tools/runqlat.py - platform/external/bcc - Git at Google

 #!/usr/bin/python
 # @lint-avoid-python-3-compatibility-imports
 #
 # runqlat   Run queue (scheduler) latency as a histogram.
 #           For Linux, uses BCC, eBPF.
 #
 # USAGE: runqlat [-h] [-T] [-m] [-P] [-L] [-p PID] [interval] [count]
 #
 # This measures the time a task spends waiting on a run queue for a turn
 # on-CPU, and shows this time as a histogram. This time should be small, but a
 # task may need to wait its turn due to CPU load.
 #
 # This measures two types of run queue latency:
 # 1. The time from a task being enqueued on a run queue to its context switch
 #    and execution. This traces ttwu_do_wakeup(), wake_up_new_task() ->
 #    finish_task_switch() with either raw tracepoints (if supported) or kprobes
 #    and instruments the run queue latency after a voluntary context switch.
 # 2. The time from when a task was involuntary context switched and still
 #    in the runnable state, to when it next executed. This is instrumented
 #    from finish_task_switch() alone.
 #
 # Copyright 2016 Netflix, Inc.
 # Licensed under the Apache License, Version 2.0 (the "License")
 #
 # 07-Feb-2016   Brendan Gregg   Created this.

 from __future__ import print_function
 from bcc import BPF
 from time import sleep, strftime
 import argparse

 # arguments
 examples = """examples:
     ./runqlat            # summarize run queue latency as a histogram
     ./runqlat 1 10       # print 1 second summaries, 10 times
     ./runqlat -mT 1      # 1s summaries, milliseconds, and timestamps
     ./runqlat -P         # show each PID separately
     ./runqlat -p 185     # trace PID 185 only
 """
 parser = argparse.ArgumentParser(
     description="Summarize run queue (scheduler) latency as a histogram",
     formatter_class=argparse.RawDescriptionHelpFormatter,
     epilog=examples)
 parser.add_argument("-T", "--timestamp", action="store_true",
     help="include timestamp on output")
 parser.add_argument("-m", "--milliseconds", action="store_true",
     help="millisecond histogram")
 parser.add_argument("-P", "--pids", action="store_true",
     help="print a histogram per process ID")
 # PID options are --pid and --pids, so namespaces should be --pidns (not done
 # yet) and --pidnss:
 parser.add_argument("--pidnss", action="store_true",
     help="print a histogram per PID namespace")
 parser.add_argument("-L", "--tids", action="store_true",
     help="print a histogram per thread ID")
 parser.add_argument("-p", "--pid",
     help="trace this PID only")
 parser.add_argument("interval", nargs="?", default=99999999,
     help="output interval, in seconds")
 parser.add_argument("count", nargs="?", default=99999999,
     help="number of outputs")
 parser.add_argument("--ebpf", action="store_true",
     help=argparse.SUPPRESS)
 args = parser.parse_args()
 countdown = int(args.count)
 debug = 0

 # define BPF program
 bpf_text = """
 #include <uapi/linux/ptrace.h>
 #include <linux/sched.h>
 #include <linux/nsproxy.h>
 #include <linux/pid_namespace.h>

 typedef struct pid_key {
     u64 id;    // work around
     u64 slot;
 } pid_key_t;

 typedef struct pidns_key {
     u64 id;    // work around
     u64 slot;
 } pidns_key_t;

 BPF_HASH(start, u32);
 STORAGE

 struct rq;

 // record enqueue timestamp
 static int trace_enqueue(u32 tgid, u32 pid)
 {
     if (FILTER || pid == 0)
         return 0;
     u64 ts = bpf_ktime_get_ns();
     start.update(&pid, &ts);
     return 0;
 }
 """

 bpf_text_kprobe = """
 int trace_wake_up_new_task(struct pt_regs *ctx, struct task_struct *p)
 {
     return trace_enqueue(p->tgid, p->pid);
 }

 int trace_ttwu_do_wakeup(struct pt_regs *ctx, struct rq *rq, struct task_struct *p,
     int wake_flags)
 {
     return trace_enqueue(p->tgid, p->pid);
 }

 // calculate latency
 int trace_run(struct pt_regs *ctx, struct task_struct *prev)
 {
     u32 pid, tgid;

     // ivcsw: treat like an enqueue event and store timestamp
     if (prev->state == TASK_RUNNING) {
         tgid = prev->tgid;
         pid = prev->pid;
         if (!(FILTER || pid == 0)) {
             u64 ts = bpf_ktime_get_ns();
             start.update(&pid, &ts);
         }
     }

     tgid = bpf_get_current_pid_tgid() >> 32;
     pid = bpf_get_current_pid_tgid();
     if (FILTER || pid == 0)
         return 0;
     u64 *tsp, delta;

     // fetch timestamp and calculate delta
     tsp = start.lookup(&pid);
     if (tsp == 0) {
         return 0;   // missed enqueue
     }
     delta = bpf_ktime_get_ns() - *tsp;
     FACTOR

     // store as histogram
     STORE

     start.delete(&pid);
     return 0;
 }
 """

 bpf_text_raw_tp = """
 RAW_TRACEPOINT_PROBE(sched_wakeup)
 {
     // TP_PROTO(struct task_struct *p)
     struct task_struct *p = (struct task_struct *)ctx->args[0];
     return trace_enqueue(p->tgid, p->pid);
 }

 RAW_TRACEPOINT_PROBE(sched_wakeup_new)
 {
     // TP_PROTO(struct task_struct *p)
     struct task_struct *p = (struct task_struct *)ctx->args[0];
     return trace_enqueue(p->tgid, p->pid);
 }

 RAW_TRACEPOINT_PROBE(sched_switch)
 {
     // TP_PROTO(bool preempt, struct task_struct *prev, struct task_struct *next)
     struct task_struct *prev = (struct task_struct *)ctx->args[1];
     struct task_struct *next = (struct task_struct *)ctx->args[2];
     u32 pid, tgid;

     // ivcsw: treat like an enqueue event and store timestamp
     if (prev->state == TASK_RUNNING) {
         tgid = prev->tgid;
         pid = prev->pid;
         if (!(FILTER || pid == 0)) {
             u64 ts = bpf_ktime_get_ns();
             start.update(&pid, &ts);
         }
     }

     tgid = next->tgid;
     pid = next->pid;
     if (FILTER || pid == 0)
         return 0;
     u64 *tsp, delta;

     // fetch timestamp and calculate delta
     tsp = start.lookup(&pid);
     if (tsp == 0) {
         return 0;   // missed enqueue
     }
     delta = bpf_ktime_get_ns() - *tsp;
     FACTOR

     // store as histogram
     STORE

     start.delete(&pid);
     return 0;
 }
 """

 is_support_raw_tp = BPF.support_raw_tracepoint()
 if is_support_raw_tp:
     bpf_text += bpf_text_raw_tp
 else:
     bpf_text += bpf_text_kprobe

 # code substitutions
 if args.pid:
     # pid from userspace point of view is thread group from kernel pov
     bpf_text = bpf_text.replace('FILTER', 'tgid != %s' % args.pid)
 else:
     bpf_text = bpf_text.replace('FILTER', '0')
 if args.milliseconds:
     bpf_text = bpf_text.replace('FACTOR', 'delta /= 1000000;')
     label = "msecs"
 else:
     bpf_text = bpf_text.replace('FACTOR', 'delta /= 1000;')
     label = "usecs"
 if args.pids or args.tids:
     section = "pid"
     pid = "tgid"
     if args.tids:
         pid = "pid"
         section = "tid"
     bpf_text = bpf_text.replace('STORAGE',
         'BPF_HISTOGRAM(dist, pid_key_t);')
     bpf_text = bpf_text.replace('STORE',
         'pid_key_t key = {.id = ' + pid + ', .slot = bpf_log2l(delta)}; ' +
         'dist.increment(key);')
 elif args.pidnss:
     section = "pidns"
     bpf_text = bpf_text.replace('STORAGE',
         'BPF_HISTOGRAM(dist, pidns_key_t);')
     bpf_text = bpf_text.replace('STORE', 'pidns_key_t key = ' +
         '{.id = prev->nsproxy->pid_ns_for_children->ns.inum, ' +
         '.slot = bpf_log2l(delta)}; dist.increment(key);')
 else:
     section = ""
     bpf_text = bpf_text.replace('STORAGE', 'BPF_HISTOGRAM(dist);')
     bpf_text = bpf_text.replace('STORE',
         'dist.increment(bpf_log2l(delta));')
 if debug or args.ebpf:
     print(bpf_text)
     if args.ebpf:
         exit()

 # load BPF program
 b = BPF(text=bpf_text)
 if not is_support_raw_tp:
     b.attach_kprobe(event="ttwu_do_wakeup", fn_name="trace_ttwu_do_wakeup")
     b.attach_kprobe(event="wake_up_new_task", fn_name="trace_wake_up_new_task")
     b.attach_kprobe(event="finish_task_switch", fn_name="trace_run")

 print("Tracing run queue latency... Hit Ctrl-C to end.")

 # output
 exiting = 0 if args.interval else 1
 dist = b.get_table("dist")
 while (1):
     try:
         sleep(int(args.interval))
     except KeyboardInterrupt:
         exiting = 1

     print()
     if args.timestamp:
         print("%-8s\n" % strftime("%H:%M:%S"), end="")

     dist.print_log2_hist(label, section, section_print_fn=int)
     dist.clear()

     countdown -= 1
     if exiting or countdown == 0:
         exit()
	#!/usr/bin/python
	# @lint-avoid-python-3-compatibility-imports
	#
	# runqlat Run queue (scheduler) latency as a histogram.
	# For Linux, uses BCC, eBPF.
	#
	# USAGE: runqlat [-h] [-T] [-m] [-P] [-L] [-p PID] [interval] [count]
	#
	# This measures the time a task spends waiting on a run queue for a turn
	# on-CPU, and shows this time as a histogram. This time should be small, but a
	# task may need to wait its turn due to CPU load.
	#
	# This measures two types of run queue latency:
	# 1. The time from a task being enqueued on a run queue to its context switch
	# and execution. This traces ttwu_do_wakeup(), wake_up_new_task() ->
	# finish_task_switch() with either raw tracepoints (if supported) or kprobes
	# and instruments the run queue latency after a voluntary context switch.
	# 2. The time from when a task was involuntary context switched and still
	# in the runnable state, to when it next executed. This is instrumented
	# from finish_task_switch() alone.
	#
	# Copyright 2016 Netflix, Inc.
	# Licensed under the Apache License, Version 2.0 (the "License")
	#
	# 07-Feb-2016 Brendan Gregg Created this.

	from __future__ import print_function
	from bcc import BPF
	from time import sleep, strftime
	import argparse

	# arguments
	examples = """examples:
	./runqlat # summarize run queue latency as a histogram
	./runqlat 1 10 # print 1 second summaries, 10 times
	./runqlat -mT 1 # 1s summaries, milliseconds, and timestamps
	./runqlat -P # show each PID separately
	./runqlat -p 185 # trace PID 185 only
	"""
	parser = argparse.ArgumentParser(
	description="Summarize run queue (scheduler) latency as a histogram",
	formatter_class=argparse.RawDescriptionHelpFormatter,
	epilog=examples)
	parser.add_argument("-T", "--timestamp", action="store_true",
	help="include timestamp on output")
	parser.add_argument("-m", "--milliseconds", action="store_true",
	help="millisecond histogram")
	parser.add_argument("-P", "--pids", action="store_true",
	help="print a histogram per process ID")
	# PID options are --pid and --pids, so namespaces should be --pidns (not done
	# yet) and --pidnss:
	parser.add_argument("--pidnss", action="store_true",
	help="print a histogram per PID namespace")
	parser.add_argument("-L", "--tids", action="store_true",
	help="print a histogram per thread ID")
	parser.add_argument("-p", "--pid",
	help="trace this PID only")
	parser.add_argument("interval", nargs="?", default=99999999,
	help="output interval, in seconds")
	parser.add_argument("count", nargs="?", default=99999999,
	help="number of outputs")
	parser.add_argument("--ebpf", action="store_true",
	help=argparse.SUPPRESS)
	args = parser.parse_args()
	countdown = int(args.count)
	debug = 0

	# define BPF program
	bpf_text = """
	#include <uapi/linux/ptrace.h>
	#include <linux/sched.h>
	#include <linux/nsproxy.h>
	#include <linux/pid_namespace.h>

	typedef struct pid_key {
	u64 id; // work around
	u64 slot;
	} pid_key_t;

	typedef struct pidns_key {
	u64 id; // work around
	u64 slot;
	} pidns_key_t;

	BPF_HASH(start, u32);
	STORAGE

	struct rq;

	// record enqueue timestamp
	static int trace_enqueue(u32 tgid, u32 pid)
	{
	if (FILTER \|\| pid == 0)
	return 0;
	u64 ts = bpf_ktime_get_ns();
	start.update(&pid, &ts);
	return 0;
	}
	"""

	bpf_text_kprobe = """
	int trace_wake_up_new_task(struct pt_regs ctx, struct task_struct p)
	{
	return trace_enqueue(p->tgid, p->pid);
	}

	int trace_ttwu_do_wakeup(struct pt_regs ctx, struct rq rq, struct task_struct *p,
	int wake_flags)
	{
	return trace_enqueue(p->tgid, p->pid);
	}

	// calculate latency
	int trace_run(struct pt_regs ctx, struct task_struct prev)
	{
	u32 pid, tgid;

	// ivcsw: treat like an enqueue event and store timestamp
	if (prev->state == TASK_RUNNING) {
	tgid = prev->tgid;
	pid = prev->pid;
	if (!(FILTER \|\| pid == 0)) {
	u64 ts = bpf_ktime_get_ns();
	start.update(&pid, &ts);
	}
	}

	tgid = bpf_get_current_pid_tgid() >> 32;
	pid = bpf_get_current_pid_tgid();
	if (FILTER \|\| pid == 0)
	return 0;
	u64 *tsp, delta;

	// fetch timestamp and calculate delta
	tsp = start.lookup(&pid);
	if (tsp == 0) {
	return 0; // missed enqueue
	}
	delta = bpf_ktime_get_ns() - *tsp;
	FACTOR

	// store as histogram
	STORE

	start.delete(&pid);
	return 0;
	}
	"""

	bpf_text_raw_tp = """
	RAW_TRACEPOINT_PROBE(sched_wakeup)
	{
	// TP_PROTO(struct task_struct *p)
	struct task_struct p = (struct task_struct )ctx->args[0];
	return trace_enqueue(p->tgid, p->pid);
	}

	RAW_TRACEPOINT_PROBE(sched_wakeup_new)
	{
	// TP_PROTO(struct task_struct *p)
	struct task_struct p = (struct task_struct )ctx->args[0];
	return trace_enqueue(p->tgid, p->pid);
	}

	RAW_TRACEPOINT_PROBE(sched_switch)
	{
	// TP_PROTO(bool preempt, struct task_struct prev, struct task_struct next)
	struct task_struct prev = (struct task_struct )ctx->args[1];
	struct task_struct next = (struct task_struct )ctx->args[2];
	u32 pid, tgid;

	// ivcsw: treat like an enqueue event and store timestamp
	if (prev->state == TASK_RUNNING) {
	tgid = prev->tgid;
	pid = prev->pid;
	if (!(FILTER \|\| pid == 0)) {
	u64 ts = bpf_ktime_get_ns();
	start.update(&pid, &ts);
	}
	}

	tgid = next->tgid;
	pid = next->pid;
	if (FILTER \|\| pid == 0)
	return 0;
	u64 *tsp, delta;

	// fetch timestamp and calculate delta
	tsp = start.lookup(&pid);
	if (tsp == 0) {
	return 0; // missed enqueue
	}
	delta = bpf_ktime_get_ns() - *tsp;
	FACTOR

	// store as histogram
	STORE

	start.delete(&pid);
	return 0;
	}
	"""

	is_support_raw_tp = BPF.support_raw_tracepoint()
	if is_support_raw_tp:
	bpf_text += bpf_text_raw_tp
	else:
	bpf_text += bpf_text_kprobe

	# code substitutions
	if args.pid:
	# pid from userspace point of view is thread group from kernel pov
	bpf_text = bpf_text.replace('FILTER', 'tgid != %s' % args.pid)
	else:
	bpf_text = bpf_text.replace('FILTER', '0')
	if args.milliseconds:
	bpf_text = bpf_text.replace('FACTOR', 'delta /= 1000000;')
	label = "msecs"
	else:
	bpf_text = bpf_text.replace('FACTOR', 'delta /= 1000;')
	label = "usecs"
	if args.pids or args.tids:
	section = "pid"
	pid = "tgid"
	if args.tids:
	pid = "pid"
	section = "tid"
	bpf_text = bpf_text.replace('STORAGE',
	'BPF_HISTOGRAM(dist, pid_key_t);')
	bpf_text = bpf_text.replace('STORE',
	'pid_key_t key = {.id = ' + pid + ', .slot = bpf_log2l(delta)}; ' +
	'dist.increment(key);')
	elif args.pidnss:
	section = "pidns"
	bpf_text = bpf_text.replace('STORAGE',
	'BPF_HISTOGRAM(dist, pidns_key_t);')
	bpf_text = bpf_text.replace('STORE', 'pidns_key_t key = ' +
	'{.id = prev->nsproxy->pid_ns_for_children->ns.inum, ' +
	'.slot = bpf_log2l(delta)}; dist.increment(key);')
	else:
	section = ""
	bpf_text = bpf_text.replace('STORAGE', 'BPF_HISTOGRAM(dist);')
	bpf_text = bpf_text.replace('STORE',
	'dist.increment(bpf_log2l(delta));')
	if debug or args.ebpf:
	print(bpf_text)
	if args.ebpf:
	exit()

	# load BPF program
	b = BPF(text=bpf_text)
	if not is_support_raw_tp:
	b.attach_kprobe(event="ttwu_do_wakeup", fn_name="trace_ttwu_do_wakeup")
	b.attach_kprobe(event="wake_up_new_task", fn_name="trace_wake_up_new_task")
	b.attach_kprobe(event="finish_task_switch", fn_name="trace_run")

	print("Tracing run queue latency... Hit Ctrl-C to end.")

	# output
	exiting = 0 if args.interval else 1
	dist = b.get_table("dist")
	while (1):
	try:
	sleep(int(args.interval))
	except KeyboardInterrupt:
	exiting = 1

	print()
	if args.timestamp:
	print("%-8s\n" % strftime("%H:%M:%S"), end="")

	dist.print_log2_hist(label, section, section_print_fn=int)
	dist.clear()

	countdown -= 1
	if exiting or countdown == 0:
	exit()