// Copyright 2015 The Chromium Authors // 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/work_queue.h" #include #include "base/debug/alias.h" #include "base/task/sequence_manager/fence.h" #include "base/task/sequence_manager/sequence_manager_impl.h" #include "base/task/sequence_manager/task_order.h" #include "base/task/sequence_manager/work_queue_sets.h" #include "build/build_config.h" #include "third_party/abseil-cpp/absl/container/inlined_vector.h" namespace base { namespace sequence_manager { namespace internal { WorkQueue::WorkQueue(TaskQueueImpl* task_queue, const char* name, QueueType queue_type) : task_queue_(task_queue), name_(name), queue_type_(queue_type) {} Value::List WorkQueue::AsValue(TimeTicks now) const { Value::List state; for (const Task& task : tasks_) state.Append(TaskQueueImpl::TaskAsValue(task, now)); return state; } WorkQueue::~WorkQueue() { DCHECK(!work_queue_sets_) << task_queue_->GetName() << " : " << work_queue_sets_->GetName() << " : " << name_; } const Task* WorkQueue::GetFrontTask() const { if (tasks_.empty()) return nullptr; return &tasks_.front(); } const Task* WorkQueue::GetBackTask() const { if (tasks_.empty()) return nullptr; return &tasks_.back(); } bool WorkQueue::BlockedByFence() const { if (!fence_) return false; // If the queue is empty then any future tasks will have a higher enqueue // order and will be blocked. The queue is also blocked if the head is past // the fence. return tasks_.empty() || tasks_.front().task_order() >= fence_->task_order(); } std::optional WorkQueue::GetFrontTaskOrder() const { if (tasks_.empty() || BlockedByFence()) return std::nullopt; // Quick sanity check. DCHECK(tasks_.front().task_order() <= tasks_.back().task_order()) << task_queue_->GetName() << " : " << work_queue_sets_->GetName() << " : " << name_; return tasks_.front().task_order(); } void WorkQueue::Push(Task task) { bool was_empty = tasks_.empty(); #ifndef NDEBUG DCHECK(task.enqueue_order_set()); #endif // Make sure the task order is strictly increasing. DCHECK(was_empty || tasks_.back().task_order() < task.task_order()); // Make sure enqueue order is strictly increasing for immediate queues and // monotonically increasing for delayed queues. DCHECK(was_empty || tasks_.back().enqueue_order() < task.enqueue_order() || (queue_type_ == QueueType::kDelayed && tasks_.back().enqueue_order() == task.enqueue_order())); // Amortized O(1). tasks_.push_back(std::move(task)); if (!was_empty) return; // If we hit the fence, pretend to WorkQueueSets that we're empty. if (work_queue_sets_ && !BlockedByFence()) work_queue_sets_->OnTaskPushedToEmptyQueue(this); } WorkQueue::TaskPusher::TaskPusher(WorkQueue* work_queue) : work_queue_(work_queue), was_empty_(work_queue->Empty()) {} WorkQueue::TaskPusher::TaskPusher(TaskPusher&& other) : work_queue_(other.work_queue_), was_empty_(other.was_empty_) { other.work_queue_ = nullptr; } void WorkQueue::TaskPusher::Push(Task task) { DCHECK(work_queue_); #ifndef NDEBUG DCHECK(task.enqueue_order_set()); #endif // Make sure the task order is strictly increasing. DCHECK(work_queue_->tasks_.empty() || work_queue_->tasks_.back().task_order() < task.task_order()); // Make sure enqueue order is strictly increasing for immediate queues and // monotonically increasing for delayed queues. DCHECK(work_queue_->tasks_.empty() || work_queue_->tasks_.back().enqueue_order() < task.enqueue_order() || (work_queue_->queue_type_ == QueueType::kDelayed && work_queue_->tasks_.back().enqueue_order() == task.enqueue_order())); // Amortized O(1). work_queue_->tasks_.push_back(std::move(task)); } WorkQueue::TaskPusher::~TaskPusher() { // If |work_queue_| became non empty and it isn't blocked by a fence then we // must notify |work_queue_->work_queue_sets_|. if (was_empty_ && work_queue_ && !work_queue_->Empty() && work_queue_->work_queue_sets_ && !work_queue_->BlockedByFence()) { work_queue_->work_queue_sets_->OnTaskPushedToEmptyQueue(work_queue_); } } WorkQueue::TaskPusher WorkQueue::CreateTaskPusher() { return TaskPusher(this); } void WorkQueue::PushNonNestableTaskToFront(Task task) { DCHECK(task.nestable == Nestable::kNonNestable); bool was_empty = tasks_.empty(); bool was_blocked = BlockedByFence(); #ifndef NDEBUG DCHECK(task.enqueue_order_set()); #endif if (!was_empty) { // Make sure the task order is strictly increasing. DCHECK(task.task_order() < tasks_.front().task_order()) << task_queue_->GetName() << " : " << work_queue_sets_->GetName() << " : " << name_; // Make sure the enqueue order is strictly increasing for immediate queues // and monotonically increasing for delayed queues. DCHECK(task.enqueue_order() < tasks_.front().enqueue_order() || (queue_type_ == QueueType::kDelayed && task.enqueue_order() == tasks_.front().enqueue_order())) << task_queue_->GetName() << " : " << work_queue_sets_->GetName() << " : " << name_; } // Amortized O(1). tasks_.push_front(std::move(task)); if (!work_queue_sets_) return; // Pretend to WorkQueueSets that nothing has changed if we're blocked. if (BlockedByFence()) return; // Pushing task to front may unblock the fence. if (was_empty || was_blocked) { work_queue_sets_->OnTaskPushedToEmptyQueue(this); } else { work_queue_sets_->OnQueuesFrontTaskChanged(this); } } void WorkQueue::TakeImmediateIncomingQueueTasks() { DCHECK(tasks_.empty()); task_queue_->TakeImmediateIncomingQueueTasks(&tasks_); if (tasks_.empty()) return; // If we hit the fence, pretend to WorkQueueSets that we're empty. if (work_queue_sets_ && !BlockedByFence()) work_queue_sets_->OnTaskPushedToEmptyQueue(this); } Task WorkQueue::TakeTaskFromWorkQueue() { DCHECK(work_queue_sets_); DCHECK(!tasks_.empty()); Task pending_task = std::move(tasks_.front()); tasks_.pop_front(); // NB immediate tasks have a different pipeline to delayed ones. if (tasks_.empty()) { // NB delayed tasks are inserted via Push, no don't need to reload those. if (queue_type_ == QueueType::kImmediate) { // Short-circuit the queue reload so that OnPopMinQueueInSet does the // right thing. task_queue_->TakeImmediateIncomingQueueTasks(&tasks_); } // Since the queue is empty, now is a good time to consider reducing it's // capacity if we're wasting memory. tasks_.MaybeShrinkQueue(); } DCHECK(work_queue_sets_); #if DCHECK_IS_ON() // If diagnostics are on it's possible task queues are being selected at // random so we can't use the (slightly) more efficient OnPopMinQueueInSet. work_queue_sets_->OnQueuesFrontTaskChanged(this); #else // OnPopMinQueueInSet calls GetFrontTaskOrder which checks // BlockedByFence() so we don't need to here. work_queue_sets_->OnPopMinQueueInSet(this); #endif task_queue_->TraceQueueSize(); return pending_task; } bool WorkQueue::RemoveAllCanceledTasksFromFront() { if (!work_queue_sets_) { return false; } // Since task destructors could have a side-effect of deleting this task queue // we move cancelled tasks into a temporary container which can be emptied // without accessing |this|. absl::InlinedVector tasks_to_delete; while (!tasks_.empty()) { const auto& pending_task = tasks_.front(); if (pending_task.task && !pending_task.IsCanceled()) break; tasks_to_delete.push_back(std::move(tasks_.front())); tasks_.pop_front(); } if (!tasks_to_delete.empty()) { if (tasks_.empty()) { // NB delayed tasks are inserted via Push, no don't need to reload those. if (queue_type_ == QueueType::kImmediate) { // Short-circuit the queue reload so that OnPopMinQueueInSet does the // right thing. task_queue_->TakeImmediateIncomingQueueTasks(&tasks_); } // Since the queue is empty, now is a good time to consider reducing it's // capacity if we're wasting memory. tasks_.MaybeShrinkQueue(); } // If we have a valid |heap_handle_| (i.e. we're not blocked by a fence or // disabled) then |work_queue_sets_| needs to be told. if (heap_handle_.IsValid()) work_queue_sets_->OnQueuesFrontTaskChanged(this); task_queue_->TraceQueueSize(); } return !tasks_to_delete.empty(); } void WorkQueue::AssignToWorkQueueSets(WorkQueueSets* work_queue_sets) { work_queue_sets_ = work_queue_sets; } void WorkQueue::AssignSetIndex(size_t work_queue_set_index) { work_queue_set_index_ = work_queue_set_index; } bool WorkQueue::InsertFenceImpl(Fence fence) { DCHECK(!fence_ || fence.task_order() >= fence_->task_order() || fence.IsBlockingFence()); bool was_blocked_by_fence = BlockedByFence(); fence_ = fence; return was_blocked_by_fence; } void WorkQueue::InsertFenceSilently(Fence fence) { // Ensure that there is no fence present or a new one blocks queue completely. DCHECK(!fence_ || fence_->IsBlockingFence()); InsertFenceImpl(fence); } bool WorkQueue::InsertFence(Fence fence) { bool was_blocked_by_fence = InsertFenceImpl(fence); if (!work_queue_sets_) return false; // Moving the fence forward may unblock some tasks. if (!tasks_.empty() && was_blocked_by_fence && !BlockedByFence()) { work_queue_sets_->OnTaskPushedToEmptyQueue(this); return true; } // Fence insertion may have blocked all tasks in this work queue. if (BlockedByFence()) work_queue_sets_->OnQueueBlocked(this); return false; } bool WorkQueue::RemoveFence() { bool was_blocked_by_fence = BlockedByFence(); fence_ = std::nullopt; if (work_queue_sets_ && !tasks_.empty() && was_blocked_by_fence) { work_queue_sets_->OnTaskPushedToEmptyQueue(this); return true; } return false; } void WorkQueue::MaybeShrinkQueue() { tasks_.MaybeShrinkQueue(); } void WorkQueue::PopTaskForTesting() { if (tasks_.empty()) return; tasks_.pop_front(); } void WorkQueue::CollectTasksOlderThan(TaskOrder reference, std::vector* result) const { for (const Task& task : tasks_) { if (task.task_order() >= reference) break; result->push_back(&task); } } } // namespace internal } // namespace sequence_manager } // namespace base