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linux-stable/tools/perf/builtin-timechart.c
Ian Rogers 0dd5041c9a perf addr_location: Add init/exit/copy functions 
struct addr_location holds references to multiple reference counted
objects. Add init/exit functions to make maintenance of those more
consistent with the rest of the code and to try to avoid
leaks. Modification of thread reference counts isn't included in this
change.

Committer notes:

I needed to initialize result to sample->ip to make sure is set to
something, fixing a compile time error, mostly keeping the previous
logic as build_alloc_func_list() already does debugging/error prints
about what went wrong if it takes the 'goto out'.

Signed-off-by: Ian Rogers <irogers@google.com>
Cc: Adrian Hunter <adrian.hunter@intel.com>
Cc: Alexander Shishkin <alexander.shishkin@linux.intel.com>
Cc: Ali Saidi <alisaidi@amazon.com>
Cc: Andi Kleen <ak@linux.intel.com>
Cc: Athira Rajeev <atrajeev@linux.vnet.ibm.com>
Cc: Brian Robbins <brianrob@linux.microsoft.com>
Cc: Changbin Du <changbin.du@huawei.com>
Cc: Dmitrii Dolgov <9erthalion6@gmail.com>
Cc: Fangrui Song <maskray@google.com>
Cc: German Gomez <german.gomez@arm.com>
Cc: Ingo Molnar <mingo@redhat.com>
Cc: Ivan Babrou <ivan@cloudflare.com>
Cc: James Clark <james.clark@arm.com>
Cc: Jing Zhang <renyu.zj@linux.alibaba.com>
Cc: Jiri Olsa <jolsa@kernel.org>
Cc: John Garry <john.g.garry@oracle.com>
Cc: K Prateek Nayak <kprateek.nayak@amd.com>
Cc: Kan Liang <kan.liang@linux.intel.com>
Cc: Leo Yan <leo.yan@linaro.org>
Cc: Liam Howlett <liam.howlett@oracle.com>
Cc: Mark Rutland <mark.rutland@arm.com>
Cc: Miguel Ojeda <ojeda@kernel.org>
Cc: Mike Leach <mike.leach@linaro.org>
Cc: Namhyung Kim <namhyung@kernel.org>
Cc: Naveen N. Rao <naveen.n.rao@linux.vnet.ibm.com>
Cc: Peter Zijlstra <peterz@infradead.org>
Cc: Ravi Bangoria <ravi.bangoria@amd.com>
Cc: Sean Christopherson <seanjc@google.com>
Cc: Steinar H. Gunderson <sesse@google.com>
Cc: Suzuki Poulouse <suzuki.poulose@arm.com>
Cc: Wenyu Liu <liuwenyu7@huawei.com>
Cc: Will Deacon <will@kernel.org>
Cc: Yang Jihong <yangjihong1@huawei.com>
Cc: Ye Xingchen <ye.xingchen@zte.com.cn>
Cc: Yuan Can <yuancan@huawei.com>
Cc: coresight@lists.linaro.org
Cc: linux-arm-kernel@lists.infradead.org
Link: https://lore.kernel.org/r/20230608232823.4027869-7-irogers@google.com
Signed-off-by: Arnaldo Carvalho de Melo <acme@redhat.com>
2023-06-12 15:57:53 -03:00

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// SPDX-License-Identifier: GPL-2.0-only
/*
* builtin-timechart.c - make an svg timechart of system activity
*
* (C) Copyright 2009 Intel Corporation
*
* Authors:
* Arjan van de Ven <arjan@linux.intel.com>
*/
#include <errno.h>
#include <inttypes.h>
#include "builtin.h"
#include "util/color.h"
#include <linux/list.h>
#include "util/evlist.h" // for struct evsel_str_handler
#include "util/evsel.h"
#include <linux/kernel.h>
#include <linux/rbtree.h>
#include <linux/time64.h>
#include <linux/zalloc.h>
#include "util/symbol.h"
#include "util/thread.h"
#include "util/callchain.h"
#include "util/header.h"
#include <subcmd/pager.h>
#include <subcmd/parse-options.h>
#include "util/parse-events.h"
#include "util/event.h"
#include "util/session.h"
#include "util/svghelper.h"
#include "util/tool.h"
#include "util/data.h"
#include "util/debug.h"
#include "util/string2.h"
#include "util/tracepoint.h"
#include "util/util.h"
#include <linux/err.h>
#include <traceevent/event-parse.h>
#ifdef LACKS_OPEN_MEMSTREAM_PROTOTYPE
FILE *open_memstream(char **ptr, size_t *sizeloc);
#endif
#define SUPPORT_OLD_POWER_EVENTS 1
#define PWR_EVENT_EXIT -1
struct per_pid;
struct power_event;
struct wake_event;
struct timechart {
struct perf_tool tool;
struct per_pid *all_data;
struct power_event *power_events;
struct wake_event *wake_events;
int proc_num;
unsigned int numcpus;
u64 min_freq, /* Lowest CPU frequency seen */
max_freq, /* Highest CPU frequency seen */
turbo_frequency,
first_time, last_time;
bool power_only,
tasks_only,
with_backtrace,
topology;
bool force;
/* IO related settings */
bool io_only,
skip_eagain;
u64 io_events;
u64 min_time,
merge_dist;
};
struct per_pidcomm;
struct cpu_sample;
struct io_sample;
/*
* Datastructure layout:
* We keep an list of "pid"s, matching the kernels notion of a task struct.
* Each "pid" entry, has a list of "comm"s.
* this is because we want to track different programs different, while
* exec will reuse the original pid (by design).
* Each comm has a list of samples that will be used to draw
* final graph.
*/
struct per_pid {
struct per_pid *next;
int pid;
int ppid;
u64 start_time;
u64 end_time;
u64 total_time;
u64 total_bytes;
int display;
struct per_pidcomm *all;
struct per_pidcomm *current;
};
struct per_pidcomm {
struct per_pidcomm *next;
u64 start_time;
u64 end_time;
u64 total_time;
u64 max_bytes;
u64 total_bytes;
int Y;
int display;
long state;
u64 state_since;
char *comm;
struct cpu_sample *samples;
struct io_sample *io_samples;
};
struct sample_wrapper {
struct sample_wrapper *next;
u64 timestamp;
unsigned char data[];
};
#define TYPE_NONE 0
#define TYPE_RUNNING 1
#define TYPE_WAITING 2
#define TYPE_BLOCKED 3
struct cpu_sample {
struct cpu_sample *next;
u64 start_time;
u64 end_time;
int type;
int cpu;
const char *backtrace;
};
enum {
IOTYPE_READ,
IOTYPE_WRITE,
IOTYPE_SYNC,
IOTYPE_TX,
IOTYPE_RX,
IOTYPE_POLL,
};
struct io_sample {
struct io_sample *next;
u64 start_time;
u64 end_time;
u64 bytes;
int type;
int fd;
int err;
int merges;
};
#define CSTATE 1
#define PSTATE 2
struct power_event {
struct power_event *next;
int type;
int state;
u64 start_time;
u64 end_time;
int cpu;
};
struct wake_event {
struct wake_event *next;
int waker;
int wakee;
u64 time;
const char *backtrace;
};
struct process_filter {
char *name;
int pid;
struct process_filter *next;
};
static struct process_filter *process_filter;
static struct per_pid *find_create_pid(struct timechart *tchart, int pid)
{
struct per_pid *cursor = tchart->all_data;
while (cursor) {
if (cursor->pid == pid)
return cursor;
cursor = cursor->next;
}
cursor = zalloc(sizeof(*cursor));
assert(cursor != NULL);
cursor->pid = pid;
cursor->next = tchart->all_data;
tchart->all_data = cursor;
return cursor;
}
static struct per_pidcomm *create_pidcomm(struct per_pid *p)
{
struct per_pidcomm *c;
c = zalloc(sizeof(*c));
if (!c)
return NULL;
p->current = c;
c->next = p->all;
p->all = c;
return c;
}
static void pid_set_comm(struct timechart *tchart, int pid, char *comm)
{
struct per_pid *p;
struct per_pidcomm *c;
p = find_create_pid(tchart, pid);
c = p->all;
while (c) {
if (c->comm && strcmp(c->comm, comm) == 0) {
p->current = c;
return;
}
if (!c->comm) {
c->comm = strdup(comm);
p->current = c;
return;
}
c = c->next;
}
c = create_pidcomm(p);
assert(c != NULL);
c->comm = strdup(comm);
}
static void pid_fork(struct timechart *tchart, int pid, int ppid, u64 timestamp)
{
struct per_pid *p, *pp;
p = find_create_pid(tchart, pid);
pp = find_create_pid(tchart, ppid);
p->ppid = ppid;
if (pp->current && pp->current->comm && !p->current)
pid_set_comm(tchart, pid, pp->current->comm);
p->start_time = timestamp;
if (p->current && !p->current->start_time) {
p->current->start_time = timestamp;
p->current->state_since = timestamp;
}
}
static void pid_exit(struct timechart *tchart, int pid, u64 timestamp)
{
struct per_pid *p;
p = find_create_pid(tchart, pid);
p->end_time = timestamp;
if (p->current)
p->current->end_time = timestamp;
}
static void pid_put_sample(struct timechart *tchart, int pid, int type,
unsigned int cpu, u64 start, u64 end,
const char *backtrace)
{
struct per_pid *p;
struct per_pidcomm *c;
struct cpu_sample *sample;
p = find_create_pid(tchart, pid);
c = p->current;
if (!c) {
c = create_pidcomm(p);
assert(c != NULL);
}
sample = zalloc(sizeof(*sample));
assert(sample != NULL);
sample->start_time = start;
sample->end_time = end;
sample->type = type;
sample->next = c->samples;
sample->cpu = cpu;
sample->backtrace = backtrace;
c->samples = sample;
if (sample->type == TYPE_RUNNING && end > start && start > 0) {
c->total_time += (end-start);
p->total_time += (end-start);
}
if (c->start_time == 0 || c->start_time > start)
c->start_time = start;
if (p->start_time == 0 || p->start_time > start)
p->start_time = start;
}
#define MAX_CPUS 4096
static u64 *cpus_cstate_start_times;
static int *cpus_cstate_state;
static u64 *cpus_pstate_start_times;
static u64 *cpus_pstate_state;
static int process_comm_event(struct perf_tool *tool,
union perf_event *event,
struct perf_sample *sample __maybe_unused,
struct machine *machine __maybe_unused)
{
struct timechart *tchart = container_of(tool, struct timechart, tool);
pid_set_comm(tchart, event->comm.tid, event->comm.comm);
return 0;
}
static int process_fork_event(struct perf_tool *tool,
union perf_event *event,
struct perf_sample *sample __maybe_unused,
struct machine *machine __maybe_unused)
{
struct timechart *tchart = container_of(tool, struct timechart, tool);
pid_fork(tchart, event->fork.pid, event->fork.ppid, event->fork.time);
return 0;
}
static int process_exit_event(struct perf_tool *tool,
union perf_event *event,
struct perf_sample *sample __maybe_unused,
struct machine *machine __maybe_unused)
{
struct timechart *tchart = container_of(tool, struct timechart, tool);
pid_exit(tchart, event->fork.pid, event->fork.time);
return 0;
}
#ifdef SUPPORT_OLD_POWER_EVENTS
static int use_old_power_events;
#endif
static void c_state_start(int cpu, u64 timestamp, int state)
{
cpus_cstate_start_times[cpu] = timestamp;
cpus_cstate_state[cpu] = state;
}
static void c_state_end(struct timechart *tchart, int cpu, u64 timestamp)
{
struct power_event *pwr = zalloc(sizeof(*pwr));
if (!pwr)
return;
pwr->state = cpus_cstate_state[cpu];
pwr->start_time = cpus_cstate_start_times[cpu];
pwr->end_time = timestamp;
pwr->cpu = cpu;
pwr->type = CSTATE;
pwr->next = tchart->power_events;
tchart->power_events = pwr;
}
static struct power_event *p_state_end(struct timechart *tchart, int cpu,
u64 timestamp)
{
struct power_event *pwr = zalloc(sizeof(*pwr));
if (!pwr)
return NULL;
pwr->state = cpus_pstate_state[cpu];
pwr->start_time = cpus_pstate_start_times[cpu];
pwr->end_time = timestamp;
pwr->cpu = cpu;
pwr->type = PSTATE;
pwr->next = tchart->power_events;
if (!pwr->start_time)
pwr->start_time = tchart->first_time;
tchart->power_events = pwr;
return pwr;
}
static void p_state_change(struct timechart *tchart, int cpu, u64 timestamp, u64 new_freq)
{
struct power_event *pwr;
if (new_freq > 8000000) /* detect invalid data */
return;
pwr = p_state_end(tchart, cpu, timestamp);
if (!pwr)
return;
cpus_pstate_state[cpu] = new_freq;
cpus_pstate_start_times[cpu] = timestamp;
if ((u64)new_freq > tchart->max_freq)
tchart->max_freq = new_freq;
if (new_freq < tchart->min_freq || tchart->min_freq == 0)
tchart->min_freq = new_freq;
if (new_freq == tchart->max_freq - 1000)
tchart->turbo_frequency = tchart->max_freq;
}
static void sched_wakeup(struct timechart *tchart, int cpu, u64 timestamp,
int waker, int wakee, u8 flags, const char *backtrace)
{
struct per_pid *p;
struct wake_event *we = zalloc(sizeof(*we));
if (!we)
return;
we->time = timestamp;
we->waker = waker;
we->backtrace = backtrace;
if ((flags & TRACE_FLAG_HARDIRQ) || (flags & TRACE_FLAG_SOFTIRQ))
we->waker = -1;
we->wakee = wakee;
we->next = tchart->wake_events;
tchart->wake_events = we;
p = find_create_pid(tchart, we->wakee);
if (p && p->current && p->current->state == TYPE_NONE) {
p->current->state_since = timestamp;
p->current->state = TYPE_WAITING;
}
if (p && p->current && p->current->state == TYPE_BLOCKED) {
pid_put_sample(tchart, p->pid, p->current->state, cpu,
p->current->state_since, timestamp, NULL);
p->current->state_since = timestamp;
p->current->state = TYPE_WAITING;
}
}
static void sched_switch(struct timechart *tchart, int cpu, u64 timestamp,
int prev_pid, int next_pid, u64 prev_state,
const char *backtrace)
{
struct per_pid *p = NULL, *prev_p;
prev_p = find_create_pid(tchart, prev_pid);
p = find_create_pid(tchart, next_pid);
if (prev_p->current && prev_p->current->state != TYPE_NONE)
pid_put_sample(tchart, prev_pid, TYPE_RUNNING, cpu,
prev_p->current->state_since, timestamp,
backtrace);
if (p && p->current) {
if (p->current->state != TYPE_NONE)
pid_put_sample(tchart, next_pid, p->current->state, cpu,
p->current->state_since, timestamp,
backtrace);
p->current->state_since = timestamp;
p->current->state = TYPE_RUNNING;
}
if (prev_p->current) {
prev_p->current->state = TYPE_NONE;
prev_p->current->state_since = timestamp;
if (prev_state & 2)
prev_p->current->state = TYPE_BLOCKED;
if (prev_state == 0)
prev_p->current->state = TYPE_WAITING;
}
}
static const char *cat_backtrace(union perf_event *event,
struct perf_sample *sample,
struct machine *machine)
{
struct addr_location al;
unsigned int i;
char *p = NULL;
size_t p_len;
u8 cpumode = PERF_RECORD_MISC_USER;
struct ip_callchain *chain = sample->callchain;
FILE *f = open_memstream(&p, &p_len);
if (!f) {
perror("open_memstream error");
return NULL;
}
addr_location__init(&al);
if (!chain)
goto exit;
if (machine__resolve(machine, &al, sample) < 0) {
fprintf(stderr, "problem processing %d event, skipping it.\n",
event->header.type);
goto exit;
}
for (i = 0; i < chain->nr; i++) {
u64 ip;
struct addr_location tal;
if (callchain_param.order == ORDER_CALLEE)
ip = chain->ips[i];
else
ip = chain->ips[chain->nr - i - 1];
if (ip >= PERF_CONTEXT_MAX) {
switch (ip) {
case PERF_CONTEXT_HV:
cpumode = PERF_RECORD_MISC_HYPERVISOR;
break;
case PERF_CONTEXT_KERNEL:
cpumode = PERF_RECORD_MISC_KERNEL;
break;
case PERF_CONTEXT_USER:
cpumode = PERF_RECORD_MISC_USER;
break;
default:
pr_debug("invalid callchain context: "
"%"PRId64"\n", (s64) ip);
/*
* It seems the callchain is corrupted.
* Discard all.
*/
zfree(&p);
goto exit;
}
continue;
}
addr_location__init(&tal);
tal.filtered = 0;
if (thread__find_symbol(al.thread, cpumode, ip, &tal))
fprintf(f, "..... %016" PRIx64 " %s\n", ip, tal.sym->name);
else
fprintf(f, "..... %016" PRIx64 "\n", ip);
addr_location__exit(&tal);
}
exit:
addr_location__exit(&al);
fclose(f);
return p;
}
typedef int (*tracepoint_handler)(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace);
static int process_sample_event(struct perf_tool *tool,
union perf_event *event,
struct perf_sample *sample,
struct evsel *evsel,
struct machine *machine)
{
struct timechart *tchart = container_of(tool, struct timechart, tool);
if (evsel->core.attr.sample_type & PERF_SAMPLE_TIME) {
if (!tchart->first_time || tchart->first_time > sample->time)
tchart->first_time = sample->time;
if (tchart->last_time < sample->time)
tchart->last_time = sample->time;
}
if (evsel->handler != NULL) {
tracepoint_handler f = evsel->handler;
return f(tchart, evsel, sample,
cat_backtrace(event, sample, machine));
}
return 0;
}
static int
process_sample_cpu_idle(struct timechart *tchart __maybe_unused,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace __maybe_unused)
{
u32 state = evsel__intval(evsel, sample, "state");
u32 cpu_id = evsel__intval(evsel, sample, "cpu_id");
if (state == (u32)PWR_EVENT_EXIT)
c_state_end(tchart, cpu_id, sample->time);
else
c_state_start(cpu_id, sample->time, state);
return 0;
}
static int
process_sample_cpu_frequency(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace __maybe_unused)
{
u32 state = evsel__intval(evsel, sample, "state");
u32 cpu_id = evsel__intval(evsel, sample, "cpu_id");
p_state_change(tchart, cpu_id, sample->time, state);
return 0;
}
static int
process_sample_sched_wakeup(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace)
{
u8 flags = evsel__intval(evsel, sample, "common_flags");
int waker = evsel__intval(evsel, sample, "common_pid");
int wakee = evsel__intval(evsel, sample, "pid");
sched_wakeup(tchart, sample->cpu, sample->time, waker, wakee, flags, backtrace);
return 0;
}
static int
process_sample_sched_switch(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace)
{
int prev_pid = evsel__intval(evsel, sample, "prev_pid");
int next_pid = evsel__intval(evsel, sample, "next_pid");
u64 prev_state = evsel__intval(evsel, sample, "prev_state");
sched_switch(tchart, sample->cpu, sample->time, prev_pid, next_pid,
prev_state, backtrace);
return 0;
}
#ifdef SUPPORT_OLD_POWER_EVENTS
static int
process_sample_power_start(struct timechart *tchart __maybe_unused,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace __maybe_unused)
{
u64 cpu_id = evsel__intval(evsel, sample, "cpu_id");
u64 value = evsel__intval(evsel, sample, "value");
c_state_start(cpu_id, sample->time, value);
return 0;
}
static int
process_sample_power_end(struct timechart *tchart,
struct evsel *evsel __maybe_unused,
struct perf_sample *sample,
const char *backtrace __maybe_unused)
{
c_state_end(tchart, sample->cpu, sample->time);
return 0;
}
static int
process_sample_power_frequency(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample,
const char *backtrace __maybe_unused)
{
u64 cpu_id = evsel__intval(evsel, sample, "cpu_id");
u64 value = evsel__intval(evsel, sample, "value");
p_state_change(tchart, cpu_id, sample->time, value);
return 0;
}
#endif /* SUPPORT_OLD_POWER_EVENTS */
/*
* After the last sample we need to wrap up the current C/P state
* and close out each CPU for these.
*/
static void end_sample_processing(struct timechart *tchart)
{
u64 cpu;
struct power_event *pwr;
for (cpu = 0; cpu <= tchart->numcpus; cpu++) {
/* C state */
#if 0
pwr = zalloc(sizeof(*pwr));
if (!pwr)
return;
pwr->state = cpus_cstate_state[cpu];
pwr->start_time = cpus_cstate_start_times[cpu];
pwr->end_time = tchart->last_time;
pwr->cpu = cpu;
pwr->type = CSTATE;
pwr->next = tchart->power_events;
tchart->power_events = pwr;
#endif
/* P state */
pwr = p_state_end(tchart, cpu, tchart->last_time);
if (!pwr)
return;
if (!pwr->state)
pwr->state = tchart->min_freq;
}
}
static int pid_begin_io_sample(struct timechart *tchart, int pid, int type,
u64 start, int fd)
{
struct per_pid *p = find_create_pid(tchart, pid);
struct per_pidcomm *c = p->current;
struct io_sample *sample;
struct io_sample *prev;
if (!c) {
c = create_pidcomm(p);
if (!c)
return -ENOMEM;
}
prev = c->io_samples;
if (prev && prev->start_time && !prev->end_time) {
pr_warning("Skip invalid start event: "
"previous event already started!\n");
/* remove previous event that has been started,
* we are not sure we will ever get an end for it */
c->io_samples = prev->next;
free(prev);
return 0;
}
sample = zalloc(sizeof(*sample));
if (!sample)
return -ENOMEM;
sample->start_time = start;
sample->type = type;
sample->fd = fd;
sample->next = c->io_samples;
c->io_samples = sample;
if (c->start_time == 0 || c->start_time > start)
c->start_time = start;
return 0;
}
static int pid_end_io_sample(struct timechart *tchart, int pid, int type,
u64 end, long ret)
{
struct per_pid *p = find_create_pid(tchart, pid);
struct per_pidcomm *c = p->current;
struct io_sample *sample, *prev;
if (!c) {
pr_warning("Invalid pidcomm!\n");
return -1;
}
sample = c->io_samples;
if (!sample) /* skip partially captured events */
return 0;
if (sample->end_time) {
pr_warning("Skip invalid end event: "
"previous event already ended!\n");
return 0;
}
if (sample->type != type) {
pr_warning("Skip invalid end event: invalid event type!\n");
return 0;
}
sample->end_time = end;
prev = sample->next;
/* we want to be able to see small and fast transfers, so make them
* at least min_time long, but don't overlap them */
if (sample->end_time - sample->start_time < tchart->min_time)
sample->end_time = sample->start_time + tchart->min_time;
if (prev && sample->start_time < prev->end_time) {
if (prev->err) /* try to make errors more visible */
sample->start_time = prev->end_time;
else
prev->end_time = sample->start_time;
}
if (ret < 0) {
sample->err = ret;
} else if (type == IOTYPE_READ || type == IOTYPE_WRITE ||
type == IOTYPE_TX || type == IOTYPE_RX) {
if ((u64)ret > c->max_bytes)
c->max_bytes = ret;
c->total_bytes += ret;
p->total_bytes += ret;
sample->bytes = ret;
}
/* merge two requests to make svg smaller and render-friendly */
if (prev &&
prev->type == sample->type &&
prev->err == sample->err &&
prev->fd == sample->fd &&
prev->end_time + tchart->merge_dist >= sample->start_time) {
sample->bytes += prev->bytes;
sample->merges += prev->merges + 1;
sample->start_time = prev->start_time;
sample->next = prev->next;
free(prev);
if (!sample->err && sample->bytes > c->max_bytes)
c->max_bytes = sample->bytes;
}
tchart->io_events++;
return 0;
}
static int
process_enter_read(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_READ,
sample->time, fd);
}
static int
process_exit_read(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_READ,
sample->time, ret);
}
static int
process_enter_write(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_WRITE,
sample->time, fd);
}
static int
process_exit_write(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_WRITE,
sample->time, ret);
}
static int
process_enter_sync(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_SYNC,
sample->time, fd);
}
static int
process_exit_sync(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_SYNC,
sample->time, ret);
}
static int
process_enter_tx(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_TX,
sample->time, fd);
}
static int
process_exit_tx(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_TX,
sample->time, ret);
}
static int
process_enter_rx(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_RX,
sample->time, fd);
}
static int
process_exit_rx(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_RX,
sample->time, ret);
}
static int
process_enter_poll(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long fd = evsel__intval(evsel, sample, "fd");
return pid_begin_io_sample(tchart, sample->tid, IOTYPE_POLL,
sample->time, fd);
}
static int
process_exit_poll(struct timechart *tchart,
struct evsel *evsel,
struct perf_sample *sample)
{
long ret = evsel__intval(evsel, sample, "ret");
return pid_end_io_sample(tchart, sample->tid, IOTYPE_POLL,
sample->time, ret);
}
/*
* Sort the pid datastructure
*/
static void sort_pids(struct timechart *tchart)
{
struct per_pid *new_list, *p, *cursor, *prev;
/* sort by ppid first, then by pid, lowest to highest */
new_list = NULL;
while (tchart->all_data) {
p = tchart->all_data;
tchart->all_data = p->next;
p->next = NULL;
if (new_list == NULL) {
new_list = p;
p->next = NULL;
continue;
}
prev = NULL;
cursor = new_list;
while (cursor) {
if (cursor->ppid > p->ppid ||
(cursor->ppid == p->ppid && cursor->pid > p->pid)) {
/* must insert before */
if (prev) {
p->next = prev->next;
prev->next = p;
cursor = NULL;
continue;
} else {
p->next = new_list;
new_list = p;
cursor = NULL;
continue;
}
}
prev = cursor;
cursor = cursor->next;
if (!cursor)
prev->next = p;
}
}
tchart->all_data = new_list;
}
static void draw_c_p_states(struct timechart *tchart)
{
struct power_event *pwr;
pwr = tchart->power_events;
/*
* two pass drawing so that the P state bars are on top of the C state blocks
*/
while (pwr) {
if (pwr->type == CSTATE)
svg_cstate(pwr->cpu, pwr->start_time, pwr->end_time, pwr->state);
pwr = pwr->next;
}
pwr = tchart->power_events;
while (pwr) {
if (pwr->type == PSTATE) {
if (!pwr->state)
pwr->state = tchart->min_freq;
svg_pstate(pwr->cpu, pwr->start_time, pwr->end_time, pwr->state);
}
pwr = pwr->next;
}
}
static void draw_wakeups(struct timechart *tchart)
{
struct wake_event *we;
struct per_pid *p;
struct per_pidcomm *c;
we = tchart->wake_events;
while (we) {
int from = 0, to = 0;
char *task_from = NULL, *task_to = NULL;
/* locate the column of the waker and wakee */
p = tchart->all_data;
while (p) {
if (p->pid == we->waker || p->pid == we->wakee) {
c = p->all;
while (c) {
if (c->Y && c->start_time <= we->time && c->end_time >= we->time) {
if (p->pid == we->waker && !from) {
from = c->Y;
task_from = strdup(c->comm);
}
if (p->pid == we->wakee && !to) {
to = c->Y;
task_to = strdup(c->comm);
}
}
c = c->next;
}
c = p->all;
while (c) {
if (p->pid == we->waker && !from) {
from = c->Y;
task_from = strdup(c->comm);
}
if (p->pid == we->wakee && !to) {
to = c->Y;
task_to = strdup(c->comm);
}
c = c->next;
}
}
p = p->next;
}
if (!task_from) {
task_from = malloc(40);
sprintf(task_from, "[%i]", we->waker);
}
if (!task_to) {
task_to = malloc(40);
sprintf(task_to, "[%i]", we->wakee);
}
if (we->waker == -1)
svg_interrupt(we->time, to, we->backtrace);
else if (from && to && abs(from - to) == 1)
svg_wakeline(we->time, from, to, we->backtrace);
else
svg_partial_wakeline(we->time, from, task_from, to,
task_to, we->backtrace);
we = we->next;
free(task_from);
free(task_to);
}
}
static void draw_cpu_usage(struct timechart *tchart)
{
struct per_pid *p;
struct per_pidcomm *c;
struct cpu_sample *sample;
p = tchart->all_data;
while (p) {
c = p->all;
while (c) {
sample = c->samples;
while (sample) {
if (sample->type == TYPE_RUNNING) {
svg_process(sample->cpu,
sample->start_time,
sample->end_time,
p->pid,
c->comm,
sample->backtrace);
}
sample = sample->next;
}
c = c->next;
}
p = p->next;
}
}
static void draw_io_bars(struct timechart *tchart)
{
const char *suf;
double bytes;
char comm[256];
struct per_pid *p;
struct per_pidcomm *c;
struct io_sample *sample;
int Y = 1;
p = tchart->all_data;
while (p) {
c = p->all;
while (c) {
if (!c->display) {
c->Y = 0;
c = c->next;
continue;
}
svg_box(Y, c->start_time, c->end_time, "process3");
sample = c->io_samples;
for (sample = c->io_samples; sample; sample = sample->next) {
double h = (double)sample->bytes / c->max_bytes;
if (tchart->skip_eagain &&
sample->err == -EAGAIN)
continue;
if (sample->err)
h = 1;
if (sample->type == IOTYPE_SYNC)
svg_fbox(Y,
sample->start_time,
sample->end_time,
1,
sample->err ? "error" : "sync",
sample->fd,
sample->err,
sample->merges);
else if (sample->type == IOTYPE_POLL)
svg_fbox(Y,
sample->start_time,
sample->end_time,
1,
sample->err ? "error" : "poll",
sample->fd,
sample->err,
sample->merges);
else if (sample->type == IOTYPE_READ)
svg_ubox(Y,
sample->start_time,
sample->end_time,
h,
sample->err ? "error" : "disk",
sample->fd,
sample->err,
sample->merges);
else if (sample->type == IOTYPE_WRITE)
svg_lbox(Y,
sample->start_time,
sample->end_time,
h,
sample->err ? "error" : "disk",
sample->fd,
sample->err,
sample->merges);
else if (sample->type == IOTYPE_RX)
svg_ubox(Y,
sample->start_time,
sample->end_time,
h,
sample->err ? "error" : "net",
sample->fd,
sample->err,
sample->merges);
else if (sample->type == IOTYPE_TX)
svg_lbox(Y,
sample->start_time,
sample->end_time,
h,
sample->err ? "error" : "net",
sample->fd,
sample->err,
sample->merges);
}
suf = "";
bytes = c->total_bytes;
if (bytes > 1024) {
bytes = bytes / 1024;
suf = "K";
}
if (bytes > 1024) {
bytes = bytes / 1024;
suf = "M";
}
if (bytes > 1024) {
bytes = bytes / 1024;
suf = "G";
}
sprintf(comm, "%s:%i (%3.1f %sbytes)", c->comm ?: "", p->pid, bytes, suf);
svg_text(Y, c->start_time, comm);
c->Y = Y;
Y++;
c = c->next;
}
p = p->next;
}
}
static void draw_process_bars(struct timechart *tchart)
{
struct per_pid *p;
struct per_pidcomm *c;
struct cpu_sample *sample;
int Y = 0;
Y = 2 * tchart->numcpus + 2;
p = tchart->all_data;
while (p) {
c = p->all;
while (c) {
if (!c->display) {
c->Y = 0;
c = c->next;
continue;
}
svg_box(Y, c->start_time, c->end_time, "process");
sample = c->samples;
while (sample) {
if (sample->type == TYPE_RUNNING)
svg_running(Y, sample->cpu,
sample->start_time,
sample->end_time,
sample->backtrace);
if (sample->type == TYPE_BLOCKED)
svg_blocked(Y, sample->cpu,
sample->start_time,
sample->end_time,
sample->backtrace);
if (sample->type == TYPE_WAITING)
svg_waiting(Y, sample->cpu,
sample->start_time,
sample->end_time,
sample->backtrace);
sample = sample->next;
}
if (c->comm) {
char comm[256];
if (c->total_time > 5000000000) /* 5 seconds */
sprintf(comm, "%s:%i (%2.2fs)", c->comm, p->pid, c->total_time / (double)NSEC_PER_SEC);
else
sprintf(comm, "%s:%i (%3.1fms)", c->comm, p->pid, c->total_time / (double)NSEC_PER_MSEC);
svg_text(Y, c->start_time, comm);
}
c->Y = Y;
Y++;
c = c->next;
}
p = p->next;
}
}
static void add_process_filter(const char *string)
{
int pid = strtoull(string, NULL, 10);
struct process_filter *filt = malloc(sizeof(*filt));
if (!filt)
return;
filt->name = strdup(string);
filt->pid = pid;
filt->next = process_filter;
process_filter = filt;
}
static int passes_filter(struct per_pid *p, struct per_pidcomm *c)
{
struct process_filter *filt;
if (!process_filter)
return 1;
filt = process_filter;
while (filt) {
if (filt->pid && p->pid == filt->pid)
return 1;
if (strcmp(filt->name, c->comm) == 0)
return 1;
filt = filt->next;
}
return 0;
}
static int determine_display_tasks_filtered(struct timechart *tchart)
{
struct per_pid *p;
struct per_pidcomm *c;
int count = 0;
p = tchart->all_data;
while (p) {
p->display = 0;
if (p->start_time == 1)
p->start_time = tchart->first_time;
/* no exit marker, task kept running to the end */
if (p->end_time == 0)
p->end_time = tchart->last_time;
c = p->all;
while (c) {
c->display = 0;
if (c->start_time == 1)
c->start_time = tchart->first_time;
if (passes_filter(p, c)) {
c->display = 1;
p->display = 1;
count++;
}
if (c->end_time == 0)
c->end_time = tchart->last_time;
c = c->next;
}
p = p->next;
}
return count;
}
static int determine_display_tasks(struct timechart *tchart, u64 threshold)
{
struct per_pid *p;
struct per_pidcomm *c;
int count = 0;
p = tchart->all_data;
while (p) {
p->display = 0;
if (p->start_time == 1)
p->start_time = tchart->first_time;
/* no exit marker, task kept running to the end */
if (p->end_time == 0)
p->end_time = tchart->last_time;
if (p->total_time >= threshold)
p->display = 1;
c = p->all;
while (c) {
c->display = 0;
if (c->start_time == 1)
c->start_time = tchart->first_time;
if (c->total_time >= threshold) {
c->display = 1;
count++;
}
if (c->end_time == 0)
c->end_time = tchart->last_time;
c = c->next;
}
p = p->next;
}
return count;
}
static int determine_display_io_tasks(struct timechart *timechart, u64 threshold)
{
struct per_pid *p;
struct per_pidcomm *c;
int count = 0;
p = timechart->all_data;
while (p) {
/* no exit marker, task kept running to the end */
if (p->end_time == 0)
p->end_time = timechart->last_time;
c = p->all;
while (c) {
c->display = 0;
if (c->total_bytes >= threshold) {
c->display = 1;
count++;
}
if (c->end_time == 0)
c->end_time = timechart->last_time;
c = c->next;
}
p = p->next;
}
return count;
}
#define BYTES_THRESH (1 * 1024 * 1024)
#define TIME_THRESH 10000000
static void write_svg_file(struct timechart *tchart, const char *filename)
{
u64 i;
int count;
int thresh = tchart->io_events ? BYTES_THRESH : TIME_THRESH;
if (tchart->power_only)
tchart->proc_num = 0;
/* We'd like to show at least proc_num tasks;
* be less picky if we have fewer */
do {
if (process_filter)
count = determine_display_tasks_filtered(tchart);
else if (tchart->io_events)
count = determine_display_io_tasks(tchart, thresh);
else
count = determine_display_tasks(tchart, thresh);
thresh /= 10;
} while (!process_filter && thresh && count < tchart->proc_num);
if (!tchart->proc_num)
count = 0;
if (tchart->io_events) {
open_svg(filename, 0, count, tchart->first_time, tchart->last_time);
svg_time_grid(0.5);
svg_io_legenda();
draw_io_bars(tchart);
} else {
open_svg(filename, tchart->numcpus, count, tchart->first_time, tchart->last_time);
svg_time_grid(0);
svg_legenda();
for (i = 0; i < tchart->numcpus; i++)
svg_cpu_box(i, tchart->max_freq, tchart->turbo_frequency);
draw_cpu_usage(tchart);
if (tchart->proc_num)
draw_process_bars(tchart);
if (!tchart->tasks_only)
draw_c_p_states(tchart);
if (tchart->proc_num)
draw_wakeups(tchart);
}
svg_close();
}
static int process_header(struct perf_file_section *section __maybe_unused,
struct perf_header *ph,
int feat,
int fd __maybe_unused,
void *data)
{
struct timechart *tchart = data;
switch (feat) {
case HEADER_NRCPUS:
tchart->numcpus = ph->env.nr_cpus_avail;
break;
case HEADER_CPU_TOPOLOGY:
if (!tchart->topology)
break;
if (svg_build_topology_map(&ph->env))
fprintf(stderr, "problem building topology\n");
break;
default:
break;
}
return 0;
}
static int __cmd_timechart(struct timechart *tchart, const char *output_name)
{
const struct evsel_str_handler power_tracepoints[] = {
{ "power:cpu_idle", process_sample_cpu_idle },
{ "power:cpu_frequency", process_sample_cpu_frequency },
{ "sched:sched_wakeup", process_sample_sched_wakeup },
{ "sched:sched_switch", process_sample_sched_switch },
#ifdef SUPPORT_OLD_POWER_EVENTS
{ "power:power_start", process_sample_power_start },
{ "power:power_end", process_sample_power_end },
{ "power:power_frequency", process_sample_power_frequency },
#endif
{ "syscalls:sys_enter_read", process_enter_read },
{ "syscalls:sys_enter_pread64", process_enter_read },
{ "syscalls:sys_enter_readv", process_enter_read },
{ "syscalls:sys_enter_preadv", process_enter_read },
{ "syscalls:sys_enter_write", process_enter_write },
{ "syscalls:sys_enter_pwrite64", process_enter_write },
{ "syscalls:sys_enter_writev", process_enter_write },
{ "syscalls:sys_enter_pwritev", process_enter_write },
{ "syscalls:sys_enter_sync", process_enter_sync },
{ "syscalls:sys_enter_sync_file_range", process_enter_sync },
{ "syscalls:sys_enter_fsync", process_enter_sync },
{ "syscalls:sys_enter_msync", process_enter_sync },
{ "syscalls:sys_enter_recvfrom", process_enter_rx },
{ "syscalls:sys_enter_recvmmsg", process_enter_rx },
{ "syscalls:sys_enter_recvmsg", process_enter_rx },
{ "syscalls:sys_enter_sendto", process_enter_tx },
{ "syscalls:sys_enter_sendmsg", process_enter_tx },
{ "syscalls:sys_enter_sendmmsg", process_enter_tx },
{ "syscalls:sys_enter_epoll_pwait", process_enter_poll },
{ "syscalls:sys_enter_epoll_wait", process_enter_poll },
{ "syscalls:sys_enter_poll", process_enter_poll },
{ "syscalls:sys_enter_ppoll", process_enter_poll },
{ "syscalls:sys_enter_pselect6", process_enter_poll },
{ "syscalls:sys_enter_select", process_enter_poll },
{ "syscalls:sys_exit_read", process_exit_read },
{ "syscalls:sys_exit_pread64", process_exit_read },
{ "syscalls:sys_exit_readv", process_exit_read },
{ "syscalls:sys_exit_preadv", process_exit_read },
{ "syscalls:sys_exit_write", process_exit_write },
{ "syscalls:sys_exit_pwrite64", process_exit_write },
{ "syscalls:sys_exit_writev", process_exit_write },
{ "syscalls:sys_exit_pwritev", process_exit_write },
{ "syscalls:sys_exit_sync", process_exit_sync },
{ "syscalls:sys_exit_sync_file_range", process_exit_sync },
{ "syscalls:sys_exit_fsync", process_exit_sync },
{ "syscalls:sys_exit_msync", process_exit_sync },
{ "syscalls:sys_exit_recvfrom", process_exit_rx },
{ "syscalls:sys_exit_recvmmsg", process_exit_rx },
{ "syscalls:sys_exit_recvmsg", process_exit_rx },
{ "syscalls:sys_exit_sendto", process_exit_tx },
{ "syscalls:sys_exit_sendmsg", process_exit_tx },
{ "syscalls:sys_exit_sendmmsg", process_exit_tx },
{ "syscalls:sys_exit_epoll_pwait", process_exit_poll },
{ "syscalls:sys_exit_epoll_wait", process_exit_poll },
{ "syscalls:sys_exit_poll", process_exit_poll },
{ "syscalls:sys_exit_ppoll", process_exit_poll },
{ "syscalls:sys_exit_pselect6", process_exit_poll },
{ "syscalls:sys_exit_select", process_exit_poll },
};
struct perf_data data = {
.path = input_name,
.mode = PERF_DATA_MODE_READ,
.force = tchart->force,
};
struct perf_session *session = perf_session__new(&data, &tchart->tool);
int ret = -EINVAL;
if (IS_ERR(session))
return PTR_ERR(session);
symbol__init(&session->header.env);
(void)perf_header__process_sections(&session->header,
perf_data__fd(session->data),
tchart,
process_header);
if (!perf_session__has_traces(session, "timechart record"))
goto out_delete;
if (perf_session__set_tracepoints_handlers(session,
power_tracepoints)) {
pr_err("Initializing session tracepoint handlers failed\n");
goto out_delete;
}
ret = perf_session__process_events(session);
if (ret)
goto out_delete;
end_sample_processing(tchart);
sort_pids(tchart);
write_svg_file(tchart, output_name);
pr_info("Written %2.1f seconds of trace to %s.\n",
(tchart->last_time - tchart->first_time) / (double)NSEC_PER_SEC, output_name);
out_delete:
perf_session__delete(session);
return ret;
}
static int timechart__io_record(int argc, const char **argv)
{
unsigned int rec_argc, i;
const char **rec_argv;
const char **p;
char *filter = NULL;
const char * const common_args[] = {
"record", "-a", "-R", "-c", "1",
};
unsigned int common_args_nr = ARRAY_SIZE(common_args);
const char * const disk_events[] = {
"syscalls:sys_enter_read",
"syscalls:sys_enter_pread64",
"syscalls:sys_enter_readv",
"syscalls:sys_enter_preadv",
"syscalls:sys_enter_write",
"syscalls:sys_enter_pwrite64",
"syscalls:sys_enter_writev",
"syscalls:sys_enter_pwritev",
"syscalls:sys_enter_sync",
"syscalls:sys_enter_sync_file_range",
"syscalls:sys_enter_fsync",
"syscalls:sys_enter_msync",
"syscalls:sys_exit_read",
"syscalls:sys_exit_pread64",
"syscalls:sys_exit_readv",
"syscalls:sys_exit_preadv",
"syscalls:sys_exit_write",
"syscalls:sys_exit_pwrite64",
"syscalls:sys_exit_writev",
"syscalls:sys_exit_pwritev",
"syscalls:sys_exit_sync",
"syscalls:sys_exit_sync_file_range",
"syscalls:sys_exit_fsync",
"syscalls:sys_exit_msync",
};
unsigned int disk_events_nr = ARRAY_SIZE(disk_events);
const char * const net_events[] = {
"syscalls:sys_enter_recvfrom",
"syscalls:sys_enter_recvmmsg",
"syscalls:sys_enter_recvmsg",
"syscalls:sys_enter_sendto",
"syscalls:sys_enter_sendmsg",
"syscalls:sys_enter_sendmmsg",
"syscalls:sys_exit_recvfrom",
"syscalls:sys_exit_recvmmsg",
"syscalls:sys_exit_recvmsg",
"syscalls:sys_exit_sendto",
"syscalls:sys_exit_sendmsg",
"syscalls:sys_exit_sendmmsg",
};
unsigned int net_events_nr = ARRAY_SIZE(net_events);
const char * const poll_events[] = {
"syscalls:sys_enter_epoll_pwait",
"syscalls:sys_enter_epoll_wait",
"syscalls:sys_enter_poll",
"syscalls:sys_enter_ppoll",
"syscalls:sys_enter_pselect6",
"syscalls:sys_enter_select",
"syscalls:sys_exit_epoll_pwait",
"syscalls:sys_exit_epoll_wait",
"syscalls:sys_exit_poll",
"syscalls:sys_exit_ppoll",
"syscalls:sys_exit_pselect6",
"syscalls:sys_exit_select",
};
unsigned int poll_events_nr = ARRAY_SIZE(poll_events);
rec_argc = common_args_nr +
disk_events_nr * 4 +
net_events_nr * 4 +
poll_events_nr * 4 +
argc;
rec_argv = calloc(rec_argc + 1, sizeof(char *));
if (rec_argv == NULL)
return -ENOMEM;
if (asprintf(&filter, "common_pid != %d", getpid()) < 0) {
free(rec_argv);
return -ENOMEM;
}
p = rec_argv;
for (i = 0; i < common_args_nr; i++)
*p++ = strdup(common_args[i]);
for (i = 0; i < disk_events_nr; i++) {
if (!is_valid_tracepoint(disk_events[i])) {
rec_argc -= 4;
continue;
}
*p++ = "-e";
*p++ = strdup(disk_events[i]);
*p++ = "--filter";
*p++ = filter;
}
for (i = 0; i < net_events_nr; i++) {
if (!is_valid_tracepoint(net_events[i])) {
rec_argc -= 4;
continue;
}
*p++ = "-e";
*p++ = strdup(net_events[i]);
*p++ = "--filter";
*p++ = filter;
}
for (i = 0; i < poll_events_nr; i++) {
if (!is_valid_tracepoint(poll_events[i])) {
rec_argc -= 4;
continue;
}
*p++ = "-e";
*p++ = strdup(poll_events[i]);
*p++ = "--filter";
*p++ = filter;
}
for (i = 0; i < (unsigned int)argc; i++)
*p++ = argv[i];
return cmd_record(rec_argc, rec_argv);
}
static int timechart__record(struct timechart *tchart, int argc, const char **argv)
{
unsigned int rec_argc, i, j;
const char **rec_argv;
const char **p;
unsigned int record_elems;
const char * const common_args[] = {
"record", "-a", "-R", "-c", "1",
};
unsigned int common_args_nr = ARRAY_SIZE(common_args);
const char * const backtrace_args[] = {
"-g",
};
unsigned int backtrace_args_no = ARRAY_SIZE(backtrace_args);
const char * const power_args[] = {
"-e", "power:cpu_frequency",
"-e", "power:cpu_idle",
};
unsigned int power_args_nr = ARRAY_SIZE(power_args);
const char * const old_power_args[] = {
#ifdef SUPPORT_OLD_POWER_EVENTS
"-e", "power:power_start",
"-e", "power:power_end",
"-e", "power:power_frequency",
#endif
};
unsigned int old_power_args_nr = ARRAY_SIZE(old_power_args);
const char * const tasks_args[] = {
"-e", "sched:sched_wakeup",
"-e", "sched:sched_switch",
};
unsigned int tasks_args_nr = ARRAY_SIZE(tasks_args);
#ifdef SUPPORT_OLD_POWER_EVENTS
if (!is_valid_tracepoint("power:cpu_idle") &&
is_valid_tracepoint("power:power_start")) {
use_old_power_events = 1;
power_args_nr = 0;
} else {
old_power_args_nr = 0;
}
#endif
if (tchart->power_only)
tasks_args_nr = 0;
if (tchart->tasks_only) {
power_args_nr = 0;
old_power_args_nr = 0;
}
if (!tchart->with_backtrace)
backtrace_args_no = 0;
record_elems = common_args_nr + tasks_args_nr +
power_args_nr + old_power_args_nr + backtrace_args_no;
rec_argc = record_elems + argc;
rec_argv = calloc(rec_argc + 1, sizeof(char *));
if (rec_argv == NULL)
return -ENOMEM;
p = rec_argv;
for (i = 0; i < common_args_nr; i++)
*p++ = strdup(common_args[i]);
for (i = 0; i < backtrace_args_no; i++)
*p++ = strdup(backtrace_args[i]);
for (i = 0; i < tasks_args_nr; i++)
*p++ = strdup(tasks_args[i]);
for (i = 0; i < power_args_nr; i++)
*p++ = strdup(power_args[i]);
for (i = 0; i < old_power_args_nr; i++)
*p++ = strdup(old_power_args[i]);
for (j = 0; j < (unsigned int)argc; j++)
*p++ = argv[j];
return cmd_record(rec_argc, rec_argv);
}
static int
parse_process(const struct option *opt __maybe_unused, const char *arg,
int __maybe_unused unset)
{
if (arg)
add_process_filter(arg);
return 0;
}
static int
parse_highlight(const struct option *opt __maybe_unused, const char *arg,
int __maybe_unused unset)
{
unsigned long duration = strtoul(arg, NULL, 0);
if (svg_highlight || svg_highlight_name)
return -1;
if (duration)
svg_highlight = duration;
else
svg_highlight_name = strdup(arg);
return 0;
}
static int
parse_time(const struct option *opt, const char *arg, int __maybe_unused unset)
{
char unit = 'n';
u64 *value = opt->value;
if (sscanf(arg, "%" PRIu64 "%cs", value, &unit) > 0) {
switch (unit) {
case 'm':
*value *= NSEC_PER_MSEC;
break;
case 'u':
*value *= NSEC_PER_USEC;
break;
case 'n':
break;
default:
return -1;
}
}
return 0;
}
int cmd_timechart(int argc, const char **argv)
{
struct timechart tchart = {
.tool = {
.comm = process_comm_event,
.fork = process_fork_event,
.exit = process_exit_event,
.sample = process_sample_event,
.ordered_events = true,
},
.proc_num = 15,
.min_time = NSEC_PER_MSEC,
.merge_dist = 1000,
};
const char *output_name = "output.svg";
const struct option timechart_common_options[] = {
OPT_BOOLEAN('P', "power-only", &tchart.power_only, "output power data only"),
OPT_BOOLEAN('T', "tasks-only", &tchart.tasks_only, "output processes data only"),
OPT_END()
};
const struct option timechart_options[] = {
OPT_STRING('i', "input", &input_name, "file", "input file name"),
OPT_STRING('o', "output", &output_name, "file", "output file name"),
OPT_INTEGER('w', "width", &svg_page_width, "page width"),
OPT_CALLBACK(0, "highlight", NULL, "duration or task name",
"highlight tasks. Pass duration in ns or process name.",
parse_highlight),
OPT_CALLBACK('p', "process", NULL, "process",
"process selector. Pass a pid or process name.",
parse_process),
OPT_CALLBACK(0, "symfs", NULL, "directory",
"Look for files with symbols relative to this directory",
symbol__config_symfs),
OPT_INTEGER('n', "proc-num", &tchart.proc_num,
"min. number of tasks to print"),
OPT_BOOLEAN('t', "topology", &tchart.topology,
"sort CPUs according to topology"),
OPT_BOOLEAN(0, "io-skip-eagain", &tchart.skip_eagain,
"skip EAGAIN errors"),
OPT_CALLBACK(0, "io-min-time", &tchart.min_time, "time",
"all IO faster than min-time will visually appear longer",
parse_time),
OPT_CALLBACK(0, "io-merge-dist", &tchart.merge_dist, "time",
"merge events that are merge-dist us apart",
parse_time),
OPT_BOOLEAN('f', "force", &tchart.force, "don't complain, do it"),
OPT_PARENT(timechart_common_options),
};
const char * const timechart_subcommands[] = { "record", NULL };
const char *timechart_usage[] = {
"perf timechart [<options>] {record}",
NULL
};
const struct option timechart_record_options[] = {
OPT_BOOLEAN('I', "io-only", &tchart.io_only,
"record only IO data"),
OPT_BOOLEAN('g', "callchain", &tchart.with_backtrace, "record callchain"),
OPT_PARENT(timechart_common_options),
};
const char * const timechart_record_usage[] = {
"perf timechart record [<options>]",
NULL
};
int ret;
cpus_cstate_start_times = calloc(MAX_CPUS, sizeof(*cpus_cstate_start_times));
if (!cpus_cstate_start_times)
return -ENOMEM;
cpus_cstate_state = calloc(MAX_CPUS, sizeof(*cpus_cstate_state));
if (!cpus_cstate_state) {
ret = -ENOMEM;
goto out;
}
cpus_pstate_start_times = calloc(MAX_CPUS, sizeof(*cpus_pstate_start_times));
if (!cpus_pstate_start_times) {
ret = -ENOMEM;
goto out;
}
cpus_pstate_state = calloc(MAX_CPUS, sizeof(*cpus_pstate_state));
if (!cpus_pstate_state) {
ret = -ENOMEM;
goto out;
}
argc = parse_options_subcommand(argc, argv, timechart_options, timechart_subcommands,
timechart_usage, PARSE_OPT_STOP_AT_NON_OPTION);
if (tchart.power_only && tchart.tasks_only) {
pr_err("-P and -T options cannot be used at the same time.\n");
ret = -1;
goto out;
}
if (argc && strlen(argv[0]) > 2 && strstarts("record", argv[0])) {
argc = parse_options(argc, argv, timechart_record_options,
timechart_record_usage,
PARSE_OPT_STOP_AT_NON_OPTION);
if (tchart.power_only && tchart.tasks_only) {
pr_err("-P and -T options cannot be used at the same time.\n");
ret = -1;
goto out;
}
if (tchart.io_only)
ret = timechart__io_record(argc, argv);
else
ret = timechart__record(&tchart, argc, argv);
goto out;
} else if (argc)
usage_with_options(timechart_usage, timechart_options);
setup_pager();
ret = __cmd_timechart(&tchart, output_name);
out:
zfree(&cpus_cstate_start_times);
zfree(&cpus_cstate_state);
zfree(&cpus_pstate_start_times);
zfree(&cpus_pstate_state);
return ret;
}
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