src/base/task/sequence_manager/work_queue.h - cobalt - Git at Google

 // Copyright 2015 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.

 #ifndef BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_
 #define BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_

 #include "base/base_export.h"
 #include "base/task/sequence_manager/enqueue_order.h"
 #include "base/task/sequence_manager/intrusive_heap.h"
 #include "base/task/sequence_manager/sequenced_task_source.h"
 #include "base/task/sequence_manager/task_queue_impl.h"
 #include "base/trace_event/trace_event.h"
 #include "base/trace_event/trace_event_argument.h"

 namespace base {
 namespace sequence_manager {
 namespace internal {

 class WorkQueueSets;

 // This class keeps track of immediate and delayed tasks which are due to run
 // now. It interfaces deeply with WorkQueueSets which keeps track of which queue
 // (with a given priority) contains the oldest task.
 //
 // If a fence is inserted, WorkQueue behaves normally up until
 // TakeTaskFromWorkQueue reaches or exceeds the fence.  At that point it the
 // API subset used by WorkQueueSets pretends the WorkQueue is empty until the
 // fence is removed.  This functionality is a primitive intended for use by
 // throttling mechanisms.
 class BASE_EXPORT WorkQueue {
  public:
   using QueueType = internal::TaskQueueImpl::WorkQueueType;

   // Note |task_queue| can be null if queue_type is kNonNestable.
   WorkQueue(TaskQueueImpl* task_queue, const char* name, QueueType queue_type);
   ~WorkQueue();

   // Associates this work queue with the given work queue sets. This must be
   // called before any tasks can be inserted into this work queue.
   void AssignToWorkQueueSets(WorkQueueSets* work_queue_sets);

   // Assigns the current set index.
   void AssignSetIndex(size_t work_queue_set_index);

   void AsValueInto(TimeTicks now, trace_event::TracedValue* state) const;

   // Returns true if the |tasks_| is empty. This method ignores any fences.
   bool Empty() const { return tasks_.empty(); }

   // If the |tasks_| isn't empty and a fence hasn't been reached,
   // |enqueue_order| gets set to the enqueue order of the front task and the
   // function returns true. Otherwise the function returns false.
   bool GetFrontTaskEnqueueOrder(EnqueueOrder* enqueue_order) const;

   // Returns the first task in this queue or null if the queue is empty. This
   // method ignores any fences.
   const Task* GetFrontTask() const;

   // Returns the last task in this queue or null if the queue is empty. This
   // method ignores any fences.
   const Task* GetBackTask() const;

   // Pushes the task onto the |tasks_| and if a fence hasn't been reached
   // it informs the WorkQueueSets if the head changed.
   void Push(Task task);

   // Pushes the task onto the front of the |tasks_| and if it's before any
   // fence it informs the WorkQueueSets the head changed. Use with caution this
   // API can easily lead to task starvation if misused.
   void PushNonNestableTaskToFront(Task task);

   // Reloads the empty |tasks_| with
   // |task_queue_->TakeImmediateIncomingQueue| and if a fence hasn't been
   // reached it informs the WorkQueueSets if the head changed.
   void ReloadEmptyImmediateQueue();

   size_t Size() const { return tasks_.size(); }

   size_t Capacity() const { return tasks_.capacity(); }

   // Pulls a task off the |tasks_| and informs the WorkQueueSets.  If the
   // task removed had an enqueue order >= the current fence then WorkQueue
   // pretends to be empty as far as the WorkQueueSets is concerned.
   Task TakeTaskFromWorkQueue();

   // Removes all canceled tasks from the head of the list. Returns true if any
   // tasks were removed.
   bool RemoveAllCanceledTasksFromFront();

   const char* name() const { return name_; }

   TaskQueueImpl* task_queue() const { return task_queue_; }

   WorkQueueSets* work_queue_sets() const { return work_queue_sets_; }

   size_t work_queue_set_index() const { return work_queue_set_index_; }

   HeapHandle heap_handle() const { return heap_handle_; }

   void set_heap_handle(HeapHandle handle) { heap_handle_ = handle; }

   QueueType queue_type() const { return queue_type_; }

   // Returns true if the front task in this queue has an older enqueue order
   // than the front task of |other_queue|. Both queue are assumed to be
   // non-empty. This method ignores any fences.
   bool ShouldRunBefore(const WorkQueue* other_queue) const;

   // Submit a fence. When TakeTaskFromWorkQueue encounters a task whose
   // enqueue_order is >= |fence| then the WorkQueue will start pretending to be.
   // empty.
   // Inserting a fence may supersede a previous one and unblock some tasks.
   // Returns true if any tasks where unblocked, returns false otherwise.
   bool InsertFence(EnqueueOrder fence);

   // Submit a fence without triggering a WorkQueueSets notification.
   // Caller must ensure that WorkQueueSets are properly updated.
   // This method should not be called when a fence is already present.
   void InsertFenceSilently(EnqueueOrder fence);

   // Removes any fences that where added and if WorkQueue was pretending to be
   // empty, then the real value is reported to WorkQueueSets. Returns true if
   // any tasks where unblocked.
   bool RemoveFence();

   // Returns true if any tasks are blocked by the fence. Returns true if the
   // queue is empty and fence has been set (i.e. future tasks would be blocked).
   // Otherwise returns false.
   bool BlockedByFence() const;

   // Test support function. This should not be used in production code.
   void PopTaskForTesting();

   // Shrinks |tasks_| if it's wasting memory.
   void MaybeShrinkQueue();

  private:
   bool InsertFenceImpl(EnqueueOrder fence);

   TaskQueueImpl::TaskDeque tasks_;
   WorkQueueSets* work_queue_sets_ = nullptr;  // NOT OWNED.
   TaskQueueImpl* const task_queue_;           // NOT OWNED.
   size_t work_queue_set_index_ = 0;
   HeapHandle heap_handle_;
   const char* const name_;
   EnqueueOrder fence_;
   const QueueType queue_type_;

   DISALLOW_COPY_AND_ASSIGN(WorkQueue);
 };

 }  // namespace internal
 }  // namespace sequence_manager
 }  // namespace base

 #endif  // BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_
	// Copyright 2015 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.

	#ifndef BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_
	#define BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_

	#include "base/base_export.h"
	#include "base/task/sequence_manager/enqueue_order.h"
	#include "base/task/sequence_manager/intrusive_heap.h"
	#include "base/task/sequence_manager/sequenced_task_source.h"
	#include "base/task/sequence_manager/task_queue_impl.h"
	#include "base/trace_event/trace_event.h"
	#include "base/trace_event/trace_event_argument.h"

	namespace base {
	namespace sequence_manager {
	namespace internal {

	class WorkQueueSets;

	// This class keeps track of immediate and delayed tasks which are due to run
	// now. It interfaces deeply with WorkQueueSets which keeps track of which queue
	// (with a given priority) contains the oldest task.
	//
	// If a fence is inserted, WorkQueue behaves normally up until
	// TakeTaskFromWorkQueue reaches or exceeds the fence. At that point it the
	// API subset used by WorkQueueSets pretends the WorkQueue is empty until the
	// fence is removed. This functionality is a primitive intended for use by
	// throttling mechanisms.
	class BASE_EXPORT WorkQueue {
	public:
	using QueueType = internal::TaskQueueImpl::WorkQueueType;

	// Note \|task_queue\| can be null if queue_type is kNonNestable.
	WorkQueue(TaskQueueImpl* task_queue, const char* name, QueueType queue_type);
	~WorkQueue();

	// Associates this work queue with the given work queue sets. This must be
	// called before any tasks can be inserted into this work queue.
	void AssignToWorkQueueSets(WorkQueueSets* work_queue_sets);

	// Assigns the current set index.
	void AssignSetIndex(size_t work_queue_set_index);

	void AsValueInto(TimeTicks now, trace_event::TracedValue* state) const;

	// Returns true if the \|tasks_\| is empty. This method ignores any fences.
	bool Empty() const { return tasks_.empty(); }

	// If the \|tasks_\| isn't empty and a fence hasn't been reached,
	// \|enqueue_order\| gets set to the enqueue order of the front task and the
	// function returns true. Otherwise the function returns false.
	bool GetFrontTaskEnqueueOrder(EnqueueOrder* enqueue_order) const;

	// Returns the first task in this queue or null if the queue is empty. This
	// method ignores any fences.
	const Task* GetFrontTask() const;

	// Returns the last task in this queue or null if the queue is empty. This
	// method ignores any fences.
	const Task* GetBackTask() const;

	// Pushes the task onto the \|tasks_\| and if a fence hasn't been reached
	// it informs the WorkQueueSets if the head changed.
	void Push(Task task);

	// Pushes the task onto the front of the \|tasks_\| and if it's before any
	// fence it informs the WorkQueueSets the head changed. Use with caution this
	// API can easily lead to task starvation if misused.
	void PushNonNestableTaskToFront(Task task);

	// Reloads the empty \|tasks_\| with
	// \|task_queue_->TakeImmediateIncomingQueue\| and if a fence hasn't been
	// reached it informs the WorkQueueSets if the head changed.
	void ReloadEmptyImmediateQueue();

	size_t Size() const { return tasks_.size(); }

	size_t Capacity() const { return tasks_.capacity(); }

	// Pulls a task off the \|tasks_\| and informs the WorkQueueSets. If the
	// task removed had an enqueue order >= the current fence then WorkQueue
	// pretends to be empty as far as the WorkQueueSets is concerned.
	Task TakeTaskFromWorkQueue();

	// Removes all canceled tasks from the head of the list. Returns true if any
	// tasks were removed.
	bool RemoveAllCanceledTasksFromFront();

	const char* name() const { return name_; }

	TaskQueueImpl* task_queue() const { return task_queue_; }

	WorkQueueSets* work_queue_sets() const { return work_queue_sets_; }

	size_t work_queue_set_index() const { return work_queue_set_index_; }

	HeapHandle heap_handle() const { return heap_handle_; }

	void set_heap_handle(HeapHandle handle) { heap_handle_ = handle; }

	QueueType queue_type() const { return queue_type_; }

	// Returns true if the front task in this queue has an older enqueue order
	// than the front task of \|other_queue\|. Both queue are assumed to be
	// non-empty. This method ignores any fences.
	bool ShouldRunBefore(const WorkQueue* other_queue) const;

	// Submit a fence. When TakeTaskFromWorkQueue encounters a task whose
	// enqueue_order is >= \|fence\| then the WorkQueue will start pretending to be.
	// empty.
	// Inserting a fence may supersede a previous one and unblock some tasks.
	// Returns true if any tasks where unblocked, returns false otherwise.
	bool InsertFence(EnqueueOrder fence);

	// Submit a fence without triggering a WorkQueueSets notification.
	// Caller must ensure that WorkQueueSets are properly updated.
	// This method should not be called when a fence is already present.
	void InsertFenceSilently(EnqueueOrder fence);

	// Removes any fences that where added and if WorkQueue was pretending to be
	// empty, then the real value is reported to WorkQueueSets. Returns true if
	// any tasks where unblocked.
	bool RemoveFence();

	// Returns true if any tasks are blocked by the fence. Returns true if the
	// queue is empty and fence has been set (i.e. future tasks would be blocked).
	// Otherwise returns false.
	bool BlockedByFence() const;

	// Test support function. This should not be used in production code.
	void PopTaskForTesting();

	// Shrinks \|tasks_\| if it's wasting memory.
	void MaybeShrinkQueue();

	private:
	bool InsertFenceImpl(EnqueueOrder fence);

	TaskQueueImpl::TaskDeque tasks_;
	WorkQueueSets* work_queue_sets_ = nullptr; // NOT OWNED.
	TaskQueueImpl* const task_queue_; // NOT OWNED.
	size_t work_queue_set_index_ = 0;
	HeapHandle heap_handle_;
	const char* const name_;
	EnqueueOrder fence_;
	const QueueType queue_type_;

	DISALLOW_COPY_AND_ASSIGN(WorkQueue);
	};

	} // namespace internal
	} // namespace sequence_manager
	} // namespace base

	#endif // BASE_TASK_SEQUENCE_MANAGER_WORK_QUEUE_H_