Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Adrian Hunter | 5318 | 93.89% | 28 | 38.89% |
Namhyung Kim | 97 | 1.71% | 2 | 2.78% |
Ian Rogers | 84 | 1.48% | 10 | 13.89% |
Jiri Olsa | 67 | 1.18% | 13 | 18.06% |
Arnaldo Carvalho de Melo | 33 | 0.58% | 11 | 15.28% |
Alexander Shishkin | 33 | 0.58% | 1 | 1.39% |
Kan Liang | 12 | 0.21% | 1 | 1.39% |
Igor Lubashev | 5 | 0.09% | 1 | 1.39% |
James Clark | 5 | 0.09% | 1 | 1.39% |
Mathieu J. Poirier | 4 | 0.07% | 1 | 1.39% |
Ingo Molnar | 3 | 0.05% | 1 | 1.39% |
Thomas Gleixner | 2 | 0.04% | 1 | 1.39% |
Josh Poimboeuf | 1 | 0.02% | 1 | 1.39% |
Total | 5664 | 72 |
// SPDX-License-Identifier: GPL-2.0-only /* * intel_pt.c: Intel Processor Trace support * Copyright (c) 2013-2015, Intel Corporation. */ #include <errno.h> #include <stdbool.h> #include <linux/kernel.h> #include <linux/types.h> #include <linux/bitops.h> #include <linux/log2.h> #include <linux/zalloc.h> #include <linux/err.h> #include <cpuid.h> #include "../../../util/session.h" #include "../../../util/event.h" #include "../../../util/evlist.h" #include "../../../util/evsel.h" #include "../../../util/evsel_config.h" #include "../../../util/cpumap.h" #include "../../../util/mmap.h" #include <subcmd/parse-options.h> #include "../../../util/parse-events.h" #include "../../../util/pmus.h" #include "../../../util/debug.h" #include "../../../util/auxtrace.h" #include "../../../util/perf_api_probe.h" #include "../../../util/record.h" #include "../../../util/target.h" #include "../../../util/tsc.h" #include <internal/lib.h> // page_size #include "../../../util/intel-pt.h" #include <api/fs/fs.h> #define KiB(x) ((x) * 1024) #define MiB(x) ((x) * 1024 * 1024) #define KiB_MASK(x) (KiB(x) - 1) #define MiB_MASK(x) (MiB(x) - 1) #define INTEL_PT_PSB_PERIOD_NEAR 256 struct intel_pt_snapshot_ref { void *ref_buf; size_t ref_offset; bool wrapped; }; struct intel_pt_recording { struct auxtrace_record itr; struct perf_pmu *intel_pt_pmu; int have_sched_switch; struct evlist *evlist; bool snapshot_mode; bool snapshot_init_done; size_t snapshot_size; size_t snapshot_ref_buf_size; int snapshot_ref_cnt; struct intel_pt_snapshot_ref *snapshot_refs; size_t priv_size; }; static int intel_pt_parse_terms_with_default(const struct perf_pmu *pmu, const char *str, u64 *config) { struct parse_events_terms terms; struct perf_event_attr attr = { .size = 0, }; int err; parse_events_terms__init(&terms); err = parse_events_terms(&terms, str, /*input=*/ NULL); if (err) goto out_free; attr.config = *config; err = perf_pmu__config_terms(pmu, &attr, &terms, /*zero=*/true, /*err=*/NULL); if (err) goto out_free; *config = attr.config; out_free: parse_events_terms__exit(&terms); return err; } static int intel_pt_parse_terms(const struct perf_pmu *pmu, const char *str, u64 *config) { *config = 0; return intel_pt_parse_terms_with_default(pmu, str, config); } static u64 intel_pt_masked_bits(u64 mask, u64 bits) { const u64 top_bit = 1ULL << 63; u64 res = 0; int i; for (i = 0; i < 64; i++) { if (mask & top_bit) { res <<= 1; if (bits & top_bit) res |= 1; } mask <<= 1; bits <<= 1; } return res; } static int intel_pt_read_config(struct perf_pmu *intel_pt_pmu, const char *str, struct evlist *evlist, u64 *res) { struct evsel *evsel; u64 mask; *res = 0; mask = perf_pmu__format_bits(intel_pt_pmu, str); if (!mask) return -EINVAL; evlist__for_each_entry(evlist, evsel) { if (evsel->core.attr.type == intel_pt_pmu->type) { *res = intel_pt_masked_bits(mask, evsel->core.attr.config); return 0; } } return -EINVAL; } static size_t intel_pt_psb_period(struct perf_pmu *intel_pt_pmu, struct evlist *evlist) { u64 val; int err, topa_multiple_entries; size_t psb_period; if (perf_pmu__scan_file(intel_pt_pmu, "caps/topa_multiple_entries", "%d", &topa_multiple_entries) != 1) topa_multiple_entries = 0; /* * Use caps/topa_multiple_entries to indicate early hardware that had * extra frequent PSBs. */ if (!topa_multiple_entries) { psb_period = 256; goto out; } err = intel_pt_read_config(intel_pt_pmu, "psb_period", evlist, &val); if (err) val = 0; psb_period = 1 << (val + 11); out: pr_debug2("%s psb_period %zu\n", intel_pt_pmu->name, psb_period); return psb_period; } static int intel_pt_pick_bit(int bits, int target) { int pos, pick = -1; for (pos = 0; bits; bits >>= 1, pos++) { if (bits & 1) { if (pos <= target || pick < 0) pick = pos; if (pos >= target) break; } } return pick; } static u64 intel_pt_default_config(const struct perf_pmu *intel_pt_pmu) { char buf[256]; int mtc, mtc_periods = 0, mtc_period; int psb_cyc, psb_periods, psb_period; int pos = 0; u64 config; char c; int dirfd; dirfd = perf_pmu__event_source_devices_fd(); pos += scnprintf(buf + pos, sizeof(buf) - pos, "tsc"); if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "caps/mtc", "%d", &mtc) != 1) mtc = 1; if (mtc) { if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "caps/mtc_periods", "%x", &mtc_periods) != 1) mtc_periods = 0; if (mtc_periods) { mtc_period = intel_pt_pick_bit(mtc_periods, 3); pos += scnprintf(buf + pos, sizeof(buf) - pos, ",mtc,mtc_period=%d", mtc_period); } } if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "caps/psb_cyc", "%d", &psb_cyc) != 1) psb_cyc = 1; if (psb_cyc && mtc_periods) { if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "caps/psb_periods", "%x", &psb_periods) != 1) psb_periods = 0; if (psb_periods) { psb_period = intel_pt_pick_bit(psb_periods, 3); pos += scnprintf(buf + pos, sizeof(buf) - pos, ",psb_period=%d", psb_period); } } if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "format/pt", "%c", &c) == 1 && perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "format/branch", "%c", &c) == 1) pos += scnprintf(buf + pos, sizeof(buf) - pos, ",pt,branch"); pr_debug2("%s default config: %s\n", intel_pt_pmu->name, buf); intel_pt_parse_terms(intel_pt_pmu, buf, &config); close(dirfd); return config; } static int intel_pt_parse_snapshot_options(struct auxtrace_record *itr, struct record_opts *opts, const char *str) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); unsigned long long snapshot_size = 0; char *endptr; if (str) { snapshot_size = strtoull(str, &endptr, 0); if (*endptr || snapshot_size > SIZE_MAX) return -1; } opts->auxtrace_snapshot_mode = true; opts->auxtrace_snapshot_size = snapshot_size; ptr->snapshot_size = snapshot_size; return 0; } void intel_pt_pmu_default_config(const struct perf_pmu *intel_pt_pmu, struct perf_event_attr *attr) { static u64 config; static bool initialized; if (!initialized) { config = intel_pt_default_config(intel_pt_pmu); initialized = true; } attr->config = config; } static const char *intel_pt_find_filter(struct evlist *evlist, struct perf_pmu *intel_pt_pmu) { struct evsel *evsel; evlist__for_each_entry(evlist, evsel) { if (evsel->core.attr.type == intel_pt_pmu->type) return evsel->filter; } return NULL; } static size_t intel_pt_filter_bytes(const char *filter) { size_t len = filter ? strlen(filter) : 0; return len ? roundup(len + 1, 8) : 0; } static size_t intel_pt_info_priv_size(struct auxtrace_record *itr, struct evlist *evlist) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); const char *filter = intel_pt_find_filter(evlist, ptr->intel_pt_pmu); ptr->priv_size = (INTEL_PT_AUXTRACE_PRIV_MAX * sizeof(u64)) + intel_pt_filter_bytes(filter); ptr->priv_size += sizeof(u64); /* Cap Event Trace */ return ptr->priv_size; } static void intel_pt_tsc_ctc_ratio(u32 *n, u32 *d) { unsigned int eax = 0, ebx = 0, ecx = 0, edx = 0; __get_cpuid(0x15, &eax, &ebx, &ecx, &edx); *n = ebx; *d = eax; } static int intel_pt_info_fill(struct auxtrace_record *itr, struct perf_session *session, struct perf_record_auxtrace_info *auxtrace_info, size_t priv_size) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); struct perf_pmu *intel_pt_pmu = ptr->intel_pt_pmu; struct perf_event_mmap_page *pc; struct perf_tsc_conversion tc = { .time_mult = 0, }; bool cap_user_time_zero = false, per_cpu_mmaps; u64 tsc_bit, mtc_bit, mtc_freq_bits, cyc_bit, noretcomp_bit; u32 tsc_ctc_ratio_n, tsc_ctc_ratio_d; unsigned long max_non_turbo_ratio; size_t filter_str_len; const char *filter; int event_trace; __u64 *info; int err; if (priv_size != ptr->priv_size) return -EINVAL; intel_pt_parse_terms(intel_pt_pmu, "tsc", &tsc_bit); intel_pt_parse_terms(intel_pt_pmu, "noretcomp", &noretcomp_bit); intel_pt_parse_terms(intel_pt_pmu, "mtc", &mtc_bit); mtc_freq_bits = perf_pmu__format_bits(intel_pt_pmu, "mtc_period"); intel_pt_parse_terms(intel_pt_pmu, "cyc", &cyc_bit); intel_pt_tsc_ctc_ratio(&tsc_ctc_ratio_n, &tsc_ctc_ratio_d); if (perf_pmu__scan_file(intel_pt_pmu, "max_nonturbo_ratio", "%lu", &max_non_turbo_ratio) != 1) max_non_turbo_ratio = 0; if (perf_pmu__scan_file(intel_pt_pmu, "caps/event_trace", "%d", &event_trace) != 1) event_trace = 0; filter = intel_pt_find_filter(session->evlist, ptr->intel_pt_pmu); filter_str_len = filter ? strlen(filter) : 0; if (!session->evlist->core.nr_mmaps) return -EINVAL; pc = session->evlist->mmap[0].core.base; if (pc) { err = perf_read_tsc_conversion(pc, &tc); if (err) { if (err != -EOPNOTSUPP) return err; } else { cap_user_time_zero = tc.time_mult != 0; } if (!cap_user_time_zero) ui__warning("Intel Processor Trace: TSC not available\n"); } per_cpu_mmaps = !perf_cpu_map__is_any_cpu_or_is_empty(session->evlist->core.user_requested_cpus); auxtrace_info->type = PERF_AUXTRACE_INTEL_PT; auxtrace_info->priv[INTEL_PT_PMU_TYPE] = intel_pt_pmu->type; auxtrace_info->priv[INTEL_PT_TIME_SHIFT] = tc.time_shift; auxtrace_info->priv[INTEL_PT_TIME_MULT] = tc.time_mult; auxtrace_info->priv[INTEL_PT_TIME_ZERO] = tc.time_zero; auxtrace_info->priv[INTEL_PT_CAP_USER_TIME_ZERO] = cap_user_time_zero; auxtrace_info->priv[INTEL_PT_TSC_BIT] = tsc_bit; auxtrace_info->priv[INTEL_PT_NORETCOMP_BIT] = noretcomp_bit; auxtrace_info->priv[INTEL_PT_HAVE_SCHED_SWITCH] = ptr->have_sched_switch; auxtrace_info->priv[INTEL_PT_SNAPSHOT_MODE] = ptr->snapshot_mode; auxtrace_info->priv[INTEL_PT_PER_CPU_MMAPS] = per_cpu_mmaps; auxtrace_info->priv[INTEL_PT_MTC_BIT] = mtc_bit; auxtrace_info->priv[INTEL_PT_MTC_FREQ_BITS] = mtc_freq_bits; auxtrace_info->priv[INTEL_PT_TSC_CTC_N] = tsc_ctc_ratio_n; auxtrace_info->priv[INTEL_PT_TSC_CTC_D] = tsc_ctc_ratio_d; auxtrace_info->priv[INTEL_PT_CYC_BIT] = cyc_bit; auxtrace_info->priv[INTEL_PT_MAX_NONTURBO_RATIO] = max_non_turbo_ratio; auxtrace_info->priv[INTEL_PT_FILTER_STR_LEN] = filter_str_len; info = &auxtrace_info->priv[INTEL_PT_FILTER_STR_LEN] + 1; if (filter_str_len) { size_t len = intel_pt_filter_bytes(filter); strncpy((char *)info, filter, len); info += len >> 3; } *info++ = event_trace; return 0; } #ifdef HAVE_LIBTRACEEVENT static int intel_pt_track_switches(struct evlist *evlist) { const char *sched_switch = "sched:sched_switch"; struct evsel *evsel; int err; if (!evlist__can_select_event(evlist, sched_switch)) return -EPERM; evsel = evlist__add_sched_switch(evlist, true); if (IS_ERR(evsel)) { err = PTR_ERR(evsel); pr_debug2("%s: failed to create %s, error = %d\n", __func__, sched_switch, err); return err; } evsel->immediate = true; return 0; } #endif static bool intel_pt_exclude_guest(void) { int pt_mode; if (sysfs__read_int("module/kvm_intel/parameters/pt_mode", &pt_mode)) pt_mode = 0; return pt_mode == 1; } static void intel_pt_valid_str(char *str, size_t len, u64 valid) { unsigned int val, last = 0, state = 1; int p = 0; str[0] = '\0'; for (val = 0; val <= 64; val++, valid >>= 1) { if (valid & 1) { last = val; switch (state) { case 0: p += scnprintf(str + p, len - p, ","); /* Fall through */ case 1: p += scnprintf(str + p, len - p, "%u", val); state = 2; break; case 2: state = 3; break; case 3: state = 4; break; default: break; } } else { switch (state) { case 3: p += scnprintf(str + p, len - p, ",%u", last); state = 0; break; case 4: p += scnprintf(str + p, len - p, "-%u", last); state = 0; break; default: break; } if (state != 1) state = 0; } } } static int intel_pt_val_config_term(struct perf_pmu *intel_pt_pmu, int dirfd, const char *caps, const char *name, const char *supported, u64 config) { char valid_str[256]; unsigned int shift; unsigned long long valid; u64 bits; int ok; if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, caps, "%llx", &valid) != 1) valid = 0; if (supported && perf_pmu__scan_file_at(intel_pt_pmu, dirfd, supported, "%d", &ok) == 1 && !ok) valid = 0; valid |= 1; bits = perf_pmu__format_bits(intel_pt_pmu, name); config &= bits; for (shift = 0; bits && !(bits & 1); shift++) bits >>= 1; config >>= shift; if (config > 63) goto out_err; if (valid & (1 << config)) return 0; out_err: intel_pt_valid_str(valid_str, sizeof(valid_str), valid); pr_err("Invalid %s for %s. Valid values are: %s\n", name, INTEL_PT_PMU_NAME, valid_str); return -EINVAL; } static int intel_pt_validate_config(struct perf_pmu *intel_pt_pmu, struct evsel *evsel) { int err, dirfd; char c; if (!evsel) return 0; dirfd = perf_pmu__event_source_devices_fd(); if (dirfd < 0) return dirfd; /* * If supported, force pass-through config term (pt=1) even if user * sets pt=0, which avoids senseless kernel errors. */ if (perf_pmu__scan_file_at(intel_pt_pmu, dirfd, "format/pt", "%c", &c) == 1 && !(evsel->core.attr.config & 1)) { pr_warning("pt=0 doesn't make sense, forcing pt=1\n"); evsel->core.attr.config |= 1; } err = intel_pt_val_config_term(intel_pt_pmu, dirfd, "caps/cycle_thresholds", "cyc_thresh", "caps/psb_cyc", evsel->core.attr.config); if (err) goto out; err = intel_pt_val_config_term(intel_pt_pmu, dirfd, "caps/mtc_periods", "mtc_period", "caps/mtc", evsel->core.attr.config); if (err) goto out; err = intel_pt_val_config_term(intel_pt_pmu, dirfd, "caps/psb_periods", "psb_period", "caps/psb_cyc", evsel->core.attr.config); out: close(dirfd); return err; } static void intel_pt_min_max_sample_sz(struct evlist *evlist, size_t *min_sz, size_t *max_sz) { struct evsel *evsel; evlist__for_each_entry(evlist, evsel) { size_t sz = evsel->core.attr.aux_sample_size; if (!sz) continue; if (min_sz && (sz < *min_sz || !*min_sz)) *min_sz = sz; if (max_sz && sz > *max_sz) *max_sz = sz; } } /* * Currently, there is not enough information to disambiguate different PEBS * events, so only allow one. */ static bool intel_pt_too_many_aux_output(struct evlist *evlist) { struct evsel *evsel; int aux_output_cnt = 0; evlist__for_each_entry(evlist, evsel) aux_output_cnt += !!evsel->core.attr.aux_output; if (aux_output_cnt > 1) { pr_err(INTEL_PT_PMU_NAME " supports at most one event with aux-output\n"); return true; } return false; } static int intel_pt_recording_options(struct auxtrace_record *itr, struct evlist *evlist, struct record_opts *opts) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); struct perf_pmu *intel_pt_pmu = ptr->intel_pt_pmu; bool have_timing_info, need_immediate = false; struct evsel *evsel, *intel_pt_evsel = NULL; const struct perf_cpu_map *cpus = evlist->core.user_requested_cpus; bool privileged = perf_event_paranoid_check(-1); u64 tsc_bit; int err; ptr->evlist = evlist; ptr->snapshot_mode = opts->auxtrace_snapshot_mode; evlist__for_each_entry(evlist, evsel) { if (evsel->core.attr.type == intel_pt_pmu->type) { if (intel_pt_evsel) { pr_err("There may be only one " INTEL_PT_PMU_NAME " event\n"); return -EINVAL; } evsel->core.attr.freq = 0; evsel->core.attr.sample_period = 1; evsel->core.attr.exclude_guest = intel_pt_exclude_guest(); evsel->no_aux_samples = true; evsel->needs_auxtrace_mmap = true; intel_pt_evsel = evsel; opts->full_auxtrace = true; } } if (opts->auxtrace_snapshot_mode && !opts->full_auxtrace) { pr_err("Snapshot mode (-S option) requires " INTEL_PT_PMU_NAME " PMU event (-e " INTEL_PT_PMU_NAME ")\n"); return -EINVAL; } if (opts->auxtrace_snapshot_mode && opts->auxtrace_sample_mode) { pr_err("Snapshot mode (" INTEL_PT_PMU_NAME " PMU) and sample trace cannot be used together\n"); return -EINVAL; } if (opts->use_clockid) { pr_err("Cannot use clockid (-k option) with " INTEL_PT_PMU_NAME "\n"); return -EINVAL; } if (intel_pt_too_many_aux_output(evlist)) return -EINVAL; if (!opts->full_auxtrace) return 0; if (opts->auxtrace_sample_mode) evsel__set_config_if_unset(intel_pt_pmu, intel_pt_evsel, "psb_period", 0); err = intel_pt_validate_config(intel_pt_pmu, intel_pt_evsel); if (err) return err; /* Set default sizes for snapshot mode */ if (opts->auxtrace_snapshot_mode) { size_t psb_period = intel_pt_psb_period(intel_pt_pmu, evlist); if (!opts->auxtrace_snapshot_size && !opts->auxtrace_mmap_pages) { if (privileged) { opts->auxtrace_mmap_pages = MiB(4) / page_size; } else { opts->auxtrace_mmap_pages = KiB(128) / page_size; if (opts->mmap_pages == UINT_MAX) opts->mmap_pages = KiB(256) / page_size; } } else if (!opts->auxtrace_mmap_pages && !privileged && opts->mmap_pages == UINT_MAX) { opts->mmap_pages = KiB(256) / page_size; } if (!opts->auxtrace_snapshot_size) opts->auxtrace_snapshot_size = opts->auxtrace_mmap_pages * (size_t)page_size; if (!opts->auxtrace_mmap_pages) { size_t sz = opts->auxtrace_snapshot_size; sz = round_up(sz, page_size) / page_size; opts->auxtrace_mmap_pages = roundup_pow_of_two(sz); } if (opts->auxtrace_snapshot_size > opts->auxtrace_mmap_pages * (size_t)page_size) { pr_err("Snapshot size %zu must not be greater than AUX area tracing mmap size %zu\n", opts->auxtrace_snapshot_size, opts->auxtrace_mmap_pages * (size_t)page_size); return -EINVAL; } if (!opts->auxtrace_snapshot_size || !opts->auxtrace_mmap_pages) { pr_err("Failed to calculate default snapshot size and/or AUX area tracing mmap pages\n"); return -EINVAL; } pr_debug2("Intel PT snapshot size: %zu\n", opts->auxtrace_snapshot_size); if (psb_period && opts->auxtrace_snapshot_size <= psb_period + INTEL_PT_PSB_PERIOD_NEAR) ui__warning("Intel PT snapshot size (%zu) may be too small for PSB period (%zu)\n", opts->auxtrace_snapshot_size, psb_period); } /* Set default sizes for sample mode */ if (opts->auxtrace_sample_mode) { size_t psb_period = intel_pt_psb_period(intel_pt_pmu, evlist); size_t min_sz = 0, max_sz = 0; intel_pt_min_max_sample_sz(evlist, &min_sz, &max_sz); if (!opts->auxtrace_mmap_pages && !privileged && opts->mmap_pages == UINT_MAX) opts->mmap_pages = KiB(256) / page_size; if (!opts->auxtrace_mmap_pages) { size_t sz = round_up(max_sz, page_size) / page_size; opts->auxtrace_mmap_pages = roundup_pow_of_two(sz); } if (max_sz > opts->auxtrace_mmap_pages * (size_t)page_size) { pr_err("Sample size %zu must not be greater than AUX area tracing mmap size %zu\n", max_sz, opts->auxtrace_mmap_pages * (size_t)page_size); return -EINVAL; } pr_debug2("Intel PT min. sample size: %zu max. sample size: %zu\n", min_sz, max_sz); if (psb_period && min_sz <= psb_period + INTEL_PT_PSB_PERIOD_NEAR) ui__warning("Intel PT sample size (%zu) may be too small for PSB period (%zu)\n", min_sz, psb_period); } /* Set default sizes for full trace mode */ if (opts->full_auxtrace && !opts->auxtrace_mmap_pages) { if (privileged) { opts->auxtrace_mmap_pages = MiB(4) / page_size; } else { opts->auxtrace_mmap_pages = KiB(128) / page_size; if (opts->mmap_pages == UINT_MAX) opts->mmap_pages = KiB(256) / page_size; } } /* Validate auxtrace_mmap_pages */ if (opts->auxtrace_mmap_pages) { size_t sz = opts->auxtrace_mmap_pages * (size_t)page_size; size_t min_sz; if (opts->auxtrace_snapshot_mode || opts->auxtrace_sample_mode) min_sz = KiB(4); else min_sz = KiB(8); if (sz < min_sz || !is_power_of_2(sz)) { pr_err("Invalid mmap size for Intel Processor Trace: must be at least %zuKiB and a power of 2\n", min_sz / 1024); return -EINVAL; } } if (!opts->auxtrace_snapshot_mode && !opts->auxtrace_sample_mode) { size_t aw = opts->auxtrace_mmap_pages * (size_t)page_size / 4; u32 aux_watermark = aw > UINT_MAX ? UINT_MAX : aw; intel_pt_evsel->core.attr.aux_watermark = aux_watermark; } intel_pt_parse_terms(intel_pt_pmu, "tsc", &tsc_bit); if (opts->full_auxtrace && (intel_pt_evsel->core.attr.config & tsc_bit)) have_timing_info = true; else have_timing_info = false; /* * Per-cpu recording needs sched_switch events to distinguish different * threads. */ if (have_timing_info && !perf_cpu_map__is_any_cpu_or_is_empty(cpus) && !record_opts__no_switch_events(opts)) { if (perf_can_record_switch_events()) { bool cpu_wide = !target__none(&opts->target) && !target__has_task(&opts->target); if (!cpu_wide && perf_can_record_cpu_wide()) { struct evsel *switch_evsel; switch_evsel = evlist__add_dummy_on_all_cpus(evlist); if (!switch_evsel) return -ENOMEM; switch_evsel->core.attr.context_switch = 1; switch_evsel->immediate = true; evsel__set_sample_bit(switch_evsel, TID); evsel__set_sample_bit(switch_evsel, TIME); evsel__set_sample_bit(switch_evsel, CPU); evsel__reset_sample_bit(switch_evsel, BRANCH_STACK); opts->record_switch_events = false; ptr->have_sched_switch = 3; } else { opts->record_switch_events = true; need_immediate = true; if (cpu_wide) ptr->have_sched_switch = 3; else ptr->have_sched_switch = 2; } } else { #ifdef HAVE_LIBTRACEEVENT err = intel_pt_track_switches(evlist); if (err == -EPERM) pr_debug2("Unable to select sched:sched_switch\n"); else if (err) return err; else ptr->have_sched_switch = 1; #endif } } if (have_timing_info && !intel_pt_evsel->core.attr.exclude_kernel && perf_can_record_text_poke_events() && perf_can_record_cpu_wide()) opts->text_poke = true; if (intel_pt_evsel) { /* * To obtain the auxtrace buffer file descriptor, the auxtrace * event must come first. */ evlist__to_front(evlist, intel_pt_evsel); /* * In the case of per-cpu mmaps, we need the CPU on the * AUX event. */ if (!perf_cpu_map__is_any_cpu_or_is_empty(cpus)) evsel__set_sample_bit(intel_pt_evsel, CPU); } /* Add dummy event to keep tracking */ if (opts->full_auxtrace) { bool need_system_wide_tracking; struct evsel *tracking_evsel; /* * User space tasks can migrate between CPUs, so when tracing * selected CPUs, sideband for all CPUs is still needed. */ need_system_wide_tracking = opts->target.cpu_list && !intel_pt_evsel->core.attr.exclude_user; tracking_evsel = evlist__add_aux_dummy(evlist, need_system_wide_tracking); if (!tracking_evsel) return -ENOMEM; evlist__set_tracking_event(evlist, tracking_evsel); if (need_immediate) tracking_evsel->immediate = true; /* In per-cpu case, always need the time of mmap events etc */ if (!perf_cpu_map__is_any_cpu_or_is_empty(cpus)) { evsel__set_sample_bit(tracking_evsel, TIME); /* And the CPU for switch events */ evsel__set_sample_bit(tracking_evsel, CPU); } evsel__reset_sample_bit(tracking_evsel, BRANCH_STACK); } /* * Warn the user when we do not have enough information to decode i.e. * per-cpu with no sched_switch (except workload-only). */ if (!ptr->have_sched_switch && !perf_cpu_map__is_any_cpu_or_is_empty(cpus) && !target__none(&opts->target) && !intel_pt_evsel->core.attr.exclude_user) ui__warning("Intel Processor Trace decoding will not be possible except for kernel tracing!\n"); return 0; } static int intel_pt_snapshot_start(struct auxtrace_record *itr) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); struct evsel *evsel; evlist__for_each_entry(ptr->evlist, evsel) { if (evsel->core.attr.type == ptr->intel_pt_pmu->type) return evsel__disable(evsel); } return -EINVAL; } static int intel_pt_snapshot_finish(struct auxtrace_record *itr) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); struct evsel *evsel; evlist__for_each_entry(ptr->evlist, evsel) { if (evsel->core.attr.type == ptr->intel_pt_pmu->type) return evsel__enable(evsel); } return -EINVAL; } static int intel_pt_alloc_snapshot_refs(struct intel_pt_recording *ptr, int idx) { const size_t sz = sizeof(struct intel_pt_snapshot_ref); int cnt = ptr->snapshot_ref_cnt, new_cnt = cnt * 2; struct intel_pt_snapshot_ref *refs; if (!new_cnt) new_cnt = 16; while (new_cnt <= idx) new_cnt *= 2; refs = calloc(new_cnt, sz); if (!refs) return -ENOMEM; memcpy(refs, ptr->snapshot_refs, cnt * sz); ptr->snapshot_refs = refs; ptr->snapshot_ref_cnt = new_cnt; return 0; } static void intel_pt_free_snapshot_refs(struct intel_pt_recording *ptr) { int i; for (i = 0; i < ptr->snapshot_ref_cnt; i++) zfree(&ptr->snapshot_refs[i].ref_buf); zfree(&ptr->snapshot_refs); } static void intel_pt_recording_free(struct auxtrace_record *itr) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); intel_pt_free_snapshot_refs(ptr); free(ptr); } static int intel_pt_alloc_snapshot_ref(struct intel_pt_recording *ptr, int idx, size_t snapshot_buf_size) { size_t ref_buf_size = ptr->snapshot_ref_buf_size; void *ref_buf; ref_buf = zalloc(ref_buf_size); if (!ref_buf) return -ENOMEM; ptr->snapshot_refs[idx].ref_buf = ref_buf; ptr->snapshot_refs[idx].ref_offset = snapshot_buf_size - ref_buf_size; return 0; } static size_t intel_pt_snapshot_ref_buf_size(struct intel_pt_recording *ptr, size_t snapshot_buf_size) { const size_t max_size = 256 * 1024; size_t buf_size = 0, psb_period; if (ptr->snapshot_size <= 64 * 1024) return 0; psb_period = intel_pt_psb_period(ptr->intel_pt_pmu, ptr->evlist); if (psb_period) buf_size = psb_period * 2; if (!buf_size || buf_size > max_size) buf_size = max_size; if (buf_size >= snapshot_buf_size) return 0; if (buf_size >= ptr->snapshot_size / 2) return 0; return buf_size; } static int intel_pt_snapshot_init(struct intel_pt_recording *ptr, size_t snapshot_buf_size) { if (ptr->snapshot_init_done) return 0; ptr->snapshot_init_done = true; ptr->snapshot_ref_buf_size = intel_pt_snapshot_ref_buf_size(ptr, snapshot_buf_size); return 0; } /** * intel_pt_compare_buffers - compare bytes in a buffer to a circular buffer. * @buf1: first buffer * @compare_size: number of bytes to compare * @buf2: second buffer (a circular buffer) * @offs2: offset in second buffer * @buf2_size: size of second buffer * * The comparison allows for the possibility that the bytes to compare in the * circular buffer are not contiguous. It is assumed that @compare_size <= * @buf2_size. This function returns %false if the bytes are identical, %true * otherwise. */ static bool intel_pt_compare_buffers(void *buf1, size_t compare_size, void *buf2, size_t offs2, size_t buf2_size) { size_t end2 = offs2 + compare_size, part_size; if (end2 <= buf2_size) return memcmp(buf1, buf2 + offs2, compare_size); part_size = end2 - buf2_size; if (memcmp(buf1, buf2 + offs2, part_size)) return true; compare_size -= part_size; return memcmp(buf1 + part_size, buf2, compare_size); } static bool intel_pt_compare_ref(void *ref_buf, size_t ref_offset, size_t ref_size, size_t buf_size, void *data, size_t head) { size_t ref_end = ref_offset + ref_size; if (ref_end > buf_size) { if (head > ref_offset || head < ref_end - buf_size) return true; } else if (head > ref_offset && head < ref_end) { return true; } return intel_pt_compare_buffers(ref_buf, ref_size, data, ref_offset, buf_size); } static void intel_pt_copy_ref(void *ref_buf, size_t ref_size, size_t buf_size, void *data, size_t head) { if (head >= ref_size) { memcpy(ref_buf, data + head - ref_size, ref_size); } else { memcpy(ref_buf, data, head); ref_size -= head; memcpy(ref_buf + head, data + buf_size - ref_size, ref_size); } } static bool intel_pt_wrapped(struct intel_pt_recording *ptr, int idx, struct auxtrace_mmap *mm, unsigned char *data, u64 head) { struct intel_pt_snapshot_ref *ref = &ptr->snapshot_refs[idx]; bool wrapped; wrapped = intel_pt_compare_ref(ref->ref_buf, ref->ref_offset, ptr->snapshot_ref_buf_size, mm->len, data, head); intel_pt_copy_ref(ref->ref_buf, ptr->snapshot_ref_buf_size, mm->len, data, head); return wrapped; } static bool intel_pt_first_wrap(u64 *data, size_t buf_size) { int i, a, b; b = buf_size >> 3; a = b - 512; if (a < 0) a = 0; for (i = a; i < b; i++) { if (data[i]) return true; } return false; } static int intel_pt_find_snapshot(struct auxtrace_record *itr, int idx, struct auxtrace_mmap *mm, unsigned char *data, u64 *head, u64 *old) { struct intel_pt_recording *ptr = container_of(itr, struct intel_pt_recording, itr); bool wrapped; int err; pr_debug3("%s: mmap index %d old head %zu new head %zu\n", __func__, idx, (size_t)*old, (size_t)*head); err = intel_pt_snapshot_init(ptr, mm->len); if (err) goto out_err; if (idx >= ptr->snapshot_ref_cnt) { err = intel_pt_alloc_snapshot_refs(ptr, idx); if (err) goto out_err; } if (ptr->snapshot_ref_buf_size) { if (!ptr->snapshot_refs[idx].ref_buf) { err = intel_pt_alloc_snapshot_ref(ptr, idx, mm->len); if (err) goto out_err; } wrapped = intel_pt_wrapped(ptr, idx, mm, data, *head); } else { wrapped = ptr->snapshot_refs[idx].wrapped; if (!wrapped && intel_pt_first_wrap((u64 *)data, mm->len)) { ptr->snapshot_refs[idx].wrapped = true; wrapped = true; } } /* * In full trace mode 'head' continually increases. However in snapshot * mode 'head' is an offset within the buffer. Here 'old' and 'head' * are adjusted to match the full trace case which expects that 'old' is * always less than 'head'. */ if (wrapped) { *old = *head; *head += mm->len; } else { if (mm->mask) *old &= mm->mask; else *old %= mm->len; if (*old > *head) *head += mm->len; } pr_debug3("%s: wrap-around %sdetected, adjusted old head %zu adjusted new head %zu\n", __func__, wrapped ? "" : "not ", (size_t)*old, (size_t)*head); return 0; out_err: pr_err("%s: failed, error %d\n", __func__, err); return err; } static u64 intel_pt_reference(struct auxtrace_record *itr __maybe_unused) { return rdtsc(); } struct auxtrace_record *intel_pt_recording_init(int *err) { struct perf_pmu *intel_pt_pmu = perf_pmus__find(INTEL_PT_PMU_NAME); struct intel_pt_recording *ptr; if (!intel_pt_pmu) return NULL; if (setenv("JITDUMP_USE_ARCH_TIMESTAMP", "1", 1)) { *err = -errno; return NULL; } ptr = zalloc(sizeof(struct intel_pt_recording)); if (!ptr) { *err = -ENOMEM; return NULL; } ptr->intel_pt_pmu = intel_pt_pmu; ptr->itr.pmu = intel_pt_pmu; ptr->itr.recording_options = intel_pt_recording_options; ptr->itr.info_priv_size = intel_pt_info_priv_size; ptr->itr.info_fill = intel_pt_info_fill; ptr->itr.free = intel_pt_recording_free; ptr->itr.snapshot_start = intel_pt_snapshot_start; ptr->itr.snapshot_finish = intel_pt_snapshot_finish; ptr->itr.find_snapshot = intel_pt_find_snapshot; ptr->itr.parse_snapshot_options = intel_pt_parse_snapshot_options; ptr->itr.reference = intel_pt_reference; ptr->itr.read_finish = auxtrace_record__read_finish; /* * Decoding starts at a PSB packet. Minimum PSB period is 2K so 4K * should give at least 1 PSB per sample. */ ptr->itr.default_aux_sample_size = 4096; return &ptr->itr; }
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