naiveproxy/base/message_loop/incoming_task_queue.cc

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2018-02-02 13:49:39 +03:00
// Copyright 2013 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/message_loop/incoming_task_queue.h"
#include <limits>
#include <utility>
#include "base/location.h"
#include "base/message_loop/message_loop.h"
#include "base/synchronization/waitable_event.h"
#include "base/time/time.h"
#include "build/build_config.h"
namespace base {
namespace internal {
namespace {
#if DCHECK_IS_ON()
// Delays larger than this are often bogus, and a warning should be emitted in
// debug builds to warn developers. http://crbug.com/450045
constexpr TimeDelta kTaskDelayWarningThreshold = TimeDelta::FromDays(14);
#endif
// Returns true if MessagePump::ScheduleWork() must be called one
// time for every task that is added to the MessageLoop incoming queue.
bool AlwaysNotifyPump(MessageLoop::Type type) {
#if defined(OS_ANDROID)
// The Android UI message loop needs to get notified each time a task is
// added
// to the incoming queue.
return type == MessageLoop::TYPE_UI || type == MessageLoop::TYPE_JAVA;
#else
return false;
#endif
}
TimeTicks CalculateDelayedRuntime(TimeDelta delay) {
TimeTicks delayed_run_time;
if (delay > TimeDelta())
delayed_run_time = TimeTicks::Now() + delay;
else
DCHECK_EQ(delay.InMilliseconds(), 0) << "delay should not be negative";
return delayed_run_time;
}
} // namespace
IncomingTaskQueue::IncomingTaskQueue(MessageLoop* message_loop)
: always_schedule_work_(AlwaysNotifyPump(message_loop->type())),
triage_tasks_(this),
delayed_tasks_(this),
deferred_tasks_(this),
message_loop_(message_loop) {
// The constructing sequence is not necessarily the running sequence in the
// case of base::Thread.
DETACH_FROM_SEQUENCE(sequence_checker_);
}
bool IncomingTaskQueue::AddToIncomingQueue(const Location& from_here,
OnceClosure task,
TimeDelta delay,
Nestable nestable) {
// Use CHECK instead of DCHECK to crash earlier. See http://crbug.com/711167
// for details.
CHECK(task);
DLOG_IF(WARNING, delay > kTaskDelayWarningThreshold)
<< "Requesting super-long task delay period of " << delay.InSeconds()
<< " seconds from here: " << from_here.ToString();
PendingTask pending_task(from_here, std::move(task),
CalculateDelayedRuntime(delay), nestable);
#if defined(OS_WIN)
// We consider the task needs a high resolution timer if the delay is
// more than 0 and less than 32ms. This caps the relative error to
// less than 50% : a 33ms wait can wake at 48ms since the default
// resolution on Windows is between 10 and 15ms.
if (delay > TimeDelta() &&
delay.InMilliseconds() < (2 * Time::kMinLowResolutionThresholdMs)) {
pending_task.is_high_res = true;
}
#endif
return PostPendingTask(&pending_task);
}
bool IncomingTaskQueue::IsIdleForTesting() {
AutoLock lock(incoming_queue_lock_);
return incoming_queue_.empty();
}
void IncomingTaskQueue::WillDestroyCurrentMessageLoop() {
{
AutoLock auto_lock(incoming_queue_lock_);
accept_new_tasks_ = false;
}
{
AutoLock auto_lock(message_loop_lock_);
message_loop_ = nullptr;
}
}
void IncomingTaskQueue::StartScheduling() {
bool schedule_work;
{
AutoLock lock(incoming_queue_lock_);
DCHECK(!is_ready_for_scheduling_);
DCHECK(!message_loop_scheduled_);
is_ready_for_scheduling_ = true;
schedule_work = !incoming_queue_.empty();
}
if (schedule_work) {
DCHECK(message_loop_);
// Don't need to lock |message_loop_lock_| here because this function is
// called by MessageLoop on its thread.
message_loop_->ScheduleWork();
}
}
IncomingTaskQueue::~IncomingTaskQueue() {
// Verify that WillDestroyCurrentMessageLoop() has been called.
DCHECK(!message_loop_);
}
void IncomingTaskQueue::RunTask(PendingTask* pending_task) {
DCHECK_CALLED_ON_VALID_SEQUENCE(sequence_checker_);
task_annotator_.RunTask("MessageLoop::PostTask", pending_task);
}
IncomingTaskQueue::TriageQueue::TriageQueue(IncomingTaskQueue* outer)
: outer_(outer) {}
IncomingTaskQueue::TriageQueue::~TriageQueue() = default;
const PendingTask& IncomingTaskQueue::TriageQueue::Peek() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
ReloadFromIncomingQueueIfEmpty();
DCHECK(!queue_.empty());
return queue_.front();
}
PendingTask IncomingTaskQueue::TriageQueue::Pop() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
ReloadFromIncomingQueueIfEmpty();
DCHECK(!queue_.empty());
PendingTask pending_task = std::move(queue_.front());
queue_.pop();
if (pending_task.is_high_res)
--outer_->pending_high_res_tasks_;
return pending_task;
}
bool IncomingTaskQueue::TriageQueue::HasTasks() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
ReloadFromIncomingQueueIfEmpty();
return !queue_.empty();
}
void IncomingTaskQueue::TriageQueue::Clear() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
// Previously, MessageLoop would delete all tasks including delayed and
// deferred tasks in a single round before attempting to reload from the
// incoming queue to see if more tasks remained. This gave it a chance to
// assess whether or not clearing should continue. As a result, while
// reloading is automatic for getting and seeing if tasks exist, it is not
// automatic for Clear().
while (!queue_.empty()) {
PendingTask pending_task = std::move(queue_.front());
queue_.pop();
if (pending_task.is_high_res)
--outer_->pending_high_res_tasks_;
if (!pending_task.delayed_run_time.is_null()) {
outer_->delayed_tasks().Push(std::move(pending_task));
}
}
}
void IncomingTaskQueue::TriageQueue::ReloadFromIncomingQueueIfEmpty() {
if (queue_.empty()) {
// TODO(robliao): Since these high resolution tasks aren't yet in the
// delayed queue, they technically shouldn't trigger high resolution timers
// until they are.
outer_->pending_high_res_tasks_ += outer_->ReloadWorkQueue(&queue_);
}
}
IncomingTaskQueue::DelayedQueue::DelayedQueue(IncomingTaskQueue* outer)
: outer_(outer) {}
IncomingTaskQueue::DelayedQueue::~DelayedQueue() = default;
void IncomingTaskQueue::DelayedQueue::Push(PendingTask pending_task) {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
if (pending_task.is_high_res)
++outer_->pending_high_res_tasks_;
queue_.push(std::move(pending_task));
}
const PendingTask& IncomingTaskQueue::DelayedQueue::Peek() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
DCHECK(!queue_.empty());
return queue_.top();
}
PendingTask IncomingTaskQueue::DelayedQueue::Pop() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
DCHECK(!queue_.empty());
PendingTask delayed_task = std::move(const_cast<PendingTask&>(queue_.top()));
queue_.pop();
if (delayed_task.is_high_res)
--outer_->pending_high_res_tasks_;
return delayed_task;
}
bool IncomingTaskQueue::DelayedQueue::HasTasks() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
// TODO(robliao): The other queues don't check for IsCancelled(). Should they?
while (!queue_.empty() && Peek().task.IsCancelled())
Pop();
return !queue_.empty();
}
void IncomingTaskQueue::DelayedQueue::Clear() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
while (!queue_.empty())
Pop();
}
IncomingTaskQueue::DeferredQueue::DeferredQueue(IncomingTaskQueue* outer)
: outer_(outer) {}
IncomingTaskQueue::DeferredQueue::~DeferredQueue() = default;
void IncomingTaskQueue::DeferredQueue::Push(PendingTask pending_task) {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
// TODO(robliao): These tasks should not count towards the high res task count
// since they are no longer in the delayed queue.
if (pending_task.is_high_res)
++outer_->pending_high_res_tasks_;
queue_.push(std::move(pending_task));
}
const PendingTask& IncomingTaskQueue::DeferredQueue::Peek() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
DCHECK(!queue_.empty());
return queue_.front();
}
PendingTask IncomingTaskQueue::DeferredQueue::Pop() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
DCHECK(!queue_.empty());
PendingTask deferred_task = std::move(queue_.front());
queue_.pop();
if (deferred_task.is_high_res)
--outer_->pending_high_res_tasks_;
return deferred_task;
}
bool IncomingTaskQueue::DeferredQueue::HasTasks() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
return !queue_.empty();
}
void IncomingTaskQueue::DeferredQueue::Clear() {
DCHECK_CALLED_ON_VALID_SEQUENCE(outer_->sequence_checker_);
while (!queue_.empty())
Pop();
}
bool IncomingTaskQueue::PostPendingTask(PendingTask* pending_task) {
// Warning: Don't try to short-circuit, and handle this thread's tasks more
// directly, as it could starve handling of foreign threads. Put every task
// into this queue.
bool accept_new_tasks;
bool schedule_work = false;
{
AutoLock auto_lock(incoming_queue_lock_);
accept_new_tasks = accept_new_tasks_;
if (accept_new_tasks)
schedule_work = PostPendingTaskLockRequired(pending_task);
}
if (!accept_new_tasks) {
// Clear the pending task outside of |incoming_queue_lock_| to prevent any
// chance of self-deadlock if destroying a task also posts a task to this
// queue.
DCHECK(!schedule_work);
pending_task->task.Reset();
return false;
}
// Wake up the message loop and schedule work. This is done outside
// |incoming_queue_lock_| to allow for multiple post tasks to occur while
// ScheduleWork() is running. For platforms (e.g. Android) that require one
// call to ScheduleWork() for each task, all pending tasks may serialize
// within the ScheduleWork() call. As a result, holding a lock to maintain the
// lifetime of |message_loop_| is less of a concern.
if (schedule_work) {
// Ensures |message_loop_| isn't destroyed while running.
AutoLock auto_lock(message_loop_lock_);
if (message_loop_)
message_loop_->ScheduleWork();
}
return true;
}
bool IncomingTaskQueue::PostPendingTaskLockRequired(PendingTask* pending_task) {
incoming_queue_lock_.AssertAcquired();
#if defined(OS_WIN)
if (pending_task->is_high_res)
++high_res_task_count_;
#endif
// Initialize the sequence number. The sequence number is used for delayed
// tasks (to facilitate FIFO sorting when two tasks have the same
// delayed_run_time value) and for identifying the task in about:tracing.
pending_task->sequence_num = next_sequence_num_++;
task_annotator_.DidQueueTask("MessageLoop::PostTask", *pending_task);
bool was_empty = incoming_queue_.empty();
incoming_queue_.push(std::move(*pending_task));
if (is_ready_for_scheduling_ &&
(always_schedule_work_ || (!message_loop_scheduled_ && was_empty))) {
// After we've scheduled the message loop, we do not need to do so again
// until we know it has processed all of the work in our queue and is
// waiting for more work again. The message loop will always attempt to
// reload from the incoming queue before waiting again so we clear this
// flag in ReloadWorkQueue().
message_loop_scheduled_ = true;
return true;
}
return false;
}
int IncomingTaskQueue::ReloadWorkQueue(TaskQueue* work_queue) {
// Make sure no tasks are lost.
DCHECK(work_queue->empty());
// Acquire all we can from the inter-thread queue with one lock acquisition.
AutoLock lock(incoming_queue_lock_);
if (incoming_queue_.empty()) {
// If the loop attempts to reload but there are no tasks in the incoming
// queue, that means it will go to sleep waiting for more work. If the
// incoming queue becomes nonempty we need to schedule it again.
message_loop_scheduled_ = false;
} else {
incoming_queue_.swap(*work_queue);
}
// Reset the count of high resolution tasks since our queue is now empty.
int high_res_tasks = high_res_task_count_;
high_res_task_count_ = 0;
return high_res_tasks;
}
} // namespace internal
} // namespace base