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kernel / pub / scm / linux / kernel / git / jkacur / trace-cmd / 3ea6b2ddc05480ac0288f5a4b038d34d59b40c1a / . / trace-hist.c
blob: 2a2e78066f73d10fdb10c93a1bea2cb51dba894d [file] [log] [blame]
/*
* Copyright (C) 2013 Red Hat Inc, Steven Rostedt <srostedt@redhat.com>
*
* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License (not later!)
*
* This program is distributed in the hope that 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.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses>
*
* ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
*
* Several of the ideas in this file came from Arnaldo Carvalho de Melo's
* work on the perf ui.
*/
#define _LARGEFILE64_SOURCE
#include <dirent.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <getopt.h>
#include <signal.h>
#include "trace-local.h"
#include "list.h"
static int sched_wakeup_type;
static int sched_wakeup_new_type;
static int sched_switch_type;
static int function_type;
static int function_graph_entry_type;
static int function_graph_exit_type;
static int kernel_stack_type;
static int long_size;
struct format_field *common_type_field;
struct format_field *common_pid_field;
struct format_field *sched_wakeup_comm_field;
struct format_field *sched_wakeup_new_comm_field;
struct format_field *sched_wakeup_pid_field;
struct format_field *sched_wakeup_new_pid_field;
struct format_field *sched_switch_prev_field;
struct format_field *sched_switch_next_field;
struct format_field *sched_switch_prev_pid_field;
struct format_field *sched_switch_next_pid_field;
struct format_field *function_ip_field;
struct format_field *function_parent_ip_field;
struct format_field *function_graph_entry_func_field;
struct format_field *function_graph_entry_depth_field;
struct format_field *function_graph_exit_func_field;
struct format_field *function_graph_exit_depth_field;
struct format_field *function_graph_exit_calltime_field;
struct format_field *function_graph_exit_rettime_field;
struct format_field *function_graph_exit_overrun_field;
struct format_field *kernel_stack_caller_field;
static int compact;
static void *zalloc(size_t size)
{
return calloc(1, size);
}
static const char **ips;
static int ips_idx;
static int func_depth;
static int current_pid = -1;
struct stack_save {
struct stack_save *next;
const char **ips;
int ips_idx;
int func_depth;
int pid;
};
struct stack_save *saved_stacks;
static void reset_stack(void)
{
current_pid = -1;
ips_idx = 0;
func_depth = 0;
/* Don't free here, it may be saved */
ips = NULL;
}
static void save_stack(void)
{
struct stack_save *stack;
stack = zalloc(sizeof(*stack));
if (!stack)
die("malloc");
stack->pid = current_pid;
stack->ips_idx = ips_idx;
stack->func_depth = func_depth;
stack->ips = ips;
stack->next = saved_stacks;
saved_stacks = stack;
reset_stack();
}
static void restore_stack(int pid)
{
struct stack_save *last = NULL, *stack;
for (stack = saved_stacks; stack; last = stack, stack = stack->next) {
if (stack->pid == pid)
break;
}
if (!stack)
return;
if (last)
last->next = stack->next;
else
saved_stacks = stack->next;
current_pid = stack->pid;
ips_idx = stack->ips_idx;
func_depth = stack->func_depth;
free(ips);
ips = stack->ips;
free(stack);
}
struct pid_list;
struct chain {
struct chain *next;
struct chain *sibling;
const char *func;
struct chain *parents;
struct pid_list *pid_list;
int nr_parents;
int count;
int total;
int event;
};
static struct chain *chains;
static int nr_chains;
static int total_counts;
struct pid_list {
struct pid_list *next;
struct chain chain;
int pid;
};
static struct pid_list *list_pids;
static struct pid_list all_pid_list;
static void add_chain(struct chain *chain)
{
if (chain->next)
die("chain not null?");
chain->next = chains;
chains = chain;
nr_chains++;
}
static void
insert_chain(struct pid_list *pid_list, struct chain *chain_list,
const char **chain_str, int size, int event)
{
struct chain *chain;
/* Record all counts */
if (!chain_list->func)
total_counts++;
chain_list->count++;
if (!size--)
return;
for (chain = chain_list->parents; chain; chain = chain->sibling) {
if (chain->func == chain_str[size]) {
insert_chain(pid_list, chain, chain_str, size, 0);
return;
}
}
chain_list->nr_parents++;
chain = zalloc(sizeof(struct chain));
if (!chain)
die("malloc");
chain->sibling = chain_list->parents;
chain_list->parents = chain;
chain->func = chain_str[size];
chain->pid_list = pid_list;
chain->event = event;
/* NULL func means this is the top level of the chain. Store it */
if (!chain_list->func)
add_chain(chain);
insert_chain(pid_list, chain, chain_str, size, 0);
}
static void save_call_chain(int pid, const char **chain, int size, int event)
{
static struct pid_list *pid_list;
if (compact)
pid_list = &all_pid_list;
else if (!pid_list || pid_list->pid != pid) {
for (pid_list = list_pids; pid_list; pid_list = pid_list->next) {
if (pid_list->pid == pid)
break;
}
if (!pid_list) {
pid_list = zalloc(sizeof(*pid_list));
if (!pid_list)
die("malloc");
pid_list->pid = pid;
pid_list->next = list_pids;
list_pids = pid_list;
}
}
insert_chain(pid_list, &pid_list->chain, chain, size, event);
}
static void save_stored_stacks(void)
{
while (saved_stacks) {
restore_stack(saved_stacks->pid);
save_call_chain(current_pid, ips, ips_idx, 0);
}
}
static void flush_stack(void)
{
if (current_pid < 0)
return;
save_call_chain(current_pid, ips, ips_idx, 0);
free(ips);
reset_stack();
}
static void push_stack_func(const char *func)
{
ips_idx++;
ips = realloc(ips, ips_idx * sizeof(char *));
ips[ips_idx - 1] = func;
}
static void pop_stack_func(void)
{
ips_idx--;
ips[ips_idx] = NULL;
}
static void
process_function(struct pevent *pevent, struct pevent_record *record)
{
unsigned long long parent_ip;
unsigned long long ip;
unsigned long long val;
const char *parent;
const char *func;
int pid;
int ret;
ret = pevent_read_number_field(common_pid_field, record->data, &val);
if (ret < 0)
die("no pid field for function?");
ret = pevent_read_number_field(function_ip_field, record->data, &ip);
if (ret < 0)
die("no ip field for function?");
ret = pevent_read_number_field(function_parent_ip_field, record->data, &parent_ip);
if (ret < 0)
die("no parent ip field for function?");
pid = val;
func = pevent_find_function(pevent, ip);
parent = pevent_find_function(pevent, parent_ip);
if (current_pid >= 0 && pid != current_pid) {
save_stack();
restore_stack(pid);
}
current_pid = pid;
if (ips_idx) {
if (ips[ips_idx - 1] == parent)
push_stack_func(func);
else {
save_call_chain(pid, ips, ips_idx, 0);
while (ips_idx) {
pop_stack_func();
if (ips[ips_idx - 1] == parent) {
push_stack_func(func);
break;
}
}
}
}
/* The above check can set ips_idx to zero again */
if (!ips_idx) {
push_stack_func(parent);
push_stack_func(func);
}
}
static void
process_function_graph_entry(struct pevent *pevent, struct pevent_record *record)
{
unsigned long long depth;
unsigned long long ip;
unsigned long long val;
const char *func;
int pid;
int ret;
ret = pevent_read_number_field(common_pid_field, record->data, &val);
if (ret < 0)
die("no pid field for function graph entry?");
ret = pevent_read_number_field(function_graph_entry_func_field,
record->data, &ip);
if (ret < 0)
die("no ip field for function graph entry?");
ret = pevent_read_number_field(function_graph_entry_depth_field,
record->data, &depth);
if (ret < 0)
die("no parent ip field for function entry?");
pid = val;
func = pevent_find_function(pevent, ip);
if (current_pid >= 0 && pid != current_pid) {
save_stack();
restore_stack(pid);
}
current_pid = pid;
if (depth != ips_idx) {
save_call_chain(pid, ips, ips_idx, 0);
while (ips_idx > depth)
pop_stack_func();
}
func_depth = depth;
push_stack_func(func);
}
static void
process_function_graph_exit(struct pevent *pevent, struct pevent_record *record)
{
unsigned long long depth;
unsigned long long val;
int pid;
int ret;
ret = pevent_read_number_field(common_pid_field, record->data, &val);
if (ret < 0)
die("no pid field for function graph exit?");
ret = pevent_read_number_field(function_graph_exit_depth_field,
record->data, &depth);
if (ret < 0)
die("no parent ip field for function?");
pid = val;
if (current_pid >= 0 && pid != current_pid) {
save_stack();
restore_stack(pid);
}
current_pid = pid;
if (ips_idx != depth) {
save_call_chain(pid, ips, ips_idx, 0);
while (ips_idx > depth)
pop_stack_func();
}
func_depth = depth - 1;
}
static int pending_pid = -1;
static const char **pending_ips;
static int pending_ips_idx;
static void reset_pending_stack(void)
{
pending_pid = -1;
pending_ips_idx = 0;
free(pending_ips);
pending_ips = NULL;
}
static void copy_stack_to_pending(int pid)
{
pending_pid = pid;
pending_ips = zalloc(sizeof(char *) * ips_idx);
memcpy(pending_ips, ips, sizeof(char *) * ips_idx);
pending_ips_idx = ips_idx;
}
static void
process_kernel_stack(struct pevent *pevent, struct pevent_record *record)
{
struct format_field *field = kernel_stack_caller_field;
unsigned long long val;
void *data = record->data;
int do_restore = 0;
int pid;
int ret;
ret = pevent_read_number_field(common_pid_field, record->data, &val);
if (ret < 0)
die("no pid field for function?");
pid = val;
if (pending_pid >= 0 && pid != pending_pid) {
reset_pending_stack();
return;
}
if (!field)
die("no caller field for kernel stack?");
if (pending_pid >= 0) {
if (current_pid >= 0) {
save_stack();
do_restore = 1;
}
} else {
/* function stack trace? */
if (current_pid >= 0) {
copy_stack_to_pending(current_pid);
free(ips);
reset_stack();
}
}
current_pid = pid;
/* Need to start at the end of the callers and work up */
for (data += field->offset; data < record->data + record->size;
data += long_size) {
unsigned long long addr;
addr = pevent_read_number(pevent, data, long_size);
if ((long_size == 8 && addr == (unsigned long long)-1) ||
((int)addr == -1))
break;
}
for (data -= long_size; data >= record->data + field->offset; data -= long_size) {
unsigned long long addr;
const char *func;
addr = pevent_read_number(pevent, data, long_size);
func = pevent_find_function(pevent, addr);
if (func)
push_stack_func(func);
}
if (pending_pid >= 0) {
push_stack_func(pending_ips[pending_ips_idx - 1]);
reset_pending_stack();
}
save_call_chain(current_pid, ips, ips_idx, 1);
if (do_restore)
restore_stack(current_pid);
}
static void
process_sched_wakeup(struct pevent *pevent, struct pevent_record *record, int type)
{
unsigned long long val;
const char *comm;
int pid;
int ret;
if (type == sched_wakeup_type) {
comm = (char *)(record->data + sched_wakeup_comm_field->offset);
ret = pevent_read_number_field(sched_wakeup_pid_field, record->data, &val);
if (ret < 0)
die("no pid field in sched_wakeup?");
} else {
comm = (char *)(record->data + sched_wakeup_new_comm_field->offset);
ret = pevent_read_number_field(sched_wakeup_new_pid_field, record->data, &val);
if (ret < 0)
die("no pid field in sched_wakeup_new?");
}
pid = val;
pevent_register_comm(pevent, comm, pid);
}
static void
process_sched_switch(struct pevent *pevent, struct pevent_record *record)
{
unsigned long long val;
const char *comm;
int pid;
int ret;
comm = (char *)(record->data + sched_switch_prev_field->offset);
ret = pevent_read_number_field(sched_switch_prev_pid_field, record->data, &val);
if (ret < 0)
die("no prev_pid field in sched_switch?");
pid = val;
pevent_register_comm(pevent, comm, pid);
comm = (char *)(record->data + sched_switch_next_field->offset);
ret = pevent_read_number_field(sched_switch_next_pid_field, record->data, &val);
if (ret < 0)
die("no next_pid field in sched_switch?");
pid = val;
pevent_register_comm(pevent, comm, pid);
}
static void
process_event(struct pevent *pevent, struct pevent_record *record, int type)
{
struct event_format *event;
const char *event_name;
unsigned long long val;
int pid;
int ret;
if (pending_pid >= 0) {
save_call_chain(pending_pid, pending_ips, pending_ips_idx, 1);
reset_pending_stack();
}
event = pevent_data_event_from_type(pevent, type);
event_name = event->name;
ret = pevent_read_number_field(common_pid_field, record->data, &val);
if (ret < 0)
die("no pid field for function?");
pid = val;
/*
* Even if function or function graph tracer is running,
* if the user ran with stack traces on events, we want to use
* that instead. But unfortunately, that stack doesn't come
* until after the event. Thus, we only add the event into
* the pending stack.
*/
push_stack_func(event_name);
copy_stack_to_pending(pid);
pop_stack_func();
}
static void
process_record(struct pevent *pevent, struct pevent_record *record)
{
unsigned long long val;
int type;
pevent_read_number_field(common_type_field, record->data, &val);
type = val;
if (type == function_type)
return process_function(pevent, record);
if (type == function_graph_entry_type)
return process_function_graph_entry(pevent, record);
if (type == function_graph_exit_type)
return process_function_graph_exit(pevent, record);
if (type == kernel_stack_type)
return process_kernel_stack(pevent, record);
if (type == sched_wakeup_type || type == sched_wakeup_new_type)
process_sched_wakeup(pevent, record, type);
else if (type == sched_switch_type)
process_sched_switch(pevent, record);
process_event(pevent, record, type);
}
static struct event_format *
update_event(struct pevent *pevent,
const char *sys, const char *name, int *id)
{
struct event_format *event;
event = pevent_find_event_by_name(pevent, sys, name);
if (!event)
return NULL;
*id = event->id;
return event;
}
static void update_sched_wakeup(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "sched", "sched_wakeup", &sched_wakeup_type);
if (!event)
return;
sched_wakeup_comm_field = pevent_find_field(event, "comm");
sched_wakeup_pid_field = pevent_find_field(event, "pid");
}
static void update_sched_wakeup_new(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "sched", "sched_wakeup_new", &sched_wakeup_new_type);
if (!event)
return;
sched_wakeup_new_comm_field = pevent_find_field(event, "comm");
sched_wakeup_new_pid_field = pevent_find_field(event, "pid");
}
static void update_sched_switch(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "sched", "sched_switch", &sched_switch_type);
if (!event)
return;
sched_switch_prev_field = pevent_find_field(event, "prev_comm");
sched_switch_next_field = pevent_find_field(event, "next_comm");
sched_switch_prev_pid_field = pevent_find_field(event, "prev_pid");
sched_switch_next_pid_field = pevent_find_field(event, "next_pid");
}
static void update_function(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "ftrace", "function", &function_type);
if (!event)
return;
function_ip_field = pevent_find_field(event, "ip");
function_parent_ip_field = pevent_find_field(event, "parent_ip");
}
static void update_function_graph_entry(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "ftrace", "funcgraph_entry", &function_graph_entry_type);
if (!event)
return;
function_graph_entry_func_field = pevent_find_field(event, "func");
function_graph_entry_depth_field = pevent_find_field(event, "depth");
}
static void update_function_graph_exit(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "ftrace", "funcgraph_exit", &function_graph_exit_type);
if (!event)
return;
function_graph_exit_func_field = pevent_find_field(event, "func");
function_graph_exit_depth_field = pevent_find_field(event, "depth");
function_graph_exit_calltime_field = pevent_find_field(event, "calltime");
function_graph_exit_rettime_field = pevent_find_field(event, "rettime");
function_graph_exit_overrun_field = pevent_find_field(event, "overrun");
}
static void update_kernel_stack(struct pevent *pevent)
{
struct event_format *event;
event = update_event(pevent, "ftrace", "kernel_stack", &kernel_stack_type);
if (!event)
return;
kernel_stack_caller_field = pevent_find_field(event, "caller");
}
enum field { NEXT_PTR, SIB_PTR };
static struct chain *next_ptr(struct chain *chain, enum field field)
{
if (field == NEXT_PTR)
return chain->next;
return chain->sibling;
}
static struct chain *split_chain(struct chain *orig, int size, enum field field)
{
struct chain *chain;
int i;
if (size < 2)
return NULL;
for (i = 1; i < (size + 1) / 2; i++, orig = next_ptr(orig, field))
;
if (field == NEXT_PTR) {
chain = orig->next;
orig->next = NULL;
} else {
chain = orig->sibling;
orig->sibling = NULL;
}
return chain;
}
static struct chain *
merge_chains(struct chain *a, int nr_a, struct chain *b, int nr_b, enum field field)
{
struct chain *chain;
struct chain *final;
struct chain **next = &final;
int i;
if (!a)
return b;
if (!b)
return a;
for (i = 0, chain = a; chain; i++, chain = next_ptr(chain, field))
;
if (i != nr_a)
die("WTF %d %d", i, nr_a);
chain = split_chain(a, nr_a, field);
a = merge_chains(chain, nr_a / 2, a, (nr_a + 1) / 2, field);
chain = split_chain(b, nr_b, field);
b = merge_chains(chain, nr_b / 2, b, (nr_b + 1) / 2, field);
while (a && b) {
if (a->count > b->count) {
*next = a;
if (field == NEXT_PTR)
next = &a->next;
else
next = &a->sibling;
a = *next;
*next = NULL;
} else {
*next = b;
if (field == NEXT_PTR)
next = &b->next;
else
next = &b->sibling;
b = *next;
*next = NULL;
}
}
if (a)
*next = a;
else
*next = b;
return final;
}
static void sort_chain_parents(struct chain *chain)
{
struct chain *parent;
parent = split_chain(chain->parents, chain->nr_parents, SIB_PTR);
chain->parents = merge_chains(parent, chain->nr_parents / 2,
chain->parents, (chain->nr_parents + 1) / 2,
SIB_PTR);
for (chain = chain->parents; chain; chain = chain->sibling)
sort_chain_parents(chain);
}
static void sort_chains(void)
{
struct chain *chain;
chain = split_chain(chains, nr_chains, NEXT_PTR);
/* The original always has more or equal to the split */
chains = merge_chains(chain, nr_chains / 2, chains, (nr_chains + 1) / 2, NEXT_PTR);
for (chain = chains; chain; chain = chain->next)
sort_chain_parents(chain);
}
static double get_percent(int total, int partial)
{
return ((double)partial / (double)total) * 100.0;
}
static int single_chain(struct chain *chain)
{
if (chain->nr_parents > 1)
return 0;
if (!chain->parents)
return 1;
return single_chain(chain->parents);
}
#define START " |\n"
#define TICK " --- "
#define BLANK " "
#define LINE " |"
#define INDENT " "
unsigned long long line_mask;
void make_indent(int indent)
{
int i;
for (i = 0; i < indent; i++) {
if (line_mask & (1 << i))
printf(LINE);
else
printf(INDENT);
}
}
static void
print_single_parent(struct chain *chain, int indent)
{
make_indent(indent);
printf(BLANK);
printf("%s\n", chain->parents->func);
}
static void
dump_chain(struct pevent *pevent, struct chain *chain, int indent)
{
if (!chain->parents)
return;
print_single_parent(chain, indent);
dump_chain(pevent, chain->parents, indent);
}
static void print_parents(struct pevent *pevent, struct chain *chain, int indent)
{
struct chain *parent = chain->parents;
int x;
if (single_chain(chain)) {
dump_chain(pevent, chain, indent);
return;
}
line_mask |= 1ULL << (indent);
for (x = 0; parent; x++, parent = parent->sibling) {
struct chain *save_parent;
make_indent(indent + 1);
printf("\n");
make_indent(indent + 1);
printf("--%%%.2f-- %s # %d\n",
get_percent(chain->count, parent->count),
parent->func, parent->count);
if (x == chain->nr_parents - 1)
line_mask &= (1ULL << indent) - 1;
if (single_chain(parent))
dump_chain(pevent, parent, indent + 1);
else {
save_parent = parent;
while (parent && parent->parents && parent->nr_parents < 2 &&
parent->parents->count == parent->count) {
print_single_parent(parent, indent + 1);
parent = parent->parents;
}
if (parent)
print_parents(pevent, parent, indent + 1);
parent = save_parent;
}
}
}
static void print_chains(struct pevent *pevent)
{
struct chain *chain = chains;
int pid;
for (; chain; chain = chain->next) {
pid = chain->pid_list->pid;
if (chain != chains)
printf("\n");
if (compact)
printf(" %%%3.2f <all pids> %30s #%d\n",
get_percent(total_counts, chain->count),
chain->func,
chain->count);
else
printf(" %%%3.2f (%d) %s %30s #%d\n",
get_percent(total_counts, chain->count),
pid,
pevent_data_comm_from_pid(pevent, pid),
chain->func,
chain->count);
printf(START);
if (chain->event)
printf(TICK "*%s*\n", chain->func);
else
printf(TICK "%s\n", chain->func);
print_parents(pevent, chain, 0);
}
}
static void do_trace_hist(struct tracecmd_input *handle)
{
struct pevent *pevent = tracecmd_get_pevent(handle);
struct event_format *event;
struct pevent_record *record;
int cpus;
int cpu;
int ret;
cpus = tracecmd_cpus(handle);
/* Need to get any event */
for (cpu = 0; cpu < cpus; cpu++) {
record = tracecmd_peek_data(handle, cpu);
if (record)
break;
}
if (!record)
die("No records found in file");
ret = pevent_data_type(pevent, record);
event = pevent_data_event_from_type(pevent, ret);
long_size = tracecmd_long_size(handle);
common_type_field = pevent_find_common_field(event, "common_type");
if (!common_type_field)
die("Can't find a 'type' field?");
common_pid_field = pevent_find_common_field(event, "common_pid");
if (!common_pid_field)
die("Can't find a 'pid' field?");
update_sched_wakeup(pevent);
update_sched_wakeup_new(pevent);
update_sched_switch(pevent);
update_function(pevent);
update_function_graph_entry(pevent);
update_function_graph_exit(pevent);
update_kernel_stack(pevent);
for (cpu = 0; cpu < cpus; cpu++) {
for (;;) {
struct pevent_record *record;
record = tracecmd_read_data(handle, cpu);
if (!record)
break;
/* If we missed events, just flush out the current stack */
if (record->missed_events)
flush_stack();
process_record(pevent, record);
free_record(record);
}
}
if (current_pid >= 0)
save_call_chain(current_pid, ips, ips_idx, 0);
if (pending_pid >= 0)
save_call_chain(pending_pid, pending_ips, pending_ips_idx, 1);
save_stored_stacks();
sort_chains();
print_chains(pevent);
}
void trace_hist(int argc, char **argv)
{
struct tracecmd_input *handle;
const char *input_file = NULL;
int instances;
int ret;
for (;;) {
int c;
c = getopt(argc-1, argv+1, "+hi:P");
if (c == -1)
break;
switch (c) {
case 'h':
usage(argv);
break;
case 'i':
if (input_file)
die("Only one input for historgram");
input_file = optarg;
break;
case 'P':
compact = 1;
break;
default:
usage(argv);
}
}
if ((argc - optind) >= 2) {
if (input_file)
usage(argv);
input_file = argv[optind + 1];
}
if (!input_file)
input_file = "trace.dat";
handle = tracecmd_alloc(input_file);
if (!handle)
die("can't open %s\n", input_file);
ret = tracecmd_read_headers(handle);
if (ret)
return;
ret = tracecmd_init_data(handle);
if (ret < 0)
die("failed to init data");
if (ret > 0)
die("trace-cmd hist does not work with latency traces\n");
instances = tracecmd_buffer_instances(handle);
if (instances) {
struct tracecmd_input *new_handle;
int i;
for (i = 0; i < instances; i++) {
new_handle = tracecmd_buffer_instance_handle(handle, i);
if (!new_handle) {
warning("could not retrieve handle %d", i);
continue;
}
do_trace_hist(new_handle);
tracecmd_close(new_handle);
}
} else {
do_trace_hist(handle);
}
tracecmd_close(handle);
}