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288 lines
10 KiB
C++
288 lines
10 KiB
C++
// Copyright 2017 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include "base/task/sequence_manager/thread_controller_impl.h"
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#include <algorithm>
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#include "base/bind.h"
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#include "base/memory/ptr_util.h"
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#include "base/message_loop/message_loop.h"
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#include "base/run_loop.h"
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#include "base/task/sequence_manager/lazy_now.h"
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#include "base/task/sequence_manager/sequenced_task_source.h"
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#include "base/trace_event/trace_event.h"
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namespace base {
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namespace sequence_manager {
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namespace internal {
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ThreadControllerImpl::ThreadControllerImpl(
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MessageLoop* message_loop,
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scoped_refptr<SingleThreadTaskRunner> task_runner,
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const TickClock* time_source)
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: message_loop_(message_loop),
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task_runner_(task_runner),
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associated_thread_(AssociatedThreadId::CreateUnbound()),
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message_loop_task_runner_(message_loop ? message_loop->task_runner()
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: nullptr),
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time_source_(time_source),
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weak_factory_(this) {
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immediate_do_work_closure_ =
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BindRepeating(&ThreadControllerImpl::DoWork, weak_factory_.GetWeakPtr(),
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WorkType::kImmediate);
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delayed_do_work_closure_ =
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BindRepeating(&ThreadControllerImpl::DoWork, weak_factory_.GetWeakPtr(),
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WorkType::kDelayed);
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}
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ThreadControllerImpl::~ThreadControllerImpl() = default;
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ThreadControllerImpl::AnySequence::AnySequence() = default;
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ThreadControllerImpl::AnySequence::~AnySequence() = default;
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ThreadControllerImpl::MainSequenceOnly::MainSequenceOnly() = default;
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ThreadControllerImpl::MainSequenceOnly::~MainSequenceOnly() = default;
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std::unique_ptr<ThreadControllerImpl> ThreadControllerImpl::Create(
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MessageLoop* message_loop,
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const TickClock* time_source) {
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return WrapUnique(new ThreadControllerImpl(
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message_loop, message_loop->task_runner(), time_source));
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}
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void ThreadControllerImpl::SetSequencedTaskSource(
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SequencedTaskSource* sequence) {
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DCHECK_CALLED_ON_VALID_SEQUENCE(associated_thread_->sequence_checker);
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DCHECK(sequence);
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DCHECK(!sequence_);
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sequence_ = sequence;
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}
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void ThreadControllerImpl::SetTimerSlack(TimerSlack timer_slack) {
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if (!message_loop_)
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return;
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message_loop_->SetTimerSlack(timer_slack);
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}
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void ThreadControllerImpl::ScheduleWork() {
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DCHECK(sequence_);
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AutoLock lock(any_sequence_lock_);
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// Don't post a DoWork if there's an immediate DoWork in flight or if we're
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// inside a top level DoWork. We can rely on a continuation being posted as
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// needed.
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if (any_sequence().immediate_do_work_posted ||
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(any_sequence().do_work_running_count > any_sequence().nesting_depth)) {
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return;
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}
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any_sequence().immediate_do_work_posted = true;
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TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"),
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"ThreadControllerImpl::ScheduleWork::PostTask");
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task_runner_->PostTask(FROM_HERE, immediate_do_work_closure_);
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}
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void ThreadControllerImpl::SetNextDelayedDoWork(LazyNow* lazy_now,
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TimeTicks run_time) {
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DCHECK_CALLED_ON_VALID_SEQUENCE(associated_thread_->sequence_checker);
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DCHECK(sequence_);
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if (main_sequence_only().next_delayed_do_work == run_time)
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return;
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// Cancel DoWork if it was scheduled and we set an "infinite" delay now.
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if (run_time == TimeTicks::Max()) {
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cancelable_delayed_do_work_closure_.Cancel();
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main_sequence_only().next_delayed_do_work = TimeTicks::Max();
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return;
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}
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// If DoWork is running then we don't need to do anything because it will post
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// a continuation as needed. Bailing out here is by far the most common case.
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if (main_sequence_only().do_work_running_count >
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main_sequence_only().nesting_depth) {
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return;
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}
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// If DoWork is about to run then we also don't need to do anything.
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{
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AutoLock lock(any_sequence_lock_);
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if (any_sequence().immediate_do_work_posted)
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return;
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}
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base::TimeDelta delay = std::max(TimeDelta(), run_time - lazy_now->Now());
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TRACE_EVENT1(TRACE_DISABLED_BY_DEFAULT("sequence_manager"),
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"ThreadControllerImpl::SetNextDelayedDoWork::PostDelayedTask",
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"delay_ms", delay.InMillisecondsF());
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main_sequence_only().next_delayed_do_work = run_time;
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// Reset also causes cancellation of the previous DoWork task.
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cancelable_delayed_do_work_closure_.Reset(delayed_do_work_closure_);
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task_runner_->PostDelayedTask(
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FROM_HERE, cancelable_delayed_do_work_closure_.callback(), delay);
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}
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bool ThreadControllerImpl::RunsTasksInCurrentSequence() {
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return task_runner_->RunsTasksInCurrentSequence();
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}
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const TickClock* ThreadControllerImpl::GetClock() {
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return time_source_;
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}
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void ThreadControllerImpl::SetDefaultTaskRunner(
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scoped_refptr<SingleThreadTaskRunner> task_runner) {
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if (!message_loop_)
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return;
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message_loop_->SetTaskRunner(task_runner);
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}
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void ThreadControllerImpl::RestoreDefaultTaskRunner() {
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if (!message_loop_)
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return;
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message_loop_->SetTaskRunner(message_loop_task_runner_);
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}
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void ThreadControllerImpl::WillQueueTask(PendingTask* pending_task) {
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task_annotator_.WillQueueTask("SequenceManager::PostTask", pending_task);
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}
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void ThreadControllerImpl::DoWork(WorkType work_type) {
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TRACE_EVENT0("sequence_manager", "ThreadControllerImpl::DoWork");
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DCHECK_CALLED_ON_VALID_SEQUENCE(associated_thread_->sequence_checker);
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DCHECK(sequence_);
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{
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AutoLock lock(any_sequence_lock_);
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if (work_type == WorkType::kImmediate)
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any_sequence().immediate_do_work_posted = false;
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any_sequence().do_work_running_count++;
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}
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main_sequence_only().do_work_running_count++;
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WeakPtr<ThreadControllerImpl> weak_ptr = weak_factory_.GetWeakPtr();
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// TODO(scheduler-dev): Consider moving to a time based work batch instead.
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for (int i = 0; i < main_sequence_only().work_batch_size_; i++) {
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Optional<PendingTask> task = sequence_->TakeTask();
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if (!task)
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break;
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{
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TRACE_TASK_EXECUTION("ThreadControllerImpl::RunTask", *task);
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task_annotator_.RunTask("ThreadControllerImpl::RunTask", &*task);
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}
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if (!weak_ptr)
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return;
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sequence_->DidRunTask();
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// NOTE: https://crbug.com/828835.
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// When we're running inside a nested RunLoop it may quit anytime, so any
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// outstanding pending tasks must run in the outer RunLoop
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// (see SequenceManagerTestWithMessageLoop.QuitWhileNested test).
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// Unfortunately, it's MessageLoop who's receving that signal and we can't
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// know it before we return from DoWork, hence, OnExitNestedRunLoop
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// will be called later. Since we must implement ThreadController and
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// SequenceManager in conformance with MessageLoop task runners, we need
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// to disable this batching optimization while nested.
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// Implementing RunLoop::Delegate ourselves will help to resolve this issue.
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if (main_sequence_only().nesting_depth > 0)
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break;
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}
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main_sequence_only().do_work_running_count--;
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{
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AutoLock lock(any_sequence_lock_);
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any_sequence().do_work_running_count--;
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DCHECK_GE(any_sequence().do_work_running_count, 0);
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LazyNow lazy_now(time_source_);
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TimeDelta delay_till_next_task = sequence_->DelayTillNextTask(&lazy_now);
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if (delay_till_next_task <= TimeDelta()) {
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// The next task needs to run immediately, post a continuation if needed.
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if (!any_sequence().immediate_do_work_posted) {
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any_sequence().immediate_do_work_posted = true;
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task_runner_->PostTask(FROM_HERE, immediate_do_work_closure_);
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}
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} else if (delay_till_next_task < TimeDelta::Max()) {
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// The next task needs to run after a delay, post a continuation if
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// needed.
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TimeTicks next_task_at = lazy_now.Now() + delay_till_next_task;
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if (next_task_at != main_sequence_only().next_delayed_do_work) {
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main_sequence_only().next_delayed_do_work = next_task_at;
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cancelable_delayed_do_work_closure_.Reset(delayed_do_work_closure_);
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task_runner_->PostDelayedTask(
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FROM_HERE, cancelable_delayed_do_work_closure_.callback(),
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delay_till_next_task);
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}
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} else {
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// There is no next task scheduled.
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main_sequence_only().next_delayed_do_work = TimeTicks::Max();
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}
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}
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}
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void ThreadControllerImpl::AddNestingObserver(
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RunLoop::NestingObserver* observer) {
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DCHECK_CALLED_ON_VALID_SEQUENCE(associated_thread_->sequence_checker);
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nesting_observer_ = observer;
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RunLoop::AddNestingObserverOnCurrentThread(this);
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}
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void ThreadControllerImpl::RemoveNestingObserver(
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RunLoop::NestingObserver* observer) {
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DCHECK_CALLED_ON_VALID_SEQUENCE(associated_thread_->sequence_checker);
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DCHECK_EQ(observer, nesting_observer_);
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nesting_observer_ = nullptr;
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RunLoop::RemoveNestingObserverOnCurrentThread(this);
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}
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const scoped_refptr<AssociatedThreadId>&
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ThreadControllerImpl::GetAssociatedThread() const {
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return associated_thread_;
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}
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void ThreadControllerImpl::OnBeginNestedRunLoop() {
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main_sequence_only().nesting_depth++;
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{
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// We just entered a nested run loop, make sure there's a DoWork posted or
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// the system will grind to a halt.
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AutoLock lock(any_sequence_lock_);
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any_sequence().nesting_depth++;
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if (!any_sequence().immediate_do_work_posted) {
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any_sequence().immediate_do_work_posted = true;
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TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"),
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"ThreadControllerImpl::OnBeginNestedRunLoop::PostTask");
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task_runner_->PostTask(FROM_HERE, immediate_do_work_closure_);
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}
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}
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if (nesting_observer_)
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nesting_observer_->OnBeginNestedRunLoop();
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}
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void ThreadControllerImpl::OnExitNestedRunLoop() {
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main_sequence_only().nesting_depth--;
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{
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AutoLock lock(any_sequence_lock_);
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any_sequence().nesting_depth--;
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DCHECK_GE(any_sequence().nesting_depth, 0);
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}
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if (nesting_observer_)
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nesting_observer_->OnExitNestedRunLoop();
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}
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void ThreadControllerImpl::SetWorkBatchSize(int work_batch_size) {
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main_sequence_only().work_batch_size_ = work_batch_size;
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}
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} // namespace internal
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} // namespace sequence_manager
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} // namespace base
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