Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Steven Rostedt | 5463 | 51.38% | 69 | 38.98% |
Jiri Olsa | 1507 | 14.17% | 13 | 7.34% |
Tom Zanussi | 1291 | 12.14% | 13 | 7.34% |
Valentin Schneider | 1029 | 9.68% | 11 | 6.21% |
Li Zefan | 335 | 3.15% | 22 | 12.43% |
Frédéric Weisbecker | 309 | 2.91% | 7 | 3.95% |
Tejun Heo | 282 | 2.65% | 2 | 1.13% |
Masami Hiramatsu | 149 | 1.40% | 2 | 1.13% |
Daniel Wagner | 47 | 0.44% | 1 | 0.56% |
Tomas Bortoli | 32 | 0.30% | 1 | 0.56% |
Ingo Molnar | 31 | 0.29% | 2 | 1.13% |
Américo Wang | 23 | 0.22% | 1 | 0.56% |
Oleg Nesterov | 20 | 0.19% | 2 | 1.13% |
Pavel Tikhomirov | 19 | 0.18% | 1 | 0.56% |
Namhyung Kim | 15 | 0.14% | 1 | 0.56% |
Peter Zijlstra | 12 | 0.11% | 4 | 2.26% |
Paul Mackerras | 8 | 0.08% | 1 | 0.56% |
Kees Cook | 8 | 0.08% | 1 | 0.56% |
Navid Emamdoost | 8 | 0.08% | 1 | 0.56% |
Qiujun Huang | 6 | 0.06% | 3 | 1.69% |
Linus Torvalds (pre-git) | 5 | 0.05% | 3 | 1.69% |
Gustavo A. R. Silva | 4 | 0.04% | 1 | 0.56% |
Ravi Bangoria | 4 | 0.04% | 1 | 0.56% |
Mathieu Desnoyers | 3 | 0.03% | 1 | 0.56% |
Rasmus Villemoes | 3 | 0.03% | 1 | 0.56% |
Paul Mundt | 3 | 0.03% | 1 | 0.56% |
Xiao Guangrong | 3 | 0.03% | 1 | 0.56% |
Paul E. McKenney | 2 | 0.02% | 1 | 0.56% |
Jovi Zhangwei | 2 | 0.02% | 1 | 0.56% |
Randy Dunlap | 2 | 0.02% | 1 | 0.56% |
Colin Ian King | 1 | 0.01% | 1 | 0.56% |
Jérémy Lefaure | 1 | 0.01% | 1 | 0.56% |
Thomas Meyer | 1 | 0.01% | 1 | 0.56% |
Linus Torvalds | 1 | 0.01% | 1 | 0.56% |
sunliming | 1 | 0.01% | 1 | 0.56% |
Keita Suzuki | 1 | 0.01% | 1 | 0.56% |
Bhaskar Chowdhury | 1 | 0.01% | 1 | 0.56% |
Total | 10632 | 177 |
// SPDX-License-Identifier: GPL-2.0 /* * trace_events_filter - generic event filtering * * Copyright (C) 2009 Tom Zanussi <tzanussi@gmail.com> */ #include <linux/uaccess.h> #include <linux/module.h> #include <linux/ctype.h> #include <linux/mutex.h> #include <linux/perf_event.h> #include <linux/slab.h> #include "trace.h" #include "trace_output.h" #define DEFAULT_SYS_FILTER_MESSAGE \ "### global filter ###\n" \ "# Use this to set filters for multiple events.\n" \ "# Only events with the given fields will be affected.\n" \ "# If no events are modified, an error message will be displayed here" /* Due to token parsing '<=' must be before '<' and '>=' must be before '>' */ #define OPS \ C( OP_GLOB, "~" ), \ C( OP_NE, "!=" ), \ C( OP_EQ, "==" ), \ C( OP_LE, "<=" ), \ C( OP_LT, "<" ), \ C( OP_GE, ">=" ), \ C( OP_GT, ">" ), \ C( OP_BAND, "&" ), \ C( OP_MAX, NULL ) #undef C #define C(a, b) a enum filter_op_ids { OPS }; #undef C #define C(a, b) b static const char * ops[] = { OPS }; enum filter_pred_fn { FILTER_PRED_FN_NOP, FILTER_PRED_FN_64, FILTER_PRED_FN_64_CPUMASK, FILTER_PRED_FN_S64, FILTER_PRED_FN_U64, FILTER_PRED_FN_32, FILTER_PRED_FN_32_CPUMASK, FILTER_PRED_FN_S32, FILTER_PRED_FN_U32, FILTER_PRED_FN_16, FILTER_PRED_FN_16_CPUMASK, FILTER_PRED_FN_S16, FILTER_PRED_FN_U16, FILTER_PRED_FN_8, FILTER_PRED_FN_8_CPUMASK, FILTER_PRED_FN_S8, FILTER_PRED_FN_U8, FILTER_PRED_FN_COMM, FILTER_PRED_FN_STRING, FILTER_PRED_FN_STRLOC, FILTER_PRED_FN_STRRELLOC, FILTER_PRED_FN_PCHAR_USER, FILTER_PRED_FN_PCHAR, FILTER_PRED_FN_CPU, FILTER_PRED_FN_CPU_CPUMASK, FILTER_PRED_FN_CPUMASK, FILTER_PRED_FN_CPUMASK_CPU, FILTER_PRED_FN_FUNCTION, FILTER_PRED_FN_, FILTER_PRED_TEST_VISITED, }; struct filter_pred { struct regex *regex; struct cpumask *mask; unsigned short *ops; struct ftrace_event_field *field; u64 val; u64 val2; enum filter_pred_fn fn_num; int offset; int not; int op; }; /* * pred functions are OP_LE, OP_LT, OP_GE, OP_GT, and OP_BAND * pred_funcs_##type below must match the order of them above. */ #define PRED_FUNC_START OP_LE #define PRED_FUNC_MAX (OP_BAND - PRED_FUNC_START) #define ERRORS \ C(NONE, "No error"), \ C(INVALID_OP, "Invalid operator"), \ C(TOO_MANY_OPEN, "Too many '('"), \ C(TOO_MANY_CLOSE, "Too few '('"), \ C(MISSING_QUOTE, "Missing matching quote"), \ C(MISSING_BRACE_OPEN, "Missing '{'"), \ C(MISSING_BRACE_CLOSE, "Missing '}'"), \ C(OPERAND_TOO_LONG, "Operand too long"), \ C(EXPECT_STRING, "Expecting string field"), \ C(EXPECT_DIGIT, "Expecting numeric field"), \ C(ILLEGAL_FIELD_OP, "Illegal operation for field type"), \ C(FIELD_NOT_FOUND, "Field not found"), \ C(ILLEGAL_INTVAL, "Illegal integer value"), \ C(BAD_SUBSYS_FILTER, "Couldn't find or set field in one of a subsystem's events"), \ C(TOO_MANY_PREDS, "Too many terms in predicate expression"), \ C(INVALID_FILTER, "Meaningless filter expression"), \ C(INVALID_CPULIST, "Invalid cpulist"), \ C(IP_FIELD_ONLY, "Only 'ip' field is supported for function trace"), \ C(INVALID_VALUE, "Invalid value (did you forget quotes)?"), \ C(NO_FUNCTION, "Function not found"), \ C(ERRNO, "Error"), \ C(NO_FILTER, "No filter found") #undef C #define C(a, b) FILT_ERR_##a enum { ERRORS }; #undef C #define C(a, b) b static const char *err_text[] = { ERRORS }; /* Called after a '!' character but "!=" and "!~" are not "not"s */ static bool is_not(const char *str) { switch (str[1]) { case '=': case '~': return false; } return true; } /** * struct prog_entry - a singe entry in the filter program * @target: Index to jump to on a branch (actually one minus the index) * @when_to_branch: The value of the result of the predicate to do a branch * @pred: The predicate to execute. */ struct prog_entry { int target; int when_to_branch; struct filter_pred *pred; }; /** * update_preds - assign a program entry a label target * @prog: The program array * @N: The index of the current entry in @prog * @invert: What to assign a program entry for its branch condition * * The program entry at @N has a target that points to the index of a program * entry that can have its target and when_to_branch fields updated. * Update the current program entry denoted by index @N target field to be * that of the updated entry. This will denote the entry to update if * we are processing an "||" after an "&&". */ static void update_preds(struct prog_entry *prog, int N, int invert) { int t, s; t = prog[N].target; s = prog[t].target; prog[t].when_to_branch = invert; prog[t].target = N; prog[N].target = s; } struct filter_parse_error { int lasterr; int lasterr_pos; }; static void parse_error(struct filter_parse_error *pe, int err, int pos) { pe->lasterr = err; pe->lasterr_pos = pos; } typedef int (*parse_pred_fn)(const char *str, void *data, int pos, struct filter_parse_error *pe, struct filter_pred **pred); enum { INVERT = 1, PROCESS_AND = 2, PROCESS_OR = 4, }; static void free_predicate(struct filter_pred *pred) { if (pred) { kfree(pred->regex); kfree(pred->mask); kfree(pred); } } /* * Without going into a formal proof, this explains the method that is used in * parsing the logical expressions. * * For example, if we have: "a && !(!b || (c && g)) || d || e && !f" * The first pass will convert it into the following program: * * n1: r=a; l1: if (!r) goto l4; * n2: r=b; l2: if (!r) goto l4; * n3: r=c; r=!r; l3: if (r) goto l4; * n4: r=g; r=!r; l4: if (r) goto l5; * n5: r=d; l5: if (r) goto T * n6: r=e; l6: if (!r) goto l7; * n7: r=f; r=!r; l7: if (!r) goto F * T: return TRUE * F: return FALSE * * To do this, we use a data structure to represent each of the above * predicate and conditions that has: * * predicate, when_to_branch, invert, target * * The "predicate" will hold the function to determine the result "r". * The "when_to_branch" denotes what "r" should be if a branch is to be taken * "&&" would contain "!r" or (0) and "||" would contain "r" or (1). * The "invert" holds whether the value should be reversed before testing. * The "target" contains the label "l#" to jump to. * * A stack is created to hold values when parentheses are used. * * To simplify the logic, the labels will start at 0 and not 1. * * The possible invert values are 1 and 0. The number of "!"s that are in scope * before the predicate determines the invert value, if the number is odd then * the invert value is 1 and 0 otherwise. This means the invert value only * needs to be toggled when a new "!" is introduced compared to what is stored * on the stack, where parentheses were used. * * The top of the stack and "invert" are initialized to zero. * * ** FIRST PASS ** * * #1 A loop through all the tokens is done: * * #2 If the token is an "(", the stack is push, and the current stack value * gets the current invert value, and the loop continues to the next token. * The top of the stack saves the "invert" value to keep track of what * the current inversion is. As "!(a && !b || c)" would require all * predicates being affected separately by the "!" before the parentheses. * And that would end up being equivalent to "(!a || b) && !c" * * #3 If the token is an "!", the current "invert" value gets inverted, and * the loop continues. Note, if the next token is a predicate, then * this "invert" value is only valid for the current program entry, * and does not affect other predicates later on. * * The only other acceptable token is the predicate string. * * #4 A new entry into the program is added saving: the predicate and the * current value of "invert". The target is currently assigned to the * previous program index (this will not be its final value). * * #5 We now enter another loop and look at the next token. The only valid * tokens are ")", "&&", "||" or end of the input string "\0". * * #6 The invert variable is reset to the current value saved on the top of * the stack. * * #7 The top of the stack holds not only the current invert value, but also * if a "&&" or "||" needs to be processed. Note, the "&&" takes higher * precedence than "||". That is "a && b || c && d" is equivalent to * "(a && b) || (c && d)". Thus the first thing to do is to see if "&&" needs * to be processed. This is the case if an "&&" was the last token. If it was * then we call update_preds(). This takes the program, the current index in * the program, and the current value of "invert". More will be described * below about this function. * * #8 If the next token is "&&" then we set a flag in the top of the stack * that denotes that "&&" needs to be processed, break out of this loop * and continue with the outer loop. * * #9 Otherwise, if a "||" needs to be processed then update_preds() is called. * This is called with the program, the current index in the program, but * this time with an inverted value of "invert" (that is !invert). This is * because the value taken will become the "when_to_branch" value of the * program. * Note, this is called when the next token is not an "&&". As stated before, * "&&" takes higher precedence, and "||" should not be processed yet if the * next logical operation is "&&". * * #10 If the next token is "||" then we set a flag in the top of the stack * that denotes that "||" needs to be processed, break out of this loop * and continue with the outer loop. * * #11 If this is the end of the input string "\0" then we break out of both * loops. * * #12 Otherwise, the next token is ")", where we pop the stack and continue * this inner loop. * * Now to discuss the update_pred() function, as that is key to the setting up * of the program. Remember the "target" of the program is initialized to the * previous index and not the "l" label. The target holds the index into the * program that gets affected by the operand. Thus if we have something like * "a || b && c", when we process "a" the target will be "-1" (undefined). * When we process "b", its target is "0", which is the index of "a", as that's * the predicate that is affected by "||". But because the next token after "b" * is "&&" we don't call update_preds(). Instead continue to "c". As the * next token after "c" is not "&&" but the end of input, we first process the * "&&" by calling update_preds() for the "&&" then we process the "||" by * calling updates_preds() with the values for processing "||". * * What does that mean? What update_preds() does is to first save the "target" * of the program entry indexed by the current program entry's "target" * (remember the "target" is initialized to previous program entry), and then * sets that "target" to the current index which represents the label "l#". * That entry's "when_to_branch" is set to the value passed in (the "invert" * or "!invert"). Then it sets the current program entry's target to the saved * "target" value (the old value of the program that had its "target" updated * to the label). * * Looking back at "a || b && c", we have the following steps: * "a" - prog[0] = { "a", X, -1 } // pred, when_to_branch, target * "||" - flag that we need to process "||"; continue outer loop * "b" - prog[1] = { "b", X, 0 } * "&&" - flag that we need to process "&&"; continue outer loop * (Notice we did not process "||") * "c" - prog[2] = { "c", X, 1 } * update_preds(prog, 2, 0); // invert = 0 as we are processing "&&" * t = prog[2].target; // t = 1 * s = prog[t].target; // s = 0 * prog[t].target = 2; // Set target to "l2" * prog[t].when_to_branch = 0; * prog[2].target = s; * update_preds(prog, 2, 1); // invert = 1 as we are now processing "||" * t = prog[2].target; // t = 0 * s = prog[t].target; // s = -1 * prog[t].target = 2; // Set target to "l2" * prog[t].when_to_branch = 1; * prog[2].target = s; * * #13 Which brings us to the final step of the first pass, which is to set * the last program entry's when_to_branch and target, which will be * when_to_branch = 0; target = N; ( the label after the program entry after * the last program entry processed above). * * If we denote "TRUE" to be the entry after the last program entry processed, * and "FALSE" the program entry after that, we are now done with the first * pass. * * Making the above "a || b && c" have a program of: * prog[0] = { "a", 1, 2 } * prog[1] = { "b", 0, 2 } * prog[2] = { "c", 0, 3 } * * Which translates into: * n0: r = a; l0: if (r) goto l2; * n1: r = b; l1: if (!r) goto l2; * n2: r = c; l2: if (!r) goto l3; // Which is the same as "goto F;" * T: return TRUE; l3: * F: return FALSE * * Although, after the first pass, the program is correct, it is * inefficient. The simple sample of "a || b && c" could be easily been * converted into: * n0: r = a; if (r) goto T * n1: r = b; if (!r) goto F * n2: r = c; if (!r) goto F * T: return TRUE; * F: return FALSE; * * The First Pass is over the input string. The next too passes are over * the program itself. * * ** SECOND PASS ** * * Which brings us to the second pass. If a jump to a label has the * same condition as that label, it can instead jump to its target. * The original example of "a && !(!b || (c && g)) || d || e && !f" * where the first pass gives us: * * n1: r=a; l1: if (!r) goto l4; * n2: r=b; l2: if (!r) goto l4; * n3: r=c; r=!r; l3: if (r) goto l4; * n4: r=g; r=!r; l4: if (r) goto l5; * n5: r=d; l5: if (r) goto T * n6: r=e; l6: if (!r) goto l7; * n7: r=f; r=!r; l7: if (!r) goto F: * T: return TRUE; * F: return FALSE * * We can see that "l3: if (r) goto l4;" and at l4, we have "if (r) goto l5;". * And "l5: if (r) goto T", we could optimize this by converting l3 and l4 * to go directly to T. To accomplish this, we start from the last * entry in the program and work our way back. If the target of the entry * has the same "when_to_branch" then we could use that entry's target. * Doing this, the above would end up as: * * n1: r=a; l1: if (!r) goto l4; * n2: r=b; l2: if (!r) goto l4; * n3: r=c; r=!r; l3: if (r) goto T; * n4: r=g; r=!r; l4: if (r) goto T; * n5: r=d; l5: if (r) goto T; * n6: r=e; l6: if (!r) goto F; * n7: r=f; r=!r; l7: if (!r) goto F; * T: return TRUE * F: return FALSE * * In that same pass, if the "when_to_branch" doesn't match, we can simply * go to the program entry after the label. That is, "l2: if (!r) goto l4;" * where "l4: if (r) goto T;", then we can convert l2 to be: * "l2: if (!r) goto n5;". * * This will have the second pass give us: * n1: r=a; l1: if (!r) goto n5; * n2: r=b; l2: if (!r) goto n5; * n3: r=c; r=!r; l3: if (r) goto T; * n4: r=g; r=!r; l4: if (r) goto T; * n5: r=d; l5: if (r) goto T * n6: r=e; l6: if (!r) goto F; * n7: r=f; r=!r; l7: if (!r) goto F * T: return TRUE * F: return FALSE * * Notice, all the "l#" labels are no longer used, and they can now * be discarded. * * ** THIRD PASS ** * * For the third pass we deal with the inverts. As they simply just * make the "when_to_branch" get inverted, a simple loop over the * program to that does: "when_to_branch ^= invert;" will do the * job, leaving us with: * n1: r=a; if (!r) goto n5; * n2: r=b; if (!r) goto n5; * n3: r=c: if (!r) goto T; * n4: r=g; if (!r) goto T; * n5: r=d; if (r) goto T * n6: r=e; if (!r) goto F; * n7: r=f; if (r) goto F * T: return TRUE * F: return FALSE * * As "r = a; if (!r) goto n5;" is obviously the same as * "if (!a) goto n5;" without doing anything we can interpret the * program as: * n1: if (!a) goto n5; * n2: if (!b) goto n5; * n3: if (!c) goto T; * n4: if (!g) goto T; * n5: if (d) goto T * n6: if (!e) goto F; * n7: if (f) goto F * T: return TRUE * F: return FALSE * * Since the inverts are discarded at the end, there's no reason to store * them in the program array (and waste memory). A separate array to hold * the inverts is used and freed at the end. */ static struct prog_entry * predicate_parse(const char *str, int nr_parens, int nr_preds, parse_pred_fn parse_pred, void *data, struct filter_parse_error *pe) { struct prog_entry *prog_stack; struct prog_entry *prog; const char *ptr = str; char *inverts = NULL; int *op_stack; int *top; int invert = 0; int ret = -ENOMEM; int len; int N = 0; int i; nr_preds += 2; /* For TRUE and FALSE */ op_stack = kmalloc_array(nr_parens, sizeof(*op_stack), GFP_KERNEL); if (!op_stack) return ERR_PTR(-ENOMEM); prog_stack = kcalloc(nr_preds, sizeof(*prog_stack), GFP_KERNEL); if (!prog_stack) { parse_error(pe, -ENOMEM, 0); goto out_free; } inverts = kmalloc_array(nr_preds, sizeof(*inverts), GFP_KERNEL); if (!inverts) { parse_error(pe, -ENOMEM, 0); goto out_free; } top = op_stack; prog = prog_stack; *top = 0; /* First pass */ while (*ptr) { /* #1 */ const char *next = ptr++; if (isspace(*next)) continue; switch (*next) { case '(': /* #2 */ if (top - op_stack > nr_parens) { ret = -EINVAL; goto out_free; } *(++top) = invert; continue; case '!': /* #3 */ if (!is_not(next)) break; invert = !invert; continue; } if (N >= nr_preds) { parse_error(pe, FILT_ERR_TOO_MANY_PREDS, next - str); goto out_free; } inverts[N] = invert; /* #4 */ prog[N].target = N-1; len = parse_pred(next, data, ptr - str, pe, &prog[N].pred); if (len < 0) { ret = len; goto out_free; } ptr = next + len; N++; ret = -1; while (1) { /* #5 */ next = ptr++; if (isspace(*next)) continue; switch (*next) { case ')': case '\0': break; case '&': case '|': /* accepting only "&&" or "||" */ if (next[1] == next[0]) { ptr++; break; } fallthrough; default: parse_error(pe, FILT_ERR_TOO_MANY_PREDS, next - str); goto out_free; } invert = *top & INVERT; if (*top & PROCESS_AND) { /* #7 */ update_preds(prog, N - 1, invert); *top &= ~PROCESS_AND; } if (*next == '&') { /* #8 */ *top |= PROCESS_AND; break; } if (*top & PROCESS_OR) { /* #9 */ update_preds(prog, N - 1, !invert); *top &= ~PROCESS_OR; } if (*next == '|') { /* #10 */ *top |= PROCESS_OR; break; } if (!*next) /* #11 */ goto out; if (top == op_stack) { ret = -1; /* Too few '(' */ parse_error(pe, FILT_ERR_TOO_MANY_CLOSE, ptr - str); goto out_free; } top--; /* #12 */ } } out: if (top != op_stack) { /* Too many '(' */ parse_error(pe, FILT_ERR_TOO_MANY_OPEN, ptr - str); goto out_free; } if (!N) { /* No program? */ ret = -EINVAL; parse_error(pe, FILT_ERR_NO_FILTER, ptr - str); goto out_free; } prog[N].pred = NULL; /* #13 */ prog[N].target = 1; /* TRUE */ prog[N+1].pred = NULL; prog[N+1].target = 0; /* FALSE */ prog[N-1].target = N; prog[N-1].when_to_branch = false; /* Second Pass */ for (i = N-1 ; i--; ) { int target = prog[i].target; if (prog[i].when_to_branch == prog[target].when_to_branch) prog[i].target = prog[target].target; } /* Third Pass */ for (i = 0; i < N; i++) { invert = inverts[i] ^ prog[i].when_to_branch; prog[i].when_to_branch = invert; /* Make sure the program always moves forward */ if (WARN_ON(prog[i].target <= i)) { ret = -EINVAL; goto out_free; } } kfree(op_stack); kfree(inverts); return prog; out_free: kfree(op_stack); kfree(inverts); if (prog_stack) { for (i = 0; prog_stack[i].pred; i++) free_predicate(prog_stack[i].pred); kfree(prog_stack); } return ERR_PTR(ret); } static inline int do_filter_cpumask(int op, const struct cpumask *mask, const struct cpumask *cmp) { switch (op) { case OP_EQ: return cpumask_equal(mask, cmp); case OP_NE: return !cpumask_equal(mask, cmp); case OP_BAND: return cpumask_intersects(mask, cmp); default: return 0; } } /* Optimisation of do_filter_cpumask() for scalar fields */ static inline int do_filter_scalar_cpumask(int op, unsigned int cpu, const struct cpumask *mask) { /* * Per the weight-of-one cpumask optimisations, the mask passed in this * function has a weight >= 2, so it is never equal to a single scalar. */ switch (op) { case OP_EQ: return false; case OP_NE: return true; case OP_BAND: return cpumask_test_cpu(cpu, mask); default: return 0; } } static inline int do_filter_cpumask_scalar(int op, const struct cpumask *mask, unsigned int cpu) { switch (op) { case OP_EQ: return cpumask_test_cpu(cpu, mask) && cpumask_nth(1, mask) >= nr_cpu_ids; case OP_NE: return !cpumask_test_cpu(cpu, mask) || cpumask_nth(1, mask) < nr_cpu_ids; case OP_BAND: return cpumask_test_cpu(cpu, mask); default: return 0; } } enum pred_cmp_types { PRED_CMP_TYPE_NOP, PRED_CMP_TYPE_LT, PRED_CMP_TYPE_LE, PRED_CMP_TYPE_GT, PRED_CMP_TYPE_GE, PRED_CMP_TYPE_BAND, }; #define DEFINE_COMPARISON_PRED(type) \ static int filter_pred_##type(struct filter_pred *pred, void *event) \ { \ switch (pred->op) { \ case OP_LT: { \ type *addr = (type *)(event + pred->offset); \ type val = (type)pred->val; \ return *addr < val; \ } \ case OP_LE: { \ type *addr = (type *)(event + pred->offset); \ type val = (type)pred->val; \ return *addr <= val; \ } \ case OP_GT: { \ type *addr = (type *)(event + pred->offset); \ type val = (type)pred->val; \ return *addr > val; \ } \ case OP_GE: { \ type *addr = (type *)(event + pred->offset); \ type val = (type)pred->val; \ return *addr >= val; \ } \ case OP_BAND: { \ type *addr = (type *)(event + pred->offset); \ type val = (type)pred->val; \ return !!(*addr & val); \ } \ default: \ return 0; \ } \ } #define DEFINE_CPUMASK_COMPARISON_PRED(size) \ static int filter_pred_##size##_cpumask(struct filter_pred *pred, void *event) \ { \ u##size *addr = (u##size *)(event + pred->offset); \ unsigned int cpu = *addr; \ \ if (cpu >= nr_cpu_ids) \ return 0; \ \ return do_filter_scalar_cpumask(pred->op, cpu, pred->mask); \ } #define DEFINE_EQUALITY_PRED(size) \ static int filter_pred_##size(struct filter_pred *pred, void *event) \ { \ u##size *addr = (u##size *)(event + pred->offset); \ u##size val = (u##size)pred->val; \ int match; \ \ match = (val == *addr) ^ pred->not; \ \ return match; \ } DEFINE_COMPARISON_PRED(s64); DEFINE_COMPARISON_PRED(u64); DEFINE_COMPARISON_PRED(s32); DEFINE_COMPARISON_PRED(u32); DEFINE_COMPARISON_PRED(s16); DEFINE_COMPARISON_PRED(u16); DEFINE_COMPARISON_PRED(s8); DEFINE_COMPARISON_PRED(u8); DEFINE_CPUMASK_COMPARISON_PRED(64); DEFINE_CPUMASK_COMPARISON_PRED(32); DEFINE_CPUMASK_COMPARISON_PRED(16); DEFINE_CPUMASK_COMPARISON_PRED(8); DEFINE_EQUALITY_PRED(64); DEFINE_EQUALITY_PRED(32); DEFINE_EQUALITY_PRED(16); DEFINE_EQUALITY_PRED(8); /* user space strings temp buffer */ #define USTRING_BUF_SIZE 1024 struct ustring_buffer { char buffer[USTRING_BUF_SIZE]; }; static __percpu struct ustring_buffer *ustring_per_cpu; static __always_inline char *test_string(char *str) { struct ustring_buffer *ubuf; char *kstr; if (!ustring_per_cpu) return NULL; ubuf = this_cpu_ptr(ustring_per_cpu); kstr = ubuf->buffer; /* For safety, do not trust the string pointer */ if (!strncpy_from_kernel_nofault(kstr, str, USTRING_BUF_SIZE)) return NULL; return kstr; } static __always_inline char *test_ustring(char *str) { struct ustring_buffer *ubuf; char __user *ustr; char *kstr; if (!ustring_per_cpu) return NULL; ubuf = this_cpu_ptr(ustring_per_cpu); kstr = ubuf->buffer; /* user space address? */ ustr = (char __user *)str; if (!strncpy_from_user_nofault(kstr, ustr, USTRING_BUF_SIZE)) return NULL; return kstr; } /* Filter predicate for fixed sized arrays of characters */ static int filter_pred_string(struct filter_pred *pred, void *event) { char *addr = (char *)(event + pred->offset); int cmp, match; cmp = pred->regex->match(addr, pred->regex, pred->regex->field_len); match = cmp ^ pred->not; return match; } static __always_inline int filter_pchar(struct filter_pred *pred, char *str) { int cmp, match; int len; len = strlen(str) + 1; /* including tailing '\0' */ cmp = pred->regex->match(str, pred->regex, len); match = cmp ^ pred->not; return match; } /* Filter predicate for char * pointers */ static int filter_pred_pchar(struct filter_pred *pred, void *event) { char **addr = (char **)(event + pred->offset); char *str; str = test_string(*addr); if (!str) return 0; return filter_pchar(pred, str); } /* Filter predicate for char * pointers in user space*/ static int filter_pred_pchar_user(struct filter_pred *pred, void *event) { char **addr = (char **)(event + pred->offset); char *str; str = test_ustring(*addr); if (!str) return 0; return filter_pchar(pred, str); } /* * Filter predicate for dynamic sized arrays of characters. * These are implemented through a list of strings at the end * of the entry. * Also each of these strings have a field in the entry which * contains its offset from the beginning of the entry. * We have then first to get this field, dereference it * and add it to the address of the entry, and at last we have * the address of the string. */ static int filter_pred_strloc(struct filter_pred *pred, void *event) { u32 str_item = *(u32 *)(event + pred->offset); int str_loc = str_item & 0xffff; int str_len = str_item >> 16; char *addr = (char *)(event + str_loc); int cmp, match; cmp = pred->regex->match(addr, pred->regex, str_len); match = cmp ^ pred->not; return match; } /* * Filter predicate for relative dynamic sized arrays of characters. * These are implemented through a list of strings at the end * of the entry as same as dynamic string. * The difference is that the relative one records the location offset * from the field itself, not the event entry. */ static int filter_pred_strrelloc(struct filter_pred *pred, void *event) { u32 *item = (u32 *)(event + pred->offset); u32 str_item = *item; int str_loc = str_item & 0xffff; int str_len = str_item >> 16; char *addr = (char *)(&item[1]) + str_loc; int cmp, match; cmp = pred->regex->match(addr, pred->regex, str_len); match = cmp ^ pred->not; return match; } /* Filter predicate for CPUs. */ static int filter_pred_cpu(struct filter_pred *pred, void *event) { int cpu, cmp; cpu = raw_smp_processor_id(); cmp = pred->val; switch (pred->op) { case OP_EQ: return cpu == cmp; case OP_NE: return cpu != cmp; case OP_LT: return cpu < cmp; case OP_LE: return cpu <= cmp; case OP_GT: return cpu > cmp; case OP_GE: return cpu >= cmp; default: return 0; } } /* Filter predicate for current CPU vs user-provided cpumask */ static int filter_pred_cpu_cpumask(struct filter_pred *pred, void *event) { int cpu = raw_smp_processor_id(); return do_filter_scalar_cpumask(pred->op, cpu, pred->mask); } /* Filter predicate for cpumask field vs user-provided cpumask */ static int filter_pred_cpumask(struct filter_pred *pred, void *event) { u32 item = *(u32 *)(event + pred->offset); int loc = item & 0xffff; const struct cpumask *mask = (event + loc); const struct cpumask *cmp = pred->mask; return do_filter_cpumask(pred->op, mask, cmp); } /* Filter predicate for cpumask field vs user-provided scalar */ static int filter_pred_cpumask_cpu(struct filter_pred *pred, void *event) { u32 item = *(u32 *)(event + pred->offset); int loc = item & 0xffff; const struct cpumask *mask = (event + loc); unsigned int cpu = pred->val; return do_filter_cpumask_scalar(pred->op, mask, cpu); } /* Filter predicate for COMM. */ static int filter_pred_comm(struct filter_pred *pred, void *event) { int cmp; cmp = pred->regex->match(current->comm, pred->regex, TASK_COMM_LEN); return cmp ^ pred->not; } /* Filter predicate for functions. */ static int filter_pred_function(struct filter_pred *pred, void *event) { unsigned long *addr = (unsigned long *)(event + pred->offset); unsigned long start = (unsigned long)pred->val; unsigned long end = (unsigned long)pred->val2; int ret = *addr >= start && *addr < end; return pred->op == OP_EQ ? ret : !ret; } /* * regex_match_foo - Basic regex callbacks * * @str: the string to be searched * @r: the regex structure containing the pattern string * @len: the length of the string to be searched (including '\0') * * Note: * - @str might not be NULL-terminated if it's of type DYN_STRING * RDYN_STRING, or STATIC_STRING, unless @len is zero. */ static int regex_match_full(char *str, struct regex *r, int len) { /* len of zero means str is dynamic and ends with '\0' */ if (!len) return strcmp(str, r->pattern) == 0; return strncmp(str, r->pattern, len) == 0; } static int regex_match_front(char *str, struct regex *r, int len) { if (len && len < r->len) return 0; return strncmp(str, r->pattern, r->len) == 0; } static int regex_match_middle(char *str, struct regex *r, int len) { if (!len) return strstr(str, r->pattern) != NULL; return strnstr(str, r->pattern, len) != NULL; } static int regex_match_end(char *str, struct regex *r, int len) { int strlen = len - 1; if (strlen >= r->len && memcmp(str + strlen - r->len, r->pattern, r->len) == 0) return 1; return 0; } static int regex_match_glob(char *str, struct regex *r, int len __maybe_unused) { if (glob_match(r->pattern, str)) return 1; return 0; } /** * filter_parse_regex - parse a basic regex * @buff: the raw regex * @len: length of the regex * @search: will point to the beginning of the string to compare * @not: tell whether the match will have to be inverted * * This passes in a buffer containing a regex and this function will * set search to point to the search part of the buffer and * return the type of search it is (see enum above). * This does modify buff. * * Returns enum type. * search returns the pointer to use for comparison. * not returns 1 if buff started with a '!' * 0 otherwise. */ enum regex_type filter_parse_regex(char *buff, int len, char **search, int *not) { int type = MATCH_FULL; int i; if (buff[0] == '!') { *not = 1; buff++; len--; } else *not = 0; *search = buff; if (isdigit(buff[0])) return MATCH_INDEX; for (i = 0; i < len; i++) { if (buff[i] == '*') { if (!i) { type = MATCH_END_ONLY; } else if (i == len - 1) { if (type == MATCH_END_ONLY) type = MATCH_MIDDLE_ONLY; else type = MATCH_FRONT_ONLY; buff[i] = 0; break; } else { /* pattern continues, use full glob */ return MATCH_GLOB; } } else if (strchr("[?\\", buff[i])) { return MATCH_GLOB; } } if (buff[0] == '*') *search = buff + 1; return type; } static void filter_build_regex(struct filter_pred *pred) { struct regex *r = pred->regex; char *search; enum regex_type type = MATCH_FULL; if (pred->op == OP_GLOB) { type = filter_parse_regex(r->pattern, r->len, &search, &pred->not); r->len = strlen(search); memmove(r->pattern, search, r->len+1); } switch (type) { /* MATCH_INDEX should not happen, but if it does, match full */ case MATCH_INDEX: case MATCH_FULL: r->match = regex_match_full; break; case MATCH_FRONT_ONLY: r->match = regex_match_front; break; case MATCH_MIDDLE_ONLY: r->match = regex_match_middle; break; case MATCH_END_ONLY: r->match = regex_match_end; break; case MATCH_GLOB: r->match = regex_match_glob; break; } } #ifdef CONFIG_FTRACE_STARTUP_TEST static int test_pred_visited_fn(struct filter_pred *pred, void *event); #else static int test_pred_visited_fn(struct filter_pred *pred, void *event) { return 0; } #endif static int filter_pred_fn_call(struct filter_pred *pred, void *event); /* return 1 if event matches, 0 otherwise (discard) */ int filter_match_preds(struct event_filter *filter, void *rec) { struct prog_entry *prog; int i; /* no filter is considered a match */ if (!filter) return 1; /* Protected by either SRCU(tracepoint_srcu) or preempt_disable */ prog = rcu_dereference_raw(filter->prog); if (!prog) return 1; for (i = 0; prog[i].pred; i++) { struct filter_pred *pred = prog[i].pred; int match = filter_pred_fn_call(pred, rec); if (match == prog[i].when_to_branch) i = prog[i].target; } return prog[i].target; } EXPORT_SYMBOL_GPL(filter_match_preds); static void remove_filter_string(struct event_filter *filter) { if (!filter) return; kfree(filter->filter_string); filter->filter_string = NULL; } static void append_filter_err(struct trace_array *tr, struct filter_parse_error *pe, struct event_filter *filter) { struct trace_seq *s; int pos = pe->lasterr_pos; char *buf; int len; if (WARN_ON(!filter->filter_string)) return; s = kmalloc(sizeof(*s), GFP_KERNEL); if (!s) return; trace_seq_init(s); len = strlen(filter->filter_string); if (pos > len) pos = len; /* indexing is off by one */ if (pos) pos++; trace_seq_puts(s, filter->filter_string); if (pe->lasterr > 0) { trace_seq_printf(s, "\n%*s", pos, "^"); trace_seq_printf(s, "\nparse_error: %s\n", err_text[pe->lasterr]); tracing_log_err(tr, "event filter parse error", filter->filter_string, err_text, pe->lasterr, pe->lasterr_pos); } else { trace_seq_printf(s, "\nError: (%d)\n", pe->lasterr); tracing_log_err(tr, "event filter parse error", filter->filter_string, err_text, FILT_ERR_ERRNO, 0); } trace_seq_putc(s, 0); buf = kmemdup_nul(s->buffer, s->seq.len, GFP_KERNEL); if (buf) { kfree(filter->filter_string); filter->filter_string = buf; } kfree(s); } static inline struct event_filter *event_filter(struct trace_event_file *file) { return file->filter; } /* caller must hold event_mutex */ void print_event_filter(struct trace_event_file *file, struct trace_seq *s) { struct event_filter *filter = event_filter(file); if (filter && filter->filter_string) trace_seq_printf(s, "%s\n", filter->filter_string); else trace_seq_puts(s, "none\n"); } void print_subsystem_event_filter(struct event_subsystem *system, struct trace_seq *s) { struct event_filter *filter; mutex_lock(&event_mutex); filter = system->filter; if (filter && filter->filter_string) trace_seq_printf(s, "%s\n", filter->filter_string); else trace_seq_puts(s, DEFAULT_SYS_FILTER_MESSAGE "\n"); mutex_unlock(&event_mutex); } static void free_prog(struct event_filter *filter) { struct prog_entry *prog; int i; prog = rcu_access_pointer(filter->prog); if (!prog) return; for (i = 0; prog[i].pred; i++) free_predicate(prog[i].pred); kfree(prog); } static void filter_disable(struct trace_event_file *file) { unsigned long old_flags = file->flags; file->flags &= ~EVENT_FILE_FL_FILTERED; if (old_flags != file->flags) trace_buffered_event_disable(); } static void __free_filter(struct event_filter *filter) { if (!filter) return; free_prog(filter); kfree(filter->filter_string); kfree(filter); } void free_event_filter(struct event_filter *filter) { __free_filter(filter); } static inline void __remove_filter(struct trace_event_file *file) { filter_disable(file); remove_filter_string(file->filter); } static void filter_free_subsystem_preds(struct trace_subsystem_dir *dir, struct trace_array *tr) { struct trace_event_file *file; list_for_each_entry(file, &tr->events, list) { if (file->system != dir) continue; __remove_filter(file); } } static inline void __free_subsystem_filter(struct trace_event_file *file) { __free_filter(file->filter); file->filter = NULL; } static void filter_free_subsystem_filters(struct trace_subsystem_dir *dir, struct trace_array *tr) { struct trace_event_file *file; list_for_each_entry(file, &tr->events, list) { if (file->system != dir) continue; __free_subsystem_filter(file); } } int filter_assign_type(const char *type) { if (strstr(type, "__data_loc")) { if (strstr(type, "char")) return FILTER_DYN_STRING; if (strstr(type, "cpumask_t")) return FILTER_CPUMASK; } if (strstr(type, "__rel_loc") && strstr(type, "char")) return FILTER_RDYN_STRING; if (strchr(type, '[') && strstr(type, "char")) return FILTER_STATIC_STRING; if (strcmp(type, "char *") == 0 || strcmp(type, "const char *") == 0) return FILTER_PTR_STRING; return FILTER_OTHER; } static enum filter_pred_fn select_comparison_fn(enum filter_op_ids op, int field_size, int field_is_signed) { enum filter_pred_fn fn = FILTER_PRED_FN_NOP; int pred_func_index = -1; switch (op) { case OP_EQ: case OP_NE: break; default: if (WARN_ON_ONCE(op < PRED_FUNC_START)) return fn; pred_func_index = op - PRED_FUNC_START; if (WARN_ON_ONCE(pred_func_index > PRED_FUNC_MAX)) return fn; } switch (field_size) { case 8: if (pred_func_index < 0) fn = FILTER_PRED_FN_64; else if (field_is_signed) fn = FILTER_PRED_FN_S64; else fn = FILTER_PRED_FN_U64; break; case 4: if (pred_func_index < 0) fn = FILTER_PRED_FN_32; else if (field_is_signed) fn = FILTER_PRED_FN_S32; else fn = FILTER_PRED_FN_U32; break; case 2: if (pred_func_index < 0) fn = FILTER_PRED_FN_16; else if (field_is_signed) fn = FILTER_PRED_FN_S16; else fn = FILTER_PRED_FN_U16; break; case 1: if (pred_func_index < 0) fn = FILTER_PRED_FN_8; else if (field_is_signed) fn = FILTER_PRED_FN_S8; else fn = FILTER_PRED_FN_U8; break; } return fn; } static int filter_pred_fn_call(struct filter_pred *pred, void *event) { switch (pred->fn_num) { case FILTER_PRED_FN_64: return filter_pred_64(pred, event); case FILTER_PRED_FN_64_CPUMASK: return filter_pred_64_cpumask(pred, event); case FILTER_PRED_FN_S64: return filter_pred_s64(pred, event); case FILTER_PRED_FN_U64: return filter_pred_u64(pred, event); case FILTER_PRED_FN_32: return filter_pred_32(pred, event); case FILTER_PRED_FN_32_CPUMASK: return filter_pred_32_cpumask(pred, event); case FILTER_PRED_FN_S32: return filter_pred_s32(pred, event); case FILTER_PRED_FN_U32: return filter_pred_u32(pred, event); case FILTER_PRED_FN_16: return filter_pred_16(pred, event); case FILTER_PRED_FN_16_CPUMASK: return filter_pred_16_cpumask(pred, event); case FILTER_PRED_FN_S16: return filter_pred_s16(pred, event); case FILTER_PRED_FN_U16: return filter_pred_u16(pred, event); case FILTER_PRED_FN_8: return filter_pred_8(pred, event); case FILTER_PRED_FN_8_CPUMASK: return filter_pred_8_cpumask(pred, event); case FILTER_PRED_FN_S8: return filter_pred_s8(pred, event); case FILTER_PRED_FN_U8: return filter_pred_u8(pred, event); case FILTER_PRED_FN_COMM: return filter_pred_comm(pred, event); case FILTER_PRED_FN_STRING: return filter_pred_string(pred, event); case FILTER_PRED_FN_STRLOC: return filter_pred_strloc(pred, event); case FILTER_PRED_FN_STRRELLOC: return filter_pred_strrelloc(pred, event); case FILTER_PRED_FN_PCHAR_USER: return filter_pred_pchar_user(pred, event); case FILTER_PRED_FN_PCHAR: return filter_pred_pchar(pred, event); case FILTER_PRED_FN_CPU: return filter_pred_cpu(pred, event); case FILTER_PRED_FN_CPU_CPUMASK: return filter_pred_cpu_cpumask(pred, event); case FILTER_PRED_FN_CPUMASK: return filter_pred_cpumask(pred, event); case FILTER_PRED_FN_CPUMASK_CPU: return filter_pred_cpumask_cpu(pred, event); case FILTER_PRED_FN_FUNCTION: return filter_pred_function(pred, event); case FILTER_PRED_TEST_VISITED: return test_pred_visited_fn(pred, event); default: return 0; } } /* Called when a predicate is encountered by predicate_parse() */ static int parse_pred(const char *str, void *data, int pos, struct filter_parse_error *pe, struct filter_pred **pred_ptr) { struct trace_event_call *call = data; struct ftrace_event_field *field; struct filter_pred *pred = NULL; unsigned long offset; unsigned long size; unsigned long ip; char num_buf[24]; /* Big enough to hold an address */ char *field_name; char *name; bool function = false; bool ustring = false; char q; u64 val; int len; int ret; int op; int s; int i = 0; /* First find the field to associate to */ while (isspace(str[i])) i++; s = i; while (isalnum(str[i]) || str[i] == '_') i++; len = i - s; if (!len) return -1; field_name = kmemdup_nul(str + s, len, GFP_KERNEL); if (!field_name) return -ENOMEM; /* Make sure that the field exists */ field = trace_find_event_field(call, field_name); kfree(field_name); if (!field) { parse_error(pe, FILT_ERR_FIELD_NOT_FOUND, pos + i); return -EINVAL; } /* See if the field is a user space string */ if ((len = str_has_prefix(str + i, ".ustring"))) { ustring = true; i += len; } /* See if the field is a kernel function name */ if ((len = str_has_prefix(str + i, ".function"))) { function = true; i += len; } while (isspace(str[i])) i++; /* Make sure this op is supported */ for (op = 0; ops[op]; op++) { /* This is why '<=' must come before '<' in ops[] */ if (strncmp(str + i, ops[op], strlen(ops[op])) == 0) break; } if (!ops[op]) { parse_error(pe, FILT_ERR_INVALID_OP, pos + i); goto err_free; } i += strlen(ops[op]); while (isspace(str[i])) i++; s = i; pred = kzalloc(sizeof(*pred), GFP_KERNEL); if (!pred) return -ENOMEM; pred->field = field; pred->offset = field->offset; pred->op = op; if (function) { /* The field must be the same size as long */ if (field->size != sizeof(long)) { parse_error(pe, FILT_ERR_ILLEGAL_FIELD_OP, pos + i); goto err_free; } /* Function only works with '==' or '!=' and an unquoted string */ switch (op) { case OP_NE: case OP_EQ: break; default: parse_error(pe, FILT_ERR_INVALID_OP, pos + i); goto err_free; } if (isdigit(str[i])) { /* We allow 0xDEADBEEF */ while (isalnum(str[i])) i++; len = i - s; /* 0xfeedfacedeadbeef is 18 chars max */ if (len >= sizeof(num_buf)) { parse_error(pe, FILT_ERR_OPERAND_TOO_LONG, pos + i); goto err_free; } strncpy(num_buf, str + s, len); num_buf[len] = 0; ret = kstrtoul(num_buf, 0, &ip); if (ret) { parse_error(pe, FILT_ERR_INVALID_VALUE, pos + i); goto err_free; } } else { s = i; for (; str[i] && !isspace(str[i]); i++) ; len = i - s; name = kmemdup_nul(str + s, len, GFP_KERNEL); if (!name) goto err_mem; ip = kallsyms_lookup_name(name); kfree(name); if (!ip) { parse_error(pe, FILT_ERR_NO_FUNCTION, pos + i); goto err_free; } } /* Now find the function start and end address */ if (!kallsyms_lookup_size_offset(ip, &size, &offset)) { parse_error(pe, FILT_ERR_NO_FUNCTION, pos + i); goto err_free; } pred->fn_num = FILTER_PRED_FN_FUNCTION; pred->val = ip - offset; pred->val2 = pred->val + size; } else if (ftrace_event_is_function(call)) { /* * Perf does things different with function events. * It only allows an "ip" field, and expects a string. * But the string does not need to be surrounded by quotes. * If it is a string, the assigned function as a nop, * (perf doesn't use it) and grab everything. */ if (strcmp(field->name, "ip") != 0) { parse_error(pe, FILT_ERR_IP_FIELD_ONLY, pos + i); goto err_free; } pred->fn_num = FILTER_PRED_FN_NOP; /* * Quotes are not required, but if they exist then we need * to read them till we hit a matching one. */ if (str[i] == '\'' || str[i] == '"') q = str[i]; else q = 0; for (i++; str[i]; i++) { if (q && str[i] == q) break; if (!q && (str[i] == ')' || str[i] == '&' || str[i] == '|')) break; } /* Skip quotes */ if (q) s++; len = i - s; if (len >= MAX_FILTER_STR_VAL) { parse_error(pe, FILT_ERR_OPERAND_TOO_LONG, pos + i); goto err_free; } pred->regex = kzalloc(sizeof(*pred->regex), GFP_KERNEL); if (!pred->regex) goto err_mem; pred->regex->len = len; strncpy(pred->regex->pattern, str + s, len); pred->regex->pattern[len] = 0; } else if (!strncmp(str + i, "CPUS", 4)) { unsigned int maskstart; bool single; char *tmp; switch (field->filter_type) { case FILTER_CPUMASK: case FILTER_CPU: case FILTER_OTHER: break; default: parse_error(pe, FILT_ERR_ILLEGAL_FIELD_OP, pos + i); goto err_free; } switch (op) { case OP_EQ: case OP_NE: case OP_BAND: break; default: parse_error(pe, FILT_ERR_ILLEGAL_FIELD_OP, pos + i); goto err_free; } /* Skip CPUS */ i += 4; if (str[i++] != '{') { parse_error(pe, FILT_ERR_MISSING_BRACE_OPEN, pos + i); goto err_free; } maskstart = i; /* Walk the cpulist until closing } */ for (; str[i] && str[i] != '}'; i++) ; if (str[i] != '}') { parse_error(pe, FILT_ERR_MISSING_BRACE_CLOSE, pos + i); goto err_free; } if (maskstart == i) { parse_error(pe, FILT_ERR_INVALID_CPULIST, pos + i); goto err_free; } /* Copy the cpulist between { and } */ tmp = kmalloc((i - maskstart) + 1, GFP_KERNEL); if (!tmp) goto err_mem; strscpy(tmp, str + maskstart, (i - maskstart) + 1); pred->mask = kzalloc(cpumask_size(), GFP_KERNEL); if (!pred->mask) { kfree(tmp); goto err_mem; } /* Now parse it */ if (cpulist_parse(tmp, pred->mask)) { kfree(tmp); parse_error(pe, FILT_ERR_INVALID_CPULIST, pos + i); goto err_free; } kfree(tmp); /* Move along */ i++; /* * Optimisation: if the user-provided mask has a weight of one * then we can treat it as a scalar input. */ single = cpumask_weight(pred->mask) == 1; if (single) { pred->val = cpumask_first(pred->mask); kfree(pred->mask); pred->mask = NULL; } if (field->filter_type == FILTER_CPUMASK) { pred->fn_num = single ? FILTER_PRED_FN_CPUMASK_CPU : FILTER_PRED_FN_CPUMASK; } else if (field->filter_type == FILTER_CPU) { if (single) { if (pred->op == OP_BAND) pred->op = OP_EQ; pred->fn_num = FILTER_PRED_FN_CPU; } else { pred->fn_num = FILTER_PRED_FN_CPU_CPUMASK; } } else if (single) { if (pred->op == OP_BAND) pred->op = OP_EQ; pred->fn_num = select_comparison_fn(pred->op, field->size, false); if (pred->op == OP_NE) pred->not = 1; } else { switch (field->size) { case 8: pred->fn_num = FILTER_PRED_FN_64_CPUMASK; break; case 4: pred->fn_num = FILTER_PRED_FN_32_CPUMASK; break; case 2: pred->fn_num = FILTER_PRED_FN_16_CPUMASK; break; case 1: pred->fn_num = FILTER_PRED_FN_8_CPUMASK; break; } } /* This is either a string, or an integer */ } else if (str[i] == '\'' || str[i] == '"') { char q = str[i]; /* Make sure the op is OK for strings */ switch (op) { case OP_NE: pred->not = 1; fallthrough; case OP_GLOB: case OP_EQ: break; default: parse_error(pe, FILT_ERR_ILLEGAL_FIELD_OP, pos + i); goto err_free; } /* Make sure the field is OK for strings */ if (!is_string_field(field)) { parse_error(pe, FILT_ERR_EXPECT_DIGIT, pos + i); goto err_free; } for (i++; str[i]; i++) { if (str[i] == q) break; } if (!str[i]) { parse_error(pe, FILT_ERR_MISSING_QUOTE, pos + i); goto err_free; } /* Skip quotes */ s++; len = i - s; if (len >= MAX_FILTER_STR_VAL) { parse_error(pe, FILT_ERR_OPERAND_TOO_LONG, pos + i); goto err_free; } pred->regex = kzalloc(sizeof(*pred->regex), GFP_KERNEL); if (!pred->regex) goto err_mem; pred->regex->len = len; strncpy(pred->regex->pattern, str + s, len); pred->regex->pattern[len] = 0; filter_build_regex(pred); if (field->filter_type == FILTER_COMM) { pred->fn_num = FILTER_PRED_FN_COMM; } else if (field->filter_type == FILTER_STATIC_STRING) { pred->fn_num = FILTER_PRED_FN_STRING; pred->regex->field_len = field->size; } else if (field->filter_type == FILTER_DYN_STRING) { pred->fn_num = FILTER_PRED_FN_STRLOC; } else if (field->filter_type == FILTER_RDYN_STRING) pred->fn_num = FILTER_PRED_FN_STRRELLOC; else { if (!ustring_per_cpu) { /* Once allocated, keep it around for good */ ustring_per_cpu = alloc_percpu(struct ustring_buffer); if (!ustring_per_cpu) goto err_mem; } if (ustring) pred->fn_num = FILTER_PRED_FN_PCHAR_USER; else pred->fn_num = FILTER_PRED_FN_PCHAR; } /* go past the last quote */ i++; } else if (isdigit(str[i]) || str[i] == '-') { /* Make sure the field is not a string */ if (is_string_field(field)) { parse_error(pe, FILT_ERR_EXPECT_STRING, pos + i); goto err_free; } if (op == OP_GLOB) { parse_error(pe, FILT_ERR_ILLEGAL_FIELD_OP, pos + i); goto err_free; } if (str[i] == '-') i++; /* We allow 0xDEADBEEF */ while (isalnum(str[i])) i++; len = i - s; /* 0xfeedfacedeadbeef is 18 chars max */ if (len >= sizeof(num_buf)) { parse_error(pe, FILT_ERR_OPERAND_TOO_LONG, pos + i); goto err_free; } strncpy(num_buf, str + s, len); num_buf[len] = 0; /* Make sure it is a value */ if (field->is_signed) ret = kstrtoll(num_buf, 0, &val); else ret = kstrtoull(num_buf, 0, &val); if (ret) { parse_error(pe, FILT_ERR_ILLEGAL_INTVAL, pos + s); goto err_free; } pred->val = val; if (field->filter_type == FILTER_CPU) pred->fn_num = FILTER_PRED_FN_CPU; else { pred->fn_num = select_comparison_fn(pred->op, field->size, field->is_signed); if (pred->op == OP_NE) pred->not = 1; } } else { parse_error(pe, FILT_ERR_INVALID_VALUE, pos + i); goto err_free; } *pred_ptr = pred; return i; err_free: free_predicate(pred); return -EINVAL; err_mem: free_predicate(pred); return -ENOMEM; } enum { TOO_MANY_CLOSE = -1, TOO_MANY_OPEN = -2, MISSING_QUOTE = -3, }; /* * Read the filter string once to calculate the number of predicates * as well as how deep the parentheses go. * * Returns: * 0 - everything is fine (err is undefined) * -1 - too many ')' * -2 - too many '(' * -3 - No matching quote */ static int calc_stack(const char *str, int *parens, int *preds, int *err) { bool is_pred = false; int nr_preds = 0; int open = 1; /* Count the expression as "(E)" */ int last_quote = 0; int max_open = 1; int quote = 0; int i; *err = 0; for (i = 0; str[i]; i++) { if (isspace(str[i])) continue; if (quote) { if (str[i] == quote) quote = 0; continue; } switch (str[i]) { case '\'': case '"': quote = str[i]; last_quote = i; break; case '|': case '&': if (str[i+1] != str[i]) break; is_pred = false; continue; case '(': is_pred = false; open++; if (open > max_open) max_open = open; continue; case ')': is_pred = false; if (open == 1) { *err = i; return TOO_MANY_CLOSE; } open--; continue; } if (!is_pred) { nr_preds++; is_pred = true; } } if (quote) { *err = last_quote; return MISSING_QUOTE; } if (open != 1) { int level = open; /* find the bad open */ for (i--; i; i--) { if (quote) { if (str[i] == quote) quote = 0; continue; } switch (str[i]) { case '(': if (level == open) { *err = i; return TOO_MANY_OPEN; } level--; break; case ')': level++; break; case '\'': case '"': quote = str[i]; break; } } /* First character is the '(' with missing ')' */ *err = 0; return TOO_MANY_OPEN; } /* Set the size of the required stacks */ *parens = max_open; *preds = nr_preds; return 0; } static int process_preds(struct trace_event_call *call, const char *filter_string, struct event_filter *filter, struct filter_parse_error *pe) { struct prog_entry *prog; int nr_parens; int nr_preds; int index; int ret; ret = calc_stack(filter_string, &nr_parens, &nr_preds, &index); if (ret < 0) { switch (ret) { case MISSING_QUOTE: parse_error(pe, FILT_ERR_MISSING_QUOTE, index); break; case TOO_MANY_OPEN: parse_error(pe, FILT_ERR_TOO_MANY_OPEN, index); break; default: parse_error(pe, FILT_ERR_TOO_MANY_CLOSE, index); } return ret; } if (!nr_preds) return -EINVAL; prog = predicate_parse(filter_string, nr_parens, nr_preds, parse_pred, call, pe); if (IS_ERR(prog)) return PTR_ERR(prog); rcu_assign_pointer(filter->prog, prog); return 0; } static inline void event_set_filtered_flag(struct trace_event_file *file) { unsigned long old_flags = file->flags; file->flags |= EVENT_FILE_FL_FILTERED; if (old_flags != file->flags) trace_buffered_event_enable(); } static inline void event_set_filter(struct trace_event_file *file, struct event_filter *filter) { rcu_assign_pointer(file->filter, filter); } static inline void event_clear_filter(struct trace_event_file *file) { RCU_INIT_POINTER(file->filter, NULL); } struct filter_list { struct list_head list; struct event_filter *filter; }; static int process_system_preds(struct trace_subsystem_dir *dir, struct trace_array *tr, struct filter_parse_error *pe, char *filter_string) { struct trace_event_file *file; struct filter_list *filter_item; struct event_filter *filter = NULL; struct filter_list *tmp; LIST_HEAD(filter_list); bool fail = true; int err; list_for_each_entry(file, &tr->events, list) { if (file->system != dir) continue; filter = kzalloc(sizeof(*filter), GFP_KERNEL); if (!filter) goto fail_mem; filter->filter_string = kstrdup(filter_string, GFP_KERNEL); if (!filter->filter_string) goto fail_mem; err = process_preds(file->event_call, filter_string, filter, pe); if (err) { filter_disable(file); parse_error(pe, FILT_ERR_BAD_SUBSYS_FILTER, 0); append_filter_err(tr, pe, filter); } else event_set_filtered_flag(file); filter_item = kzalloc(sizeof(*filter_item), GFP_KERNEL); if (!filter_item) goto fail_mem; list_add_tail(&filter_item->list, &filter_list); /* * Regardless of if this returned an error, we still * replace the filter for the call. */ filter_item->filter = event_filter(file); event_set_filter(file, filter); filter = NULL; fail = false; } if (fail) goto fail; /* * The calls can still be using the old filters. * Do a synchronize_rcu() and to ensure all calls are * done with them before we free them. */ tracepoint_synchronize_unregister(); list_for_each_entry_safe(filter_item, tmp, &filter_list, list) { __free_filter(filter_item->filter); list_del(&filter_item->list); kfree(filter_item); } return 0; fail: /* No call succeeded */ list_for_each_entry_safe(filter_item, tmp, &filter_list, list) { list_del(&filter_item->list); kfree(filter_item); } parse_error(pe, FILT_ERR_BAD_SUBSYS_FILTER, 0); return -EINVAL; fail_mem: __free_filter(filter); /* If any call succeeded, we still need to sync */ if (!fail) tracepoint_synchronize_unregister(); list_for_each_entry_safe(filter_item, tmp, &filter_list, list) { __free_filter(filter_item->filter); list_del(&filter_item->list); kfree(filter_item); } return -ENOMEM; } static int create_filter_start(char *filter_string, bool set_str, struct filter_parse_error **pse, struct event_filter **filterp) { struct event_filter *filter; struct filter_parse_error *pe = NULL; int err = 0; if (WARN_ON_ONCE(*pse || *filterp)) return -EINVAL; filter = kzalloc(sizeof(*filter), GFP_KERNEL); if (filter && set_str) { filter->filter_string = kstrdup(filter_string, GFP_KERNEL); if (!filter->filter_string) err = -ENOMEM; } pe = kzalloc(sizeof(*pe), GFP_KERNEL); if (!filter || !pe || err) { kfree(pe); __free_filter(filter); return -ENOMEM; } /* we're committed to creating a new filter */ *filterp = filter; *pse = pe; return 0; } static void create_filter_finish(struct filter_parse_error *pe) { kfree(pe); } /** * create_filter - create a filter for a trace_event_call * @tr: the trace array associated with these events * @call: trace_event_call to create a filter for * @filter_string: filter string * @set_str: remember @filter_str and enable detailed error in filter * @filterp: out param for created filter (always updated on return) * Must be a pointer that references a NULL pointer. * * Creates a filter for @call with @filter_str. If @set_str is %true, * @filter_str is copied and recorded in the new filter. * * On success, returns 0 and *@filterp points to the new filter. On * failure, returns -errno and *@filterp may point to %NULL or to a new * filter. In the latter case, the returned filter contains error * information if @set_str is %true and the caller is responsible for * freeing it. */ static int create_filter(struct trace_array *tr, struct trace_event_call *call, char *filter_string, bool set_str, struct event_filter **filterp) { struct filter_parse_error *pe = NULL; int err; /* filterp must point to NULL */ if (WARN_ON(*filterp)) *filterp = NULL; err = create_filter_start(filter_string, set_str, &pe, filterp); if (err) return err; err = process_preds(call, filter_string, *filterp, pe); if (err && set_str) append_filter_err(tr, pe, *filterp); create_filter_finish(pe); return err; } int create_event_filter(struct trace_array *tr, struct trace_event_call *call, char *filter_str, bool set_str, struct event_filter **filterp) { return create_filter(tr, call, filter_str, set_str, filterp); } /** * create_system_filter - create a filter for an event subsystem * @dir: the descriptor for the subsystem directory * @filter_str: filter string * @filterp: out param for created filter (always updated on return) * * Identical to create_filter() except that it creates a subsystem filter * and always remembers @filter_str. */ static int create_system_filter(struct trace_subsystem_dir *dir, char *filter_str, struct event_filter **filterp) { struct filter_parse_error *pe = NULL; int err; err = create_filter_start(filter_str, true, &pe, filterp); if (!err) { err = process_system_preds(dir, dir->tr, pe, filter_str); if (!err) { /* System filters just show a default message */ kfree((*filterp)->filter_string); (*filterp)->filter_string = NULL; } else { append_filter_err(dir->tr, pe, *filterp); } } create_filter_finish(pe); return err; } /* caller must hold event_mutex */ int apply_event_filter(struct trace_event_file *file, char *filter_string) { struct trace_event_call *call = file->event_call; struct event_filter *filter = NULL; int err; if (file->flags & EVENT_FILE_FL_FREED) return -ENODEV; if (!strcmp(strstrip(filter_string), "0")) { filter_disable(file); filter = event_filter(file); if (!filter) return 0; event_clear_filter(file); /* Make sure the filter is not being used */ tracepoint_synchronize_unregister(); __free_filter(filter); return 0; } err = create_filter(file->tr, call, filter_string, true, &filter); /* * Always swap the call filter with the new filter * even if there was an error. If there was an error * in the filter, we disable the filter and show the error * string */ if (filter) { struct event_filter *tmp; tmp = event_filter(file); if (!err) event_set_filtered_flag(file); else filter_disable(file); event_set_filter(file, filter); if (tmp) { /* Make sure the call is done with the filter */ tracepoint_synchronize_unregister(); __free_filter(tmp); } } return err; } int apply_subsystem_event_filter(struct trace_subsystem_dir *dir, char *filter_string) { struct event_subsystem *system = dir->subsystem; struct trace_array *tr = dir->tr; struct event_filter *filter = NULL; int err = 0; mutex_lock(&event_mutex); /* Make sure the system still has events */ if (!dir->nr_events) { err = -ENODEV; goto out_unlock; } if (!strcmp(strstrip(filter_string), "0")) { filter_free_subsystem_preds(dir, tr); remove_filter_string(system->filter); filter = system->filter; system->filter = NULL; /* Ensure all filters are no longer used */ tracepoint_synchronize_unregister(); filter_free_subsystem_filters(dir, tr); __free_filter(filter); goto out_unlock; } err = create_system_filter(dir, filter_string, &filter); if (filter) { /* * No event actually uses the system filter * we can free it without synchronize_rcu(). */ __free_filter(system->filter); system->filter = filter; } out_unlock: mutex_unlock(&event_mutex); return err; } #ifdef CONFIG_PERF_EVENTS void ftrace_profile_free_filter(struct perf_event *event) { struct event_filter *filter = event->filter; event->filter = NULL; __free_filter(filter); } struct function_filter_data { struct ftrace_ops *ops; int first_filter; int first_notrace; }; #ifdef CONFIG_FUNCTION_TRACER static char ** ftrace_function_filter_re(char *buf, int len, int *count) { char *str, **re; str = kstrndup(buf, len, GFP_KERNEL); if (!str) return NULL; /* * The argv_split function takes white space * as a separator, so convert ',' into spaces. */ strreplace(str, ',', ' '); re = argv_split(GFP_KERNEL, str, count); kfree(str); return re; } static int ftrace_function_set_regexp(struct ftrace_ops *ops, int filter, int reset, char *re, int len) { int ret; if (filter) ret = ftrace_set_filter(ops, re, len, reset); else ret = ftrace_set_notrace(ops, re, len, reset); return ret; } static int __ftrace_function_set_filter(int filter, char *buf, int len, struct function_filter_data *data) { int i, re_cnt, ret = -EINVAL; int *reset; char **re; reset = filter ? &data->first_filter : &data->first_notrace; /* * The 'ip' field could have multiple filters set, separated * either by space or comma. We first cut the filter and apply * all pieces separately. */ re = ftrace_function_filter_re(buf, len, &re_cnt); if (!re) return -EINVAL; for (i = 0; i < re_cnt; i++) { ret = ftrace_function_set_regexp(data->ops, filter, *reset, re[i], strlen(re[i])); if (ret) break; if (*reset) *reset = 0; } argv_free(re); return ret; } static int ftrace_function_check_pred(struct filter_pred *pred) { struct ftrace_event_field *field = pred->field; /* * Check the predicate for function trace, verify: * - only '==' and '!=' is used * - the 'ip' field is used */ if ((pred->op != OP_EQ) && (pred->op != OP_NE)) return -EINVAL; if (strcmp(field->name, "ip")) return -EINVAL; return 0; } static int ftrace_function_set_filter_pred(struct filter_pred *pred, struct function_filter_data *data) { int ret; /* Checking the node is valid for function trace. */ ret = ftrace_function_check_pred(pred); if (ret) return ret; return __ftrace_function_set_filter(pred->op == OP_EQ, pred->regex->pattern, pred->regex->len, data); } static bool is_or(struct prog_entry *prog, int i) { int target; /* * Only "||" is allowed for function events, thus, * all true branches should jump to true, and any * false branch should jump to false. */ target = prog[i].target + 1; /* True and false have NULL preds (all prog entries should jump to one */ if (prog[target].pred) return false; /* prog[target].target is 1 for TRUE, 0 for FALSE */ return prog[i].when_to_branch == prog[target].target; } static int ftrace_function_set_filter(struct perf_event *event, struct event_filter *filter) { struct prog_entry *prog = rcu_dereference_protected(filter->prog, lockdep_is_held(&event_mutex)); struct function_filter_data data = { .first_filter = 1, .first_notrace = 1, .ops = &event->ftrace_ops, }; int i; for (i = 0; prog[i].pred; i++) { struct filter_pred *pred = prog[i].pred; if (!is_or(prog, i)) return -EINVAL; if (ftrace_function_set_filter_pred(pred, &data) < 0) return -EINVAL; } return 0; } #else static int ftrace_function_set_filter(struct perf_event *event, struct event_filter *filter) { return -ENODEV; } #endif /* CONFIG_FUNCTION_TRACER */ int ftrace_profile_set_filter(struct perf_event *event, int event_id, char *filter_str) { int err; struct event_filter *filter = NULL; struct trace_event_call *call; mutex_lock(&event_mutex); call = event->tp_event; err = -EINVAL; if (!call) goto out_unlock; err = -EEXIST; if (event->filter) goto out_unlock; err = create_filter(NULL, call, filter_str, false, &filter); if (err) goto free_filter; if (ftrace_event_is_function(call)) err = ftrace_function_set_filter(event, filter); else event->filter = filter; free_filter: if (err || ftrace_event_is_function(call)) __free_filter(filter); out_unlock: mutex_unlock(&event_mutex); return err; } #endif /* CONFIG_PERF_EVENTS */ #ifdef CONFIG_FTRACE_STARTUP_TEST #include <linux/types.h> #include <linux/tracepoint.h> #define CREATE_TRACE_POINTS #include "trace_events_filter_test.h" #define DATA_REC(m, va, vb, vc, vd, ve, vf, vg, vh, nvisit) \ { \ .filter = FILTER, \ .rec = { .a = va, .b = vb, .c = vc, .d = vd, \ .e = ve, .f = vf, .g = vg, .h = vh }, \ .match = m, \ .not_visited = nvisit, \ } #define YES 1 #define NO 0 static struct test_filter_data_t { char *filter; struct trace_event_raw_ftrace_test_filter rec; int match; char *not_visited; } test_filter_data[] = { #define FILTER "a == 1 && b == 1 && c == 1 && d == 1 && " \ "e == 1 && f == 1 && g == 1 && h == 1" DATA_REC(YES, 1, 1, 1, 1, 1, 1, 1, 1, ""), DATA_REC(NO, 0, 1, 1, 1, 1, 1, 1, 1, "bcdefgh"), DATA_REC(NO, 1, 1, 1, 1, 1, 1, 1, 0, ""), #undef FILTER #define FILTER "a == 1 || b == 1 || c == 1 || d == 1 || " \ "e == 1 || f == 1 || g == 1 || h == 1" DATA_REC(NO, 0, 0, 0, 0, 0, 0, 0, 0, ""), DATA_REC(YES, 0, 0, 0, 0, 0, 0, 0, 1, ""), DATA_REC(YES, 1, 0, 0, 0, 0, 0, 0, 0, "bcdefgh"), #undef FILTER #define FILTER "(a == 1 || b == 1) && (c == 1 || d == 1) && " \ "(e == 1 || f == 1) && (g == 1 || h == 1)" DATA_REC(NO, 0, 0, 1, 1, 1, 1, 1, 1, "dfh"), DATA_REC(YES, 0, 1, 0, 1, 0, 1, 0, 1, ""), DATA_REC(YES, 1, 0, 1, 0, 0, 1, 0, 1, "bd"), DATA_REC(NO, 1, 0, 1, 0, 0, 1, 0, 0, "bd"), #undef FILTER #define FILTER "(a == 1 && b == 1) || (c == 1 && d == 1) || " \ "(e == 1 && f == 1) || (g == 1 && h == 1)" DATA_REC(YES, 1, 0, 1, 1, 1, 1, 1, 1, "efgh"), DATA_REC(YES, 0, 0, 0, 0, 0, 0, 1, 1, ""), DATA_REC(NO, 0, 0, 0, 0, 0, 0, 0, 1, ""), #undef FILTER #define FILTER "(a == 1 && b == 1) && (c == 1 && d == 1) && " \ "(e == 1 && f == 1) || (g == 1 && h == 1)" DATA_REC(YES, 1, 1, 1, 1, 1, 1, 0, 0, "gh"), DATA_REC(NO, 0, 0, 0, 0, 0, 0, 0, 1, ""), DATA_REC(YES, 1, 1, 1, 1, 1, 0, 1, 1, ""), #undef FILTER #define FILTER "((a == 1 || b == 1) || (c == 1 || d == 1) || " \ "(e == 1 || f == 1)) && (g == 1 || h == 1)" DATA_REC(YES, 1, 1, 1, 1, 1, 1, 0, 1, "bcdef"), DATA_REC(NO, 0, 0, 0, 0, 0, 0, 0, 0, ""), DATA_REC(YES, 1, 1, 1, 1, 1, 0, 1, 1, "h"), #undef FILTER #define FILTER "((((((((a == 1) && (b == 1)) || (c == 1)) && (d == 1)) || " \ "(e == 1)) && (f == 1)) || (g == 1)) && (h == 1))" DATA_REC(YES, 1, 1, 1, 1, 1, 1, 1, 1, "ceg"), DATA_REC(NO, 0, 1, 0, 1, 0, 1, 0, 1, ""), DATA_REC(NO, 1, 0, 1, 0, 1, 0, 1, 0, ""), #undef FILTER #define FILTER "((((((((a == 1) || (b == 1)) && (c == 1)) || (d == 1)) && " \ "(e == 1)) || (f == 1)) && (g == 1)) || (h == 1))" DATA_REC(YES, 1, 1, 1, 1, 1, 1, 1, 1, "bdfh"), DATA_REC(YES, 0, 1, 0, 1, 0, 1, 0, 1, ""), DATA_REC(YES, 1, 0, 1, 0, 1, 0, 1, 0, "bdfh"), }; #undef DATA_REC #undef FILTER #undef YES #undef NO #define DATA_CNT ARRAY_SIZE(test_filter_data) static int test_pred_visited; static int test_pred_visited_fn(struct filter_pred *pred, void *event) { struct ftrace_event_field *field = pred->field; test_pred_visited = 1; printk(KERN_INFO "\npred visited %s\n", field->name); return 1; } static void update_pred_fn(struct event_filter *filter, char *fields) { struct prog_entry *prog = rcu_dereference_protected(filter->prog, lockdep_is_held(&event_mutex)); int i; for (i = 0; prog[i].pred; i++) { struct filter_pred *pred = prog[i].pred; struct ftrace_event_field *field = pred->field; WARN_ON_ONCE(pred->fn_num == FILTER_PRED_FN_NOP); if (!field) { WARN_ONCE(1, "all leafs should have field defined %d", i); continue; } if (!strchr(fields, *field->name)) continue; pred->fn_num = FILTER_PRED_TEST_VISITED; } } static __init int ftrace_test_event_filter(void) { int i; printk(KERN_INFO "Testing ftrace filter: "); for (i = 0; i < DATA_CNT; i++) { struct event_filter *filter = NULL; struct test_filter_data_t *d = &test_filter_data[i]; int err; err = create_filter(NULL, &event_ftrace_test_filter, d->filter, false, &filter); if (err) { printk(KERN_INFO "Failed to get filter for '%s', err %d\n", d->filter, err); __free_filter(filter); break; } /* Needed to dereference filter->prog */ mutex_lock(&event_mutex); /* * The preemption disabling is not really needed for self * tests, but the rcu dereference will complain without it. */ preempt_disable(); if (*d->not_visited) update_pred_fn(filter, d->not_visited); test_pred_visited = 0; err = filter_match_preds(filter, &d->rec); preempt_enable(); mutex_unlock(&event_mutex); __free_filter(filter); if (test_pred_visited) { printk(KERN_INFO "Failed, unwanted pred visited for filter %s\n", d->filter); break; } if (err != d->match) { printk(KERN_INFO "Failed to match filter '%s', expected %d\n", d->filter, d->match); break; } } if (i == DATA_CNT) printk(KERN_CONT "OK\n"); return 0; } late_initcall(ftrace_test_event_filter); #endif /* CONFIG_FTRACE_STARTUP_TEST */
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