blob: 38942e1eac8f53678948d8ed16bea8b7844fb824 [file] [log] [blame]
/*
* intel_pt.c: Intel Processor Trace support
* Copyright (c) 2013-2015, Intel Corporation.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
*/
#include <stdio.h>
#include <stdbool.h>
#include <errno.h>
#include <linux/kernel.h>
#include <linux/types.h>
#include "../perf.h"
#include "session.h"
#include "machine.h"
#include "tool.h"
#include "event.h"
#include "evlist.h"
#include "evsel.h"
#include "map.h"
#include "color.h"
#include "util.h"
#include "thread.h"
#include "thread-stack.h"
#include "symbol.h"
#include "callchain.h"
#include "dso.h"
#include "debug.h"
#include "auxtrace.h"
#include "tsc.h"
#include "intel-pt.h"
#include "intel-pt-decoder/intel-pt-log.h"
#include "intel-pt-decoder/intel-pt-decoder.h"
#include "intel-pt-decoder/intel-pt-insn-decoder.h"
#include "intel-pt-decoder/intel-pt-pkt-decoder.h"
#define MAX_TIMESTAMP (~0ULL)
struct intel_pt {
struct auxtrace auxtrace;
struct auxtrace_queues queues;
struct auxtrace_heap heap;
u32 auxtrace_type;
struct perf_session *session;
struct machine *machine;
struct perf_evsel *switch_evsel;
struct thread *unknown_thread;
bool timeless_decoding;
bool sampling_mode;
bool snapshot_mode;
bool per_cpu_mmaps;
bool have_tsc;
bool data_queued;
bool est_tsc;
bool sync_switch;
int have_sched_switch;
u32 pmu_type;
u64 kernel_start;
u64 switch_ip;
u64 ptss_ip;
struct perf_tsc_conversion tc;
bool cap_user_time_zero;
struct itrace_synth_opts synth_opts;
bool sample_instructions;
u64 instructions_sample_type;
u64 instructions_sample_period;
u64 instructions_id;
bool sample_branches;
u32 branches_filter;
u64 branches_sample_type;
u64 branches_id;
bool sample_transactions;
u64 transactions_sample_type;
u64 transactions_id;
bool synth_needs_swap;
u64 tsc_bit;
u64 mtc_bit;
u64 mtc_freq_bits;
u32 tsc_ctc_ratio_n;
u32 tsc_ctc_ratio_d;
u64 cyc_bit;
u64 noretcomp_bit;
unsigned max_non_turbo_ratio;
};
enum switch_state {
INTEL_PT_SS_NOT_TRACING,
INTEL_PT_SS_UNKNOWN,
INTEL_PT_SS_TRACING,
INTEL_PT_SS_EXPECTING_SWITCH_EVENT,
INTEL_PT_SS_EXPECTING_SWITCH_IP,
};
struct intel_pt_queue {
struct intel_pt *pt;
unsigned int queue_nr;
struct auxtrace_buffer *buffer;
void *decoder;
const struct intel_pt_state *state;
struct ip_callchain *chain;
union perf_event *event_buf;
bool on_heap;
bool stop;
bool step_through_buffers;
bool use_buffer_pid_tid;
pid_t pid, tid;
int cpu;
int switch_state;
pid_t next_tid;
struct thread *thread;
bool exclude_kernel;
bool have_sample;
u64 time;
u64 timestamp;
u32 flags;
u16 insn_len;
u64 last_insn_cnt;
};
static void intel_pt_dump(struct intel_pt *pt __maybe_unused,
unsigned char *buf, size_t len)
{
struct intel_pt_pkt packet;
size_t pos = 0;
int ret, pkt_len, i;
char desc[INTEL_PT_PKT_DESC_MAX];
const char *color = PERF_COLOR_BLUE;
color_fprintf(stdout, color,
". ... Intel Processor Trace data: size %zu bytes\n",
len);
while (len) {
ret = intel_pt_get_packet(buf, len, &packet);
if (ret > 0)
pkt_len = ret;
else
pkt_len = 1;
printf(".");
color_fprintf(stdout, color, " %08x: ", pos);
for (i = 0; i < pkt_len; i++)
color_fprintf(stdout, color, " %02x", buf[i]);
for (; i < 16; i++)
color_fprintf(stdout, color, " ");
if (ret > 0) {
ret = intel_pt_pkt_desc(&packet, desc,
INTEL_PT_PKT_DESC_MAX);
if (ret > 0)
color_fprintf(stdout, color, " %s\n", desc);
} else {
color_fprintf(stdout, color, " Bad packet!\n");
}
pos += pkt_len;
buf += pkt_len;
len -= pkt_len;
}
}
static void intel_pt_dump_event(struct intel_pt *pt, unsigned char *buf,
size_t len)
{
printf(".\n");
intel_pt_dump(pt, buf, len);
}
static int intel_pt_do_fix_overlap(struct intel_pt *pt, struct auxtrace_buffer *a,
struct auxtrace_buffer *b)
{
void *start;
start = intel_pt_find_overlap(a->data, a->size, b->data, b->size,
pt->have_tsc);
if (!start)
return -EINVAL;
b->use_size = b->data + b->size - start;
b->use_data = start;
return 0;
}
static void intel_pt_use_buffer_pid_tid(struct intel_pt_queue *ptq,
struct auxtrace_queue *queue,
struct auxtrace_buffer *buffer)
{
if (queue->cpu == -1 && buffer->cpu != -1)
ptq->cpu = buffer->cpu;
ptq->pid = buffer->pid;
ptq->tid = buffer->tid;
intel_pt_log("queue %u cpu %d pid %d tid %d\n",
ptq->queue_nr, ptq->cpu, ptq->pid, ptq->tid);
thread__zput(ptq->thread);
if (ptq->tid != -1) {
if (ptq->pid != -1)
ptq->thread = machine__findnew_thread(ptq->pt->machine,
ptq->pid,
ptq->tid);
else
ptq->thread = machine__find_thread(ptq->pt->machine, -1,
ptq->tid);
}
}
/* This function assumes data is processed sequentially only */
static int intel_pt_get_trace(struct intel_pt_buffer *b, void *data)
{
struct intel_pt_queue *ptq = data;
struct auxtrace_buffer *buffer = ptq->buffer, *old_buffer = buffer;
struct auxtrace_queue *queue;
if (ptq->stop) {
b->len = 0;
return 0;
}
queue = &ptq->pt->queues.queue_array[ptq->queue_nr];
buffer = auxtrace_buffer__next(queue, buffer);
if (!buffer) {
if (old_buffer)
auxtrace_buffer__drop_data(old_buffer);
b->len = 0;
return 0;
}
ptq->buffer = buffer;
if (!buffer->data) {
int fd = perf_data_file__fd(ptq->pt->session->file);
buffer->data = auxtrace_buffer__get_data(buffer, fd);
if (!buffer->data)
return -ENOMEM;
}
if (ptq->pt->snapshot_mode && !buffer->consecutive && old_buffer &&
intel_pt_do_fix_overlap(ptq->pt, old_buffer, buffer))
return -ENOMEM;
if (old_buffer)
auxtrace_buffer__drop_data(old_buffer);
if (buffer->use_data) {
b->len = buffer->use_size;
b->buf = buffer->use_data;
} else {
b->len = buffer->size;
b->buf = buffer->data;
}
b->ref_timestamp = buffer->reference;
if (!old_buffer || ptq->pt->sampling_mode || (ptq->pt->snapshot_mode &&
!buffer->consecutive)) {
b->consecutive = false;
b->trace_nr = buffer->buffer_nr + 1;
} else {
b->consecutive = true;
}
if (ptq->use_buffer_pid_tid && (ptq->pid != buffer->pid ||
ptq->tid != buffer->tid))
intel_pt_use_buffer_pid_tid(ptq, queue, buffer);
if (ptq->step_through_buffers)
ptq->stop = true;
if (!b->len)
return intel_pt_get_trace(b, data);
return 0;
}
struct intel_pt_cache_entry {
struct auxtrace_cache_entry entry;
u64 insn_cnt;
u64 byte_cnt;
enum intel_pt_insn_op op;
enum intel_pt_insn_branch branch;
int length;
int32_t rel;
};
static int intel_pt_config_div(const char *var, const char *value, void *data)
{
int *d = data;
long val;
if (!strcmp(var, "intel-pt.cache-divisor")) {
val = strtol(value, NULL, 0);
if (val > 0 && val <= INT_MAX)
*d = val;
}
return 0;
}
static int intel_pt_cache_divisor(void)
{
static int d;
if (d)
return d;
perf_config(intel_pt_config_div, &d);
if (!d)
d = 64;
return d;
}
static unsigned int intel_pt_cache_size(struct dso *dso,
struct machine *machine)
{
off_t size;
size = dso__data_size(dso, machine);
size /= intel_pt_cache_divisor();
if (size < 1000)
return 10;
if (size > (1 << 21))
return 21;
return 32 - __builtin_clz(size);
}
static struct auxtrace_cache *intel_pt_cache(struct dso *dso,
struct machine *machine)
{
struct auxtrace_cache *c;
unsigned int bits;
if (dso->auxtrace_cache)
return dso->auxtrace_cache;
bits = intel_pt_cache_size(dso, machine);
/* Ignoring cache creation failure */
c = auxtrace_cache__new(bits, sizeof(struct intel_pt_cache_entry), 200);
dso->auxtrace_cache = c;
return c;
}
static int intel_pt_cache_add(struct dso *dso, struct machine *machine,
u64 offset, u64 insn_cnt, u64 byte_cnt,
struct intel_pt_insn *intel_pt_insn)
{
struct auxtrace_cache *c = intel_pt_cache(dso, machine);
struct intel_pt_cache_entry *e;
int err;
if (!c)
return -ENOMEM;
e = auxtrace_cache__alloc_entry(c);
if (!e)
return -ENOMEM;
e->insn_cnt = insn_cnt;
e->byte_cnt = byte_cnt;
e->op = intel_pt_insn->op;
e->branch = intel_pt_insn->branch;
e->length = intel_pt_insn->length;
e->rel = intel_pt_insn->rel;
err = auxtrace_cache__add(c, offset, &e->entry);
if (err)
auxtrace_cache__free_entry(c, e);
return err;
}
static struct intel_pt_cache_entry *
intel_pt_cache_lookup(struct dso *dso, struct machine *machine, u64 offset)
{
struct auxtrace_cache *c = intel_pt_cache(dso, machine);
if (!c)
return NULL;
return auxtrace_cache__lookup(dso->auxtrace_cache, offset);
}
static int intel_pt_walk_next_insn(struct intel_pt_insn *intel_pt_insn,
uint64_t *insn_cnt_ptr, uint64_t *ip,
uint64_t to_ip, uint64_t max_insn_cnt,
void *data)
{
struct intel_pt_queue *ptq = data;
struct machine *machine = ptq->pt->machine;
struct thread *thread;
struct addr_location al;
unsigned char buf[1024];
size_t bufsz;
ssize_t len;
int x86_64;
u8 cpumode;
u64 offset, start_offset, start_ip;
u64 insn_cnt = 0;
bool one_map = true;
if (to_ip && *ip == to_ip)
goto out_no_cache;
bufsz = intel_pt_insn_max_size();
if (*ip >= ptq->pt->kernel_start)
cpumode = PERF_RECORD_MISC_KERNEL;
else
cpumode = PERF_RECORD_MISC_USER;
thread = ptq->thread;
if (!thread) {
if (cpumode != PERF_RECORD_MISC_KERNEL)
return -EINVAL;
thread = ptq->pt->unknown_thread;
}
while (1) {
thread__find_addr_map(thread, cpumode, MAP__FUNCTION, *ip, &al);
if (!al.map || !al.map->dso)
return -EINVAL;
if (al.map->dso->data.status == DSO_DATA_STATUS_ERROR &&
dso__data_status_seen(al.map->dso,
DSO_DATA_STATUS_SEEN_ITRACE))
return -ENOENT;
offset = al.map->map_ip(al.map, *ip);
if (!to_ip && one_map) {
struct intel_pt_cache_entry *e;
e = intel_pt_cache_lookup(al.map->dso, machine, offset);
if (e &&
(!max_insn_cnt || e->insn_cnt <= max_insn_cnt)) {
*insn_cnt_ptr = e->insn_cnt;
*ip += e->byte_cnt;
intel_pt_insn->op = e->op;
intel_pt_insn->branch = e->branch;
intel_pt_insn->length = e->length;
intel_pt_insn->rel = e->rel;
intel_pt_log_insn_no_data(intel_pt_insn, *ip);
return 0;
}
}
start_offset = offset;
start_ip = *ip;
/* Load maps to ensure dso->is_64_bit has been updated */
map__load(al.map, machine->symbol_filter);
x86_64 = al.map->dso->is_64_bit;
while (1) {
len = dso__data_read_offset(al.map->dso, machine,
offset, buf, bufsz);
if (len <= 0)
return -EINVAL;
if (intel_pt_get_insn(buf, len, x86_64, intel_pt_insn))
return -EINVAL;
intel_pt_log_insn(intel_pt_insn, *ip);
insn_cnt += 1;
if (intel_pt_insn->branch != INTEL_PT_BR_NO_BRANCH)
goto out;
if (max_insn_cnt && insn_cnt >= max_insn_cnt)
goto out_no_cache;
*ip += intel_pt_insn->length;
if (to_ip && *ip == to_ip)
goto out_no_cache;
if (*ip >= al.map->end)
break;
offset += intel_pt_insn->length;
}
one_map = false;
}
out:
*insn_cnt_ptr = insn_cnt;
if (!one_map)
goto out_no_cache;
/*
* Didn't lookup in the 'to_ip' case, so do it now to prevent duplicate
* entries.
*/
if (to_ip) {
struct intel_pt_cache_entry *e;
e = intel_pt_cache_lookup(al.map->dso, machine, start_offset);
if (e)
return 0;
}
/* Ignore cache errors */
intel_pt_cache_add(al.map->dso, machine, start_offset, insn_cnt,
*ip - start_ip, intel_pt_insn);
return 0;
out_no_cache:
*insn_cnt_ptr = insn_cnt;
return 0;
}
static bool intel_pt_get_config(struct intel_pt *pt,
struct perf_event_attr *attr, u64 *config)
{
if (attr->type == pt->pmu_type) {
if (config)
*config = attr->config;
return true;
}
return false;
}
static bool intel_pt_exclude_kernel(struct intel_pt *pt)
{
struct perf_evsel *evsel;
evlist__for_each(pt->session->evlist, evsel) {
if (intel_pt_get_config(pt, &evsel->attr, NULL) &&
!evsel->attr.exclude_kernel)
return false;
}
return true;
}
static bool intel_pt_return_compression(struct intel_pt *pt)
{
struct perf_evsel *evsel;
u64 config;
if (!pt->noretcomp_bit)
return true;
evlist__for_each(pt->session->evlist, evsel) {
if (intel_pt_get_config(pt, &evsel->attr, &config) &&
(config & pt->noretcomp_bit))
return false;
}
return true;
}
static unsigned int intel_pt_mtc_period(struct intel_pt *pt)
{
struct perf_evsel *evsel;
unsigned int shift;
u64 config;
if (!pt->mtc_freq_bits)
return 0;
for (shift = 0, config = pt->mtc_freq_bits; !(config & 1); shift++)
config >>= 1;
evlist__for_each(pt->session->evlist, evsel) {
if (intel_pt_get_config(pt, &evsel->attr, &config))
return (config & pt->mtc_freq_bits) >> shift;
}
return 0;
}
static bool intel_pt_timeless_decoding(struct intel_pt *pt)
{
struct perf_evsel *evsel;
bool timeless_decoding = true;
u64 config;
if (!pt->tsc_bit || !pt->cap_user_time_zero)
return true;
evlist__for_each(pt->session->evlist, evsel) {
if (!(evsel->attr.sample_type & PERF_SAMPLE_TIME))
return true;
if (intel_pt_get_config(pt, &evsel->attr, &config)) {
if (config & pt->tsc_bit)
timeless_decoding = false;
else
return true;
}
}
return timeless_decoding;
}
static bool intel_pt_tracing_kernel(struct intel_pt *pt)
{
struct perf_evsel *evsel;
evlist__for_each(pt->session->evlist, evsel) {
if (intel_pt_get_config(pt, &evsel->attr, NULL) &&
!evsel->attr.exclude_kernel)
return true;
}
return false;
}
static bool intel_pt_have_tsc(struct intel_pt *pt)
{
struct perf_evsel *evsel;
bool have_tsc = false;
u64 config;
if (!pt->tsc_bit)
return false;
evlist__for_each(pt->session->evlist, evsel) {
if (intel_pt_get_config(pt, &evsel->attr, &config)) {
if (config & pt->tsc_bit)
have_tsc = true;
else
return false;
}
}
return have_tsc;
}
static u64 intel_pt_ns_to_ticks(const struct intel_pt *pt, u64 ns)
{
u64 quot, rem;
quot = ns / pt->tc.time_mult;
rem = ns % pt->tc.time_mult;
return (quot << pt->tc.time_shift) + (rem << pt->tc.time_shift) /
pt->tc.time_mult;
}
static struct intel_pt_queue *intel_pt_alloc_queue(struct intel_pt *pt,
unsigned int queue_nr)
{
struct intel_pt_params params = { .get_trace = 0, };
struct intel_pt_queue *ptq;
ptq = zalloc(sizeof(struct intel_pt_queue));
if (!ptq)
return NULL;
if (pt->synth_opts.callchain) {
size_t sz = sizeof(struct ip_callchain);
sz += pt->synth_opts.callchain_sz * sizeof(u64);
ptq->chain = zalloc(sz);
if (!ptq->chain)
goto out_free;
}
ptq->event_buf = malloc(PERF_SAMPLE_MAX_SIZE);
if (!ptq->event_buf)
goto out_free;
ptq->pt = pt;
ptq->queue_nr = queue_nr;
ptq->exclude_kernel = intel_pt_exclude_kernel(pt);
ptq->pid = -1;
ptq->tid = -1;
ptq->cpu = -1;
ptq->next_tid = -1;
params.get_trace = intel_pt_get_trace;
params.walk_insn = intel_pt_walk_next_insn;
params.data = ptq;
params.return_compression = intel_pt_return_compression(pt);
params.max_non_turbo_ratio = pt->max_non_turbo_ratio;
params.mtc_period = intel_pt_mtc_period(pt);
params.tsc_ctc_ratio_n = pt->tsc_ctc_ratio_n;
params.tsc_ctc_ratio_d = pt->tsc_ctc_ratio_d;
if (pt->synth_opts.instructions) {
if (pt->synth_opts.period) {
switch (pt->synth_opts.period_type) {
case PERF_ITRACE_PERIOD_INSTRUCTIONS:
params.period_type =
INTEL_PT_PERIOD_INSTRUCTIONS;
params.period = pt->synth_opts.period;
break;
case PERF_ITRACE_PERIOD_TICKS:
params.period_type = INTEL_PT_PERIOD_TICKS;
params.period = pt->synth_opts.period;
break;
case PERF_ITRACE_PERIOD_NANOSECS:
params.period_type = INTEL_PT_PERIOD_TICKS;
params.period = intel_pt_ns_to_ticks(pt,
pt->synth_opts.period);
break;
default:
break;
}
}
if (!params.period) {
params.period_type = INTEL_PT_PERIOD_INSTRUCTIONS;
params.period = 1000;
}
}
ptq->decoder = intel_pt_decoder_new(&params);
if (!ptq->decoder)
goto out_free;
return ptq;
out_free:
zfree(&ptq->event_buf);
zfree(&ptq->chain);
free(ptq);
return NULL;
}
static void intel_pt_free_queue(void *priv)
{
struct intel_pt_queue *ptq = priv;
if (!ptq)
return;
thread__zput(ptq->thread);
intel_pt_decoder_free(ptq->decoder);
zfree(&ptq->event_buf);
zfree(&ptq->chain);
free(ptq);
}
static void intel_pt_set_pid_tid_cpu(struct intel_pt *pt,
struct auxtrace_queue *queue)
{
struct intel_pt_queue *ptq = queue->priv;
if (queue->tid == -1 || pt->have_sched_switch) {
ptq->tid = machine__get_current_tid(pt->machine, ptq->cpu);
thread__zput(ptq->thread);
}
if (!ptq->thread && ptq->tid != -1)
ptq->thread = machine__find_thread(pt->machine, -1, ptq->tid);
if (ptq->thread) {
ptq->pid = ptq->thread->pid_;
if (queue->cpu == -1)
ptq->cpu = ptq->thread->cpu;
}
}
static void intel_pt_sample_flags(struct intel_pt_queue *ptq)
{
if (ptq->state->flags & INTEL_PT_ABORT_TX) {
ptq->flags = PERF_IP_FLAG_BRANCH | PERF_IP_FLAG_TX_ABORT;
} else if (ptq->state->flags & INTEL_PT_ASYNC) {
if (ptq->state->to_ip)
ptq->flags = PERF_IP_FLAG_BRANCH | PERF_IP_FLAG_CALL |
PERF_IP_FLAG_ASYNC |
PERF_IP_FLAG_INTERRUPT;
else
ptq->flags = PERF_IP_FLAG_BRANCH |
PERF_IP_FLAG_TRACE_END;
ptq->insn_len = 0;
} else {
if (ptq->state->from_ip)
ptq->flags = intel_pt_insn_type(ptq->state->insn_op);
else
ptq->flags = PERF_IP_FLAG_BRANCH |
PERF_IP_FLAG_TRACE_BEGIN;
if (ptq->state->flags & INTEL_PT_IN_TX)
ptq->flags |= PERF_IP_FLAG_IN_TX;
ptq->insn_len = ptq->state->insn_len;
}
}
static int intel_pt_setup_queue(struct intel_pt *pt,
struct auxtrace_queue *queue,
unsigned int queue_nr)
{
struct intel_pt_queue *ptq = queue->priv;
if (list_empty(&queue->head))
return 0;
if (!ptq) {
ptq = intel_pt_alloc_queue(pt, queue_nr);
if (!ptq)
return -ENOMEM;
queue->priv = ptq;
if (queue->cpu != -1)
ptq->cpu = queue->cpu;
ptq->tid = queue->tid;
if (pt->sampling_mode) {
if (pt->timeless_decoding)
ptq->step_through_buffers = true;
if (pt->timeless_decoding || !pt->have_sched_switch)
ptq->use_buffer_pid_tid = true;
}
}
if (!ptq->on_heap &&
(!pt->sync_switch ||
ptq->switch_state != INTEL_PT_SS_EXPECTING_SWITCH_EVENT)) {
const struct intel_pt_state *state;
int ret;
if (pt->timeless_decoding)
return 0;
intel_pt_log("queue %u getting timestamp\n", queue_nr);
intel_pt_log("queue %u decoding cpu %d pid %d tid %d\n",
queue_nr, ptq->cpu, ptq->pid, ptq->tid);
while (1) {
state = intel_pt_decode(ptq->decoder);
if (state->err) {
if (state->err == INTEL_PT_ERR_NODATA) {
intel_pt_log("queue %u has no timestamp\n",
queue_nr);
return 0;
}
continue;
}
if (state->timestamp)
break;
}
ptq->timestamp = state->timestamp;
intel_pt_log("queue %u timestamp 0x%" PRIx64 "\n",
queue_nr, ptq->timestamp);
ptq->state = state;
ptq->have_sample = true;
intel_pt_sample_flags(ptq);
ret = auxtrace_heap__add(&pt->heap, queue_nr, ptq->timestamp);
if (ret)
return ret;
ptq->on_heap = true;
}
return 0;
}
static int intel_pt_setup_queues(struct intel_pt *pt)
{
unsigned int i;
int ret;
for (i = 0; i < pt->queues.nr_queues; i++) {
ret = intel_pt_setup_queue(pt, &pt->queues.queue_array[i], i);
if (ret)
return ret;
}
return 0;
}
static int intel_pt_inject_event(union perf_event *event,
struct perf_sample *sample, u64 type,
bool swapped)
{
event->header.size = perf_event__sample_event_size(sample, type, 0);
return perf_event__synthesize_sample(event, type, 0, sample, swapped);
}
static int intel_pt_synth_branch_sample(struct intel_pt_queue *ptq)
{
int ret;
struct intel_pt *pt = ptq->pt;
union perf_event *event = ptq->event_buf;
struct perf_sample sample = { .ip = 0, };
event->sample.header.type = PERF_RECORD_SAMPLE;
event->sample.header.misc = PERF_RECORD_MISC_USER;
event->sample.header.size = sizeof(struct perf_event_header);
if (!pt->timeless_decoding)
sample.time = tsc_to_perf_time(ptq->timestamp, &pt->tc);
sample.ip = ptq->state->from_ip;
sample.pid = ptq->pid;
sample.tid = ptq->tid;
sample.addr = ptq->state->to_ip;
sample.id = ptq->pt->branches_id;
sample.stream_id = ptq->pt->branches_id;
sample.period = 1;
sample.cpu = ptq->cpu;
sample.flags = ptq->flags;
sample.insn_len = ptq->insn_len;
if (pt->branches_filter && !(pt->branches_filter & ptq->flags))
return 0;
if (pt->synth_opts.inject) {
ret = intel_pt_inject_event(event, &sample,
pt->branches_sample_type,
pt->synth_needs_swap);
if (ret)
return ret;
}
ret = perf_session__deliver_synth_event(pt->session, event, &sample);
if (ret)
pr_err("Intel Processor Trace: failed to deliver branch event, error %d\n",
ret);
return ret;
}
static int intel_pt_synth_instruction_sample(struct intel_pt_queue *ptq)
{
int ret;
struct intel_pt *pt = ptq->pt;
union perf_event *event = ptq->event_buf;
struct perf_sample sample = { .ip = 0, };
event->sample.header.type = PERF_RECORD_SAMPLE;
event->sample.header.misc = PERF_RECORD_MISC_USER;
event->sample.header.size = sizeof(struct perf_event_header);
if (!pt->timeless_decoding)
sample.time = tsc_to_perf_time(ptq->timestamp, &pt->tc);
sample.ip = ptq->state->from_ip;
sample.pid = ptq->pid;
sample.tid = ptq->tid;
sample.addr = ptq->state->to_ip;
sample.id = ptq->pt->instructions_id;
sample.stream_id = ptq->pt->instructions_id;
sample.period = ptq->state->tot_insn_cnt - ptq->last_insn_cnt;
sample.cpu = ptq->cpu;
sample.flags = ptq->flags;
sample.insn_len = ptq->insn_len;
ptq->last_insn_cnt = ptq->state->tot_insn_cnt;
if (pt->synth_opts.callchain) {
thread_stack__sample(ptq->thread, ptq->chain,
pt->synth_opts.callchain_sz, sample.ip);
sample.callchain = ptq->chain;
}
if (pt->synth_opts.inject) {
ret = intel_pt_inject_event(event, &sample,
pt->instructions_sample_type,
pt->synth_needs_swap);
if (ret)
return ret;
}
ret = perf_session__deliver_synth_event(pt->session, event, &sample);
if (ret)
pr_err("Intel Processor Trace: failed to deliver instruction event, error %d\n",
ret);
return ret;
}
static int intel_pt_synth_transaction_sample(struct intel_pt_queue *ptq)
{
int ret;
struct intel_pt *pt = ptq->pt;
union perf_event *event = ptq->event_buf;
struct perf_sample sample = { .ip = 0, };
event->sample.header.type = PERF_RECORD_SAMPLE;
event->sample.header.misc = PERF_RECORD_MISC_USER;
event->sample.header.size = sizeof(struct perf_event_header);
if (!pt->timeless_decoding)
sample.time = tsc_to_perf_time(ptq->timestamp, &pt->tc);
sample.ip = ptq->state->from_ip;
sample.pid = ptq->pid;
sample.tid = ptq->tid;
sample.addr = ptq->state->to_ip;
sample.id = ptq->pt->transactions_id;
sample.stream_id = ptq->pt->transactions_id;
sample.period = 1;
sample.cpu = ptq->cpu;
sample.flags = ptq->flags;
sample.insn_len = ptq->insn_len;
if (pt->synth_opts.callchain) {
thread_stack__sample(ptq->thread, ptq->chain,
pt->synth_opts.callchain_sz, sample.ip);
sample.callchain = ptq->chain;
}
if (pt->synth_opts.inject) {
ret = intel_pt_inject_event(event, &sample,
pt->transactions_sample_type,
pt->synth_needs_swap);
if (ret)
return ret;
}
ret = perf_session__deliver_synth_event(pt->session, event, &sample);
if (ret)
pr_err("Intel Processor Trace: failed to deliver transaction event, error %d\n",
ret);
return ret;
}
static int intel_pt_synth_error(struct intel_pt *pt, int code, int cpu,
pid_t pid, pid_t tid, u64 ip)
{
union perf_event event;
char msg[MAX_AUXTRACE_ERROR_MSG];
int err;
intel_pt__strerror(code, msg, MAX_AUXTRACE_ERROR_MSG);
auxtrace_synth_error(&event.auxtrace_error, PERF_AUXTRACE_ERROR_ITRACE,
code, cpu, pid, tid, ip, msg);
err = perf_session__deliver_synth_event(pt->session, &event, NULL);
if (err)
pr_err("Intel Processor Trace: failed to deliver error event, error %d\n",
err);
return err;
}
static int intel_pt_next_tid(struct intel_pt *pt, struct intel_pt_queue *ptq)
{
struct auxtrace_queue *queue;
pid_t tid = ptq->next_tid;
int err;
if (tid == -1)
return 0;
intel_pt_log("switch: cpu %d tid %d\n", ptq->cpu, tid);
err = machine__set_current_tid(pt->machine, ptq->cpu, -1, tid);
queue = &pt->queues.queue_array[ptq->queue_nr];
intel_pt_set_pid_tid_cpu(pt, queue);
ptq->next_tid = -1;
return err;
}
static inline bool intel_pt_is_switch_ip(struct intel_pt_queue *ptq, u64 ip)
{
struct intel_pt *pt = ptq->pt;
return ip == pt->switch_ip &&
(ptq->flags & PERF_IP_FLAG_BRANCH) &&
!(ptq->flags & (PERF_IP_FLAG_CONDITIONAL | PERF_IP_FLAG_ASYNC |
PERF_IP_FLAG_INTERRUPT | PERF_IP_FLAG_TX_ABORT));
}
static int intel_pt_sample(struct intel_pt_queue *ptq)
{
const struct intel_pt_state *state = ptq->state;
struct intel_pt *pt = ptq->pt;
int err;
if (!ptq->have_sample)
return 0;
ptq->have_sample = false;
if (pt->sample_instructions &&
(state->type & INTEL_PT_INSTRUCTION)) {
err = intel_pt_synth_instruction_sample(ptq);
if (err)
return err;
}
if (pt->sample_transactions &&
(state->type & INTEL_PT_TRANSACTION)) {
err = intel_pt_synth_transaction_sample(ptq);
if (err)
return err;
}
if (!(state->type & INTEL_PT_BRANCH))
return 0;
if (pt->synth_opts.callchain)
thread_stack__event(ptq->thread, ptq->flags, state->from_ip,
state->to_ip, ptq->insn_len,
state->trace_nr);
else
thread_stack__set_trace_nr(ptq->thread, state->trace_nr);
if (pt->sample_branches) {
err = intel_pt_synth_branch_sample(ptq);
if (err)
return err;
}
if (!pt->sync_switch)
return 0;
if (intel_pt_is_switch_ip(ptq, state->to_ip)) {
switch (ptq->switch_state) {
case INTEL_PT_SS_UNKNOWN:
case INTEL_PT_SS_EXPECTING_SWITCH_IP:
err = intel_pt_next_tid(pt, ptq);
if (err)
return err;
ptq->switch_state = INTEL_PT_SS_TRACING;
break;
default:
ptq->switch_state = INTEL_PT_SS_EXPECTING_SWITCH_EVENT;
return 1;
}
} else if (!state->to_ip) {
ptq->switch_state = INTEL_PT_SS_NOT_TRACING;
} else if (ptq->switch_state == INTEL_PT_SS_NOT_TRACING) {
ptq->switch_state = INTEL_PT_SS_UNKNOWN;
} else if (ptq->switch_state == INTEL_PT_SS_UNKNOWN &&
state->to_ip == pt->ptss_ip &&
(ptq->flags & PERF_IP_FLAG_CALL)) {
ptq->switch_state = INTEL_PT_SS_TRACING;
}
return 0;
}
static u64 intel_pt_switch_ip(struct intel_pt *pt, u64 *ptss_ip)
{
struct machine *machine = pt->machine;
struct map *map;
struct symbol *sym, *start;
u64 ip, switch_ip = 0;
const char *ptss;
if (ptss_ip)
*ptss_ip = 0;
map = machine__kernel_map(machine, MAP__FUNCTION);
if (!map)
return 0;
if (map__load(map, machine->symbol_filter))
return 0;
start = dso__first_symbol(map->dso, MAP__FUNCTION);
for (sym = start; sym; sym = dso__next_symbol(sym)) {
if (sym->binding == STB_GLOBAL &&
!strcmp(sym->name, "__switch_to")) {
ip = map->unmap_ip(map, sym->start);
if (ip >= map->start && ip < map->end) {
switch_ip = ip;
break;
}
}
}
if (!switch_ip || !ptss_ip)
return 0;
if (pt->have_sched_switch == 1)
ptss = "perf_trace_sched_switch";
else
ptss = "__perf_event_task_sched_out";
for (sym = start; sym; sym = dso__next_symbol(sym)) {
if (!strcmp(sym->name, ptss)) {
ip = map->unmap_ip(map, sym->start);
if (ip >= map->start && ip < map->end) {
*ptss_ip = ip;
break;
}
}
}
return switch_ip;
}
static int intel_pt_run_decoder(struct intel_pt_queue *ptq, u64 *timestamp)
{
const struct intel_pt_state *state = ptq->state;
struct intel_pt *pt = ptq->pt;
int err;
if (!pt->kernel_start) {
pt->kernel_start = machine__kernel_start(pt->machine);
if (pt->per_cpu_mmaps &&
(pt->have_sched_switch == 1 || pt->have_sched_switch == 3) &&
!pt->timeless_decoding && intel_pt_tracing_kernel(pt) &&
!pt->sampling_mode) {
pt->switch_ip = intel_pt_switch_ip(pt, &pt->ptss_ip);
if (pt->switch_ip) {
intel_pt_log("switch_ip: %"PRIx64" ptss_ip: %"PRIx64"\n",
pt->switch_ip, pt->ptss_ip);
pt->sync_switch = true;
}
}
}
intel_pt_log("queue %u decoding cpu %d pid %d tid %d\n",
ptq->queue_nr, ptq->cpu, ptq->pid, ptq->tid);
while (1) {
err = intel_pt_sample(ptq);
if (err)
return err;
state = intel_pt_decode(ptq->decoder);
if (state->err) {
if (state->err == INTEL_PT_ERR_NODATA)
return 1;
if (pt->sync_switch &&
state->from_ip >= pt->kernel_start) {
pt->sync_switch = false;
intel_pt_next_tid(pt, ptq);
}
if (pt->synth_opts.errors) {
err = intel_pt_synth_error(pt, state->err,
ptq->cpu, ptq->pid,
ptq->tid,
state->from_ip);
if (err)
return err;
}
continue;
}
ptq->state = state;
ptq->have_sample = true;
intel_pt_sample_flags(ptq);
/* Use estimated TSC upon return to user space */
if (pt->est_tsc &&
(state->from_ip >= pt->kernel_start || !state->from_ip) &&
state->to_ip && state->to_ip < pt->kernel_start) {
intel_pt_log("TSC %"PRIx64" est. TSC %"PRIx64"\n",
state->timestamp, state->est_timestamp);
ptq->timestamp = state->est_timestamp;
/* Use estimated TSC in unknown switch state */
} else if (pt->sync_switch &&
ptq->switch_state == INTEL_PT_SS_UNKNOWN &&
intel_pt_is_switch_ip(ptq, state->to_ip) &&
ptq->next_tid == -1) {
intel_pt_log("TSC %"PRIx64" est. TSC %"PRIx64"\n",
state->timestamp, state->est_timestamp);
ptq->timestamp = state->est_timestamp;
} else if (state->timestamp > ptq->timestamp) {
ptq->timestamp = state->timestamp;
}
if (!pt->timeless_decoding && ptq->timestamp >= *timestamp) {
*timestamp = ptq->timestamp;
return 0;
}
}
return 0;
}
static inline int intel_pt_update_queues(struct intel_pt *pt)
{
if (pt->queues.new_data) {
pt->queues.new_data = false;
return intel_pt_setup_queues(pt);
}
return 0;
}
static int intel_pt_process_queues(struct intel_pt *pt, u64 timestamp)
{
unsigned int queue_nr;
u64 ts;
int ret;
while (1) {
struct auxtrace_queue *queue;
struct intel_pt_queue *ptq;
if (!pt->heap.heap_cnt)
return 0;
if (pt->heap.heap_array[0].ordinal >= timestamp)
return 0;
queue_nr = pt->heap.heap_array[0].queue_nr;
queue = &pt->queues.queue_array[queue_nr];
ptq = queue->priv;
intel_pt_log("queue %u processing 0x%" PRIx64 " to 0x%" PRIx64 "\n",
queue_nr, pt->heap.heap_array[0].ordinal,
timestamp);
auxtrace_heap__pop(&pt->heap);
if (pt->heap.heap_cnt) {
ts = pt->heap.heap_array[0].ordinal + 1;
if (ts > timestamp)
ts = timestamp;
} else {
ts = timestamp;
}
intel_pt_set_pid_tid_cpu(pt, queue);
ret = intel_pt_run_decoder(ptq, &ts);
if (ret < 0) {
auxtrace_heap__add(&pt->heap, queue_nr, ts);
return ret;
}
if (!ret) {
ret = auxtrace_heap__add(&pt->heap, queue_nr, ts);
if (ret < 0)
return ret;
} else {
ptq->on_heap = false;
}
}
return 0;
}
static int intel_pt_process_timeless_queues(struct intel_pt *pt, pid_t tid,
u64 time_)
{
struct auxtrace_queues *queues = &pt->queues;
unsigned int i;
u64 ts = 0;
for (i = 0; i < queues->nr_queues; i++) {
struct auxtrace_queue *queue = &pt->queues.queue_array[i];
struct intel_pt_queue *ptq = queue->priv;
if (ptq && (tid == -1 || ptq->tid == tid)) {
ptq->time = time_;
intel_pt_set_pid_tid_cpu(pt, queue);
intel_pt_run_decoder(ptq, &ts);
}
}
return 0;
}
static int intel_pt_lost(struct intel_pt *pt, struct perf_sample *sample)
{
return intel_pt_synth_error(pt, INTEL_PT_ERR_LOST, sample->cpu,
sample->pid, sample->tid, 0);
}
static struct intel_pt_queue *intel_pt_cpu_to_ptq(struct intel_pt *pt, int cpu)
{
unsigned i, j;
if (cpu < 0 || !pt->queues.nr_queues)
return NULL;
if ((unsigned)cpu >= pt->queues.nr_queues)
i = pt->queues.nr_queues - 1;
else
i = cpu;
if (pt->queues.queue_array[i].cpu == cpu)
return pt->queues.queue_array[i].priv;
for (j = 0; i > 0; j++) {
if (pt->queues.queue_array[--i].cpu == cpu)
return pt->queues.queue_array[i].priv;
}
for (; j < pt->queues.nr_queues; j++) {
if (pt->queues.queue_array[j].cpu == cpu)
return pt->queues.queue_array[j].priv;
}
return NULL;
}
static int intel_pt_sync_switch(struct intel_pt *pt, int cpu, pid_t tid,
u64 timestamp)
{
struct intel_pt_queue *ptq;
int err;
if (!pt->sync_switch)
return 1;
ptq = intel_pt_cpu_to_ptq(pt, cpu);
if (!ptq)
return 1;
switch (ptq->switch_state) {
case INTEL_PT_SS_NOT_TRACING:
ptq->next_tid = -1;
break;
case INTEL_PT_SS_UNKNOWN:
case INTEL_PT_SS_TRACING:
ptq->next_tid = tid;
ptq->switch_state = INTEL_PT_SS_EXPECTING_SWITCH_IP;
return 0;
case INTEL_PT_SS_EXPECTING_SWITCH_EVENT:
if (!ptq->on_heap) {
ptq->timestamp = perf_time_to_tsc(timestamp,
&pt->tc);
err = auxtrace_heap__add(&pt->heap, ptq->queue_nr,
ptq->timestamp);
if (err)
return err;
ptq->on_heap = true;
}
ptq->switch_state = INTEL_PT_SS_TRACING;
break;
case INTEL_PT_SS_EXPECTING_SWITCH_IP:
ptq->next_tid = tid;
intel_pt_log("ERROR: cpu %d expecting switch ip\n", cpu);
break;
default:
break;
}
return 1;
}
static int intel_pt_process_switch(struct intel_pt *pt,
struct perf_sample *sample)
{
struct perf_evsel *evsel;
pid_t tid;
int cpu, ret;
evsel = perf_evlist__id2evsel(pt->session->evlist, sample->id);
if (evsel != pt->switch_evsel)
return 0;
tid = perf_evsel__intval(evsel, sample, "next_pid");
cpu = sample->cpu;
intel_pt_log("sched_switch: cpu %d tid %d time %"PRIu64" tsc %#"PRIx64"\n",
cpu, tid, sample->time, perf_time_to_tsc(sample->time,
&pt->tc));
ret = intel_pt_sync_switch(pt, cpu, tid, sample->time);
if (ret <= 0)
return ret;
return machine__set_current_tid(pt->machine, cpu, -1, tid);
}
static int intel_pt_context_switch(struct intel_pt *pt, union perf_event *event,
struct perf_sample *sample)
{
bool out = event->header.misc & PERF_RECORD_MISC_SWITCH_OUT;
pid_t pid, tid;
int cpu, ret;
cpu = sample->cpu;
if (pt->have_sched_switch == 3) {
if (!out)
return 0;
if (event->header.type != PERF_RECORD_SWITCH_CPU_WIDE) {
pr_err("Expecting CPU-wide context switch event\n");
return -EINVAL;
}
pid = event->context_switch.next_prev_pid;
tid = event->context_switch.next_prev_tid;
} else {
if (out)
return 0;
pid = sample->pid;
tid = sample->tid;
}
if (tid == -1) {
pr_err("context_switch event has no tid\n");
return -EINVAL;
}
intel_pt_log("context_switch: cpu %d pid %d tid %d time %"PRIu64" tsc %#"PRIx64"\n",
cpu, pid, tid, sample->time, perf_time_to_tsc(sample->time,
&pt->tc));
ret = intel_pt_sync_switch(pt, cpu, tid, sample->time);
if (ret <= 0)
return ret;
return machine__set_current_tid(pt->machine, cpu, pid, tid);
}
static int intel_pt_process_itrace_start(struct intel_pt *pt,
union perf_event *event,
struct perf_sample *sample)
{
if (!pt->per_cpu_mmaps)
return 0;
intel_pt_log("itrace_start: cpu %d pid %d tid %d time %"PRIu64" tsc %#"PRIx64"\n",
sample->cpu, event->itrace_start.pid,
event->itrace_start.tid, sample->time,
perf_time_to_tsc(sample->time, &pt->tc));
return machine__set_current_tid(pt->machine, sample->cpu,
event->itrace_start.pid,
event->itrace_start.tid);
}
static int intel_pt_process_event(struct perf_session *session,
union perf_event *event,
struct perf_sample *sample,
struct perf_tool *tool)
{
struct intel_pt *pt = container_of(session->auxtrace, struct intel_pt,
auxtrace);
u64 timestamp;
int err = 0;
if (dump_trace)
return 0;
if (!tool->ordered_events) {
pr_err("Intel Processor Trace requires ordered events\n");
return -EINVAL;
}
if (sample->time && sample->time != (u64)-1)
timestamp = perf_time_to_tsc(sample->time, &pt->tc);
else
timestamp = 0;
if (timestamp || pt->timeless_decoding) {
err = intel_pt_update_queues(pt);
if (err)
return err;
}
if (pt->timeless_decoding) {
if (event->header.type == PERF_RECORD_EXIT) {
err = intel_pt_process_timeless_queues(pt,
event->fork.tid,
sample->time);
}
} else if (timestamp) {
err = intel_pt_process_queues(pt, timestamp);
}
if (err)
return err;
if (event->header.type == PERF_RECORD_AUX &&
(event->aux.flags & PERF_AUX_FLAG_TRUNCATED) &&
pt->synth_opts.errors) {
err = intel_pt_lost(pt, sample);
if (err)
return err;
}
if (pt->switch_evsel && event->header.type == PERF_RECORD_SAMPLE)
err = intel_pt_process_switch(pt, sample);
else if (event->header.type == PERF_RECORD_ITRACE_START)
err = intel_pt_process_itrace_start(pt, event, sample);
else if (event->header.type == PERF_RECORD_SWITCH ||
event->header.type == PERF_RECORD_SWITCH_CPU_WIDE)
err = intel_pt_context_switch(pt, event, sample);
intel_pt_log("event %s (%u): cpu %d time %"PRIu64" tsc %#"PRIx64"\n",
perf_event__name(event->header.type), event->header.type,
sample->cpu, sample->time, timestamp);
return err;
}
static int intel_pt_flush(struct perf_session *session, struct perf_tool *tool)
{
struct intel_pt *pt = container_of(session->auxtrace, struct intel_pt,
auxtrace);
int ret;
if (dump_trace)
return 0;
if (!tool->ordered_events)
return -EINVAL;
ret = intel_pt_update_queues(pt);
if (ret < 0)
return ret;
if (pt->timeless_decoding)
return intel_pt_process_timeless_queues(pt, -1,
MAX_TIMESTAMP - 1);
return intel_pt_process_queues(pt, MAX_TIMESTAMP);
}
static void intel_pt_free_events(struct perf_session *session)
{
struct intel_pt *pt = container_of(session->auxtrace, struct intel_pt,
auxtrace);
struct auxtrace_queues *queues = &pt->queues;
unsigned int i;
for (i = 0; i < queues->nr_queues; i++) {
intel_pt_free_queue(queues->queue_array[i].priv);
queues->queue_array[i].priv = NULL;
}
intel_pt_log_disable();
auxtrace_queues__free(queues);
}
static void intel_pt_free(struct perf_session *session)
{
struct intel_pt *pt = container_of(session->auxtrace, struct intel_pt,
auxtrace);
auxtrace_heap__free(&pt->heap);
intel_pt_free_events(session);
session->auxtrace = NULL;
thread__delete(pt->unknown_thread);
free(pt);
}
static int intel_pt_process_auxtrace_event(struct perf_session *session,
union perf_event *event,
struct perf_tool *tool __maybe_unused)
{
struct intel_pt *pt = container_of(session->auxtrace, struct intel_pt,
auxtrace);
if (pt->sampling_mode)
return 0;
if (!pt->data_queued) {
struct auxtrace_buffer *buffer;
off_t data_offset;
int fd = perf_data_file__fd(session->file);
int err;
if (perf_data_file__is_pipe(session->file)) {
data_offset = 0;
} else {
data_offset = lseek(fd, 0, SEEK_CUR);
if (data_offset == -1)
return -errno;
}
err = auxtrace_queues__add_event(&pt->queues, session, event,
data_offset, &buffer);
if (err)
return err;
/* Dump here now we have copied a piped trace out of the pipe */
if (dump_trace) {
if (auxtrace_buffer__get_data(buffer, fd)) {
intel_pt_dump_event(pt, buffer->data,
buffer->size);
auxtrace_buffer__put_data(buffer);
}
}
}
return 0;
}
struct intel_pt_synth {
struct perf_tool dummy_tool;
struct perf_session *session;
};
static int intel_pt_event_synth(struct perf_tool *tool,
union perf_event *event,
struct perf_sample *sample __maybe_unused,
struct machine *machine __maybe_unused)
{
struct intel_pt_synth *intel_pt_synth =
container_of(tool, struct intel_pt_synth, dummy_tool);
return perf_session__deliver_synth_event(intel_pt_synth->session, event,
NULL);
}
static int intel_pt_synth_event(struct perf_session *session,
struct perf_event_attr *attr, u64 id)
{
struct intel_pt_synth intel_pt_synth;
memset(&intel_pt_synth, 0, sizeof(struct intel_pt_synth));
intel_pt_synth.session = session;
return perf_event__synthesize_attr(&intel_pt_synth.dummy_tool, attr, 1,
&id, intel_pt_event_synth);
}
static int intel_pt_synth_events(struct intel_pt *pt,
struct perf_session *session)
{
struct perf_evlist *evlist = session->evlist;
struct perf_evsel *evsel;
struct perf_event_attr attr;
bool found = false;
u64 id;
int err;
evlist__for_each(evlist, evsel) {
if (evsel->attr.type == pt->pmu_type && evsel->ids) {
found = true;
break;
}
}
if (!found) {
pr_debug("There are no selected events with Intel Processor Trace data\n");
return 0;
}
memset(&attr, 0, sizeof(struct perf_event_attr));
attr.size = sizeof(struct perf_event_attr);
attr.type = PERF_TYPE_HARDWARE;
attr.sample_type = evsel->attr.sample_type & PERF_SAMPLE_MASK;
attr.sample_type |= PERF_SAMPLE_IP | PERF_SAMPLE_TID |
PERF_SAMPLE_PERIOD;
if (pt->timeless_decoding)
attr.sample_type &= ~(u64)PERF_SAMPLE_TIME;
else
attr.sample_type |= PERF_SAMPLE_TIME;
if (!pt->per_cpu_mmaps)
attr.sample_type &= ~(u64)PERF_SAMPLE_CPU;
attr.exclude_user = evsel->attr.exclude_user;
attr.exclude_kernel = evsel->attr.exclude_kernel;
attr.exclude_hv = evsel->attr.exclude_hv;
attr.exclude_host = evsel->attr.exclude_host;
attr.exclude_guest = evsel->attr.exclude_guest;
attr.sample_id_all = evsel->attr.sample_id_all;
attr.read_format = evsel->attr.read_format;
id = evsel->id[0] + 1000000000;
if (!id)
id = 1;
if (pt->synth_opts.instructions) {
attr.config = PERF_COUNT_HW_INSTRUCTIONS;
if (pt->synth_opts.period_type == PERF_ITRACE_PERIOD_NANOSECS)
attr.sample_period =
intel_pt_ns_to_ticks(pt, pt->synth_opts.period);
else
attr.sample_period = pt->synth_opts.period;
pt->instructions_sample_period = attr.sample_period;
if (pt->synth_opts.callchain)
attr.sample_type |= PERF_SAMPLE_CALLCHAIN;
pr_debug("Synthesizing 'instructions' event with id %" PRIu64 " sample type %#" PRIx64 "\n",
id, (u64)attr.sample_type);
err = intel_pt_synth_event(session, &attr, id);
if (err) {
pr_err("%s: failed to synthesize 'instructions' event type\n",
__func__);
return err;
}
pt->sample_instructions = true;
pt->instructions_sample_type = attr.sample_type;
pt->instructions_id = id;
id += 1;
}
if (pt->synth_opts.transactions) {
attr.config = PERF_COUNT_HW_INSTRUCTIONS;
attr.sample_period = 1;
if (pt->synth_opts.callchain)
attr.sample_type |= PERF_SAMPLE_CALLCHAIN;
pr_debug("Synthesizing 'transactions' event with id %" PRIu64 " sample type %#" PRIx64 "\n",
id, (u64)attr.sample_type);
err = intel_pt_synth_event(session, &attr, id);
if (err) {
pr_err("%s: failed to synthesize 'transactions' event type\n",
__func__);
return err;
}
pt->sample_transactions = true;
pt->transactions_id = id;
id += 1;
evlist__for_each(evlist, evsel) {
if (evsel->id && evsel->id[0] == pt->transactions_id) {
if (evsel->name)
zfree(&evsel->name);
evsel->name = strdup("transactions");
break;
}
}
}
if (pt->synth_opts.branches) {
attr.config = PERF_COUNT_HW_BRANCH_INSTRUCTIONS;
attr.sample_period = 1;
attr.sample_type |= PERF_SAMPLE_ADDR;
attr.sample_type &= ~(u64)PERF_SAMPLE_CALLCHAIN;
pr_debug("Synthesizing 'branches' event with id %" PRIu64 " sample type %#" PRIx64 "\n",
id, (u64)attr.sample_type);
err = intel_pt_synth_event(session, &attr, id);
if (err) {
pr_err("%s: failed to synthesize 'branches' event type\n",
__func__);
return err;
}
pt->sample_branches = true;
pt->branches_sample_type = attr.sample_type;
pt->branches_id = id;
}
pt->synth_needs_swap = evsel->needs_swap;
return 0;
}
static struct perf_evsel *intel_pt_find_sched_switch(struct perf_evlist *evlist)
{
struct perf_evsel *evsel;
evlist__for_each_reverse(evlist, evsel) {
const char *name = perf_evsel__name(evsel);
if (!strcmp(name, "sched:sched_switch"))
return evsel;
}
return NULL;
}
static bool intel_pt_find_switch(struct perf_evlist *evlist)
{
struct perf_evsel *evsel;
evlist__for_each(evlist, evsel) {
if (evsel->attr.context_switch)
return true;
}
return false;
}
static const char * const intel_pt_info_fmts[] = {
[INTEL_PT_PMU_TYPE] = " PMU Type %"PRId64"\n",
[INTEL_PT_TIME_SHIFT] = " Time Shift %"PRIu64"\n",
[INTEL_PT_TIME_MULT] = " Time Muliplier %"PRIu64"\n",
[INTEL_PT_TIME_ZERO] = " Time Zero %"PRIu64"\n",
[INTEL_PT_CAP_USER_TIME_ZERO] = " Cap Time Zero %"PRId64"\n",
[INTEL_PT_TSC_BIT] = " TSC bit %#"PRIx64"\n",
[INTEL_PT_NORETCOMP_BIT] = " NoRETComp bit %#"PRIx64"\n",
[INTEL_PT_HAVE_SCHED_SWITCH] = " Have sched_switch %"PRId64"\n",
[INTEL_PT_SNAPSHOT_MODE] = " Snapshot mode %"PRId64"\n",
[INTEL_PT_PER_CPU_MMAPS] = " Per-cpu maps %"PRId64"\n",
[INTEL_PT_MTC_BIT] = " MTC bit %#"PRIx64"\n",
[INTEL_PT_TSC_CTC_N] = " TSC:CTC numerator %"PRIu64"\n",
[INTEL_PT_TSC_CTC_D] = " TSC:CTC denominator %"PRIu64"\n",
[INTEL_PT_CYC_BIT] = " CYC bit %#"PRIx64"\n",
};
static void intel_pt_print_info(u64 *arr, int start, int finish)
{
int i;
if (!dump_trace)
return;
for (i = start; i <= finish; i++)
fprintf(stdout, intel_pt_info_fmts[i], arr[i]);
}
int intel_pt_process_auxtrace_info(union perf_event *event,
struct perf_session *session)
{
struct auxtrace_info_event *auxtrace_info = &event->auxtrace_info;
size_t min_sz = sizeof(u64) * INTEL_PT_PER_CPU_MMAPS;
struct intel_pt *pt;
int err;
if (auxtrace_info->header.size < sizeof(struct auxtrace_info_event) +
min_sz)
return -EINVAL;
pt = zalloc(sizeof(struct intel_pt));
if (!pt)
return -ENOMEM;
err = auxtrace_queues__init(&pt->queues);
if (err)
goto err_free;
intel_pt_log_set_name(INTEL_PT_PMU_NAME);
pt->session = session;
pt->machine = &session->machines.host; /* No kvm support */
pt->auxtrace_type = auxtrace_info->type;
pt->pmu_type = auxtrace_info->priv[INTEL_PT_PMU_TYPE];
pt->tc.time_shift = auxtrace_info->priv[INTEL_PT_TIME_SHIFT];
pt->tc.time_mult = auxtrace_info->priv[INTEL_PT_TIME_MULT];
pt->tc.time_zero = auxtrace_info->priv[INTEL_PT_TIME_ZERO];
pt->cap_user_time_zero = auxtrace_info->priv[INTEL_PT_CAP_USER_TIME_ZERO];
pt->tsc_bit = auxtrace_info->priv[INTEL_PT_TSC_BIT];
pt->noretcomp_bit = auxtrace_info->priv[INTEL_PT_NORETCOMP_BIT];
pt->have_sched_switch = auxtrace_info->priv[INTEL_PT_HAVE_SCHED_SWITCH];
pt->snapshot_mode = auxtrace_info->priv[INTEL_PT_SNAPSHOT_MODE];
pt->per_cpu_mmaps = auxtrace_info->priv[INTEL_PT_PER_CPU_MMAPS];
intel_pt_print_info(&auxtrace_info->priv[0], INTEL_PT_PMU_TYPE,
INTEL_PT_PER_CPU_MMAPS);
if (auxtrace_info->header.size >= sizeof(struct auxtrace_info_event) +
(sizeof(u64) * INTEL_PT_CYC_BIT)) {
pt->mtc_bit = auxtrace_info->priv[INTEL_PT_MTC_BIT];
pt->mtc_freq_bits = auxtrace_info->priv[INTEL_PT_MTC_FREQ_BITS];
pt->tsc_ctc_ratio_n = auxtrace_info->priv[INTEL_PT_TSC_CTC_N];
pt->tsc_ctc_ratio_d = auxtrace_info->priv[INTEL_PT_TSC_CTC_D];
pt->cyc_bit = auxtrace_info->priv[INTEL_PT_CYC_BIT];
intel_pt_print_info(&auxtrace_info->priv[0], INTEL_PT_MTC_BIT,
INTEL_PT_CYC_BIT);
}
pt->timeless_decoding = intel_pt_timeless_decoding(pt);
pt->have_tsc = intel_pt_have_tsc(pt);
pt->sampling_mode = false;
pt->est_tsc = !pt->timeless_decoding;
pt->unknown_thread = thread__new(999999999, 999999999);
if (!pt->unknown_thread) {
err = -ENOMEM;
goto err_free_queues;
}
err = thread__set_comm(pt->unknown_thread, "unknown", 0);
if (err)
goto err_delete_thread;
if (thread__init_map_groups(pt->unknown_thread, pt->machine)) {
err = -ENOMEM;
goto err_delete_thread;
}
pt->auxtrace.process_event = intel_pt_process_event;
pt->auxtrace.process_auxtrace_event = intel_pt_process_auxtrace_event;
pt->auxtrace.flush_events = intel_pt_flush;
pt->auxtrace.free_events = intel_pt_free_events;
pt->auxtrace.free = intel_pt_free;
session->auxtrace = &pt->auxtrace;
if (dump_trace)
return 0;
if (pt->have_sched_switch == 1) {
pt->switch_evsel = intel_pt_find_sched_switch(session->evlist);
if (!pt->switch_evsel) {
pr_err("%s: missing sched_switch event\n", __func__);
goto err_delete_thread;
}
} else if (pt->have_sched_switch == 2 &&
!intel_pt_find_switch(session->evlist)) {
pr_err("%s: missing context_switch attribute flag\n", __func__);
goto err_delete_thread;
}
if (session->itrace_synth_opts && session->itrace_synth_opts->set) {
pt->synth_opts = *session->itrace_synth_opts;
} else {
itrace_synth_opts__set_default(&pt->synth_opts);
if (use_browser != -1) {
pt->synth_opts.branches = false;
pt->synth_opts.callchain = true;
}
}
if (pt->synth_opts.log)
intel_pt_log_enable();
/* Maximum non-turbo ratio is TSC freq / 100 MHz */
if (pt->tc.time_mult) {
u64 tsc_freq = intel_pt_ns_to_ticks(pt, 1000000000);
pt->max_non_turbo_ratio = (tsc_freq + 50000000) / 100000000;
intel_pt_log("TSC frequency %"PRIu64"\n", tsc_freq);
intel_pt_log("Maximum non-turbo ratio %u\n",
pt->max_non_turbo_ratio);
}
if (pt->synth_opts.calls)
pt->branches_filter |= PERF_IP_FLAG_CALL | PERF_IP_FLAG_ASYNC |
PERF_IP_FLAG_TRACE_END;
if (pt->synth_opts.returns)
pt->branches_filter |= PERF_IP_FLAG_RETURN |
PERF_IP_FLAG_TRACE_BEGIN;
if (pt->synth_opts.callchain && !symbol_conf.use_callchain) {
symbol_conf.use_callchain = true;
if (callchain_register_param(&callchain_param) < 0) {
symbol_conf.use_callchain = false;
pt->synth_opts.callchain = false;
}
}
err = intel_pt_synth_events(pt, session);
if (err)
goto err_delete_thread;
err = auxtrace_queues__process_index(&pt->queues, session);
if (err)
goto err_delete_thread;
if (pt->queues.populated)
pt->data_queued = true;
if (pt->timeless_decoding)
pr_debug2("Intel PT decoding without timestamps\n");
return 0;
err_delete_thread:
thread__delete(pt->unknown_thread);
err_free_queues:
intel_pt_log_disable();
auxtrace_queues__free(&pt->queues);
session->auxtrace = NULL;
err_free:
free(pt);
return err;
}