trace, documentation: Fix branch profiling location in debugfs
[linux-2.6.git] / kernel / trace / trace_events_filter.c
1 /*
2  * trace_events_filter - generic event filtering
3  *
4  * This program is free software; you can redistribute it and/or modify
5  * it under the terms of the GNU General Public License as published by
6  * the Free Software Foundation; either version 2 of the License, or
7  * (at your option) any later version.
8  *
9  * This program is distributed in the hope that it will be useful,
10  * but WITHOUT ANY WARRANTY; without even the implied warranty of
11  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
12  * GNU General Public License for more details.
13  *
14  * You should have received a copy of the GNU General Public License
15  * along with this program; if not, write to the Free Software
16  * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
17  *
18  * Copyright (C) 2009 Tom Zanussi <tzanussi@gmail.com>
19  */
20
21 #include <linux/module.h>
22 #include <linux/ctype.h>
23 #include <linux/mutex.h>
24 #include <linux/perf_event.h>
25 #include <linux/slab.h>
26
27 #include "trace.h"
28 #include "trace_output.h"
29
30 enum filter_op_ids
31 {
32         OP_OR,
33         OP_AND,
34         OP_GLOB,
35         OP_NE,
36         OP_EQ,
37         OP_LT,
38         OP_LE,
39         OP_GT,
40         OP_GE,
41         OP_NONE,
42         OP_OPEN_PAREN,
43 };
44
45 struct filter_op {
46         int id;
47         char *string;
48         int precedence;
49 };
50
51 static struct filter_op filter_ops[] = {
52         { OP_OR,        "||",           1 },
53         { OP_AND,       "&&",           2 },
54         { OP_GLOB,      "~",            4 },
55         { OP_NE,        "!=",           4 },
56         { OP_EQ,        "==",           4 },
57         { OP_LT,        "<",            5 },
58         { OP_LE,        "<=",           5 },
59         { OP_GT,        ">",            5 },
60         { OP_GE,        ">=",           5 },
61         { OP_NONE,      "OP_NONE",      0 },
62         { OP_OPEN_PAREN, "(",           0 },
63 };
64
65 enum {
66         FILT_ERR_NONE,
67         FILT_ERR_INVALID_OP,
68         FILT_ERR_UNBALANCED_PAREN,
69         FILT_ERR_TOO_MANY_OPERANDS,
70         FILT_ERR_OPERAND_TOO_LONG,
71         FILT_ERR_FIELD_NOT_FOUND,
72         FILT_ERR_ILLEGAL_FIELD_OP,
73         FILT_ERR_ILLEGAL_INTVAL,
74         FILT_ERR_BAD_SUBSYS_FILTER,
75         FILT_ERR_TOO_MANY_PREDS,
76         FILT_ERR_MISSING_FIELD,
77         FILT_ERR_INVALID_FILTER,
78 };
79
80 static char *err_text[] = {
81         "No error",
82         "Invalid operator",
83         "Unbalanced parens",
84         "Too many operands",
85         "Operand too long",
86         "Field not found",
87         "Illegal operation for field type",
88         "Illegal integer value",
89         "Couldn't find or set field in one of a subsystem's events",
90         "Too many terms in predicate expression",
91         "Missing field name and/or value",
92         "Meaningless filter expression",
93 };
94
95 struct opstack_op {
96         int op;
97         struct list_head list;
98 };
99
100 struct postfix_elt {
101         int op;
102         char *operand;
103         struct list_head list;
104 };
105
106 struct filter_parse_state {
107         struct filter_op *ops;
108         struct list_head opstack;
109         struct list_head postfix;
110         int lasterr;
111         int lasterr_pos;
112
113         struct {
114                 char *string;
115                 unsigned int cnt;
116                 unsigned int tail;
117         } infix;
118
119         struct {
120                 char string[MAX_FILTER_STR_VAL];
121                 int pos;
122                 unsigned int tail;
123         } operand;
124 };
125
126 struct pred_stack {
127         struct filter_pred      **preds;
128         int                     index;
129 };
130
131 #define DEFINE_COMPARISON_PRED(type)                                    \
132 static int filter_pred_##type(struct filter_pred *pred, void *event)    \
133 {                                                                       \
134         type *addr = (type *)(event + pred->offset);                    \
135         type val = (type)pred->val;                                     \
136         int match = 0;                                                  \
137                                                                         \
138         switch (pred->op) {                                             \
139         case OP_LT:                                                     \
140                 match = (*addr < val);                                  \
141                 break;                                                  \
142         case OP_LE:                                                     \
143                 match = (*addr <= val);                                 \
144                 break;                                                  \
145         case OP_GT:                                                     \
146                 match = (*addr > val);                                  \
147                 break;                                                  \
148         case OP_GE:                                                     \
149                 match = (*addr >= val);                                 \
150                 break;                                                  \
151         default:                                                        \
152                 break;                                                  \
153         }                                                               \
154                                                                         \
155         return match;                                                   \
156 }
157
158 #define DEFINE_EQUALITY_PRED(size)                                      \
159 static int filter_pred_##size(struct filter_pred *pred, void *event)    \
160 {                                                                       \
161         u##size *addr = (u##size *)(event + pred->offset);              \
162         u##size val = (u##size)pred->val;                               \
163         int match;                                                      \
164                                                                         \
165         match = (val == *addr) ^ pred->not;                             \
166                                                                         \
167         return match;                                                   \
168 }
169
170 DEFINE_COMPARISON_PRED(s64);
171 DEFINE_COMPARISON_PRED(u64);
172 DEFINE_COMPARISON_PRED(s32);
173 DEFINE_COMPARISON_PRED(u32);
174 DEFINE_COMPARISON_PRED(s16);
175 DEFINE_COMPARISON_PRED(u16);
176 DEFINE_COMPARISON_PRED(s8);
177 DEFINE_COMPARISON_PRED(u8);
178
179 DEFINE_EQUALITY_PRED(64);
180 DEFINE_EQUALITY_PRED(32);
181 DEFINE_EQUALITY_PRED(16);
182 DEFINE_EQUALITY_PRED(8);
183
184 /* Filter predicate for fixed sized arrays of characters */
185 static int filter_pred_string(struct filter_pred *pred, void *event)
186 {
187         char *addr = (char *)(event + pred->offset);
188         int cmp, match;
189
190         cmp = pred->regex.match(addr, &pred->regex, pred->regex.field_len);
191
192         match = cmp ^ pred->not;
193
194         return match;
195 }
196
197 /* Filter predicate for char * pointers */
198 static int filter_pred_pchar(struct filter_pred *pred, void *event)
199 {
200         char **addr = (char **)(event + pred->offset);
201         int cmp, match;
202         int len = strlen(*addr) + 1;    /* including tailing '\0' */
203
204         cmp = pred->regex.match(*addr, &pred->regex, len);
205
206         match = cmp ^ pred->not;
207
208         return match;
209 }
210
211 /*
212  * Filter predicate for dynamic sized arrays of characters.
213  * These are implemented through a list of strings at the end
214  * of the entry.
215  * Also each of these strings have a field in the entry which
216  * contains its offset from the beginning of the entry.
217  * We have then first to get this field, dereference it
218  * and add it to the address of the entry, and at last we have
219  * the address of the string.
220  */
221 static int filter_pred_strloc(struct filter_pred *pred, void *event)
222 {
223         u32 str_item = *(u32 *)(event + pred->offset);
224         int str_loc = str_item & 0xffff;
225         int str_len = str_item >> 16;
226         char *addr = (char *)(event + str_loc);
227         int cmp, match;
228
229         cmp = pred->regex.match(addr, &pred->regex, str_len);
230
231         match = cmp ^ pred->not;
232
233         return match;
234 }
235
236 static int filter_pred_none(struct filter_pred *pred, void *event)
237 {
238         return 0;
239 }
240
241 /*
242  * regex_match_foo - Basic regex callbacks
243  *
244  * @str: the string to be searched
245  * @r:   the regex structure containing the pattern string
246  * @len: the length of the string to be searched (including '\0')
247  *
248  * Note:
249  * - @str might not be NULL-terminated if it's of type DYN_STRING
250  *   or STATIC_STRING
251  */
252
253 static int regex_match_full(char *str, struct regex *r, int len)
254 {
255         if (strncmp(str, r->pattern, len) == 0)
256                 return 1;
257         return 0;
258 }
259
260 static int regex_match_front(char *str, struct regex *r, int len)
261 {
262         if (strncmp(str, r->pattern, r->len) == 0)
263                 return 1;
264         return 0;
265 }
266
267 static int regex_match_middle(char *str, struct regex *r, int len)
268 {
269         if (strnstr(str, r->pattern, len))
270                 return 1;
271         return 0;
272 }
273
274 static int regex_match_end(char *str, struct regex *r, int len)
275 {
276         int strlen = len - 1;
277
278         if (strlen >= r->len &&
279             memcmp(str + strlen - r->len, r->pattern, r->len) == 0)
280                 return 1;
281         return 0;
282 }
283
284 /**
285  * filter_parse_regex - parse a basic regex
286  * @buff:   the raw regex
287  * @len:    length of the regex
288  * @search: will point to the beginning of the string to compare
289  * @not:    tell whether the match will have to be inverted
290  *
291  * This passes in a buffer containing a regex and this function will
292  * set search to point to the search part of the buffer and
293  * return the type of search it is (see enum above).
294  * This does modify buff.
295  *
296  * Returns enum type.
297  *  search returns the pointer to use for comparison.
298  *  not returns 1 if buff started with a '!'
299  *     0 otherwise.
300  */
301 enum regex_type filter_parse_regex(char *buff, int len, char **search, int *not)
302 {
303         int type = MATCH_FULL;
304         int i;
305
306         if (buff[0] == '!') {
307                 *not = 1;
308                 buff++;
309                 len--;
310         } else
311                 *not = 0;
312
313         *search = buff;
314
315         for (i = 0; i < len; i++) {
316                 if (buff[i] == '*') {
317                         if (!i) {
318                                 *search = buff + 1;
319                                 type = MATCH_END_ONLY;
320                         } else {
321                                 if (type == MATCH_END_ONLY)
322                                         type = MATCH_MIDDLE_ONLY;
323                                 else
324                                         type = MATCH_FRONT_ONLY;
325                                 buff[i] = 0;
326                                 break;
327                         }
328                 }
329         }
330
331         return type;
332 }
333
334 static void filter_build_regex(struct filter_pred *pred)
335 {
336         struct regex *r = &pred->regex;
337         char *search;
338         enum regex_type type = MATCH_FULL;
339         int not = 0;
340
341         if (pred->op == OP_GLOB) {
342                 type = filter_parse_regex(r->pattern, r->len, &search, &not);
343                 r->len = strlen(search);
344                 memmove(r->pattern, search, r->len+1);
345         }
346
347         switch (type) {
348         case MATCH_FULL:
349                 r->match = regex_match_full;
350                 break;
351         case MATCH_FRONT_ONLY:
352                 r->match = regex_match_front;
353                 break;
354         case MATCH_MIDDLE_ONLY:
355                 r->match = regex_match_middle;
356                 break;
357         case MATCH_END_ONLY:
358                 r->match = regex_match_end;
359                 break;
360         }
361
362         pred->not ^= not;
363 }
364
365 enum move_type {
366         MOVE_DOWN,
367         MOVE_UP_FROM_LEFT,
368         MOVE_UP_FROM_RIGHT
369 };
370
371 static struct filter_pred *
372 get_pred_parent(struct filter_pred *pred, struct filter_pred *preds,
373                 int index, enum move_type *move)
374 {
375         if (pred->parent & FILTER_PRED_IS_RIGHT)
376                 *move = MOVE_UP_FROM_RIGHT;
377         else
378                 *move = MOVE_UP_FROM_LEFT;
379         pred = &preds[pred->parent & ~FILTER_PRED_IS_RIGHT];
380
381         return pred;
382 }
383
384 /*
385  * A series of AND or ORs where found together. Instead of
386  * climbing up and down the tree branches, an array of the
387  * ops were made in order of checks. We can just move across
388  * the array and short circuit if needed.
389  */
390 static int process_ops(struct filter_pred *preds,
391                        struct filter_pred *op, void *rec)
392 {
393         struct filter_pred *pred;
394         int type;
395         int match;
396         int i;
397
398         /*
399          * Micro-optimization: We set type to true if op
400          * is an OR and false otherwise (AND). Then we
401          * just need to test if the match is equal to
402          * the type, and if it is, we can short circuit the
403          * rest of the checks:
404          *
405          * if ((match && op->op == OP_OR) ||
406          *     (!match && op->op == OP_AND))
407          *        return match;
408          */
409         type = op->op == OP_OR;
410
411         for (i = 0; i < op->val; i++) {
412                 pred = &preds[op->ops[i]];
413                 match = pred->fn(pred, rec);
414                 if (!!match == type)
415                         return match;
416         }
417         return match;
418 }
419
420 /* return 1 if event matches, 0 otherwise (discard) */
421 int filter_match_preds(struct event_filter *filter, void *rec)
422 {
423         int match = -1;
424         enum move_type move = MOVE_DOWN;
425         struct filter_pred *preds;
426         struct filter_pred *pred;
427         struct filter_pred *root;
428         int n_preds;
429         int done = 0;
430
431         /* no filter is considered a match */
432         if (!filter)
433                 return 1;
434
435         n_preds = filter->n_preds;
436
437         if (!n_preds)
438                 return 1;
439
440         /*
441          * n_preds, root and filter->preds are protect with preemption disabled.
442          */
443         preds = rcu_dereference_sched(filter->preds);
444         root = rcu_dereference_sched(filter->root);
445         if (!root)
446                 return 1;
447
448         pred = root;
449
450         /* match is currently meaningless */
451         match = -1;
452
453         do {
454                 switch (move) {
455                 case MOVE_DOWN:
456                         /* only AND and OR have children */
457                         if (pred->left != FILTER_PRED_INVALID) {
458                                 /* If ops is set, then it was folded. */
459                                 if (!pred->ops) {
460                                         /* keep going to down the left side */
461                                         pred = &preds[pred->left];
462                                         continue;
463                                 }
464                                 /* We can treat folded ops as a leaf node */
465                                 match = process_ops(preds, pred, rec);
466                         } else
467                                 match = pred->fn(pred, rec);
468                         /* If this pred is the only pred */
469                         if (pred == root)
470                                 break;
471                         pred = get_pred_parent(pred, preds,
472                                                pred->parent, &move);
473                         continue;
474                 case MOVE_UP_FROM_LEFT:
475                         /*
476                          * Check for short circuits.
477                          *
478                          * Optimization: !!match == (pred->op == OP_OR)
479                          *   is the same as:
480                          * if ((match && pred->op == OP_OR) ||
481                          *     (!match && pred->op == OP_AND))
482                          */
483                         if (!!match == (pred->op == OP_OR)) {
484                                 if (pred == root)
485                                         break;
486                                 pred = get_pred_parent(pred, preds,
487                                                        pred->parent, &move);
488                                 continue;
489                         }
490                         /* now go down the right side of the tree. */
491                         pred = &preds[pred->right];
492                         move = MOVE_DOWN;
493                         continue;
494                 case MOVE_UP_FROM_RIGHT:
495                         /* We finished this equation. */
496                         if (pred == root)
497                                 break;
498                         pred = get_pred_parent(pred, preds,
499                                                pred->parent, &move);
500                         continue;
501                 }
502                 done = 1;
503         } while (!done);
504
505         return match;
506 }
507 EXPORT_SYMBOL_GPL(filter_match_preds);
508
509 static void parse_error(struct filter_parse_state *ps, int err, int pos)
510 {
511         ps->lasterr = err;
512         ps->lasterr_pos = pos;
513 }
514
515 static void remove_filter_string(struct event_filter *filter)
516 {
517         if (!filter)
518                 return;
519
520         kfree(filter->filter_string);
521         filter->filter_string = NULL;
522 }
523
524 static int replace_filter_string(struct event_filter *filter,
525                                  char *filter_string)
526 {
527         kfree(filter->filter_string);
528         filter->filter_string = kstrdup(filter_string, GFP_KERNEL);
529         if (!filter->filter_string)
530                 return -ENOMEM;
531
532         return 0;
533 }
534
535 static int append_filter_string(struct event_filter *filter,
536                                 char *string)
537 {
538         int newlen;
539         char *new_filter_string;
540
541         BUG_ON(!filter->filter_string);
542         newlen = strlen(filter->filter_string) + strlen(string) + 1;
543         new_filter_string = kmalloc(newlen, GFP_KERNEL);
544         if (!new_filter_string)
545                 return -ENOMEM;
546
547         strcpy(new_filter_string, filter->filter_string);
548         strcat(new_filter_string, string);
549         kfree(filter->filter_string);
550         filter->filter_string = new_filter_string;
551
552         return 0;
553 }
554
555 static void append_filter_err(struct filter_parse_state *ps,
556                               struct event_filter *filter)
557 {
558         int pos = ps->lasterr_pos;
559         char *buf, *pbuf;
560
561         buf = (char *)__get_free_page(GFP_TEMPORARY);
562         if (!buf)
563                 return;
564
565         append_filter_string(filter, "\n");
566         memset(buf, ' ', PAGE_SIZE);
567         if (pos > PAGE_SIZE - 128)
568                 pos = 0;
569         buf[pos] = '^';
570         pbuf = &buf[pos] + 1;
571
572         sprintf(pbuf, "\nparse_error: %s\n", err_text[ps->lasterr]);
573         append_filter_string(filter, buf);
574         free_page((unsigned long) buf);
575 }
576
577 void print_event_filter(struct ftrace_event_call *call, struct trace_seq *s)
578 {
579         struct event_filter *filter;
580
581         mutex_lock(&event_mutex);
582         filter = call->filter;
583         if (filter && filter->filter_string)
584                 trace_seq_printf(s, "%s\n", filter->filter_string);
585         else
586                 trace_seq_printf(s, "none\n");
587         mutex_unlock(&event_mutex);
588 }
589
590 void print_subsystem_event_filter(struct event_subsystem *system,
591                                   struct trace_seq *s)
592 {
593         struct event_filter *filter;
594
595         mutex_lock(&event_mutex);
596         filter = system->filter;
597         if (filter && filter->filter_string)
598                 trace_seq_printf(s, "%s\n", filter->filter_string);
599         else
600                 trace_seq_printf(s, "none\n");
601         mutex_unlock(&event_mutex);
602 }
603
604 static struct ftrace_event_field *
605 __find_event_field(struct list_head *head, char *name)
606 {
607         struct ftrace_event_field *field;
608
609         list_for_each_entry(field, head, link) {
610                 if (!strcmp(field->name, name))
611                         return field;
612         }
613
614         return NULL;
615 }
616
617 static struct ftrace_event_field *
618 find_event_field(struct ftrace_event_call *call, char *name)
619 {
620         struct ftrace_event_field *field;
621         struct list_head *head;
622
623         field = __find_event_field(&ftrace_common_fields, name);
624         if (field)
625                 return field;
626
627         head = trace_get_fields(call);
628         return __find_event_field(head, name);
629 }
630
631 static void filter_free_pred(struct filter_pred *pred)
632 {
633         if (!pred)
634                 return;
635
636         kfree(pred->field_name);
637         kfree(pred);
638 }
639
640 static void filter_clear_pred(struct filter_pred *pred)
641 {
642         kfree(pred->field_name);
643         pred->field_name = NULL;
644         pred->regex.len = 0;
645 }
646
647 static int __alloc_pred_stack(struct pred_stack *stack, int n_preds)
648 {
649         stack->preds = kzalloc(sizeof(*stack->preds)*(n_preds + 1), GFP_KERNEL);
650         if (!stack->preds)
651                 return -ENOMEM;
652         stack->index = n_preds;
653         return 0;
654 }
655
656 static void __free_pred_stack(struct pred_stack *stack)
657 {
658         kfree(stack->preds);
659         stack->index = 0;
660 }
661
662 static int __push_pred_stack(struct pred_stack *stack,
663                              struct filter_pred *pred)
664 {
665         int index = stack->index;
666
667         if (WARN_ON(index == 0))
668                 return -ENOSPC;
669
670         stack->preds[--index] = pred;
671         stack->index = index;
672         return 0;
673 }
674
675 static struct filter_pred *
676 __pop_pred_stack(struct pred_stack *stack)
677 {
678         struct filter_pred *pred;
679         int index = stack->index;
680
681         pred = stack->preds[index++];
682         if (!pred)
683                 return NULL;
684
685         stack->index = index;
686         return pred;
687 }
688
689 static int filter_set_pred(struct event_filter *filter,
690                            int idx,
691                            struct pred_stack *stack,
692                            struct filter_pred *src,
693                            filter_pred_fn_t fn)
694 {
695         struct filter_pred *dest = &filter->preds[idx];
696         struct filter_pred *left;
697         struct filter_pred *right;
698
699         *dest = *src;
700         if (src->field_name) {
701                 dest->field_name = kstrdup(src->field_name, GFP_KERNEL);
702                 if (!dest->field_name)
703                         return -ENOMEM;
704         }
705         dest->fn = fn;
706         dest->index = idx;
707
708         if (dest->op == OP_OR || dest->op == OP_AND) {
709                 right = __pop_pred_stack(stack);
710                 left = __pop_pred_stack(stack);
711                 if (!left || !right)
712                         return -EINVAL;
713                 /*
714                  * If both children can be folded
715                  * and they are the same op as this op or a leaf,
716                  * then this op can be folded.
717                  */
718                 if (left->index & FILTER_PRED_FOLD &&
719                     (left->op == dest->op ||
720                      left->left == FILTER_PRED_INVALID) &&
721                     right->index & FILTER_PRED_FOLD &&
722                     (right->op == dest->op ||
723                      right->left == FILTER_PRED_INVALID))
724                         dest->index |= FILTER_PRED_FOLD;
725
726                 dest->left = left->index & ~FILTER_PRED_FOLD;
727                 dest->right = right->index & ~FILTER_PRED_FOLD;
728                 left->parent = dest->index & ~FILTER_PRED_FOLD;
729                 right->parent = dest->index | FILTER_PRED_IS_RIGHT;
730         } else {
731                 /*
732                  * Make dest->left invalid to be used as a quick
733                  * way to know this is a leaf node.
734                  */
735                 dest->left = FILTER_PRED_INVALID;
736
737                 /* All leafs allow folding the parent ops. */
738                 dest->index |= FILTER_PRED_FOLD;
739         }
740
741         return __push_pred_stack(stack, dest);
742 }
743
744 static void __free_preds(struct event_filter *filter)
745 {
746         int i;
747
748         if (filter->preds) {
749                 for (i = 0; i < filter->a_preds; i++)
750                         kfree(filter->preds[i].field_name);
751                 kfree(filter->preds);
752                 filter->preds = NULL;
753         }
754         filter->a_preds = 0;
755         filter->n_preds = 0;
756 }
757
758 static void filter_disable(struct ftrace_event_call *call)
759 {
760         call->flags &= ~TRACE_EVENT_FL_FILTERED;
761 }
762
763 static void __free_filter(struct event_filter *filter)
764 {
765         if (!filter)
766                 return;
767
768         __free_preds(filter);
769         kfree(filter->filter_string);
770         kfree(filter);
771 }
772
773 /*
774  * Called when destroying the ftrace_event_call.
775  * The call is being freed, so we do not need to worry about
776  * the call being currently used. This is for module code removing
777  * the tracepoints from within it.
778  */
779 void destroy_preds(struct ftrace_event_call *call)
780 {
781         __free_filter(call->filter);
782         call->filter = NULL;
783 }
784
785 static struct event_filter *__alloc_filter(void)
786 {
787         struct event_filter *filter;
788
789         filter = kzalloc(sizeof(*filter), GFP_KERNEL);
790         return filter;
791 }
792
793 static int __alloc_preds(struct event_filter *filter, int n_preds)
794 {
795         struct filter_pred *pred;
796         int i;
797
798         if (filter->preds)
799                 __free_preds(filter);
800
801         filter->preds =
802                 kzalloc(sizeof(*filter->preds) * n_preds, GFP_KERNEL);
803
804         if (!filter->preds)
805                 return -ENOMEM;
806
807         filter->a_preds = n_preds;
808         filter->n_preds = 0;
809
810         for (i = 0; i < n_preds; i++) {
811                 pred = &filter->preds[i];
812                 pred->fn = filter_pred_none;
813         }
814
815         return 0;
816 }
817
818 static void filter_free_subsystem_preds(struct event_subsystem *system)
819 {
820         struct ftrace_event_call *call;
821
822         list_for_each_entry(call, &ftrace_events, list) {
823                 if (strcmp(call->class->system, system->name) != 0)
824                         continue;
825
826                 filter_disable(call);
827                 remove_filter_string(call->filter);
828         }
829 }
830
831 static void filter_free_subsystem_filters(struct event_subsystem *system)
832 {
833         struct ftrace_event_call *call;
834
835         list_for_each_entry(call, &ftrace_events, list) {
836                 if (strcmp(call->class->system, system->name) != 0)
837                         continue;
838                 __free_filter(call->filter);
839                 call->filter = NULL;
840         }
841 }
842
843 static int filter_add_pred_fn(struct filter_parse_state *ps,
844                               struct ftrace_event_call *call,
845                               struct event_filter *filter,
846                               struct filter_pred *pred,
847                               struct pred_stack *stack,
848                               filter_pred_fn_t fn)
849 {
850         int idx, err;
851
852         if (WARN_ON(filter->n_preds == filter->a_preds)) {
853                 parse_error(ps, FILT_ERR_TOO_MANY_PREDS, 0);
854                 return -ENOSPC;
855         }
856
857         idx = filter->n_preds;
858         filter_clear_pred(&filter->preds[idx]);
859         err = filter_set_pred(filter, idx, stack, pred, fn);
860         if (err)
861                 return err;
862
863         filter->n_preds++;
864
865         return 0;
866 }
867
868 int filter_assign_type(const char *type)
869 {
870         if (strstr(type, "__data_loc") && strstr(type, "char"))
871                 return FILTER_DYN_STRING;
872
873         if (strchr(type, '[') && strstr(type, "char"))
874                 return FILTER_STATIC_STRING;
875
876         return FILTER_OTHER;
877 }
878
879 static bool is_string_field(struct ftrace_event_field *field)
880 {
881         return field->filter_type == FILTER_DYN_STRING ||
882                field->filter_type == FILTER_STATIC_STRING ||
883                field->filter_type == FILTER_PTR_STRING;
884 }
885
886 static int is_legal_op(struct ftrace_event_field *field, int op)
887 {
888         if (is_string_field(field) &&
889             (op != OP_EQ && op != OP_NE && op != OP_GLOB))
890                 return 0;
891         if (!is_string_field(field) && op == OP_GLOB)
892                 return 0;
893
894         return 1;
895 }
896
897 static filter_pred_fn_t select_comparison_fn(int op, int field_size,
898                                              int field_is_signed)
899 {
900         filter_pred_fn_t fn = NULL;
901
902         switch (field_size) {
903         case 8:
904                 if (op == OP_EQ || op == OP_NE)
905                         fn = filter_pred_64;
906                 else if (field_is_signed)
907                         fn = filter_pred_s64;
908                 else
909                         fn = filter_pred_u64;
910                 break;
911         case 4:
912                 if (op == OP_EQ || op == OP_NE)
913                         fn = filter_pred_32;
914                 else if (field_is_signed)
915                         fn = filter_pred_s32;
916                 else
917                         fn = filter_pred_u32;
918                 break;
919         case 2:
920                 if (op == OP_EQ || op == OP_NE)
921                         fn = filter_pred_16;
922                 else if (field_is_signed)
923                         fn = filter_pred_s16;
924                 else
925                         fn = filter_pred_u16;
926                 break;
927         case 1:
928                 if (op == OP_EQ || op == OP_NE)
929                         fn = filter_pred_8;
930                 else if (field_is_signed)
931                         fn = filter_pred_s8;
932                 else
933                         fn = filter_pred_u8;
934                 break;
935         }
936
937         return fn;
938 }
939
940 static int filter_add_pred(struct filter_parse_state *ps,
941                            struct ftrace_event_call *call,
942                            struct event_filter *filter,
943                            struct filter_pred *pred,
944                            struct pred_stack *stack,
945                            bool dry_run)
946 {
947         struct ftrace_event_field *field;
948         filter_pred_fn_t fn;
949         unsigned long long val;
950         int ret;
951
952         fn = pred->fn = filter_pred_none;
953
954         if (pred->op == OP_AND)
955                 goto add_pred_fn;
956         else if (pred->op == OP_OR)
957                 goto add_pred_fn;
958
959         field = find_event_field(call, pred->field_name);
960         if (!field) {
961                 parse_error(ps, FILT_ERR_FIELD_NOT_FOUND, 0);
962                 return -EINVAL;
963         }
964
965         pred->offset = field->offset;
966
967         if (!is_legal_op(field, pred->op)) {
968                 parse_error(ps, FILT_ERR_ILLEGAL_FIELD_OP, 0);
969                 return -EINVAL;
970         }
971
972         if (is_string_field(field)) {
973                 filter_build_regex(pred);
974
975                 if (field->filter_type == FILTER_STATIC_STRING) {
976                         fn = filter_pred_string;
977                         pred->regex.field_len = field->size;
978                 } else if (field->filter_type == FILTER_DYN_STRING)
979                         fn = filter_pred_strloc;
980                 else
981                         fn = filter_pred_pchar;
982         } else {
983                 if (field->is_signed)
984                         ret = strict_strtoll(pred->regex.pattern, 0, &val);
985                 else
986                         ret = strict_strtoull(pred->regex.pattern, 0, &val);
987                 if (ret) {
988                         parse_error(ps, FILT_ERR_ILLEGAL_INTVAL, 0);
989                         return -EINVAL;
990                 }
991                 pred->val = val;
992
993                 fn = select_comparison_fn(pred->op, field->size,
994                                           field->is_signed);
995                 if (!fn) {
996                         parse_error(ps, FILT_ERR_INVALID_OP, 0);
997                         return -EINVAL;
998                 }
999         }
1000
1001         if (pred->op == OP_NE)
1002                 pred->not = 1;
1003
1004 add_pred_fn:
1005         if (!dry_run)
1006                 return filter_add_pred_fn(ps, call, filter, pred, stack, fn);
1007         return 0;
1008 }
1009
1010 static void parse_init(struct filter_parse_state *ps,
1011                        struct filter_op *ops,
1012                        char *infix_string)
1013 {
1014         memset(ps, '\0', sizeof(*ps));
1015
1016         ps->infix.string = infix_string;
1017         ps->infix.cnt = strlen(infix_string);
1018         ps->ops = ops;
1019
1020         INIT_LIST_HEAD(&ps->opstack);
1021         INIT_LIST_HEAD(&ps->postfix);
1022 }
1023
1024 static char infix_next(struct filter_parse_state *ps)
1025 {
1026         ps->infix.cnt--;
1027
1028         return ps->infix.string[ps->infix.tail++];
1029 }
1030
1031 static char infix_peek(struct filter_parse_state *ps)
1032 {
1033         if (ps->infix.tail == strlen(ps->infix.string))
1034                 return 0;
1035
1036         return ps->infix.string[ps->infix.tail];
1037 }
1038
1039 static void infix_advance(struct filter_parse_state *ps)
1040 {
1041         ps->infix.cnt--;
1042         ps->infix.tail++;
1043 }
1044
1045 static inline int is_precedence_lower(struct filter_parse_state *ps,
1046                                       int a, int b)
1047 {
1048         return ps->ops[a].precedence < ps->ops[b].precedence;
1049 }
1050
1051 static inline int is_op_char(struct filter_parse_state *ps, char c)
1052 {
1053         int i;
1054
1055         for (i = 0; strcmp(ps->ops[i].string, "OP_NONE"); i++) {
1056                 if (ps->ops[i].string[0] == c)
1057                         return 1;
1058         }
1059
1060         return 0;
1061 }
1062
1063 static int infix_get_op(struct filter_parse_state *ps, char firstc)
1064 {
1065         char nextc = infix_peek(ps);
1066         char opstr[3];
1067         int i;
1068
1069         opstr[0] = firstc;
1070         opstr[1] = nextc;
1071         opstr[2] = '\0';
1072
1073         for (i = 0; strcmp(ps->ops[i].string, "OP_NONE"); i++) {
1074                 if (!strcmp(opstr, ps->ops[i].string)) {
1075                         infix_advance(ps);
1076                         return ps->ops[i].id;
1077                 }
1078         }
1079
1080         opstr[1] = '\0';
1081
1082         for (i = 0; strcmp(ps->ops[i].string, "OP_NONE"); i++) {
1083                 if (!strcmp(opstr, ps->ops[i].string))
1084                         return ps->ops[i].id;
1085         }
1086
1087         return OP_NONE;
1088 }
1089
1090 static inline void clear_operand_string(struct filter_parse_state *ps)
1091 {
1092         memset(ps->operand.string, '\0', MAX_FILTER_STR_VAL);
1093         ps->operand.tail = 0;
1094 }
1095
1096 static inline int append_operand_char(struct filter_parse_state *ps, char c)
1097 {
1098         if (ps->operand.tail == MAX_FILTER_STR_VAL - 1)
1099                 return -EINVAL;
1100
1101         ps->operand.string[ps->operand.tail++] = c;
1102
1103         return 0;
1104 }
1105
1106 static int filter_opstack_push(struct filter_parse_state *ps, int op)
1107 {
1108         struct opstack_op *opstack_op;
1109
1110         opstack_op = kmalloc(sizeof(*opstack_op), GFP_KERNEL);
1111         if (!opstack_op)
1112                 return -ENOMEM;
1113
1114         opstack_op->op = op;
1115         list_add(&opstack_op->list, &ps->opstack);
1116
1117         return 0;
1118 }
1119
1120 static int filter_opstack_empty(struct filter_parse_state *ps)
1121 {
1122         return list_empty(&ps->opstack);
1123 }
1124
1125 static int filter_opstack_top(struct filter_parse_state *ps)
1126 {
1127         struct opstack_op *opstack_op;
1128
1129         if (filter_opstack_empty(ps))
1130                 return OP_NONE;
1131
1132         opstack_op = list_first_entry(&ps->opstack, struct opstack_op, list);
1133
1134         return opstack_op->op;
1135 }
1136
1137 static int filter_opstack_pop(struct filter_parse_state *ps)
1138 {
1139         struct opstack_op *opstack_op;
1140         int op;
1141
1142         if (filter_opstack_empty(ps))
1143                 return OP_NONE;
1144
1145         opstack_op = list_first_entry(&ps->opstack, struct opstack_op, list);
1146         op = opstack_op->op;
1147         list_del(&opstack_op->list);
1148
1149         kfree(opstack_op);
1150
1151         return op;
1152 }
1153
1154 static void filter_opstack_clear(struct filter_parse_state *ps)
1155 {
1156         while (!filter_opstack_empty(ps))
1157                 filter_opstack_pop(ps);
1158 }
1159
1160 static char *curr_operand(struct filter_parse_state *ps)
1161 {
1162         return ps->operand.string;
1163 }
1164
1165 static int postfix_append_operand(struct filter_parse_state *ps, char *operand)
1166 {
1167         struct postfix_elt *elt;
1168
1169         elt = kmalloc(sizeof(*elt), GFP_KERNEL);
1170         if (!elt)
1171                 return -ENOMEM;
1172
1173         elt->op = OP_NONE;
1174         elt->operand = kstrdup(operand, GFP_KERNEL);
1175         if (!elt->operand) {
1176                 kfree(elt);
1177                 return -ENOMEM;
1178         }
1179
1180         list_add_tail(&elt->list, &ps->postfix);
1181
1182         return 0;
1183 }
1184
1185 static int postfix_append_op(struct filter_parse_state *ps, int op)
1186 {
1187         struct postfix_elt *elt;
1188
1189         elt = kmalloc(sizeof(*elt), GFP_KERNEL);
1190         if (!elt)
1191                 return -ENOMEM;
1192
1193         elt->op = op;
1194         elt->operand = NULL;
1195
1196         list_add_tail(&elt->list, &ps->postfix);
1197
1198         return 0;
1199 }
1200
1201 static void postfix_clear(struct filter_parse_state *ps)
1202 {
1203         struct postfix_elt *elt;
1204
1205         while (!list_empty(&ps->postfix)) {
1206                 elt = list_first_entry(&ps->postfix, struct postfix_elt, list);
1207                 list_del(&elt->list);
1208                 kfree(elt->operand);
1209                 kfree(elt);
1210         }
1211 }
1212
1213 static int filter_parse(struct filter_parse_state *ps)
1214 {
1215         int in_string = 0;
1216         int op, top_op;
1217         char ch;
1218
1219         while ((ch = infix_next(ps))) {
1220                 if (ch == '"') {
1221                         in_string ^= 1;
1222                         continue;
1223                 }
1224
1225                 if (in_string)
1226                         goto parse_operand;
1227
1228                 if (isspace(ch))
1229                         continue;
1230
1231                 if (is_op_char(ps, ch)) {
1232                         op = infix_get_op(ps, ch);
1233                         if (op == OP_NONE) {
1234                                 parse_error(ps, FILT_ERR_INVALID_OP, 0);
1235                                 return -EINVAL;
1236                         }
1237
1238                         if (strlen(curr_operand(ps))) {
1239                                 postfix_append_operand(ps, curr_operand(ps));
1240                                 clear_operand_string(ps);
1241                         }
1242
1243                         while (!filter_opstack_empty(ps)) {
1244                                 top_op = filter_opstack_top(ps);
1245                                 if (!is_precedence_lower(ps, top_op, op)) {
1246                                         top_op = filter_opstack_pop(ps);
1247                                         postfix_append_op(ps, top_op);
1248                                         continue;
1249                                 }
1250                                 break;
1251                         }
1252
1253                         filter_opstack_push(ps, op);
1254                         continue;
1255                 }
1256
1257                 if (ch == '(') {
1258                         filter_opstack_push(ps, OP_OPEN_PAREN);
1259                         continue;
1260                 }
1261
1262                 if (ch == ')') {
1263                         if (strlen(curr_operand(ps))) {
1264                                 postfix_append_operand(ps, curr_operand(ps));
1265                                 clear_operand_string(ps);
1266                         }
1267
1268                         top_op = filter_opstack_pop(ps);
1269                         while (top_op != OP_NONE) {
1270                                 if (top_op == OP_OPEN_PAREN)
1271                                         break;
1272                                 postfix_append_op(ps, top_op);
1273                                 top_op = filter_opstack_pop(ps);
1274                         }
1275                         if (top_op == OP_NONE) {
1276                                 parse_error(ps, FILT_ERR_UNBALANCED_PAREN, 0);
1277                                 return -EINVAL;
1278                         }
1279                         continue;
1280                 }
1281 parse_operand:
1282                 if (append_operand_char(ps, ch)) {
1283                         parse_error(ps, FILT_ERR_OPERAND_TOO_LONG, 0);
1284                         return -EINVAL;
1285                 }
1286         }
1287
1288         if (strlen(curr_operand(ps)))
1289                 postfix_append_operand(ps, curr_operand(ps));
1290
1291         while (!filter_opstack_empty(ps)) {
1292                 top_op = filter_opstack_pop(ps);
1293                 if (top_op == OP_NONE)
1294                         break;
1295                 if (top_op == OP_OPEN_PAREN) {
1296                         parse_error(ps, FILT_ERR_UNBALANCED_PAREN, 0);
1297                         return -EINVAL;
1298                 }
1299                 postfix_append_op(ps, top_op);
1300         }
1301
1302         return 0;
1303 }
1304
1305 static struct filter_pred *create_pred(int op, char *operand1, char *operand2)
1306 {
1307         struct filter_pred *pred;
1308
1309         pred = kzalloc(sizeof(*pred), GFP_KERNEL);
1310         if (!pred)
1311                 return NULL;
1312
1313         pred->field_name = kstrdup(operand1, GFP_KERNEL);
1314         if (!pred->field_name) {
1315                 kfree(pred);
1316                 return NULL;
1317         }
1318
1319         strcpy(pred->regex.pattern, operand2);
1320         pred->regex.len = strlen(pred->regex.pattern);
1321
1322         pred->op = op;
1323
1324         return pred;
1325 }
1326
1327 static struct filter_pred *create_logical_pred(int op)
1328 {
1329         struct filter_pred *pred;
1330
1331         pred = kzalloc(sizeof(*pred), GFP_KERNEL);
1332         if (!pred)
1333                 return NULL;
1334
1335         pred->op = op;
1336
1337         return pred;
1338 }
1339
1340 static int check_preds(struct filter_parse_state *ps)
1341 {
1342         int n_normal_preds = 0, n_logical_preds = 0;
1343         struct postfix_elt *elt;
1344
1345         list_for_each_entry(elt, &ps->postfix, list) {
1346                 if (elt->op == OP_NONE)
1347                         continue;
1348
1349                 if (elt->op == OP_AND || elt->op == OP_OR) {
1350                         n_logical_preds++;
1351                         continue;
1352                 }
1353                 n_normal_preds++;
1354         }
1355
1356         if (!n_normal_preds || n_logical_preds >= n_normal_preds) {
1357                 parse_error(ps, FILT_ERR_INVALID_FILTER, 0);
1358                 return -EINVAL;
1359         }
1360
1361         return 0;
1362 }
1363
1364 static int count_preds(struct filter_parse_state *ps)
1365 {
1366         struct postfix_elt *elt;
1367         int n_preds = 0;
1368
1369         list_for_each_entry(elt, &ps->postfix, list) {
1370                 if (elt->op == OP_NONE)
1371                         continue;
1372                 n_preds++;
1373         }
1374
1375         return n_preds;
1376 }
1377
1378 /*
1379  * The tree is walked at filtering of an event. If the tree is not correctly
1380  * built, it may cause an infinite loop. Check here that the tree does
1381  * indeed terminate.
1382  */
1383 static int check_pred_tree(struct event_filter *filter,
1384                            struct filter_pred *root)
1385 {
1386         struct filter_pred *preds;
1387         struct filter_pred *pred;
1388         enum move_type move = MOVE_DOWN;
1389         int count = 0;
1390         int done = 0;
1391         int max;
1392
1393         /*
1394          * The max that we can hit a node is three times.
1395          * Once going down, once coming up from left, and
1396          * once coming up from right. This is more than enough
1397          * since leafs are only hit a single time.
1398          */
1399         max = 3 * filter->n_preds;
1400
1401         preds = filter->preds;
1402         if  (!preds)
1403                 return -EINVAL;
1404         pred = root;
1405
1406         do {
1407                 if (WARN_ON(count++ > max))
1408                         return -EINVAL;
1409
1410                 switch (move) {
1411                 case MOVE_DOWN:
1412                         if (pred->left != FILTER_PRED_INVALID) {
1413                                 pred = &preds[pred->left];
1414                                 continue;
1415                         }
1416                         /* A leaf at the root is just a leaf in the tree */
1417                         if (pred == root)
1418                                 break;
1419                         pred = get_pred_parent(pred, preds,
1420                                                pred->parent, &move);
1421                         continue;
1422                 case MOVE_UP_FROM_LEFT:
1423                         pred = &preds[pred->right];
1424                         move = MOVE_DOWN;
1425                         continue;
1426                 case MOVE_UP_FROM_RIGHT:
1427                         if (pred == root)
1428                                 break;
1429                         pred = get_pred_parent(pred, preds,
1430                                                pred->parent, &move);
1431                         continue;
1432                 }
1433                 done = 1;
1434         } while (!done);
1435
1436         /* We are fine. */
1437         return 0;
1438 }
1439
1440 static int count_leafs(struct filter_pred *preds, struct filter_pred *root)
1441 {
1442         struct filter_pred *pred;
1443         enum move_type move = MOVE_DOWN;
1444         int count = 0;
1445         int done = 0;
1446
1447         pred = root;
1448
1449         do {
1450                 switch (move) {
1451                 case MOVE_DOWN:
1452                         if (pred->left != FILTER_PRED_INVALID) {
1453                                 pred = &preds[pred->left];
1454                                 continue;
1455                         }
1456                         /* A leaf at the root is just a leaf in the tree */
1457                         if (pred == root)
1458                                 return 1;
1459                         count++;
1460                         pred = get_pred_parent(pred, preds,
1461                                                pred->parent, &move);
1462                         continue;
1463                 case MOVE_UP_FROM_LEFT:
1464                         pred = &preds[pred->right];
1465                         move = MOVE_DOWN;
1466                         continue;
1467                 case MOVE_UP_FROM_RIGHT:
1468                         if (pred == root)
1469                                 break;
1470                         pred = get_pred_parent(pred, preds,
1471                                                pred->parent, &move);
1472                         continue;
1473                 }
1474                 done = 1;
1475         } while (!done);
1476
1477         return count;
1478 }
1479
1480 static int fold_pred(struct filter_pred *preds, struct filter_pred *root)
1481 {
1482         struct filter_pred *pred;
1483         enum move_type move = MOVE_DOWN;
1484         int count = 0;
1485         int children;
1486         int done = 0;
1487
1488         /* No need to keep the fold flag */
1489         root->index &= ~FILTER_PRED_FOLD;
1490
1491         /* If the root is a leaf then do nothing */
1492         if (root->left == FILTER_PRED_INVALID)
1493                 return 0;
1494
1495         /* count the children */
1496         children = count_leafs(preds, &preds[root->left]);
1497         children += count_leafs(preds, &preds[root->right]);
1498
1499         root->ops = kzalloc(sizeof(*root->ops) * children, GFP_KERNEL);
1500         if (!root->ops)
1501                 return -ENOMEM;
1502
1503         root->val = children;
1504
1505         pred = root;
1506         do {
1507                 switch (move) {
1508                 case MOVE_DOWN:
1509                         if (pred->left != FILTER_PRED_INVALID) {
1510                                 pred = &preds[pred->left];
1511                                 continue;
1512                         }
1513                         if (WARN_ON(count == children))
1514                                 return -EINVAL;
1515                         pred->index &= ~FILTER_PRED_FOLD;
1516                         root->ops[count++] = pred->index;
1517                         pred = get_pred_parent(pred, preds,
1518                                                pred->parent, &move);
1519                         continue;
1520                 case MOVE_UP_FROM_LEFT:
1521                         pred = &preds[pred->right];
1522                         move = MOVE_DOWN;
1523                         continue;
1524                 case MOVE_UP_FROM_RIGHT:
1525                         if (pred == root)
1526                                 break;
1527                         pred = get_pred_parent(pred, preds,
1528                                                pred->parent, &move);
1529                         continue;
1530                 }
1531                 done = 1;
1532         } while (!done);
1533
1534         return 0;
1535 }
1536
1537 /*
1538  * To optimize the processing of the ops, if we have several "ors" or
1539  * "ands" together, we can put them in an array and process them all
1540  * together speeding up the filter logic.
1541  */
1542 static int fold_pred_tree(struct event_filter *filter,
1543                            struct filter_pred *root)
1544 {
1545         struct filter_pred *preds;
1546         struct filter_pred *pred;
1547         enum move_type move = MOVE_DOWN;
1548         int done = 0;
1549         int err;
1550
1551         preds = filter->preds;
1552         if  (!preds)
1553                 return -EINVAL;
1554         pred = root;
1555
1556         do {
1557                 switch (move) {
1558                 case MOVE_DOWN:
1559                         if (pred->index & FILTER_PRED_FOLD) {
1560                                 err = fold_pred(preds, pred);
1561                                 if (err)
1562                                         return err;
1563                                 /* Folded nodes are like leafs */
1564                         } else if (pred->left != FILTER_PRED_INVALID) {
1565                                 pred = &preds[pred->left];
1566                                 continue;
1567                         }
1568
1569                         /* A leaf at the root is just a leaf in the tree */
1570                         if (pred == root)
1571                                 break;
1572                         pred = get_pred_parent(pred, preds,
1573                                                pred->parent, &move);
1574                         continue;
1575                 case MOVE_UP_FROM_LEFT:
1576                         pred = &preds[pred->right];
1577                         move = MOVE_DOWN;
1578                         continue;
1579                 case MOVE_UP_FROM_RIGHT:
1580                         if (pred == root)
1581                                 break;
1582                         pred = get_pred_parent(pred, preds,
1583                                                pred->parent, &move);
1584                         continue;
1585                 }
1586                 done = 1;
1587         } while (!done);
1588
1589         return 0;
1590 }
1591
1592 static int replace_preds(struct ftrace_event_call *call,
1593                          struct event_filter *filter,
1594                          struct filter_parse_state *ps,
1595                          char *filter_string,
1596                          bool dry_run)
1597 {
1598         char *operand1 = NULL, *operand2 = NULL;
1599         struct filter_pred *pred;
1600         struct filter_pred *root;
1601         struct postfix_elt *elt;
1602         struct pred_stack stack = { }; /* init to NULL */
1603         int err;
1604         int n_preds = 0;
1605
1606         n_preds = count_preds(ps);
1607         if (n_preds >= MAX_FILTER_PRED) {
1608                 parse_error(ps, FILT_ERR_TOO_MANY_PREDS, 0);
1609                 return -ENOSPC;
1610         }
1611
1612         err = check_preds(ps);
1613         if (err)
1614                 return err;
1615
1616         if (!dry_run) {
1617                 err = __alloc_pred_stack(&stack, n_preds);
1618                 if (err)
1619                         return err;
1620                 err = __alloc_preds(filter, n_preds);
1621                 if (err)
1622                         goto fail;
1623         }
1624
1625         n_preds = 0;
1626         list_for_each_entry(elt, &ps->postfix, list) {
1627                 if (elt->op == OP_NONE) {
1628                         if (!operand1)
1629                                 operand1 = elt->operand;
1630                         else if (!operand2)
1631                                 operand2 = elt->operand;
1632                         else {
1633                                 parse_error(ps, FILT_ERR_TOO_MANY_OPERANDS, 0);
1634                                 err = -EINVAL;
1635                                 goto fail;
1636                         }
1637                         continue;
1638                 }
1639
1640                 if (WARN_ON(n_preds++ == MAX_FILTER_PRED)) {
1641                         parse_error(ps, FILT_ERR_TOO_MANY_PREDS, 0);
1642                         err = -ENOSPC;
1643                         goto fail;
1644                 }
1645
1646                 if (elt->op == OP_AND || elt->op == OP_OR) {
1647                         pred = create_logical_pred(elt->op);
1648                         goto add_pred;
1649                 }
1650
1651                 if (!operand1 || !operand2) {
1652                         parse_error(ps, FILT_ERR_MISSING_FIELD, 0);
1653                         err = -EINVAL;
1654                         goto fail;
1655                 }
1656
1657                 pred = create_pred(elt->op, operand1, operand2);
1658 add_pred:
1659                 if (!pred) {
1660                         err = -ENOMEM;
1661                         goto fail;
1662                 }
1663                 err = filter_add_pred(ps, call, filter, pred, &stack, dry_run);
1664                 filter_free_pred(pred);
1665                 if (err)
1666                         goto fail;
1667
1668                 operand1 = operand2 = NULL;
1669         }
1670
1671         if (!dry_run) {
1672                 /* We should have one item left on the stack */
1673                 pred = __pop_pred_stack(&stack);
1674                 if (!pred)
1675                         return -EINVAL;
1676                 /* This item is where we start from in matching */
1677                 root = pred;
1678                 /* Make sure the stack is empty */
1679                 pred = __pop_pred_stack(&stack);
1680                 if (WARN_ON(pred)) {
1681                         err = -EINVAL;
1682                         filter->root = NULL;
1683                         goto fail;
1684                 }
1685                 err = check_pred_tree(filter, root);
1686                 if (err)
1687                         goto fail;
1688
1689                 /* Optimize the tree */
1690                 err = fold_pred_tree(filter, root);
1691                 if (err)
1692                         goto fail;
1693
1694                 /* We don't set root until we know it works */
1695                 barrier();
1696                 filter->root = root;
1697         }
1698
1699         err = 0;
1700 fail:
1701         __free_pred_stack(&stack);
1702         return err;
1703 }
1704
1705 struct filter_list {
1706         struct list_head        list;
1707         struct event_filter     *filter;
1708 };
1709
1710 static int replace_system_preds(struct event_subsystem *system,
1711                                 struct filter_parse_state *ps,
1712                                 char *filter_string)
1713 {
1714         struct ftrace_event_call *call;
1715         struct filter_list *filter_item;
1716         struct filter_list *tmp;
1717         LIST_HEAD(filter_list);
1718         bool fail = true;
1719         int err;
1720
1721         list_for_each_entry(call, &ftrace_events, list) {
1722
1723                 if (strcmp(call->class->system, system->name) != 0)
1724                         continue;
1725
1726                 /*
1727                  * Try to see if the filter can be applied
1728                  *  (filter arg is ignored on dry_run)
1729                  */
1730                 err = replace_preds(call, NULL, ps, filter_string, true);
1731                 if (err)
1732                         goto fail;
1733         }
1734
1735         list_for_each_entry(call, &ftrace_events, list) {
1736                 struct event_filter *filter;
1737
1738                 if (strcmp(call->class->system, system->name) != 0)
1739                         continue;
1740
1741                 filter_item = kzalloc(sizeof(*filter_item), GFP_KERNEL);
1742                 if (!filter_item)
1743                         goto fail_mem;
1744
1745                 list_add_tail(&filter_item->list, &filter_list);
1746
1747                 filter_item->filter = __alloc_filter();
1748                 if (!filter_item->filter)
1749                         goto fail_mem;
1750                 filter = filter_item->filter;
1751
1752                 /* Can only fail on no memory */
1753                 err = replace_filter_string(filter, filter_string);
1754                 if (err)
1755                         goto fail_mem;
1756
1757                 err = replace_preds(call, filter, ps, filter_string, false);
1758                 if (err) {
1759                         filter_disable(call);
1760                         parse_error(ps, FILT_ERR_BAD_SUBSYS_FILTER, 0);
1761                         append_filter_err(ps, filter);
1762                 } else
1763                         call->flags |= TRACE_EVENT_FL_FILTERED;
1764                 /*
1765                  * Regardless of if this returned an error, we still
1766                  * replace the filter for the call.
1767                  */
1768                 filter = call->filter;
1769                 call->filter = filter_item->filter;
1770                 filter_item->filter = filter;
1771
1772                 fail = false;
1773         }
1774
1775         if (fail)
1776                 goto fail;
1777
1778         /*
1779          * The calls can still be using the old filters.
1780          * Do a synchronize_sched() to ensure all calls are
1781          * done with them before we free them.
1782          */
1783         synchronize_sched();
1784         list_for_each_entry_safe(filter_item, tmp, &filter_list, list) {
1785                 __free_filter(filter_item->filter);
1786                 list_del(&filter_item->list);
1787                 kfree(filter_item);
1788         }
1789         return 0;
1790  fail:
1791         /* No call succeeded */
1792         list_for_each_entry_safe(filter_item, tmp, &filter_list, list) {
1793                 list_del(&filter_item->list);
1794                 kfree(filter_item);
1795         }
1796         parse_error(ps, FILT_ERR_BAD_SUBSYS_FILTER, 0);
1797         return -EINVAL;
1798  fail_mem:
1799         /* If any call succeeded, we still need to sync */
1800         if (!fail)
1801                 synchronize_sched();
1802         list_for_each_entry_safe(filter_item, tmp, &filter_list, list) {
1803                 __free_filter(filter_item->filter);
1804                 list_del(&filter_item->list);
1805                 kfree(filter_item);
1806         }
1807         return -ENOMEM;
1808 }
1809
1810 int apply_event_filter(struct ftrace_event_call *call, char *filter_string)
1811 {
1812         struct filter_parse_state *ps;
1813         struct event_filter *filter;
1814         struct event_filter *tmp;
1815         int err = 0;
1816
1817         mutex_lock(&event_mutex);
1818
1819         if (!strcmp(strstrip(filter_string), "0")) {
1820                 filter_disable(call);
1821                 filter = call->filter;
1822                 if (!filter)
1823                         goto out_unlock;
1824                 call->filter = NULL;
1825                 /* Make sure the filter is not being used */
1826                 synchronize_sched();
1827                 __free_filter(filter);
1828                 goto out_unlock;
1829         }
1830
1831         err = -ENOMEM;
1832         ps = kzalloc(sizeof(*ps), GFP_KERNEL);
1833         if (!ps)
1834                 goto out_unlock;
1835
1836         filter = __alloc_filter();
1837         if (!filter) {
1838                 kfree(ps);
1839                 goto out_unlock;
1840         }
1841
1842         replace_filter_string(filter, filter_string);
1843
1844         parse_init(ps, filter_ops, filter_string);
1845         err = filter_parse(ps);
1846         if (err) {
1847                 append_filter_err(ps, filter);
1848                 goto out;
1849         }
1850
1851         err = replace_preds(call, filter, ps, filter_string, false);
1852         if (err) {
1853                 filter_disable(call);
1854                 append_filter_err(ps, filter);
1855         } else
1856                 call->flags |= TRACE_EVENT_FL_FILTERED;
1857 out:
1858         /*
1859          * Always swap the call filter with the new filter
1860          * even if there was an error. If there was an error
1861          * in the filter, we disable the filter and show the error
1862          * string
1863          */
1864         tmp = call->filter;
1865         call->filter = filter;
1866         if (tmp) {
1867                 /* Make sure the call is done with the filter */
1868                 synchronize_sched();
1869                 __free_filter(tmp);
1870         }
1871         filter_opstack_clear(ps);
1872         postfix_clear(ps);
1873         kfree(ps);
1874 out_unlock:
1875         mutex_unlock(&event_mutex);
1876
1877         return err;
1878 }
1879
1880 int apply_subsystem_event_filter(struct event_subsystem *system,
1881                                  char *filter_string)
1882 {
1883         struct filter_parse_state *ps;
1884         struct event_filter *filter;
1885         int err = 0;
1886
1887         mutex_lock(&event_mutex);
1888
1889         if (!strcmp(strstrip(filter_string), "0")) {
1890                 filter_free_subsystem_preds(system);
1891                 remove_filter_string(system->filter);
1892                 filter = system->filter;
1893                 system->filter = NULL;
1894                 /* Ensure all filters are no longer used */
1895                 synchronize_sched();
1896                 filter_free_subsystem_filters(system);
1897                 __free_filter(filter);
1898                 goto out_unlock;
1899         }
1900
1901         err = -ENOMEM;
1902         ps = kzalloc(sizeof(*ps), GFP_KERNEL);
1903         if (!ps)
1904                 goto out_unlock;
1905
1906         filter = __alloc_filter();
1907         if (!filter)
1908                 goto out;
1909
1910         replace_filter_string(filter, filter_string);
1911         /*
1912          * No event actually uses the system filter
1913          * we can free it without synchronize_sched().
1914          */
1915         __free_filter(system->filter);
1916         system->filter = filter;
1917
1918         parse_init(ps, filter_ops, filter_string);
1919         err = filter_parse(ps);
1920         if (err) {
1921                 append_filter_err(ps, system->filter);
1922                 goto out;
1923         }
1924
1925         err = replace_system_preds(system, ps, filter_string);
1926         if (err)
1927                 append_filter_err(ps, system->filter);
1928
1929 out:
1930         filter_opstack_clear(ps);
1931         postfix_clear(ps);
1932         kfree(ps);
1933 out_unlock:
1934         mutex_unlock(&event_mutex);
1935
1936         return err;
1937 }
1938
1939 #ifdef CONFIG_PERF_EVENTS
1940
1941 void ftrace_profile_free_filter(struct perf_event *event)
1942 {
1943         struct event_filter *filter = event->filter;
1944
1945         event->filter = NULL;
1946         __free_filter(filter);
1947 }
1948
1949 int ftrace_profile_set_filter(struct perf_event *event, int event_id,
1950                               char *filter_str)
1951 {
1952         int err;
1953         struct event_filter *filter;
1954         struct filter_parse_state *ps;
1955         struct ftrace_event_call *call = NULL;
1956
1957         mutex_lock(&event_mutex);
1958
1959         list_for_each_entry(call, &ftrace_events, list) {
1960                 if (call->event.type == event_id)
1961                         break;
1962         }
1963
1964         err = -EINVAL;
1965         if (&call->list == &ftrace_events)
1966                 goto out_unlock;
1967
1968         err = -EEXIST;
1969         if (event->filter)
1970                 goto out_unlock;
1971
1972         filter = __alloc_filter();
1973         if (!filter) {
1974                 err = PTR_ERR(filter);
1975                 goto out_unlock;
1976         }
1977
1978         err = -ENOMEM;
1979         ps = kzalloc(sizeof(*ps), GFP_KERNEL);
1980         if (!ps)
1981                 goto free_filter;
1982
1983         parse_init(ps, filter_ops, filter_str);
1984         err = filter_parse(ps);
1985         if (err)
1986                 goto free_ps;
1987
1988         err = replace_preds(call, filter, ps, filter_str, false);
1989         if (!err)
1990                 event->filter = filter;
1991
1992 free_ps:
1993         filter_opstack_clear(ps);
1994         postfix_clear(ps);
1995         kfree(ps);
1996
1997 free_filter:
1998         if (err)
1999                 __free_filter(filter);
2000
2001 out_unlock:
2002         mutex_unlock(&event_mutex);
2003
2004         return err;
2005 }
2006
2007 #endif /* CONFIG_PERF_EVENTS */
2008