 4589 if (i == 'I' && *ptr == 'c') { 4590 have_c = 1; 4591 ptr++; 4592 rc++; 4593 } 4594 4595 if (arg->type == PRINT_FUNC) { 4596 process_defined_func(s, data, size, event, arg); 4597 return rc; 4598 } 4599 4600 if (arg->type != PRINT_FIELD) { 4601 trace_seq_printf(s, "ARG TYPE NOT FIELD BUT %d", arg->type); 4602 return rc; 4603 } 4604 4605 if (!arg->field.field) { 4606 arg->field.field = 4607 pevent_find_any_field(event, arg->field.name); 4608 if (!arg->field.field) { 4609 do_warning("%s: field %s not found", 4610 __func__, arg->field.name); 4611 return rc; 4612 } 4613 } 4614 4615 buf = data + arg->field.field->offset; 4616 4617 if (arg->field.field->size != 16) { 4618 trace_seq_printf(s, "INVALIDIPv6"); 4619 return rc; 4620 } 4621 4622 if (have_c) 4623 print_ip6c_addr(s, buf); 4624 else 4625 print_ip6_addr(s, i, buf); 4626 4627 return rc; 4628} 4629 4630static int print_ipsa_arg(struct trace_seq *s, const char *ptr, char i, 4631 void *data, int size, struct event_format *event, 4632 struct print_arg *arg) 4633{ 4634 char have_c = 0, have_p = 0; 4635 unsigned char *buf; 4636 struct sockaddr_storage *sa; 4637 int rc = 0; 4638 4639 /* pISpc */ 4640 if (i == 'I') { 4641 if (*ptr == 'p') { 4642 have_p = 1; 4643 ptr++; 4644 rc++; 4645 } 4646 if (*ptr == 'c') { 4647 have_c = 1; 4648 ptr++; 4649 rc++; 4650 } 4651 } 4652 4653 if (arg->type == PRINT_FUNC) { 4654 process_defined_func(s, data, size, event, arg); 4655 return rc; 4656 } 4657 4658 if (arg->type != PRINT_FIELD) { 4659 trace_seq_printf(s, "ARG TYPE NOT FIELD BUT %d", arg->type); 4660 return rc; 4661 } 4662 4663 if (!arg->field.field) { 4664 arg->field.field = 4665 pevent_find_any_field(event, arg->field.name); 4666 if (!arg->field.field) { 4667 do_warning("%s: field %s not found", 4668 __func__, arg->field.name); 4669 return rc; 4670 } 4671 } 4672 4673 sa = (struct sockaddr_storage *) (data + arg->field.field->offset); 4674 4675 if (sa->ss_family == AF_INET) { 4676 struct sockaddr_in *sa4 = (struct sockaddr_in *) sa; 4677 4678 if (arg->field.field->size < sizeof(struct sockaddr_in)) { 4679 trace_seq_printf(s, "INVALIDIPv4"); 4680 return rc; 4681 } 4682 4683 print_ip4_addr(s, i, (unsigned char *) &sa4->sin_addr); 4684 if (have_p) 4685 trace_seq_printf(s, ":%d", ntohs(sa4->sin_port)); 4686 4687 4688 } else if (sa->ss_family == AF_INET6) { 4689 struct sockaddr_in6 *sa6 = (struct sockaddr_in6 *) sa; 4690 4691 if (arg->field.field->size < sizeof(struct sockaddr_in6)) { 4692 trace_seq_printf(s, "INVALIDIPv6"); 4693 return rc; 4694 } 4695 4696 if (have_p) 4697 trace_seq_printf(s, "["); 4698 4699 buf = (unsigned char *) &sa6->sin6_addr; 4700 if (have_c) 4701 print_ip6c_addr(s, buf); 4702 else 4703 print_ip6_addr(s, i, buf); 4704 4705 if (have_p) 4706 trace_seq_printf(s, "]:%d", ntohs(sa6->sin6_port)); 4707 } 4708 4709 return rc; 4710} 4711 4712static int print_ip_arg(struct trace_seq *s, const char *ptr, 4713 void *data, int size, struct event_format *event, 4714 struct print_arg *arg) 4715{ 4716 char i = *ptr; /* 'i' or 'I' */ 4717 char ver; 4718 int rc = 0; 4719 4720 ptr++; 4721 rc++; 4722 4723 ver = *ptr; 4724 ptr++; 4725 rc++; 4726 4727 switch (ver) { 4728 case '4': 4729 rc += print_ipv4_arg(s, ptr, i, data, size, event, arg); 4730 break; 4731 case '6': 4732 rc += print_ipv6_arg(s, ptr, i, data, size, event, arg); 4733 break; 4734 case 'S': 4735 rc += print_ipsa_arg(s, ptr, i, data, size, event, arg); 4736 break; 4737 default: 4738 return 0; 4739 } 4740 4741 return rc; 4742} 4743 4744static int is_printable_array(char *p, unsigned int len) 4745{ 4746 unsigned int i; 4747 4748 for (i = 0; i < len && p[i]; i++) 4749 if (!isprint(p[i]) && !isspace(p[i])) 4750 return 0; 4751 return 1; 4752} 4753 4754void pevent_print_field(struct trace_seq *s, void *data, 4755 struct format_field *field) 4756{ 4757 unsigned long long val; 4758 unsigned int offset, len, i; 4759 struct pevent *pevent = field->event->pevent; 4760 4761 if (field->flags & FIELD_IS_ARRAY) { 4762 offset = field->offset; 4763 len = field->size; 4764 if (field->flags & FIELD_IS_DYNAMIC) { 4765 val = pevent_read_number(pevent, data + offset, len); 4766 offset = val; 4767 len = offset >> 16; 4768 offset &= 0xffff; 4769 } 4770 if (field->flags & FIELD_IS_STRING && 4771 is_printable_array(data + offset, len)) { 4772 trace_seq_printf(s, "%s", (char *)data + offset); 4773 } else { 4774 trace_seq_puts(s, "ARRAY["); 4775 for (i = 0; i < len; i++) { 4776 if (i) 4777 trace_seq_puts(s, ", "); 4778 trace_seq_printf(s, "%02x", 4779 *((unsigned char *)data + offset + i)); 4780 } 4781 trace_seq_putc(s, ']'); 4782 field->flags &= ~FIELD_IS_STRING; 4783 } 4784 } else { 4785 val = pevent_read_number(pevent, data + field->offset, 4786 field->size); 4787 if (field->flags & FIELD_IS_POINTER) { 4788 trace_seq_printf(s, "0x%llx", val); 4789 } else if (field->flags & FIELD_IS_SIGNED) { 4790 switch (field->size) { 4791 case 4: 4792 /* 4793 * If field is long then print it in hex. 4794 * A long usually stores pointers. 4795 */ 4796 if (field->flags & FIELD_IS_LONG) 4797 trace_seq_printf(s, "0x%x", (int)val); 4798 else 4799 trace_seq_printf(s, "%d", (int)val); 4800 break; 4801 case 2: 4802 trace_seq_printf(s, "%2d", (short)val); 4803 break; 4804 case 1: 4805 trace_seq_printf(s, "%1d", (char)val); 4806 break; 4807 default: 4808 trace_seq_printf(s, "%lld", val); 4809 } 4810 } else { 4811 if (field->flags & FIELD_IS_LONG) 4812 trace_seq_printf(s, "0x%llx", val); 4813 else 4814 trace_seq_printf(s, "%llu", val); 4815 } 4816 } 4817} 4818 4819void pevent_print_fields(struct trace_seq *s, void *data, 4820 int size __maybe_unused, struct event_format *event) 4821{ 4822 struct format_field *field; 4823 4824 field = event->format.fields; 4825 while (field) { 4826 trace_seq_printf(s, " %s=", field->name); 4827 pevent_print_field(s, data, field); 4828 field = field->next; 4829 } 4830} 4831 4832static void pretty_print(struct trace_seq *s, void *data, int size, struct event_format *event) 4833{ 4834 struct pevent *pevent = event->pevent; 4835 struct print_fmt *print_fmt = &event->print_fmt; 4836 struct print_arg *arg = print_fmt->args; 4837 struct print_arg *args = NULL; 4838 const char *ptr = print_fmt->format; 4839 unsigned long long val; 4840 struct func_map *func; 4841 const char *saveptr; 4842 struct trace_seq p; 4843 char *bprint_fmt = NULL; 4844 char format[32]; 4845 int show_func; 4846 int len_as_arg; 4847 int len_arg; 4848 int len; 4849 int ls; 4850 4851 if (event->flags & EVENT_FL_FAILED) { 4852 trace_seq_printf(s, "[FAILED TO PARSE]"); 4853 pevent_print_fields(s, data, size, event); 4854 return; 4855 } 4856 4857 if (event->flags & EVENT_FL_ISBPRINT) { 4858 bprint_fmt = get_bprint_format(data, size, event); 4859 args = make_bprint_args(bprint_fmt, data, size, event); 4860 arg = args; 4861 ptr = bprint_fmt; 4862 } 4863 4864 for (; *ptr; ptr++) { 4865 ls = 0; 4866 if (*ptr == '\\') { 4867 ptr++; 4868 switch (*ptr) { 4869 case 'n': 4870 trace_seq_putc(s, '\n'); 4871 break; 4872 case 't': 4873 trace_seq_putc(s, '\t'); 4874 break; 4875 case 'r': 4876 trace_seq_putc(s, '\r'); 4877 break; 4878 case '\\': 4879 trace_seq_putc(s, '\\'); 4880 break; 4881 default: 4882 trace_seq_putc(s, *ptr); 4883 break; 4884 } 4885 4886 } else if (*ptr == '%') { 4887 saveptr = ptr; 4888 show_func = 0; 4889 len_as_arg = 0; 4890 cont_process: 4891 ptr++; 4892 switch (*ptr) { 4893 case '%': 4894 trace_seq_putc(s, '%'); 4895 break; 4896 case '#': 4897 /* FIXME: need to handle properly */ 4898 goto cont_process; 4899 case 'h': 4900 ls--; 4901 goto cont_process; 4902 case 'l': 4903 ls++; 4904 goto cont_process; 4905 case 'L': 4906 ls = 2; 4907 goto cont_process; 4908 case '*': 4909 /* The argument is the length. */ 4910 if (!arg) { 4911 do_warning_event(event, "no argument match"); 4912 event->flags |= EVENT_FL_FAILED; 4913 goto out_failed; 4914 } 4915 len_arg = eval_num_arg(data, size, event, arg); 4916 len_as_arg = 1; 4917 arg = arg->next; 4918 goto cont_process; 4919 case '.': 4920 case 'z': 4921 case 'Z': 4922 case '0' ... '9': 4923 case '-': 4924 goto cont_process; 4925 case 'p': 4926 if (pevent->long_size == 4) 4927 ls = 1; 4928 else 4929 ls = 2; 4930 4931 if (*(ptr+1) == 'F' || *(ptr+1) == 'f' || 4932 *(ptr+1) == 'S' || *(ptr+1) == 's') { 4933 ptr++; 4934 show_func = *ptr; 4935 } else if (*(ptr+1) == 'M' || *(ptr+1) == 'm') { 4936 print_mac_arg(s, *(ptr+1), data, size, event, arg); 4937 ptr++; 4938 arg = arg->next; 4939 break; 4940 } else if (*(ptr+1) == 'I' || *(ptr+1) == 'i') { 4941 int n; 4942 4943 n = print_ip_arg(s, ptr+1, data, size, event, arg); 4944 if (n > 0) { 4945 ptr += n; 4946 arg = arg->next; 4947 break; 4948 } 4949 } 4950 4951 /* fall through */ 4952 case 'd': 4953 case 'i': 4954 case 'x': 4955 case 'X': 4956 case 'u': 4957 if (!arg) { 4958 do_warning_event(event, "no argument match"); 4959 event->flags |= EVENT_FL_FAILED; 4960 goto out_failed; 4961 } 4962 4963 len = ((unsigned long)ptr + 1) - 4964 (unsigned long)saveptr; 4965 4966 /* should never happen */ 4967 if (len > 31) { 4968 do_warning_event(event, "bad format!"); 4969 event->flags |= EVENT_FL_FAILED; 4970 len = 31; 4971 } 4972 4973 memcpy(format, saveptr, len); 4974 format[len] = 0; 4975 4976 val = eval_num_arg(data, size, event, arg); 4977 arg = arg->next; 4978 4979 if (show_func) { 4980 func = find_func(pevent, val); 4981 if (func) { 4982 trace_seq_puts(s, func->func); 4983 if (show_func == 'F') 4984 trace_seq_printf(s, 4985 "+0x%llx", 4986 val - func->addr); 4987 break; 4988 } 4989 } 4990 if (pevent->long_size == 8 && ls == 1 && 4991 sizeof(long) != 8) { 4992 char *p; 4993 4994 /* make %l into %ll */ 4995 if (ls == 1 && (p = strchr(format, 'l'))) 4996 memmove(p+1, p, strlen(p)+1); 4997 else if (strcmp(format, "%p") == 0) 4998 strcpy(format, "0x%llx"); 4999 ls = 2; 5000 } 5001 switch (ls) { 5002 case -2: 5003 if (len_as_arg) 5004 trace_seq_printf(s, format, len_arg, (char)val); 5005 else 5006 trace_seq_printf(s, format, (char)val); 5007 break; 5008 case -1: 5009 if (len_as_arg) 5010 trace_seq_printf(s, format, len_arg, (short)val); 5011 else 5012 trace_seq_printf(s, format, (short)val); 5013 break; 5014 case 0: 5015 if (len_as_arg) 5016 trace_seq_printf(s, format, len_arg, (int)val); 5017 else 5018 trace_seq_printf(s, format, (int)val); 5019 break; 5020 case 1: 5021 if (len_as_arg) 5022 trace_seq_printf(s, format, len_arg, (long)val); 5023 else 5024 trace_seq_printf(s, format, (long)val); 5025 break; 5026 case 2: 5027 if (len_as_arg) 5028 trace_seq_printf(s, format, len_arg, 5029 (long long)val); 5030 else 5031 trace_seq_printf(s, format, (long long)val); 5032 break; 5033 default: 5034 do_warning_event(event, "bad count (%d)", ls); 5035 event->flags |= EVENT_FL_FAILED; 5036 } 5037 break; 5038 case 's': 5039 if (!arg) { 5040 do_warning_event(event, "no matching argument"); 5041 event->flags |= EVENT_FL_FAILED; 5042 goto out_failed; 5043 } 5044 5045 len = ((unsigned long)ptr + 1) - 5046 (unsigned long)saveptr; 5047 5048 /* should never happen */ 5049 if (len > 31) { 5050 do_warning_event(event, "bad format!"); 5051 event->flags |= EVENT_FL_FAILED; 5052 len = 31; 5053 } 5054 5055 memcpy(format, saveptr, len); 5056 format[len] = 0; 5057 if (!len_as_arg) 5058 len_arg = -1; 5059 /* Use helper trace_seq */ 5060 trace_seq_init(&p); 5061 print_str_arg(&p, data, size, event, 5062 format, len_arg, arg); 5063 trace_seq_terminate(&p); 5064 trace_seq_puts(s, p.buffer); 5065 trace_seq_destroy(&p); 5066 arg = arg->next; 5067 break; 5068 default: 5069 trace_seq_printf(s, ">%c<", *ptr); 5070 5071 } 5072 } else 5073 trace_seq_putc(s, *ptr); 5074 } 5075 5076 if (event->flags & EVENT_FL_FAILED) { 5077out_failed: 5078 trace_seq_printf(s, "[FAILED TO PARSE]"); 5079 } 5080 5081 if (args) { 5082 free_args(args); 5083 free(bprint_fmt); 5084 } 5085} 5086 5087/** 5088 * pevent_data_lat_fmt - parse the data for the latency format 5089 * @pevent: a handle to the pevent 5090 * @s: the trace_seq to write to 5091 * @record: the record to read from 5092 * 5093 * This parses out the Latency format (interrupts disabled, 5094 * need rescheduling, in hard/soft interrupt, preempt count 5095 * and lock depth) and places it into the trace_seq. 5096 */ 5097void pevent_data_lat_fmt(struct pevent *pevent, 5098 struct trace_seq *s, struct pevent_record *record) 5099{ 5100 static int check_lock_depth = 1; 5101 static int check_migrate_disable = 1; 5102 static int lock_depth_exists; 5103 static int migrate_disable_exists; 5104 unsigned int lat_flags; 5105 unsigned int pc; 5106 int lock_depth; 5107 int migrate_disable; 5108 int hardirq; 5109 int softirq; 5110 void *data = record->data; 5111 5112 lat_flags = parse_common_flags(pevent, data); 5113 pc = parse_common_pc(pevent, data); 5114 /* lock_depth may not always exist */ 5115 if (lock_depth_exists) 5116 lock_depth = parse_common_lock_depth(pevent, data); 5117 else if (check_lock_depth) { 5118 lock_depth = parse_common_lock_depth(pevent, data); 5119 if (lock_depth < 0) 5120 check_lock_depth = 0; 5121 else 5122 lock_depth_exists = 1; 5123 } 5124 5125 /* migrate_disable may not always exist */ 5126 if (migrate_disable_exists) 5127 migrate_disable = parse_common_migrate_disable(pevent, data); 5128 else if (check_migrate_disable) { 5129 migrate_disable = parse_common_migrate_disable(pevent, data); 5130 if (migrate_disable < 0) 5131 check_migrate_disable = 0; 5132 else 5133 migrate_disable_exists = 1; 5134 } 5135 5136 hardirq = lat_flags & TRACE_FLAG_HARDIRQ; 5137 softirq = lat_flags & TRACE_FLAG_SOFTIRQ; 5138 5139 trace_seq_printf(s, "%c%c%c", 5140 (lat_flags & TRACE_FLAG_IRQS_OFF) ? 'd' : 5141 (lat_flags & TRACE_FLAG_IRQS_NOSUPPORT) ? 5142 'X' : '.', 5143 (lat_flags & TRACE_FLAG_NEED_RESCHED) ? 5144 'N' : '.', 5145 (hardirq && softirq) ? 'H' : 5146 hardirq ? 'h' : softirq ? 's' : '.'); 5147 5148 if (pc) 5149 trace_seq_printf(s, "%x", pc); 5150 else 5151 trace_seq_putc(s, '.'); 5152 5153 if (migrate_disable_exists) { 5154 if (migrate_disable < 0) 5155 trace_seq_putc(s, '.'); 5156 else 5157 trace_seq_printf(s, "%d", migrate_disable); 5158 } 5159 5160 if (lock_depth_exists) { 5161 if (lock_depth < 0) 5162 trace_seq_putc(s, '.'); 5163 else 5164 trace_seq_printf(s, "%d", lock_depth); 5165 } 5166 5167 trace_seq_terminate(s); 5168} 5169 5170/** 5171 * pevent_data_type - parse out the given event type 5172 * @pevent: a handle to the pevent 5173 * @rec: the record to read from 5174 * 5175 * This returns the event id from the @rec. 5176 */ 5177int pevent_data_type(struct pevent *pevent, struct pevent_record *rec) 5178{ 5179 return trace_parse_common_type(pevent, rec->data); 5180} 5181 5182/** 5183 * pevent_data_event_from_type - find the event by a given type 5184 * @pevent: a handle to the pevent 5185 * @type: the type of the event. 5186 * 5187 * This returns the event form a given @type; 5188 */ 5189struct event_format *pevent_data_event_from_type(struct pevent *pevent, int type) 5190{ 5191 return pevent_find_event(pevent, type); 5192} 5193 5194/** 5195 * pevent_data_pid - parse the PID from record 5196 * @pevent: a handle to the pevent 5197 * @rec: the record to parse 5198 * 5199 * This returns the PID from a record. 5200 */ 5201int pevent_data_pid(struct pevent *pevent, struct pevent_record *rec) 5202{ 5203 return parse_common_pid(pevent, rec->data); 5204} 5205 5206/** 5207 * pevent_data_prempt_count - parse the preempt count from the record 5208 * @pevent: a handle to the pevent 5209 * @rec: the record to parse 5210 * 5211 * This returns the preempt count from a record. 5212 */ 5213int pevent_data_prempt_count(struct pevent *pevent, struct pevent_record *rec) 5214{ 5215 return parse_common_pc(pevent, rec->data); 5216} 5217 5218/** 5219 * pevent_data_flags - parse the latency flags from the record 5220 * @pevent: a handle to the pevent 5221 * @rec: the record to parse 5222 * 5223 * This returns the latency flags from a record. 5224 * 5225 * Use trace_flag_type enum for the flags (see event-parse.h). 5226 */ 5227int pevent_data_flags(struct pevent *pevent, struct pevent_record *rec) 5228{ 5229 return parse_common_flags(pevent, rec->data); 5230} 5231 5232/** 5233 * pevent_data_comm_from_pid - return the command line from PID 5234 * @pevent: a handle to the pevent 5235 * @pid: the PID of the task to search for 5236 * 5237 * This returns a pointer to the command line that has the given 5238 * @pid. 5239 */ 5240const char *pevent_data_comm_from_pid(struct pevent *pevent, int pid) 5241{ 5242 const char *comm; 5243 5244 comm = find_cmdline(pevent, pid); 5245 return comm; 5246} 5247 5248static struct cmdline * 5249pid_from_cmdlist(struct pevent *pevent, const char *comm, struct cmdline *next) 5250{ 5251 struct cmdline_list *cmdlist = (struct cmdline_list *)next; 5252 5253 if (cmdlist) 5254 cmdlist = cmdlist->next; 5255 else 5256 cmdlist = pevent->cmdlist; 5257 5258 while (cmdlist && strcmp(cmdlist->comm, comm) != 0) 5259 cmdlist = cmdlist->next; 5260 5261 return (struct cmdline *)cmdlist; 5262} 5263 5264/** 5265 * pevent_data_pid_from_comm - return the pid from a given comm 5266 * @pevent: a handle to the pevent 5267 * @comm: the cmdline to find the pid from 5268 * @next: the cmdline structure to find the next comm 5269 * 5270 * This returns the cmdline structure that holds a pid for a given 5271 * comm, or NULL if none found. As there may be more than one pid for 5272 * a given comm, the result of this call can be passed back into 5273 * a recurring call in the @next paramater, and then it will find the 5274 * next pid. 5275 * Also, it does a linear seach, so it may be slow. 5276 */ 5277struct cmdline *pevent_data_pid_from_comm(struct pevent *pevent, const char *comm, 5278 struct cmdline *next) 5279{ 5280 struct cmdline *cmdline; 5281 5282 /* 5283 * If the cmdlines have not been converted yet, then use 5284 * the list. 5285 */ 5286 if (!pevent->cmdlines) 5287 return pid_from_cmdlist(pevent, comm, next); 5288 5289 if (next) { 5290 /* 5291 * The next pointer could have been still from 5292 * a previous call before cmdlines were created 5293 */ 5294 if (next < pevent->cmdlines || 5295 next >= pevent->cmdlines + pevent->cmdline_count) 5296 next = NULL; 5297 else 5298 cmdline = next++; 5299 } 5300 5301 if (!next) 5302 cmdline = pevent->cmdlines; 5303 5304 while (cmdline < pevent->cmdlines + pevent->cmdline_count) { 5305 if (strcmp(cmdline->comm, comm) == 0) 5306 return cmdline; 5307 cmdline++; 5308 } 5309 return NULL; 5310} 5311 5312/** 5313 * pevent_cmdline_pid - return the pid associated to a given cmdline 5314 * @cmdline: The cmdline structure to get the pid from 5315 * 5316 * Returns the pid for a give cmdline. If @cmdline is NULL, then 5317 * -1 is returned. 5318 */ 5319int pevent_cmdline_pid(struct pevent *pevent, struct cmdline *cmdline) 5320{ 5321 struct cmdline_list *cmdlist = (struct cmdline_list *)cmdline; 5322 5323 if (!cmdline) 5324 return -1; 5325 5326 /* 5327 * If cmdlines have not been created yet, or cmdline is 5328 * not part of the array, then treat it as a cmdlist instead. 5329 */ 5330 if (!pevent->cmdlines || 5331 cmdline < pevent->cmdlines || 5332 cmdline >= pevent->cmdlines + pevent->cmdline_count) 5333 return cmdlist->pid; 5334 5335 return cmdline->pid; 5336} 5337 5338/** 5339 * pevent_data_comm_from_pid - parse the data into the print format 5340 * @s: the trace_seq to write to 5341 * @event: the handle to the event 5342 * @record: the record to read from 5343 * 5344 * This parses the raw @data using the given @event information and 5345 * writes the print format into the trace_seq. 5346 */ 5347void pevent_event_info(struct trace_seq *s, struct event_format *event, 5348 struct pevent_record *record) 5349{ 5350 int print_pretty = 1; 5351 5352 if (event->pevent->print_raw || (event->flags & EVENT_FL_PRINTRAW)) 5353 pevent_print_fields(s, record->data, record->size, event); 5354 else { 5355 5356 if (event->handler && !(event->flags & EVENT_FL_NOHANDLE)) 5357 print_pretty = event->handler(s, record, event, 5358 event->context); 5359 5360 if (print_pretty) 5361 pretty_print(s, record->data, record->size, event); 5362 } 5363 5364 trace_seq_terminate(s); 5365} 5366 5367static bool is_timestamp_in_us(char *trace_clock, bool use_trace_clock) 5368{ 5369 if (!use_trace_clock) 5370 return true; 5371 5372 if (!strcmp(trace_clock, "local") || !strcmp(trace_clock, "global") 5373 || !strcmp(trace_clock, "uptime") || !strcmp(trace_clock, "perf")) 5374 return true; 5375 5376 /* trace_clock is setting in tsc or counter mode */ 5377 return false; 5378} 5379 5380/** 5381 * pevent_find_event_by_record - return the event from a given record 5382 * @pevent: a handle to the pevent 5383 * @record: The record to get the event from 5384 * 5385 * Returns the associated event for a given record, or NULL if non is 5386 * is found. 5387 */ 5388struct event_format * 5389pevent_find_event_by_record(struct pevent *pevent, struct pevent_record *record) 5390{ 5391 int type; 5392 5393 if (record->size < 0) { 5394 do_warning("ug! negative record size %d", record->size); 5395 return NULL; 5396 } 5397 5398 type = trace_parse_common_type(pevent, record->data); 5399 5400 return pevent_find_event(pevent, type); 5401} 5402 5403/** 5404 * pevent_print_event_task - Write the event task comm, pid and CPU 5405 * @pevent: a handle to the pevent 5406 * @s: the trace_seq to write to 5407 * @event: the handle to the record's event 5408 * @record: The record to get the event from 5409 * 5410 * Writes the tasks comm, pid and CPU to @s. 5411 */ 5412void pevent_print_event_task(struct pevent *pevent, struct trace_seq *s, 5413 struct event_format *event, 5414 struct pevent_record *record) 5415{ 5416 void *data = record->data; 5417 const char *comm; 5418 int pid; 5419 5420 pid = parse_common_pid(pevent, data); 5421 comm = find_cmdline(pevent, pid); 5422 5423 if (pevent->latency_format) { 5424 trace_seq_printf(s, "%8.8s-%-5d %3d", 5425 comm, pid, record->cpu); 5426 } else 5427 trace_seq_printf(s, "%16s-%-5d [%03d]", comm, pid, record->cpu); 5428} 5429 5430/** 5431 * pevent_print_event_time - Write the event timestamp 5432 * @pevent: a handle to the pevent 5433 * @s: the trace_seq to write to 5434 * @event: the handle to the record's event 5435 * @record: The record to get the event from 5436 * @use_trace_clock: Set to parse according to the @pevent->trace_clock 5437 * 5438 * Writes the timestamp of the record into @s. 5439 */ 5440void pevent_print_event_time(struct pevent *pevent, struct trace_seq *s, 5441 struct event_format *event, 5442 struct pevent_record *record, 5443 bool use_trace_clock) 5444{ 5445 unsigned long secs; 5446 unsigned long usecs; 5447 unsigned long nsecs; 5448 int p; 5449 bool use_usec_format; 5450 5451 use_usec_format = is_timestamp_in_us(pevent->trace_clock, 5452 use_trace_clock); 5453 if (use_usec_format) { 5454 secs = record->ts / NSEC_PER_SEC; 5455 nsecs = record->ts - secs * NSEC_PER_SEC; 5456 } 5457 5458 if (pevent->latency_format) { 5459 pevent_data_lat_fmt(pevent, s, record); 5460 } 5461 5462 if (use_usec_format) { 5463 if (pevent->flags & PEVENT_NSEC_OUTPUT) { 5464 usecs = nsecs; 5465 p = 9; 5466 } else { 5467 usecs = (nsecs + 500) / NSEC_PER_USEC; 5468 /* To avoid usecs larger than 1 sec */ 5469 if (usecs >= USEC_PER_SEC) { 5470 usecs -= USEC_PER_SEC; 5471 secs++; 5472 } 5473 p = 6; 5474 } 5475 5476 trace_seq_printf(s, " %5lu.%0*lu:", secs, p, usecs); 5477 } else 5478 trace_seq_printf(s, " %12llu:", record->ts); 5479} 5480 5481/** 5482 * pevent_print_event_data - Write the event data section 5483 * @pevent: a handle to the pevent 5484 * @s: the trace_seq to write to 5485 * @event: the handle to the record's event 5486 * @record: The record to get the event from 5487 * 5488 * Writes the parsing of the record's data to @s. 5489 */ 5490void pevent_print_event_data(struct pevent *pevent, struct trace_seq *s, 5491 struct event_format *event, 5492 struct pevent_record *record) 5493{ 5494 static const char *spaces = " "; /* 20 spaces */ 5495 int len; 5496 5497 trace_seq_printf(s, " %s: ", event->name); 5498 5499 /* Space out the event names evenly. */ 5500 len = strlen(event->name); 5501 if (len < 20) 5502 trace_seq_printf(s, "%.*s", 20 - len, spaces); 5503 5504 pevent_event_info(s, event, record); 5505} 5506 5507void pevent_print_event(struct pevent *pevent, struct trace_seq *s, 5508 struct pevent_record *record, bool use_trace_clock) 5509{ 5510 struct event_format *event; 5511 5512 event = pevent_find_event_by_record(pevent, record); 5513 if (!event) { 5514 do_warning("ug! no event found for type %d", 5515 trace_parse_common_type(pevent, record->data)); 5516 return; 5517 } 5518 5519 pevent_print_event_task(pevent, s, event, record); 5520 pevent_print_event_time(pevent, s, event, record, use_trace_clock); 5521 pevent_print_event_data(pevent, s, event, record); 5522} 5523 5524static int events_id_cmp(const void *a, const void *b) 5525{ 5526 struct event_format * const * ea = a; 5527 struct event_format * const * eb = b; 5528 5529 if ((*ea)->id < (*eb)->id) 5530 return -1; 5531 5532 if ((*ea)->id > (*eb)->id) 5533 return 1; 5534 5535 return 0; 5536} 5537 5538static int events_name_cmp(const void *a, const void *b) 5539{ 5540 struct event_format * const * ea = a; 5541 struct event_format * const * eb = b; 5542 int res; 5543 5544 res = strcmp((*ea)->name, (*eb)->name); 5545 if (res) 5546 return res; 5547 5548 res = strcmp((*ea)->system, (*eb)->system); 5549 if (res) 5550 return res; 5551 5552 return events_id_cmp(a, b); 5553} 5554 5555static int events_system_cmp(const void *a, const void *b) 5556{ 5557 struct event_format * const * ea = a; 5558 struct event_format * const * eb = b; 5559 int res; 5560 5561 res = strcmp((*ea)->system, (*eb)->system); 5562 if (res) 5563 return res; 5564 5565 res = strcmp((*ea)->name, (*eb)->name); 5566 if (res) 5567 return res; 5568 5569 return events_id_cmp(a, b); 5570} 5571 5572struct event_format **pevent_list_events(struct pevent *pevent, enum event_sort_type sort_type) 5573{ 5574 struct event_format **events; 5575 int (*sort)(const void *a, const void *b); 5576 5577 events = pevent->sort_events; 5578 5579 if (events && pevent->last_type == sort_type) 5580 return events; 5581 5582 if (!events) { 5583 events = malloc(sizeof(*events) * (pevent->nr_events + 1)); 5584 if (!events) 5585 return NULL; 5586 5587 memcpy(events, pevent->events, sizeof(*events) * pevent->nr_events); 5588 events[pevent->nr_events] = NULL; 5589 5590 pevent->sort_events = events; 5591 5592 /* the internal events are sorted by id */ 5593 if (sort_type == EVENT_SORT_ID) { 5594 pevent->last_type = sort_type; 5595 return events; 5596 } 5597 } 5598 5599 switch (sort_type) { 5600 case EVENT_SORT_ID: 5601 sort = events_id_cmp; 5602 break; 5603 case EVENT_SORT_NAME: 5604 sort = events_name_cmp; 5605 break; 5606 case EVENT_SORT_SYSTEM: 5607 sort = events_system_cmp; 5608 break; 5609 default: 5610 return events; 5611 } 5612 5613 qsort(events, pevent->nr_events, sizeof(*events), sort); 5614 pevent->last_type = sort_type; 5615 5616 return events; 5617} 5618 5619static struct format_field ** 5620get_event_fields(const char *type, const char *name, 5621 int count, struct format_field *list) 5622{ 5623 struct format_field **fields; 5624 struct format_field *field; 5625 int i = 0; 5626 5627 fields = malloc(sizeof(*fields) * (count + 1)); 5628 if (!fields) 5629 return NULL; 5630 5631 for (field = list; field; field = field->next) { 5632 fields[i++] = field; 5633 if (i == count + 1) { 5634 do_warning("event %s has more %s fields than specified", 5635 name, type); 5636 i--; 5637 break; 5638 } 5639 } 5640 5641 if (i != count) 5642 do_warning("event %s has less %s fields than specified", 5643 name, type); 5644 5645 fields[i] = NULL; 5646 5647 return fields; 5648} 5649 5650/** 5651 * pevent_event_common_fields - return a list of common fields for an event 5652 * @event: the event to return the common fields of. 5653 * 5654 * Returns an allocated array of fields. The last item in the array is NULL. 5655 * The array must be freed with free(). 5656 */ 5657struct format_field **pevent_event_common_fields(struct event_format *event) 5658{ 5659 return get_event_fields("common", event->name, 5660 event->format.nr_common, 5661 event->format.common_fields); 5662} 5663 5664/** 5665 * pevent_event_fields - return a list of event specific fields for an event 5666 * @event: the event to return the fields of. 5667 * 5668 * Returns an allocated array of fields. The last item in the array is NULL. 5669 * The array must be freed with free(). 5670 */ 5671struct format_field **pevent_event_fields(struct event_format *event) 5672{ 5673 return get_event_fields("event", event->name, 5674 event->format.nr_fields, 5675 event->format.fields); 5676} 5677 5678static void print_fields(struct trace_seq *s, struct print_flag_sym *field) 5679{ 5680 trace_seq_printf(s, "{ %s, %s }", field->value, field->str); 5681 if (field->next) { 5682 trace_seq_puts(s, ", "); 5683 print_fields(s, field->next); 5684 } 5685} 5686 5687/* for debugging */ 5688static void print_args(struct print_arg *args) 5689{ 5690 int print_paren = 1; 5691 struct trace_seq s; 5692 5693 switch (args->type) { 5694 case PRINT_NULL: 5695 printf("null"); 5696 break; 5697 case PRINT_ATOM: 5698 printf("%s", args->atom.atom); 5699 break; 5700 case PRINT_FIELD: 5701 printf("REC->%s", args->field.name); 5702 break; 5703 case PRINT_FLAGS: 5704 printf("__print_flags("); 5705 print_args(args->flags.field); 5706 printf(", %s, ", args->flags.delim); 5707 trace_seq_init(&s); 5708 print_fields(&s, args->flags.flags); 5709 trace_seq_do_printf(&s); 5710 trace_seq_destroy(&s); 5711 printf(")"); 5712 break; 5713 case PRINT_SYMBOL: 5714 printf("__print_symbolic("); 5715 print_args(args->symbol.field); 5716 printf(", "); 5717 trace_seq_init(&s); 5718 print_fields(&s, args->symbol.symbols); 5719 trace_seq_do_printf(&s); 5720 trace_seq_destroy(&s); 5721 printf(")"); 5722 break; 5723 case PRINT_HEX: 5724 printf("__print_hex("); 5725 print_args(args->hex.field); 5726 printf(", "); 5727 print_args(args->hex.size); 5728 printf(")"); 5729 break; 5730 case PRINT_INT_ARRAY: 5731 printf("__print_array("); 5732 print_args(args->int_array.field); 5733 printf(", "); 5734 print_args(args->int_array.count); 5735 printf(", "); 5736 print_args(args->int_array.el_size); 5737 printf(")"); 5738 break; 5739 case PRINT_STRING: 5740 case PRINT_BSTRING: 5741 printf("__get_str(%s)", args->string.string); 5742 break; 5743 case PRINT_BITMASK: 5744 printf("__get_bitmask(%s)", args->bitmask.bitmask); 5745 break; 5746 case PRINT_TYPE: 5747 printf("(%s)", args->typecast.type); 5748 print_args(args->typecast.item); 5749 break; 5750 case PRINT_OP: 5751 if (strcmp(args->op.op, ":") == 0) 5752 print_paren = 0; 5753 if (print_paren) 5754 printf("("); 5755 print_args(args->op.left); 5756 printf(" %s ", args->op.op); 5757 print_args(args->op.right); 5758 if (print_paren) 5759 printf(")"); 5760 break; 5761 default: 5762 /* we should warn... */ 5763 return; 5764 } 5765 if (args->next) { 5766 printf("\n"); 5767 print_args(args->next); 5768 } 5769} 5770 5771static void parse_header_field(const char *field, 5772 int *offset, int *size, int mandatory) 5773{ 5774 unsigned long long save_input_buf_ptr; 5775 unsigned long long save_input_buf_siz; 5776 char *token; 5777 int type; 5778 5779 save_input_buf_ptr = input_buf_ptr; 5780 save_input_buf_siz = input_buf_siz; 5781 5782 if (read_expected(EVENT_ITEM, "field") < 0) 5783 return; 5784 if (read_expected(EVENT_OP, ":") < 0) 5785 return; 5786 5787 /* type */ 5788 if (read_expect_type(EVENT_ITEM, &token) < 0) 5789 goto fail; 5790 free_token(token); 5791 5792 /* 5793 * If this is not a mandatory field, then test it first. 5794 */ 5795 if (mandatory) { 5796 if (read_expected(EVENT_ITEM, field) < 0) 5797 return; 5798 } else { 5799 if (read_expect_type(EVENT_ITEM, &token) < 0) 5800 goto fail; 5801 if (strcmp(token, field) != 0) 5802 goto discard; 5803 free_token(token); 5804 } 5805 5806 if (read_expected(EVENT_OP, ";") < 0) 5807 return; 5808 if (read_expected(EVENT_ITEM, "offset") < 0) 5809 return; 5810 if (read_expected(EVENT_OP, ":") < 0) 5811 return; 5812 if (read_expect_type(EVENT_ITEM, &token) < 0) 5813 goto fail; 5814 *offset = atoi(token); 5815 free_token(token); 5816 if (read_expected(EVENT_OP, ";") < 0) 5817 return; 5818 if (read_expected(EVENT_ITEM, "size") < 0) 5819 return; 5820 if (read_expected(EVENT_OP, ":") < 0) 5821 return; 5822 if (read_expect_type(EVENT_ITEM, &token) < 0) 5823 goto fail; 5824 *size = atoi(token); 5825 free_token(token); 5826 if (read_expected(EVENT_OP, ";") < 0) 5827 return; 5828 type = read_token(&token); 5829 if (type != EVENT_NEWLINE) { 5830 /* newer versions of the kernel have a "signed" type */ 5831 if (type != EVENT_ITEM) 5832 goto fail; 5833 5834 if (strcmp(token, "signed") != 0) 5835 goto fail; 5836 5837 free_token(token); 5838 5839 if (read_expected(EVENT_OP, ":") < 0) 5840 return; 5841 5842 if (read_expect_type(EVENT_ITEM, &token)) 5843 goto fail; 5844 5845 free_token(token); 5846 if (read_expected(EVENT_OP, ";") < 0) 5847 return; 5848 5849 if (read_expect_type(EVENT_NEWLINE, &token)) 5850 goto fail; 5851 } 5852 fail: 5853 free_token(token); 5854 return; 5855 5856 discard: 5857 input_buf_ptr = save_input_buf_ptr; 5858 input_buf_siz = save_input_buf_siz; 5859 *offset = 0; 5860 *size = 0; 5861 free_token(token); 5862} 5863 5864/** 5865 * pevent_parse_header_page - parse the data stored in the header page 5866 * @pevent: the handle to the pevent 5867 * @buf: the buffer storing the header page format string 5868 * @size: the size of @buf 5869 * @long_size: the long size to use if there is no header 5870 * 5871 * This parses the header page format for information on the 5872 * ring buffer used. The @buf should be copied from 5873 * 5874 * /sys/kernel/debug/tracing/events/header_page 5875 */ 5876int pevent_parse_header_page(struct pevent *pevent, char *buf, unsigned long size, 5877 int long_size) 5878{ 5879 int ignore; 5880 5881 if (!size) { 5882 /* 5883 * Old kernels did not have header page info. 5884 * Sorry but we just use what we find here in user space. 5885 */ 5886 pevent->header_page_ts_size = sizeof(long long); 5887 pevent->header_page_size_size = long_size; 5888 pevent->header_page_data_offset = sizeof(long long) + long_size; 5889 pevent->old_format = 1; 5890 return -1; 5891 } 5892 init_input_buf(buf, size); 5893 5894 parse_header_field("timestamp", &pevent->header_page_ts_offset, 5895 &pevent->header_page_ts_size, 1); 5896 parse_header_field("commit", &pevent->header_page_size_offset, 5897 &pevent->header_page_size_size, 1); 5898 parse_header_field("overwrite", &pevent->header_page_overwrite, 5899 &ignore, 0); 5900 parse_header_field("data", &pevent->header_page_data_offset, 5901 &pevent->header_page_data_size, 1); 5902 5903 return 0; 5904} 5905 5906static int event_matches(struct event_format *event, 5907 int id, const char *sys_name, 5908 const char *event_name) 5909{ 5910 if (id >= 0 && id != event->id) 5911 return 0; 5912 5913 if (event_name && (strcmp(event_name, event->name) != 0)) 5914 return 0; 5915 5916 if (sys_name && (strcmp(sys_name, event->system) != 0)) 5917 return 0; 5918 5919 return 1; 5920} 5921 5922static void free_handler(struct event_handler *handle) 5923{ 5924 free((void *)handle->sys_name); 5925 free((void *)handle->event_name); 5926 free(handle); 5927} 5928 5929static int find_event_handle(struct pevent *pevent, struct event_format *event) 5930{ 5931 struct event_handler *handle, **next; 5932 5933 for (next = &pevent->handlers; *next; 5934 next = &(*next)->next) { 5935 handle = *next; 5936 if (event_matches(event, handle->id, 5937 handle->sys_name, 5938 handle->event_name)) 5939 break; 5940 } 5941 5942 if (!(*next)) 5943 return 0; 5944 5945 pr_stat("overriding event (%d) %s:%s with new print handler", 5946 event->id, event->system, event->name); 5947 5948 event->handler = handle->func; 5949 event->context = handle->context; 5950 5951 *next = handle->next; 5952 free_handler(handle); 5953 5954 return 1; 5955} 5956 5957/** 5958 * __pevent_parse_format - parse the event format 5959 * @buf: the buffer storing the event format string 5960 * @size: the size of @buf 5961 * @sys: the system the event belongs to 5962 * 5963 * This parses the event format and creates an event structure 5964 * to quickly parse raw data for a given event. 5965 * 5966 * These files currently come from: 5967 * 5968 * /sys/kernel/debug/tracing/events/.../.../format 5969 */ 5970enum pevent_errno __pevent_parse_format(struct event_format **eventp, 5971 struct pevent *pevent, const char *buf, 5972 unsigned long size, const char *sys) 5973{ 5974 struct event_format *event; 5975 int ret; 5976 5977 init_input_buf(buf, size); 5978 5979 *eventp = event = alloc_event(); 5980 if (!event) 5981 return PEVENT_ERRNO__MEM_ALLOC_FAILED; 5982 5983 event->name = event_read_name(); 5984 if (!event->name) { 5985 /* Bad event? */ 5986 ret = PEVENT_ERRNO__MEM_ALLOC_FAILED; 5987 goto event_alloc_failed; 5988 } 5989 5990 if (strcmp(sys, "ftrace") == 0) { 5991 event->flags |= EVENT_FL_ISFTRACE; 5992 5993 if (strcmp(event->name, "bprint") == 0) 5994 event->flags |= EVENT_FL_ISBPRINT; 5995 } 5996 5997 event->id = event_read_id(); 5998 if (event->id < 0) { 5999 ret = PEVENT_ERRNO__READ_ID_FAILED; 6000 /* 6001 * This isn't an allocation error actually. 6002 * But as the ID is critical, just bail out. 6003 */ 6004 goto event_alloc_failed; 6005 } 6006 6007 event->system = strdup(sys); 6008 if (!event->system) { 6009 ret = PEVENT_ERRNO__MEM_ALLOC_FAILED; 6010 goto event_alloc_failed; 6011 } 6012 6013 /* Add pevent to event so that it can be referenced */ 6014 event->pevent = pevent; 6015 6016 ret = event_read_format(event); 6017 if (ret < 0) { 6018 ret = PEVENT_ERRNO__READ_FORMAT_FAILED; 6019 goto event_parse_failed; 6020 } 6021 6022 /* 6023 * If the event has an override, don't print warnings if the event 6024 * print format fails to parse. 6025 */ 6026 if (pevent && find_event_handle(pevent, event)) 6027 show_warning = 0; 6028 6029 ret = event_read_print(event); 6030 show_warning = 1; 6031 6032 if (ret < 0) { 6033 ret = PEVENT_ERRNO__READ_PRINT_FAILED; 6034 goto event_parse_failed; 6035 } 6036 6037 if (!ret && (event->flags & EVENT_FL_ISFTRACE)) { 6038 struct format_field *field; 6039 struct print_arg *arg, **list; 6040 6041 /* old ftrace had no args */ 6042 list = &event->print_fmt.args; 6043 for (field = event->format.fields; field; field = field->next) { 6044 arg = alloc_arg(); 6045 if (!arg) { 6046 event->flags |= EVENT_FL_FAILED; 6047 return PEVENT_ERRNO__OLD_FTRACE_ARG_FAILED; 6048 } 6049 arg->type = PRINT_FIELD; 6050 arg->field.name = strdup(field->name); 6051 if (!arg->field.name) { 6052 event->flags |= EVENT_FL_FAILED; 6053 free_arg(arg); 6054 return PEVENT_ERRNO__OLD_FTRACE_ARG_FAILED; 6055 } 6056 arg->field.field = field; 6057 *list = arg; 6058 list = &arg->next; 6059 } 6060 return 0; 6061 } 6062 6063 return 0; 6064 6065 event_parse_failed: 6066 event->flags |= EVENT_FL_FAILED; 6067 return ret; 6068 6069 event_alloc_failed: 6070 free(event->system); 6071 free(event->name); 6072 free(event); 6073 *eventp = NULL; 6074 return ret; 6075} 6076 6077static enum pevent_errno 6078__pevent_parse_event(struct pevent *pevent, 6079 struct event_format **eventp, 6080 const char *buf, unsigned long size, 6081 const char *sys) 6082{ 6083 int ret = __pevent_parse_format(eventp, pevent, buf, size, sys); 6084 struct event_format *event = *eventp; 6085 6086 if (event == NULL) 6087 return ret; 6088 6089 if (pevent && add_event(pevent, event)) { 6090 ret = PEVENT_ERRNO__MEM_ALLOC_FAILED; 6091 goto event_add_failed; 6092 } 6093 6094#define PRINT_ARGS 0 6095 if (PRINT_ARGS && event->print_fmt.args) 6096 print_args(event->print_fmt.args); 6097 6098 return 0; 6099 6100event_add_failed: 6101 pevent_free_format(event); 6102 return ret; 6103} 6104 6105/** 6106 * pevent_parse_format - parse the event format 6107 * @pevent: the handle to the pevent 6108 * @eventp: returned format 6109 * @buf: the buffer storing the event format string 6110 * @size: the size of @buf 6111 * @sys: the system the event belongs to 6112 * 6113 * This parses the event format and creates an event structure 6114 * to quickly parse raw data for a given event. 6115 * 6116 * These files currently come from: 6117 * 6118 * /sys/kernel/debug/tracing/events/.../.../format 6119 */ 6120enum pevent_errno pevent_parse_format(struct pevent *pevent, 6121 struct event_format **eventp, 6122 const char *buf, 6123 unsigned long size, const char *sys) 6124{ 6125 return __pevent_parse_event(pevent, eventp, buf, size, sys); 6126} 6127 6128/** 6129 * pevent_parse_event - parse the event format 6130 * @pevent: the handle to the pevent 6131 * @buf: the buffer storing the event format string 6132 * @size: the size of @buf 6133 * @sys: the system the event belongs to 6134 * 6135 * This parses the event format and creates an event structure 6136 * to quickly parse raw data for a given event. 6137 * 6138 * These files currently come from: 6139 * 6140 * /sys/kernel/debug/tracing/events/.../.../format 6141 */ 6142enum pevent_errno pevent_parse_event(struct pevent *pevent, const char *buf, 6143 unsigned long size, const char *sys) 6144{ 6145 struct event_format *event = NULL; 6146 return __pevent_parse_event(pevent, &event, buf, size, sys); 6147} 6148 6149#undef _PE 6150#define _PE(code, str) str 6151static const char * const pevent_error_str[] = { 6152 PEVENT_ERRORS 6153}; 6154#undef _PE 6155 6156int pevent_strerror(struct pevent *pevent __maybe_unused, 6157 enum pevent_errno errnum, char *buf, size_t buflen) 6158{ 6159 int idx; 6160 const char *msg; 6161 6162 if (errnum >= 0) { 6163 str_error_r(errnum, buf, buflen); 6164 return 0; 6165 } 6166 6167 if (errnum <= __PEVENT_ERRNO__START || 6168 errnum >= __PEVENT_ERRNO__END) 6169 return -1; 6170 6171 idx = errnum - __PEVENT_ERRNO__START - 1; 6172 msg = pevent_error_str[idx]; 6173 snprintf(buf, buflen, "%s", msg); 6174 6175 return 0; 6176} 6177 6178int get_field_val(struct trace_seq *s, struct format_field *field, 6179 const char *name, struct pevent_record *record, 6180 unsigned long long *val, int err) 6181{ 6182 if (!field) { 6183 if (err) 6184 trace_seq_printf(s, "<CANT FIND FIELD %s>", name); 6185 return -1; 6186 } 6187 6188 if (pevent_read_number_field(field, record->data, val)) { 6189 if (err) 6190 trace_seq_printf(s, " %s=INVALID", name); 6191 return -1; 6192 } 6193 6194 return 0; 6195} 6196 6197/** 6198 * pevent_get_field_raw - return the raw pointer into the data field 6199 * @s: The seq to print to on error 6200 * @event: the event that the field is for 6201 * @name: The name of the field 6202 * @record: The record with the field name. 6203 * @len: place to store the field length. 6204 * @err: print default error if failed. 6205 * 6206 * Returns a pointer into record->data of the field and places 6207 * the length of the field in @len. 6208 * 6209 * On failure, it returns NULL. 6210 */ 6211void *pevent_get_field_raw(struct trace_seq *s, struct event_format *event, 6212 const char *name, struct pevent_record *record, 6213 int *len, int err) 6214{ 6215 struct format_field *field; 6216 void *data = record->data; 6217 unsigned offset; 6218 int dummy; 6219 6220 if (!event) 6221 return NULL; 6222 6223 field = pevent_find_field(event, name); 6224 6225 if (!field) { 6226 if (err) 6227 trace_seq_printf(s, "<CANT FIND FIELD %s>", name); 6228 return NULL; 6229 } 6230 6231 /* Allow @len to be NULL */ 6232 if (!len) 6233 len = &dummy; 6234 6235 offset = field->offset; 6236 if (field->flags & FIELD_IS_DYNAMIC) { 6237 offset = pevent_read_number(event->pevent, 6238 data + offset, field->size); 6239 *len = offset >> 16; 6240 offset &= 0xffff; 6241 } else 6242 *len = field->size; 6243 6244 return data + offset; 6245} 6246 6247/** 6248 * pevent_get_field_val - find a field and return its value 6249 * @s: The seq to print to on error 6250 * @event: the event that the field is for 6251 * @name: The name of the field 6252 * @record: The record with the field name. 6253 * @val: place to store the value of the field. 6254 * @err: print default error if failed. 6255 * 6256 * Returns 0 on success -1 on field not found. 6257 */ 6258int pevent_get_field_val(struct trace_seq *s, struct event_format *event, 6259 const char *name, struct pevent_record *record, 6260 unsigned long long *val, int err) 6261{ 6262 struct format_field *field; 6263 6264 if (!event) 6265 return -1; 6266 6267 field = pevent_find_field(event, name); 6268 6269 return get_field_val(s, field, name, record, val, err); 6270} 6271 6272/** 6273 * pevent_get_common_field_val - find a common field and return its value 6274 * @s: The seq to print to on error 6275 * @event: the event that the field is for 6276 * @name: The name of the field 6277 * @record: The record with the field name. 6278 * @val: place to store the value of the field. 6279 * @err: print default error if failed. 6280 * 6281 * Returns 0 on success -1 on field not found. 6282 */ 6283int pevent_get_common_field_val(struct trace_seq *s, struct event_format *event, 6284 const char *name, struct pevent_record *record, 6285 unsigned long long *val, int err) 6286{ 6287 struct format_field *field; 6288 6289 if (!event) 6290 return -1; 6291 6292 field = pevent_find_common_field(event, name); 6293 6294 return get_field_val(s, field, name, record, val, err); 6295} 6296 6297/** 6298 * pevent_get_any_field_val - find a any field and return its value 6299 * @s: The seq to print to on error 6300 * @event: the event that the field is for 6301 * @name: The name of the field 6302 * @record: The record with the field name. 6303 * @val: place to store the value of the field. 6304 * @err: print default error if failed. 6305 * 6306 * Returns 0 on success -1 on field not found. 6307 */ 6308int pevent_get_any_field_val(struct trace_seq *s, struct event_format *event, 6309 const char *name, struct pevent_record *record, 6310 unsigned long long *val, int err) 6311{ 6312 struct format_field *field; 6313 6314 if (!event) 6315 return -1; 6316 6317 field = pevent_find_any_field(event, name); 6318 6319 return get_field_val(s, field, name, record, val, err); 6320} 6321 6322/** 6323 * pevent_print_num_field - print a field and a format 6324 * @s: The seq to print to 6325 * @fmt: The printf format to print the field with. 6326 * @event: the event that the field is for 6327 * @name: The name of the field 6328 * @record: The record with the field name. 6329 * @err: print default error if failed. 6330 * 6331 * Returns: 0 on success, -1 field not found, or 1 if buffer is full. 6332 */ 6333int pevent_print_num_field(struct trace_seq *s, const char *fmt, 6334 struct event_format *event, const char *name, 6335 struct pevent_record *record, int err) 6336{ 6337 struct format_field *field = pevent_find_field(event, name); 6338 unsigned long long val; 6339 6340 if (!field) 6341 goto failed; 6342 6343 if (pevent_read_number_field(field, record->data, &val)) 6344 goto failed; 6345 6346 return trace_seq_printf(s, fmt, val); 6347 6348 failed: 6349 if (err) 6350 trace_seq_printf(s, "CAN'T FIND FIELD \"%s\"", name); 6351 return -1; 6352} 6353 6354/** 6355 * pevent_print_func_field - print a field and a format for function pointers 6356 * @s: The seq to print to 6357 * @fmt: The printf format to print the field with. 6358 * @event: the event that the field is for 6359 * @name: The name of the field 6360 * @record: The record with the field name. 6361 * @err: print default error if failed. 6362 * 6363 * Returns: 0 on success, -1 field not found, or 1 if buffer is full. 6364 */ 6365int pevent_print_func_field(struct trace_seq *s, const char *fmt, 6366 struct event_format *event, const char *name, 6367 struct pevent_record *record, int err) 6368{ 6369 struct format_field *field = pevent_find_field(event, name); 6370 struct pevent *pevent = event->pevent; 6371 unsigned long long val; 6372 struct func_map *func; 6373 char tmp[128]; 6374 6375 if (!field) 6376 goto failed; 6377 6378 if (pevent_read_number_field(field, record->data, &val)) 6379 goto failed; 6380 6381 func = find_func(pevent, val); 6382 6383 if (func) 6384 snprintf(tmp, 128, "%s/0x%llx", func->func, func->addr - val); 6385 else 6386 sprintf(tmp, "0x%08llx", val); 6387 6388 return trace_seq_printf(s, fmt, tmp); 6389 6390 failed: 6391 if (err) 6392 trace_seq_printf(s, "CAN'T FIND FIELD \"%s\"", name); 6393 return -1; 6394} 6395 6396static void free_func_handle(struct pevent_function_handler *func) 6397{ 6398 struct pevent_func_params *params; 6399 6400 free(func->name); 6401 6402 while (func->params) { 6403 params = func->params; 6404 func->params = params->next; 6405 free(params); 6406 } 6407 6408 free(func); 6409} 6410 6411/** 6412 * pevent_register_print_function - register a helper function 6413 * @pevent: the handle to the pevent 6414 * @func: the function to process the helper function 6415 * @ret_type: the return type of the helper function 6416 * @name: the name of the helper function 6417 * @parameters: A list of enum pevent_func_arg_type 6418 * 6419 * Some events may have helper functions in the print format arguments. 6420 * This allows a plugin to dynamically create a way to process one 6421 * of these functions. 6422 * 6423 * The @parameters is a variable list of pevent_func_arg_type enums that 6424 * must end with PEVENT_FUNC_ARG_VOID. 6425 */ 6426int pevent_register_print_function(struct pevent *pevent, 6427 pevent_func_handler func, 6428 enum pevent_func_arg_type ret_type, 6429 char *name, ...) 6430{ 6431 struct pevent_function_handler *func_handle; 6432 struct pevent_func_params **next_param; 6433 struct pevent_func_params *param; 6434 enum pevent_func_arg_type type; 6435 va_list ap; 6436 int ret; 6437 6438 func_handle = find_func_handler(pevent, name); 6439 if (func_handle) { 6440 /* 6441 * This is most like caused by the users own 6442 * plugins updating the function. This overrides the 6443 * system defaults. 6444 */ 6445 pr_stat("override of function helper '%s'", name); 6446 remove_func_handler(pevent, name); 6447 } 6448 6449 func_handle = calloc(1, sizeof(*func_handle)); 6450 if (!func_handle) { 6451 do_warning("Failed to allocate function handler"); 6452 return PEVENT_ERRNO__MEM_ALLOC_FAILED; 6453 } 6454 6455 func_handle->ret_type = ret_type; 6456 func_handle->name = strdup(name); 6457 func_handle->func = func; 6458 if (!func_handle->name) { 6459 do_warning("Failed to allocate function name"); 6460 free(func_handle); 6461 return PEVENT_ERRNO__MEM_ALLOC_FAILED; 6462 } 6463 6464 next_param = &(func_handle->params); 6465 va_start(ap, name); 6466 for (;;) { 6467 type = va_arg(ap, enum pevent_func_arg_type); 6468 if (type == PEVENT_FUNC_ARG_VOID) 6469 break; 6470 6471 if (type >= PEVENT_FUNC_ARG_MAX_TYPES) { 6472 do_warning("Invalid argument type %d", type); 6473 ret = PEVENT_ERRNO__INVALID_ARG_TYPE; 6474 goto out_free; 6475 } 6476 6477 param = malloc(sizeof(*param)); 6478 if (!param) { 6479 do_warning("Failed to allocate function param"); 6480 ret = PEVENT_ERRNO__MEM_ALLOC_FAILED; 6481 goto out_free; 6482 } 6483 param->type = type; 6484 param->next = NULL; 6485 6486 *next_param = param; 6487 next_param = &(param->next); 6488 6489 func_handle->nr_args++; 6490 } 6491 va_end(ap); 6492 6493 func_handle->next = pevent->func_handlers; 6494 pevent->func_handlers = func_handle; 6495 6496 return 0; 6497 out_free: 6498 va_end(ap); 6499 free_func_handle(func_handle); 6500 return ret; 6501} 6502 6503/** 6504 * pevent_unregister_print_function - unregister a helper function 6505 * @pevent: the handle to the pevent 6506 * @func: the function to process the helper function 6507 * @name: the name of the helper function 6508 * 6509 * This function removes existing print handler for function @name. 6510 * 6511 * Returns 0 if the handler was removed successully, -1 otherwise. 6512 */ 6513int pevent_unregister_print_function(struct pevent *pevent, 6514 pevent_func_handler func, char *name) 6515{ 6516 struct pevent_function_handler *func_handle; 6517 6518 func_handle = find_func_handler(pevent, name); 6519 if (func_handle && func_handle->func == func) { 6520 remove_func_handler(pevent, name); 6521 return 0; 6522 } 6523 return -1; 6524} 6525 6526static struct event_format *pevent_search_event(struct pevent *pevent, int id, 6527 const char *sys_name, 6528 const char *event_name) 6529{ 6530 struct event_format *event; 6531 6532 if (id >= 0) { 6533 /* search by id */ 6534 event = pevent_find_event(pevent, id); 6535 if (!event) 6536 return NULL; 6537 if (event_name && (strcmp(event_name, event->name) != 0)) 6538 return NULL; 6539 if (sys_name && (strcmp(sys_name, event->system) != 0)) 6540 return NULL; 6541 } else { 6542 event = pevent_find_event_by_name(pevent, sys_name, event_name); 6543 if (!event) 6544 return NULL; 6545 } 6546 return event; 6547} 6548 6549/** 6550 * pevent_register_event_handler - register a way to parse an event 6551 * @pevent: the handle to the pevent 6552 * @id: the id of the event to register 6553 * @sys_name: the system name the event belongs to 6554 * @event_name: the name of the event 6555 * @func: the function to call to parse the event information 6556 * @context: the data to be passed to @func 6557 * 6558 * This function allows a developer to override the parsing of 6559 * a given event. If for some reason the default print format 6560 * is not sufficient, this function will register a function 6561 * for an event to be used to parse the data instead. 6562 * 6563 * If @id is >= 0, then it is used to find the event. 6564 * else @sys_name and @event_name are used. 6565 */ 6566int pevent_register_event_handler(struct pevent *pevent, int id, 6567 const char *sys_name, const char *event_name, 6568 pevent_event_handler_func func, void *context) 6569{ 6570 struct event_format *event; 6571 struct event_handler *handle; 6572 6573 event = pevent_search_event(pevent, id, sys_name, event_name); 6574 if (event == NULL) 6575 goto not_found; 6576 6577 pr_stat("overriding event (%d) %s:%s with new print handler", 6578 event->id, event->system, event->name); 6579 6580 event->handler = func; 6581 event->context = context; 6582 return 0; 6583 6584 not_found: 6585 /* Save for later use. */ 6586 handle = calloc(1, sizeof(*handle)); 6587 if (!handle) { 6588 do_warning("Failed to allocate event handler"); 6589 return PEVENT_ERRNO__MEM_ALLOC_FAILED; 6590 } 6591 6592 handle->id = id; 6593 if (event_name) 6594 handle->event_name = strdup(event_name); 6595 if (sys_name) 6596 handle->sys_name = strdup(sys_name); 6597 6598 if ((event_name && !handle->event_name) || 6599 (sys_name && !handle->sys_name)) { 6600 do_warning("Failed to allocate event/sys name"); 6601 free((void *)handle->event_name); 6602 free((void *)handle->sys_name); 6603 free(handle); 6604 return PEVENT_ERRNO__MEM_ALLOC_FAILED; 6605 } 6606 6607 handle->func = func; 6608 handle->next = pevent->handlers; 6609 pevent->handlers = handle; 6610 handle->context = context; 6611 6612 return -1; 6613} 6614 6615static int handle_matches(struct event_handler *handler, int id, 6616 const char *sys_name, const char *event_name, 6617 pevent_event_handler_func func, void *context) 6618{ 6619 if (id >= 0 && id != handler->id) 6620 return 0; 6621 6622 if (event_name && (strcmp(event_name, handler->event_name) != 0)) 6623 return 0; 6624 6625 if (sys_name && (strcmp(sys_name, handler->sys_name) != 0)) 6626 return 0; 6627 6628 if (func != handler->func || context != handler->context) 6629 return 0; 6630 6631 return 1; 6632} 6633 6634/** 6635 * pevent_unregister_event_handler - unregister an existing event handler 6636 * @pevent: the handle to the pevent 6637 * @id: the id of the event to unregister 6638 * @sys_name: the system name the handler belongs to 6639 * @event_name: the name of the event handler 6640 * @func: the function to call to parse the event information 6641 * @context: the data to be passed to @func 6642 * 6643 * This function removes existing event handler (parser). 6644 * 6645 * If @id is >= 0, then it is used to find the event. 6646 * else @sys_name and @event_name are used. 6647 * 6648 * Returns 0 if handler was removed successfully, -1 if event was not found. 6649 */ 6650int pevent_unregister_event_handler(struct pevent *pevent, int id, 6651 const char *sys_name, const char *event_name, 6652 pevent_event_handler_func func, void *context) 6653{ 6654 struct event_format *event; 6655 struct event_handler *handle; 6656 struct event_handler **next; 6657 6658 event = pevent_search_event(pevent, id, sys_name, event_name); 6659 if (event == NULL) 6660 goto not_found; 6661 6662 if (event->handler == func && event->context == context) { 6663 pr_stat("removing override handler for event (%d) %s:%s. Going back to default handler.", 6664 event->id, event->system, event->name); 6665 6666 event->handler = NULL; 6667 event->context = NULL; 6668 return 0; 6669 } 6670 6671not_found: 6672 for (next = &pevent->handlers; *next; next = &(*next)->next) { 6673 handle = *next; 6674 if (handle_matches(handle, id, sys_name, event_name, 6675 func, context)) 6676 break; 6677 } 6678 6679 if (!(*next)) 6680 return -1; 6681 6682 *next = handle->next; 6683 free_handler(handle); 6684 6685 return 0; 6686} 6687 6688/** 6689 * pevent_alloc - create a pevent handle 6690 */ 6691struct pevent *pevent_alloc(void) 6692{ 6693 struct pevent *pevent = calloc(1, sizeof(*pevent)); 6694 6695 if (pevent) 6696 pevent->ref_count = 1; 6697 6698 return pevent; 6699} 6700 6701void pevent_ref(struct pevent *pevent) 6702{ 6703 pevent->ref_count++; 6704} 6705 6706void pevent_free_format_field(struct format_field *field) 6707{ 6708 free(field->type); 6709 if (field->alias != field->name) 6710 free(field->alias); 6711 free(field->name); 6712 free(field); 6713} 6714 6715static void free_format_fields(struct format_field *field) 6716{ 6717 struct format_field *next; 6718 6719 while (field) { 6720 next = field->next; 6721 pevent_free_format_field(field); 6722 field = next; 6723 } 6724} 6725 6726static void free_formats(struct format *format) 6727{ 6728 free_format_fields(format->common_fields); 6729 free_format_fields(format->fields); 6730} 6731 6732void pevent_free_format(struct event_format *event) 6733{ 6734 free(event->name); 6735 free(event->system); 6736 6737 free_formats(&event->format); 6738 6739 free(event->print_fmt.format); 6740 free_args(event->print_fmt.args); 6741 6742 free(event); 6743} 6744 6745/** 6746 * pevent_free - free a pevent handle 6747 * @pevent: the pevent handle to free 6748 */ 6749void pevent_free(struct pevent *pevent) 6750{ 6751 struct cmdline_list *cmdlist, *cmdnext; 6752 struct func_list *funclist, *funcnext; 6753 struct printk_list *printklist, *printknext; 6754 struct pevent_function_handler *func_handler; 6755 struct event_handler *handle; 6756 int i; 6757 6758 if (!pevent) 6759 return; 6760 6761 cmdlist = pevent->cmdlist; 6762 funclist = pevent->funclist; 6763 printklist = pevent->printklist; 6764 6765 pevent->ref_count--; 6766 if (pevent->ref_count) 6767 return; 6768 6769 if (pevent->cmdlines) { 6770 for (i = 0; i < pevent->cmdline_count; i++) 6771 free(pevent->cmdlines[i].comm); 6772 free(pevent->cmdlines); 6773 } 6774 6775 while (cmdlist) { 6776 cmdnext = cmdlist->next; 6777 free(cmdlist->comm); 6778 free(cmdlist); 6779 cmdlist = cmdnext; 6780 } 6781 6782 if (pevent->func_map) { 6783 for (i = 0; i < (int)pevent->func_count; i++) { 6784 free(pevent->func_map[i].func); 6785 free(pevent->func_map[i].mod); 6786 } 6787 free(pevent->func_map); 6788 } 6789 6790 while (funclist) { 6791 funcnext = funclist->next; 6792 free(funclist->func); 6793 free(funclist->mod); 6794 free(funclist); 6795 funclist = funcnext; 6796 } 6797 6798 while (pevent->func_handlers) { 6799 func_handler = pevent->func_handlers; 6800 pevent->func_handlers = func_handler->next; 6801 free_func_handle(func_handler); 6802 } 6803 6804 if (pevent->printk_map) { 6805 for (i = 0; i < (int)pevent->printk_count; i++) 6806 free(pevent->printk_map[i].printk); 6807 free(pevent->printk_map); 6808 } 6809 6810 while (printklist) { 6811 printknext = printklist->next; 6812 free(printklist->printk); 6813 free(printklist); 6814 printklist = printknext; 6815 } 6816 6817 for (i = 0; i < pevent->nr_events; i++) 6818 pevent_free_format(pevent->events[i]); 6819 6820 while (pevent->handlers) { 6821 handle = pevent->handlers; 6822 pevent->handlers = handle->next; 6823 free_handler(handle); 6824 } 6825 6826 free(pevent->trace_clock); 6827 free(pevent->events); 6828 free(pevent->sort_events); 6829 free(pevent->func_resolver); 6830 6831 free(pevent); 6832} 6833 6834void pevent_unref(struct pevent *pevent) 6835{ 6836 pevent_free(pevent); 6837}