// 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/sequence_manager/sequence_manager_impl.h" #include #include #include "base/bind.h" #include "base/bit_cast.h" #include "base/compiler_specific.h" #include "base/debug/crash_logging.h" #include "base/memory/ptr_util.h" #include "base/metrics/histogram_macros.h" #include "base/rand_util.h" #include "base/task/sequence_manager/real_time_domain.h" #include "base/task/sequence_manager/task_time_observer.h" #include "base/task/sequence_manager/thread_controller_impl.h" #include "base/task/sequence_manager/work_queue.h" #include "base/task/sequence_manager/work_queue_sets.h" #include "base/time/default_tick_clock.h" #include "base/time/tick_clock.h" #include "base/trace_event/trace_event.h" #include "build/build_config.h" namespace base { namespace sequence_manager { std::unique_ptr CreateSequenceManagerOnCurrentThread() { return internal::SequenceManagerImpl::CreateOnCurrentThread(); } namespace internal { namespace { constexpr base::TimeDelta kLongTaskTraceEventThreshold = base::TimeDelta::FromMilliseconds(50); // Proportion of tasks which will record thread time for metrics. const double kTaskSamplingRateForRecordingCPUTime = 0.01; // Proprortion of SequenceManagers which will record thread time for each task, // enabling advanced metrics. const double kThreadSamplingRateForRecordingCPUTime = 0.0001; // Magic value to protect against memory corruption and bail out // early when detected. constexpr int kMemoryCorruptionSentinelValue = 0xdeadbeef; void SweepCanceledDelayedTasksInQueue( internal::TaskQueueImpl* queue, std::map* time_domain_now) { TimeDomain* time_domain = queue->GetTimeDomain(); if (time_domain_now->find(time_domain) == time_domain_now->end()) time_domain_now->insert(std::make_pair(time_domain, time_domain->Now())); queue->SweepCanceledDelayedTasks(time_domain_now->at(time_domain)); } SequenceManager::MetricRecordingSettings InitializeMetricRecordingSettings() { bool cpu_time_recording_always_on = base::RandDouble() < kThreadSamplingRateForRecordingCPUTime; return SequenceManager::MetricRecordingSettings( cpu_time_recording_always_on, kTaskSamplingRateForRecordingCPUTime); } } // namespace SequenceManagerImpl::SequenceManagerImpl( std::unique_ptr controller) : graceful_shutdown_helper_(new internal::GracefulQueueShutdownHelper()), controller_(std::move(controller)), metric_recording_settings_(InitializeMetricRecordingSettings()), memory_corruption_sentinel_(kMemoryCorruptionSentinelValue), weak_factory_(this) { // TODO(altimin): Create a sequence checker here. DCHECK(controller_->RunsTasksInCurrentSequence()); TRACE_EVENT_WARMUP_CATEGORY("sequence_manager"); TRACE_EVENT_WARMUP_CATEGORY(TRACE_DISABLED_BY_DEFAULT("sequence_manager")); TRACE_EVENT_WARMUP_CATEGORY( TRACE_DISABLED_BY_DEFAULT("sequence_manager.debug")); TRACE_EVENT_WARMUP_CATEGORY( TRACE_DISABLED_BY_DEFAULT("sequence_manager.verbose_snapshots")); TRACE_EVENT_OBJECT_CREATED_WITH_ID( TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager", this); main_thread_only().selector.SetTaskQueueSelectorObserver(this); RegisterTimeDomain(main_thread_only().real_time_domain.get()); controller_->SetSequencedTaskSource(this); controller_->AddNestingObserver(this); } SequenceManagerImpl::~SequenceManagerImpl() { TRACE_EVENT_OBJECT_DELETED_WITH_ID( TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager", this); // TODO(altimin): restore default task runner automatically when // ThreadController is destroyed. controller_->RestoreDefaultTaskRunner(); for (internal::TaskQueueImpl* queue : main_thread_only().active_queues) { main_thread_only().selector.RemoveQueue(queue); queue->UnregisterTaskQueue(); } main_thread_only().active_queues.clear(); main_thread_only().queues_to_gracefully_shutdown.clear(); graceful_shutdown_helper_->OnSequenceManagerDeleted(); main_thread_only().selector.SetTaskQueueSelectorObserver(nullptr); controller_->RemoveNestingObserver(this); } SequenceManagerImpl::AnyThread::AnyThread() = default; SequenceManagerImpl::AnyThread::~AnyThread() = default; SequenceManagerImpl::MainThreadOnly::MainThreadOnly() : random_generator(RandUint64()), uniform_distribution(0.0, 1.0), real_time_domain(new internal::RealTimeDomain()) {} SequenceManagerImpl::MainThreadOnly::~MainThreadOnly() = default; // static std::unique_ptr SequenceManagerImpl::CreateOnCurrentThread() { return WrapUnique( new SequenceManagerImpl(internal::ThreadControllerImpl::Create( MessageLoop::current(), DefaultTickClock::GetInstance()))); } void SequenceManagerImpl::RegisterTimeDomain(TimeDomain* time_domain) { main_thread_only().time_domains.insert(time_domain); time_domain->OnRegisterWithSequenceManager(this); } void SequenceManagerImpl::UnregisterTimeDomain(TimeDomain* time_domain) { main_thread_only().time_domains.erase(time_domain); } TimeDomain* SequenceManagerImpl::GetRealTimeDomain() const { return main_thread_only().real_time_domain.get(); } std::unique_ptr SequenceManagerImpl::CreateTaskQueueImpl(const TaskQueue::Spec& spec) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); TimeDomain* time_domain = spec.time_domain ? spec.time_domain : main_thread_only().real_time_domain.get(); DCHECK(main_thread_only().time_domains.find(time_domain) != main_thread_only().time_domains.end()); std::unique_ptr task_queue = std::make_unique(this, time_domain, spec); main_thread_only().active_queues.insert(task_queue.get()); main_thread_only().selector.AddQueue(task_queue.get()); return task_queue; } void SequenceManagerImpl::SetObserver(Observer* observer) { main_thread_only().observer = observer; } bool SequenceManagerImpl::AddToIncomingImmediateWorkList( internal::TaskQueueImpl* task_queue, internal::EnqueueOrder enqueue_order) { AutoLock lock(any_thread_lock_); // Check if |task_queue| is already in the linked list. if (task_queue->immediate_work_list_storage()->queue) return false; // Insert into the linked list. task_queue->immediate_work_list_storage()->queue = task_queue; task_queue->immediate_work_list_storage()->order = enqueue_order; task_queue->immediate_work_list_storage()->next = any_thread().incoming_immediate_work_list; any_thread().incoming_immediate_work_list = task_queue->immediate_work_list_storage(); return true; } void SequenceManagerImpl::RemoveFromIncomingImmediateWorkList( internal::TaskQueueImpl* task_queue) { AutoLock lock(any_thread_lock_); internal::IncomingImmediateWorkList** prev = &any_thread().incoming_immediate_work_list; while (*prev) { if ((*prev)->queue == task_queue) { *prev = (*prev)->next; break; } prev = &(*prev)->next; } task_queue->immediate_work_list_storage()->next = nullptr; task_queue->immediate_work_list_storage()->queue = nullptr; } void SequenceManagerImpl::UnregisterTaskQueueImpl( std::unique_ptr task_queue) { TRACE_EVENT1("sequence_manager", "SequenceManagerImpl::UnregisterTaskQueue", "queue_name", task_queue->GetName()); DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); main_thread_only().selector.RemoveQueue(task_queue.get()); // After UnregisterTaskQueue returns no new tasks can be posted. // It's important to call it first to avoid race condition between removing // the task queue from various lists here and adding it to the same lists // when posting a task. task_queue->UnregisterTaskQueue(); // Remove |task_queue| from the linked list if present. // This is O(n). We assume this will be a relatively infrequent operation. RemoveFromIncomingImmediateWorkList(task_queue.get()); // Add |task_queue| to |main_thread_only().queues_to_delete| so we can prevent // it from being freed while any of our structures hold hold a raw pointer to // it. main_thread_only().active_queues.erase(task_queue.get()); main_thread_only().queues_to_delete[task_queue.get()] = std::move(task_queue); } void SequenceManagerImpl::ReloadEmptyWorkQueues() { // There are two cases where a queue needs reloading. First, it might be // completely empty and we've just posted a task (this method handles that // case). Secondly if the work queue becomes empty in when calling // WorkQueue::TakeTaskFromWorkQueue (handled there). for (internal::TaskQueueImpl* queue : main_thread_only().queues_to_reload) { queue->ReloadImmediateWorkQueueIfEmpty(); } } void SequenceManagerImpl::WakeUpReadyDelayedQueues(LazyNow* lazy_now) { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManagerImpl::WakeUpReadyDelayedQueues"); for (TimeDomain* time_domain : main_thread_only().time_domains) { if (time_domain == main_thread_only().real_time_domain.get()) { time_domain->WakeUpReadyDelayedQueues(lazy_now); } else { LazyNow time_domain_lazy_now = time_domain->CreateLazyNow(); time_domain->WakeUpReadyDelayedQueues(&time_domain_lazy_now); } } } void SequenceManagerImpl::OnBeginNestedRunLoop() { main_thread_only().nesting_depth++; if (main_thread_only().observer) main_thread_only().observer->OnBeginNestedRunLoop(); } void SequenceManagerImpl::OnExitNestedRunLoop() { main_thread_only().nesting_depth--; DCHECK_GE(main_thread_only().nesting_depth, 0); if (main_thread_only().nesting_depth == 0) { // While we were nested some non-nestable tasks may have been deferred. // We push them back onto the *front* of their original work queues, // that's why we iterate |non_nestable_task_queue| in FIFO order. while (!main_thread_only().non_nestable_task_queue.empty()) { internal::TaskQueueImpl::DeferredNonNestableTask& non_nestable_task = main_thread_only().non_nestable_task_queue.back(); non_nestable_task.task_queue->RequeueDeferredNonNestableTask( std::move(non_nestable_task)); main_thread_only().non_nestable_task_queue.pop_back(); } } if (main_thread_only().observer) main_thread_only().observer->OnExitNestedRunLoop(); } void SequenceManagerImpl::OnQueueHasIncomingImmediateWork( internal::TaskQueueImpl* queue, internal::EnqueueOrder enqueue_order, bool queue_is_blocked) { if (AddToIncomingImmediateWorkList(queue, enqueue_order) && !queue_is_blocked) controller_->ScheduleWork(); } void SequenceManagerImpl::MaybeScheduleImmediateWork( const Location& from_here) { controller_->ScheduleWork(); } void SequenceManagerImpl::SetNextDelayedDoWork(LazyNow* lazy_now, TimeTicks run_time) { controller_->SetNextDelayedDoWork(lazy_now, run_time); } Optional SequenceManagerImpl::TakeTask() { CHECK(Validate()); DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); TRACE_EVENT0("sequence_manager", "SequenceManagerImpl::TakeTask"); { AutoLock lock(any_thread_lock_); main_thread_only().queues_to_reload.clear(); for (internal::IncomingImmediateWorkList* iter = any_thread().incoming_immediate_work_list; iter; iter = iter->next) { main_thread_only().queues_to_reload.push_back(iter->queue); iter->queue = nullptr; } any_thread().incoming_immediate_work_list = nullptr; } // It's important we call ReloadEmptyWorkQueues out side of the lock to // avoid a lock order inversion. ReloadEmptyWorkQueues(); LazyNow lazy_now(controller_->GetClock()); WakeUpReadyDelayedQueues(&lazy_now); while (true) { internal::WorkQueue* work_queue = nullptr; bool should_run = main_thread_only().selector.SelectWorkQueueToService(&work_queue); TRACE_EVENT_OBJECT_SNAPSHOT_WITH_ID( TRACE_DISABLED_BY_DEFAULT("sequence_manager.debug"), "SequenceManager", this, AsValueWithSelectorResult(should_run, work_queue)); if (!should_run) return nullopt; // If the head task was canceled, remove it and run the selector again. if (work_queue->RemoveAllCanceledTasksFromFront()) continue; if (work_queue->GetFrontTask()->nestable == Nestable::kNonNestable && main_thread_only().nesting_depth > 0) { // Defer non-nestable work. NOTE these tasks can be arbitrarily delayed so // the additional delay should not be a problem. // Note because we don't delete queues while nested, it's perfectly OK to // store the raw pointer for |queue| here. internal::TaskQueueImpl::DeferredNonNestableTask deferred_task{ work_queue->TakeTaskFromWorkQueue(), work_queue->task_queue(), work_queue->queue_type()}; main_thread_only().non_nestable_task_queue.push_back( std::move(deferred_task)); continue; } main_thread_only().task_execution_stack.emplace_back( work_queue->TakeTaskFromWorkQueue(), work_queue->task_queue(), InitializeTaskTiming(work_queue->task_queue())); UMA_HISTOGRAM_COUNTS_1000("TaskQueueManager.ActiveQueuesCount", main_thread_only().active_queues.size()); ExecutingTask& executing_task = *main_thread_only().task_execution_stack.rbegin(); NotifyWillProcessTask(&executing_task, &lazy_now); return std::move(executing_task.pending_task); } } void SequenceManagerImpl::DidRunTask() { LazyNow lazy_now(controller_->GetClock()); ExecutingTask& executing_task = *main_thread_only().task_execution_stack.rbegin(); NotifyDidProcessTask(&executing_task, &lazy_now); main_thread_only().task_execution_stack.pop_back(); if (main_thread_only().nesting_depth == 0) CleanUpQueues(); } TimeDelta SequenceManagerImpl::DelayTillNextTask(LazyNow* lazy_now) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); // If the selector has non-empty queues we trivially know there is immediate // work to be done. if (!main_thread_only().selector.AllEnabledWorkQueuesAreEmpty()) return TimeDelta(); // Its possible the selectors state is dirty because ReloadEmptyWorkQueues // hasn't been called yet. This check catches the case of fresh incoming work. { AutoLock lock(any_thread_lock_); for (const internal::IncomingImmediateWorkList* iter = any_thread().incoming_immediate_work_list; iter; iter = iter->next) { if (iter->queue->CouldTaskRun(iter->order)) return TimeDelta(); } } // Otherwise we need to find the shortest delay, if any. NB we don't need to // call WakeUpReadyDelayedQueues because it's assumed DelayTillNextTask will // return TimeDelta>() if the delayed task is due to run now. TimeDelta delay_till_next_task = TimeDelta::Max(); for (TimeDomain* time_domain : main_thread_only().time_domains) { Optional delay = time_domain->DelayTillNextTask(lazy_now); if (!delay) continue; if (*delay < delay_till_next_task) delay_till_next_task = *delay; } return delay_till_next_task; } void SequenceManagerImpl::WillQueueTask( internal::TaskQueueImpl::Task* pending_task) { controller_->WillQueueTask(pending_task); } TaskQueue::TaskTiming SequenceManagerImpl::InitializeTaskTiming( internal::TaskQueueImpl* task_queue) { bool records_wall_time = (task_queue->GetShouldNotifyObservers() && main_thread_only().task_time_observers.might_have_observers()) || task_queue->RequiresTaskTiming(); bool records_thread_time = records_wall_time && ShouldRecordCPUTimeForTask(); return TaskQueue::TaskTiming(records_wall_time, records_thread_time); } void SequenceManagerImpl::NotifyWillProcessTask(ExecutingTask* executing_task, LazyNow* time_before_task) { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManagerImpl::NotifyWillProcessTaskObservers"); if (executing_task->task_queue->GetQuiescenceMonitored()) main_thread_only().task_was_run_on_quiescence_monitored_queue = true; #if !defined(OS_NACL) debug::SetCrashKeyString( main_thread_only().file_name_crash_key, executing_task->pending_task.posted_from.file_name()); debug::SetCrashKeyString( main_thread_only().function_name_crash_key, executing_task->pending_task.posted_from.function_name()); #endif // OS_NACL executing_task->task_timing.RecordTaskStart(time_before_task); if (!executing_task->task_queue->GetShouldNotifyObservers()) return; { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.WillProcessTaskObservers"); for (auto& observer : main_thread_only().task_observers) observer.WillProcessTask(executing_task->pending_task); } { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.QueueNotifyWillProcessTask"); executing_task->task_queue->NotifyWillProcessTask( executing_task->pending_task); } bool notify_time_observers = main_thread_only().task_time_observers.might_have_observers() || executing_task->task_queue->RequiresTaskTiming(); if (!notify_time_observers) return; if (main_thread_only().nesting_depth == 0) { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.WillProcessTaskTimeObservers"); for (auto& observer : main_thread_only().task_time_observers) observer.WillProcessTask(executing_task->task_timing.start_time()); } { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.QueueOnTaskStarted"); executing_task->task_queue->OnTaskStarted(executing_task->pending_task, executing_task->task_timing); } } void SequenceManagerImpl::NotifyDidProcessTask(ExecutingTask* executing_task, LazyNow* time_after_task) { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManagerImpl::NotifyDidProcessTaskObservers"); executing_task->task_timing.RecordTaskEnd(time_after_task); const TaskQueue::TaskTiming& task_timing = executing_task->task_timing; if (!executing_task->task_queue->GetShouldNotifyObservers()) return; if (task_timing.has_wall_time() && main_thread_only().nesting_depth == 0) { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.DidProcessTaskTimeObservers"); for (auto& observer : main_thread_only().task_time_observers) { observer.DidProcessTask(task_timing.start_time(), task_timing.end_time()); } } { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.DidProcessTaskObservers"); for (auto& observer : main_thread_only().task_observers) observer.DidProcessTask(executing_task->pending_task); } { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.QueueNotifyDidProcessTask"); executing_task->task_queue->NotifyDidProcessTask( executing_task->pending_task); } { TRACE_EVENT0(TRACE_DISABLED_BY_DEFAULT("sequence_manager"), "SequenceManager.QueueOnTaskCompleted"); if (task_timing.has_wall_time()) executing_task->task_queue->OnTaskCompleted(executing_task->pending_task, task_timing); } // TODO(altimin): Move this back to blink. if (task_timing.has_wall_time() && task_timing.wall_duration() > kLongTaskTraceEventThreshold && main_thread_only().nesting_depth == 0) { TRACE_EVENT_INSTANT1("blink", "LongTask", TRACE_EVENT_SCOPE_THREAD, "duration", task_timing.wall_duration().InSecondsF()); } } void SequenceManagerImpl::SetWorkBatchSize(int work_batch_size) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); DCHECK_GE(work_batch_size, 1); controller_->SetWorkBatchSize(work_batch_size); } void SequenceManagerImpl::AddTaskObserver( MessageLoop::TaskObserver* task_observer) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); main_thread_only().task_observers.AddObserver(task_observer); } void SequenceManagerImpl::RemoveTaskObserver( MessageLoop::TaskObserver* task_observer) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); main_thread_only().task_observers.RemoveObserver(task_observer); } void SequenceManagerImpl::AddTaskTimeObserver( TaskTimeObserver* task_time_observer) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); main_thread_only().task_time_observers.AddObserver(task_time_observer); } void SequenceManagerImpl::RemoveTaskTimeObserver( TaskTimeObserver* task_time_observer) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); main_thread_only().task_time_observers.RemoveObserver(task_time_observer); } bool SequenceManagerImpl::GetAndClearSystemIsQuiescentBit() { bool task_was_run = main_thread_only().task_was_run_on_quiescence_monitored_queue; main_thread_only().task_was_run_on_quiescence_monitored_queue = false; return !task_was_run; } internal::EnqueueOrder SequenceManagerImpl::GetNextSequenceNumber() { return enqueue_order_generator_.GenerateNext(); } std::unique_ptr SequenceManagerImpl::AsValueWithSelectorResult( bool should_run, internal::WorkQueue* selected_work_queue) const { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); std::unique_ptr state( new trace_event::TracedValue()); TimeTicks now = NowTicks(); state->BeginArray("active_queues"); for (auto* const queue : main_thread_only().active_queues) queue->AsValueInto(now, state.get()); state->EndArray(); state->BeginArray("queues_to_gracefully_shutdown"); for (const auto& pair : main_thread_only().queues_to_gracefully_shutdown) pair.first->AsValueInto(now, state.get()); state->EndArray(); state->BeginArray("queues_to_delete"); for (const auto& pair : main_thread_only().queues_to_delete) pair.first->AsValueInto(now, state.get()); state->EndArray(); state->BeginDictionary("selector"); main_thread_only().selector.AsValueInto(state.get()); state->EndDictionary(); if (should_run) { state->SetString("selected_queue", selected_work_queue->task_queue()->GetName()); state->SetString("work_queue_name", selected_work_queue->name()); } state->BeginArray("time_domains"); for (auto* time_domain : main_thread_only().time_domains) time_domain->AsValueInto(state.get()); state->EndArray(); { AutoLock lock(any_thread_lock_); state->BeginArray("has_incoming_immediate_work"); for (const internal::IncomingImmediateWorkList* iter = any_thread().incoming_immediate_work_list; iter; iter = iter->next) { state->AppendString(iter->queue->GetName()); } state->EndArray(); } return std::move(state); } void SequenceManagerImpl::OnTaskQueueEnabled(internal::TaskQueueImpl* queue) { DCHECK_CALLED_ON_VALID_THREAD(main_thread_checker_); DCHECK(queue->IsQueueEnabled()); // Only schedule DoWork if there's something to do. if (queue->HasTaskToRunImmediately() && !queue->BlockedByFence()) MaybeScheduleImmediateWork(FROM_HERE); } void SequenceManagerImpl::SweepCanceledDelayedTasks() { std::map time_domain_now; for (auto* const queue : main_thread_only().active_queues) SweepCanceledDelayedTasksInQueue(queue, &time_domain_now); for (const auto& pair : main_thread_only().queues_to_gracefully_shutdown) SweepCanceledDelayedTasksInQueue(pair.first, &time_domain_now); } void SequenceManagerImpl::TakeQueuesToGracefullyShutdownFromHelper() { std::vector> queues = graceful_shutdown_helper_->TakeQueues(); for (std::unique_ptr& queue : queues) { main_thread_only().queues_to_gracefully_shutdown[queue.get()] = std::move(queue); } } void SequenceManagerImpl::CleanUpQueues() { TakeQueuesToGracefullyShutdownFromHelper(); for (auto it = main_thread_only().queues_to_gracefully_shutdown.begin(); it != main_thread_only().queues_to_gracefully_shutdown.end();) { if (it->first->IsEmpty()) { UnregisterTaskQueueImpl(std::move(it->second)); main_thread_only().active_queues.erase(it->first); main_thread_only().queues_to_gracefully_shutdown.erase(it++); } else { ++it; } } main_thread_only().queues_to_delete.clear(); } scoped_refptr SequenceManagerImpl::GetGracefulQueueShutdownHelper() const { return graceful_shutdown_helper_; } WeakPtr SequenceManagerImpl::GetWeakPtr() { return weak_factory_.GetWeakPtr(); } void SequenceManagerImpl::SetDefaultTaskRunner( scoped_refptr task_runner) { controller_->SetDefaultTaskRunner(task_runner); } const TickClock* SequenceManagerImpl::GetTickClock() const { return controller_->GetClock(); } TimeTicks SequenceManagerImpl::NowTicks() const { return controller_->GetClock()->NowTicks(); } bool SequenceManagerImpl::ShouldRecordCPUTimeForTask() { return ThreadTicks::IsSupported() && main_thread_only().uniform_distribution( main_thread_only().random_generator) < metric_recording_settings_ .task_sampling_rate_for_recording_cpu_time; } const SequenceManager::MetricRecordingSettings& SequenceManagerImpl::GetMetricRecordingSettings() const { return metric_recording_settings_; } MSVC_DISABLE_OPTIMIZE() bool SequenceManagerImpl::Validate() { return memory_corruption_sentinel_ == kMemoryCorruptionSentinelValue; } MSVC_ENABLE_OPTIMIZE() void SequenceManagerImpl::EnableCrashKeys( const char* file_name_crash_key_name, const char* function_name_crash_key_name) { DCHECK(!main_thread_only().file_name_crash_key); DCHECK(!main_thread_only().function_name_crash_key); #if !defined(OS_NACL) main_thread_only().file_name_crash_key = debug::AllocateCrashKeyString( file_name_crash_key_name, debug::CrashKeySize::Size64); main_thread_only().function_name_crash_key = debug::AllocateCrashKeyString( function_name_crash_key_name, debug::CrashKeySize::Size64); #endif // OS_NACL } internal::TaskQueueImpl* SequenceManagerImpl::currently_executing_task_queue() const { if (main_thread_only().task_execution_stack.empty()) return nullptr; return main_thread_only().task_execution_stack.rbegin()->task_queue; } } // namespace internal } // namespace sequence_manager } // namespace base