// SPDX-License-Identifier: GPL-2.0 /* * Test v2 API for perf --dlfilter shared object * Copyright (c) 2023, Intel Corporation. */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <stdbool.h> /* * Copy v2 API instead of including current API */ #include <linux/perf_event.h> #include <linux/types.h> /* * The following macro can be used to determine if this header defines * perf_dlfilter_sample machine_pid and vcpu. */ #define PERF_DLFILTER_HAS_MACHINE_PID /* Definitions for perf_dlfilter_sample flags */ enum { PERF_DLFILTER_FLAG_BRANCH = 1ULL << 0, PERF_DLFILTER_FLAG_CALL = 1ULL << 1, PERF_DLFILTER_FLAG_RETURN = 1ULL << 2, PERF_DLFILTER_FLAG_CONDITIONAL = 1ULL << 3, PERF_DLFILTER_FLAG_SYSCALLRET = 1ULL << 4, PERF_DLFILTER_FLAG_ASYNC = 1ULL << 5, PERF_DLFILTER_FLAG_INTERRUPT = 1ULL << 6, PERF_DLFILTER_FLAG_TX_ABORT = 1ULL << 7, PERF_DLFILTER_FLAG_TRACE_BEGIN = 1ULL << 8, PERF_DLFILTER_FLAG_TRACE_END = 1ULL << 9, PERF_DLFILTER_FLAG_IN_TX = 1ULL << 10, PERF_DLFILTER_FLAG_VMENTRY = 1ULL << 11, PERF_DLFILTER_FLAG_VMEXIT = 1ULL << 12, }; /* * perf sample event information (as per perf script and <linux/perf_event.h>) */ struct perf_dlfilter_sample { __u32 size; /* Size of this structure (for compatibility checking) */ __u16 ins_lat; /* Refer PERF_SAMPLE_WEIGHT_TYPE in <linux/perf_event.h> */ __u16 p_stage_cyc; /* Refer PERF_SAMPLE_WEIGHT_TYPE in <linux/perf_event.h> */ __u64 ip; __s32 pid; __s32 tid; __u64 time; __u64 addr; __u64 id; __u64 stream_id; __u64 period; __u64 weight; /* Refer PERF_SAMPLE_WEIGHT_TYPE in <linux/perf_event.h> */ __u64 transaction; /* Refer PERF_SAMPLE_TRANSACTION in <linux/perf_event.h> */ __u64 insn_cnt; /* For instructions-per-cycle (IPC) */ __u64 cyc_cnt; /* For instructions-per-cycle (IPC) */ __s32 cpu; __u32 flags; /* Refer PERF_DLFILTER_FLAG_* above */ __u64 data_src; /* Refer PERF_SAMPLE_DATA_SRC in <linux/perf_event.h> */ __u64 phys_addr; /* Refer PERF_SAMPLE_PHYS_ADDR in <linux/perf_event.h> */ __u64 data_page_size; /* Refer PERF_SAMPLE_DATA_PAGE_SIZE in <linux/perf_event.h> */ __u64 code_page_size; /* Refer PERF_SAMPLE_CODE_PAGE_SIZE in <linux/perf_event.h> */ __u64 cgroup; /* Refer PERF_SAMPLE_CGROUP in <linux/perf_event.h> */ __u8 cpumode; /* Refer CPUMODE_MASK etc in <linux/perf_event.h> */ __u8 addr_correlates_sym; /* True => resolve_addr() can be called */ __u16 misc; /* Refer perf_event_header in <linux/perf_event.h> */ __u32 raw_size; /* Refer PERF_SAMPLE_RAW in <linux/perf_event.h> */ const void *raw_data; /* Refer PERF_SAMPLE_RAW in <linux/perf_event.h> */ __u64 brstack_nr; /* Number of brstack entries */ const struct perf_branch_entry *brstack; /* Refer <linux/perf_event.h> */ __u64 raw_callchain_nr; /* Number of raw_callchain entries */ const __u64 *raw_callchain; /* Refer <linux/perf_event.h> */ const char *event; __s32 machine_pid; __s32 vcpu; }; /* * Address location (as per perf script) */ struct perf_dlfilter_al { __u32 size; /* Size of this structure (for compatibility checking) */ __u32 symoff; const char *sym; __u64 addr; /* Mapped address (from dso) */ __u64 sym_start; __u64 sym_end; const char *dso; __u8 sym_binding; /* STB_LOCAL, STB_GLOBAL or STB_WEAK, refer <elf.h> */ __u8 is_64_bit; /* Only valid if dso is not NULL */ __u8 is_kernel_ip; /* True if in kernel space */ __u32 buildid_size; __u8 *buildid; /* Below members are only populated by resolve_ip() */ __u8 filtered; /* True if this sample event will be filtered out */ const char *comm; void *priv; /* Private data (v2 API) */ }; struct perf_dlfilter_fns { /* Return information about ip */ const struct perf_dlfilter_al *(*resolve_ip)(void *ctx); /* Return information about addr (if addr_correlates_sym) */ const struct perf_dlfilter_al *(*resolve_addr)(void *ctx); /* Return arguments from --dlarg option */ char **(*args)(void *ctx, int *dlargc); /* * Return information about address (al->size must be set before * calling). Returns 0 on success, -1 otherwise. Call al_cleanup() * when 'al' data is no longer needed. */ __s32 (*resolve_address)(void *ctx, __u64 address, struct perf_dlfilter_al *al); /* Return instruction bytes and length */ const __u8 *(*insn)(void *ctx, __u32 *length); /* Return source file name and line number */ const char *(*srcline)(void *ctx, __u32 *line_number); /* Return perf_event_attr, refer <linux/perf_event.h> */ struct perf_event_attr *(*attr)(void *ctx); /* Read object code, return numbers of bytes read */ __s32 (*object_code)(void *ctx, __u64 ip, void *buf, __u32 len); /* * If present (i.e. must check al_cleanup != NULL), call after * resolve_address() to free any associated resources. (v2 API) */ void (*al_cleanup)(void *ctx, struct perf_dlfilter_al *al); /* Reserved */ void *(*reserved[119])(void *); }; struct perf_dlfilter_fns perf_dlfilter_fns; static int verbose; #define pr_debug(fmt, ...) do { \ if (verbose > 0) \ fprintf(stderr, fmt, ##__VA_ARGS__); \ } while (0) static int test_fail(const char *msg) { pr_debug("%s\n", msg); return -1; } #define CHECK(x) do { \ if (!(x)) \ return test_fail("Check '" #x "' failed\n"); \ } while (0) struct filter_data { __u64 ip; __u64 addr; int do_early; int early_filter_cnt; int filter_cnt; }; static struct filter_data *filt_dat; int start(void **data, void *ctx) { int dlargc; char **dlargv; struct filter_data *d; static bool called; verbose = 1; CHECK(!filt_dat && !called); called = true; d = calloc(1, sizeof(*d)); if (!d) test_fail("Failed to allocate memory"); filt_dat = d; *data = d; dlargv = perf_dlfilter_fns.args(ctx, &dlargc); CHECK(dlargc == 6); CHECK(!strcmp(dlargv[0], "first")); verbose = strtol(dlargv[1], NULL, 0); d->ip = strtoull(dlargv[2], NULL, 0); d->addr = strtoull(dlargv[3], NULL, 0); d->do_early = strtol(dlargv[4], NULL, 0); CHECK(!strcmp(dlargv[5], "last")); pr_debug("%s API\n", __func__); return 0; } #define CHECK_SAMPLE(x) do { \ if (sample->x != expected.x) \ return test_fail("'" #x "' not expected value\n"); \ } while (0) static int check_sample(struct filter_data *d, const struct perf_dlfilter_sample *sample) { struct perf_dlfilter_sample expected = { .ip = d->ip, .pid = 12345, .tid = 12346, .time = 1234567890, .addr = d->addr, .id = 99, .stream_id = 101, .period = 543212345, .cpu = 31, .cpumode = PERF_RECORD_MISC_USER, .addr_correlates_sym = 1, .misc = PERF_RECORD_MISC_USER, }; CHECK(sample->size >= sizeof(struct perf_dlfilter_sample)); CHECK_SAMPLE(ip); CHECK_SAMPLE(pid); CHECK_SAMPLE(tid); CHECK_SAMPLE(time); CHECK_SAMPLE(addr); CHECK_SAMPLE(id); CHECK_SAMPLE(stream_id); CHECK_SAMPLE(period); CHECK_SAMPLE(cpu); CHECK_SAMPLE(cpumode); CHECK_SAMPLE(addr_correlates_sym); CHECK_SAMPLE(misc); CHECK(!sample->raw_data); CHECK_SAMPLE(brstack_nr); CHECK(!sample->brstack); CHECK_SAMPLE(raw_callchain_nr); CHECK(!sample->raw_callchain); #define EVENT_NAME "branches:" CHECK(!strncmp(sample->event, EVENT_NAME, strlen(EVENT_NAME))); return 0; } static int check_al(void *ctx) { const struct perf_dlfilter_al *al; al = perf_dlfilter_fns.resolve_ip(ctx); if (!al) return test_fail("resolve_ip() failed"); CHECK(al->sym && !strcmp("foo", al->sym)); CHECK(!al->symoff); return 0; } static int check_addr_al(void *ctx) { const struct perf_dlfilter_al *addr_al; addr_al = perf_dlfilter_fns.resolve_addr(ctx); if (!addr_al) return test_fail("resolve_addr() failed"); CHECK(addr_al->sym && !strcmp("bar", addr_al->sym)); CHECK(!addr_al->symoff); return 0; } static int check_address_al(void *ctx, const struct perf_dlfilter_sample *sample) { struct perf_dlfilter_al address_al; const struct perf_dlfilter_al *al; al = perf_dlfilter_fns.resolve_ip(ctx); if (!al) return test_fail("resolve_ip() failed"); address_al.size = sizeof(address_al); if (perf_dlfilter_fns.resolve_address(ctx, sample->ip, &address_al)) return test_fail("resolve_address() failed"); CHECK(address_al.sym && al->sym); CHECK(!strcmp(address_al.sym, al->sym)); CHECK(address_al.addr == al->addr); CHECK(address_al.sym_start == al->sym_start); CHECK(address_al.sym_end == al->sym_end); CHECK(address_al.dso && al->dso); CHECK(!strcmp(address_al.dso, al->dso)); /* al_cleanup() is v2 API so may not be present */ if (perf_dlfilter_fns.al_cleanup) perf_dlfilter_fns.al_cleanup(ctx, &address_al); return 0; } static int check_attr(void *ctx) { struct perf_event_attr *attr = perf_dlfilter_fns.attr(ctx); CHECK(attr); CHECK(attr->type == PERF_TYPE_HARDWARE); CHECK(attr->config == PERF_COUNT_HW_BRANCH_INSTRUCTIONS); return 0; } static int check_object_code(void *ctx, const struct perf_dlfilter_sample *sample) { __u8 buf[15]; CHECK(perf_dlfilter_fns.object_code(ctx, sample->ip, buf, sizeof(buf)) > 0); return 0; } static int do_checks(void *data, const struct perf_dlfilter_sample *sample, void *ctx, bool early) { struct filter_data *d = data; CHECK(data && filt_dat == data); if (early) { CHECK(!d->early_filter_cnt); d->early_filter_cnt += 1; } else { CHECK(!d->filter_cnt); CHECK(d->early_filter_cnt); CHECK(d->do_early != 2); d->filter_cnt += 1; } if (check_sample(data, sample)) return -1; if (check_attr(ctx)) return -1; if (early && !d->do_early) return 0; if (check_al(ctx) || check_addr_al(ctx) || check_address_al(ctx, sample) || check_object_code(ctx, sample)) return -1; if (early) return d->do_early == 2; return 1; } int filter_event_early(void *data, const struct perf_dlfilter_sample *sample, void *ctx) { pr_debug("%s API\n", __func__); return do_checks(data, sample, ctx, true); } int filter_event(void *data, const struct perf_dlfilter_sample *sample, void *ctx) { pr_debug("%s API\n", __func__); return do_checks(data, sample, ctx, false); } int stop(void *data, void *ctx) { static bool called; pr_debug("%s API\n", __func__); CHECK(data && filt_dat == data && !called); called = true; free(data); filt_dat = NULL; return 0; } const char *filter_description(const char **long_description) { *long_description = "Filter used by the 'dlfilter C API' perf test"; return "dlfilter to test v2 C API"; }