src/base/task/task_scheduler/service_thread.cc - cobalt - Git at Google

 // Copyright 2018 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "base/task/task_scheduler/service_thread.h"

 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/debug/alias.h"
 #include "base/rand_util.h"
 #include "base/stl_util.h"
 #include "base/task/post_task.h"
 #include "base/task/task_scheduler/task_scheduler.h"
 #include "base/task/task_scheduler/task_tracker.h"
 #include "base/task/task_traits.h"

 namespace base {
 namespace internal {

 namespace {

 TimeDelta g_heartbeat_for_testing = TimeDelta();

 }  // namespace

 ServiceThread::ServiceThread(const TaskTracker* task_tracker,
                              RepeatingClosure report_heartbeat_metrics_callback)
     : Thread("TaskSchdSvcThd"),
       task_tracker_(task_tracker),
       report_heartbeat_metrics_callback_(
           std::move(report_heartbeat_metrics_callback)) {}

 ServiceThread::~ServiceThread() = default;

 // static
 void ServiceThread::SetHeartbeatIntervalForTesting(TimeDelta heartbeat) {
   g_heartbeat_for_testing = heartbeat;
 }

 void ServiceThread::Init() {
   // In unit tests we sometimes do not have a fully functional TaskScheduler
   // environment, do not perform the heartbeat report in that case since it
   // relies on such an environment.
   if (TaskScheduler::GetInstance()) {
     // Compute the histogram every hour (with a slight offset to drift if that
     // hour tick happens to line up with specific events). Once per hour per
     // user was deemed sufficient to gather a reliable metric.
     constexpr TimeDelta kHeartbeat = TimeDelta::FromMinutes(59);

     heartbeat_metrics_timer_.Start(
         FROM_HERE,
         g_heartbeat_for_testing.is_zero() ? kHeartbeat
                                           : g_heartbeat_for_testing,
         BindRepeating(&ServiceThread::ReportHeartbeatMetrics,
                       Unretained(this)));
   }
 }

 NOINLINE void ServiceThread::Run(RunLoop* run_loop) {
   const int line_number = __LINE__;
   Thread::Run(run_loop);
   base::debug::Alias(&line_number);
 }

 void ServiceThread::ReportHeartbeatMetrics() const {
   report_heartbeat_metrics_callback_.Run();
   PerformHeartbeatLatencyReport();
 }

 void ServiceThread::PerformHeartbeatLatencyReport() const {
   if (!task_tracker_)
     return;

   static CONSTEXPR TaskTraits kReportedTraits[] = {
       {TaskPriority::BEST_EFFORT},   {TaskPriority::BEST_EFFORT, MayBlock()},
       {TaskPriority::USER_VISIBLE},  {TaskPriority::USER_VISIBLE, MayBlock()},
       {TaskPriority::USER_BLOCKING}, {TaskPriority::USER_BLOCKING, MayBlock()}};

   // Only record latency for one set of TaskTraits per report to avoid bias in
   // the order in which tasks are posted (should we record all at once) as well
   // as to avoid spinning up many worker threads to process this report if the
   // scheduler is currently idle (each pool keeps at least one idle thread so a
   // single task isn't an issue).

   // Invoke RandInt() out-of-line to ensure it's obtained before
   // TimeTicks::Now().
   const TaskTraits& profiled_traits =
       kReportedTraits[RandInt(0, base::size(kReportedTraits) - 1)];

   // Post through the static API to time the full stack. Use a new Now() for
   // every set of traits in case PostTaskWithTraits() itself is slow.
   // Bonus: this appraoch also includes the overhead of Bind() in the reported
   // latency).
   // TODO(jessemckenna): pass |profiled_traits| directly to
   // RecordHeartbeatLatencyAndTasksRunWhileQueuingHistograms() once compiler
   // error on NaCl is fixed
   TaskPriority task_priority = profiled_traits.priority();
   bool may_block = profiled_traits.may_block();
   base::PostTaskWithTraits(
       FROM_HERE, profiled_traits,
       BindOnce(
           &TaskTracker::RecordHeartbeatLatencyAndTasksRunWhileQueuingHistograms,
           Unretained(task_tracker_), task_priority, may_block, TimeTicks::Now(),
           task_tracker_->GetNumTasksRun()));
 }

 }  // namespace internal
 }  // namespace base
	// Copyright 2018 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "base/task/task_scheduler/service_thread.h"

	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/debug/alias.h"
	#include "base/rand_util.h"
	#include "base/stl_util.h"
	#include "base/task/post_task.h"
	#include "base/task/task_scheduler/task_scheduler.h"
	#include "base/task/task_scheduler/task_tracker.h"
	#include "base/task/task_traits.h"

	namespace base {
	namespace internal {

	namespace {

	TimeDelta g_heartbeat_for_testing = TimeDelta();

	} // namespace

	ServiceThread::ServiceThread(const TaskTracker* task_tracker,
	RepeatingClosure report_heartbeat_metrics_callback)
	: Thread("TaskSchdSvcThd"),
	task_tracker_(task_tracker),
	report_heartbeat_metrics_callback_(
	std::move(report_heartbeat_metrics_callback)) {}

	ServiceThread::~ServiceThread() = default;

	// static
	void ServiceThread::SetHeartbeatIntervalForTesting(TimeDelta heartbeat) {
	g_heartbeat_for_testing = heartbeat;
	}

	void ServiceThread::Init() {
	// In unit tests we sometimes do not have a fully functional TaskScheduler
	// environment, do not perform the heartbeat report in that case since it
	// relies on such an environment.
	if (TaskScheduler::GetInstance()) {
	// Compute the histogram every hour (with a slight offset to drift if that
	// hour tick happens to line up with specific events). Once per hour per
	// user was deemed sufficient to gather a reliable metric.
	constexpr TimeDelta kHeartbeat = TimeDelta::FromMinutes(59);

	heartbeat_metrics_timer_.Start(
	FROM_HERE,
	g_heartbeat_for_testing.is_zero() ? kHeartbeat
	: g_heartbeat_for_testing,
	BindRepeating(&ServiceThread::ReportHeartbeatMetrics,
	Unretained(this)));
	}
	}

	NOINLINE void ServiceThread::Run(RunLoop* run_loop) {
	const int line_number = __LINE__;
	Thread::Run(run_loop);
	base::debug::Alias(&line_number);
	}

	void ServiceThread::ReportHeartbeatMetrics() const {
	report_heartbeat_metrics_callback_.Run();
	PerformHeartbeatLatencyReport();
	}

	void ServiceThread::PerformHeartbeatLatencyReport() const {
	if (!task_tracker_)
	return;

	static CONSTEXPR TaskTraits kReportedTraits[] = {
	{TaskPriority::BEST_EFFORT}, {TaskPriority::BEST_EFFORT, MayBlock()},
	{TaskPriority::USER_VISIBLE}, {TaskPriority::USER_VISIBLE, MayBlock()},
	{TaskPriority::USER_BLOCKING}, {TaskPriority::USER_BLOCKING, MayBlock()}};

	// Only record latency for one set of TaskTraits per report to avoid bias in
	// the order in which tasks are posted (should we record all at once) as well
	// as to avoid spinning up many worker threads to process this report if the
	// scheduler is currently idle (each pool keeps at least one idle thread so a
	// single task isn't an issue).

	// Invoke RandInt() out-of-line to ensure it's obtained before
	// TimeTicks::Now().
	const TaskTraits& profiled_traits =
	kReportedTraits[RandInt(0, base::size(kReportedTraits) - 1)];

	// Post through the static API to time the full stack. Use a new Now() for
	// every set of traits in case PostTaskWithTraits() itself is slow.
	// Bonus: this appraoch also includes the overhead of Bind() in the reported
	// latency).
	// TODO(jessemckenna): pass \|profiled_traits\| directly to
	// RecordHeartbeatLatencyAndTasksRunWhileQueuingHistograms() once compiler
	// error on NaCl is fixed
	TaskPriority task_priority = profiled_traits.priority();
	bool may_block = profiled_traits.may_block();
	base::PostTaskWithTraits(
	FROM_HERE, profiled_traits,
	BindOnce(
	&TaskTracker::RecordHeartbeatLatencyAndTasksRunWhileQueuingHistograms,
	Unretained(task_tracker_), task_priority, may_block, TimeTicks::Now(),
	task_tracker_->GetNumTasksRun()));
	}

	} // namespace internal
	} // namespace base