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cobalt / cobalt / 25902c6cb1ab9cfd8ae2ee6b0fb52953f73deda5 / . / base / task / sequence_manager / task_queue_selector.cc
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// Copyright 2014 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/task_queue_selector.h"
#include <utility>
#include "base/bits.h"
#include "base/check_op.h"
#include "base/task/sequence_manager/associated_thread_id.h"
#include "base/task/sequence_manager/task_queue_impl.h"
#include "base/task/sequence_manager/work_queue.h"
#include "base/task/task_features.h"
#include "base/threading/thread_checker.h"
#include "base/trace_event/base_tracing.h"
#include "third_party/abseil-cpp/absl/types/optional.h"
namespace base {
namespace sequence_manager {
namespace internal {
std::atomic_int TaskQueueSelector::g_max_delayed_starvation_tasks =
TaskQueueSelector::kDefaultMaxDelayedStarvationTasks;
TaskQueueSelector::TaskQueueSelector(
scoped_refptr<const AssociatedThreadId> associated_thread,
const SequenceManager::Settings& settings)
: associated_thread_(std::move(associated_thread)),
#if DCHECK_IS_ON()
random_task_selection_(settings.random_task_selection_seed != 0),
#endif
non_empty_set_counts_(
std::vector<int>(settings.priority_settings.priority_count(), 0)),
delayed_work_queue_sets_("delayed", this, settings),
immediate_work_queue_sets_("immediate", this, settings) {
}
TaskQueueSelector::~TaskQueueSelector() = default;
// static
void TaskQueueSelector::InitializeFeatures() {
g_max_delayed_starvation_tasks.store(kMaxDelayedStarvationTasksParam.Get(),
std::memory_order_relaxed);
}
void TaskQueueSelector::AddQueue(internal::TaskQueueImpl* queue,
TaskQueue::QueuePriority priority) {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
DCHECK(queue->IsQueueEnabled());
AddQueueImpl(queue, priority);
}
void TaskQueueSelector::RemoveQueue(internal::TaskQueueImpl* queue) {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
if (queue->IsQueueEnabled()) {
RemoveQueueImpl(queue);
}
}
void TaskQueueSelector::EnableQueue(internal::TaskQueueImpl* queue) {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
DCHECK(queue->IsQueueEnabled());
AddQueueImpl(queue, queue->GetQueuePriority());
if (task_queue_selector_observer_)
task_queue_selector_observer_->OnTaskQueueEnabled(queue);
}
void TaskQueueSelector::DisableQueue(internal::TaskQueueImpl* queue) {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
DCHECK(!queue->IsQueueEnabled());
RemoveQueueImpl(queue);
}
void TaskQueueSelector::SetQueuePriority(internal::TaskQueueImpl* queue,
TaskQueue::QueuePriority priority) {
DCHECK_LT(priority, priority_count());
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
if (queue->IsQueueEnabled()) {
ChangeSetIndex(queue, priority);
} else {
// Disabled queue is not in any set so we can't use ChangeSetIndex here
// and have to assign priority for the queue itself.
queue->delayed_work_queue()->AssignSetIndex(priority);
queue->immediate_work_queue()->AssignSetIndex(priority);
}
DCHECK_EQ(priority, queue->GetQueuePriority());
}
void TaskQueueSelector::AddQueueImpl(internal::TaskQueueImpl* queue,
TaskQueue::QueuePriority priority) {
#if DCHECK_IS_ON()
DCHECK(!CheckContainsQueueForTest(queue));
#endif
delayed_work_queue_sets_.AddQueue(queue->delayed_work_queue(), priority);
immediate_work_queue_sets_.AddQueue(queue->immediate_work_queue(), priority);
#if DCHECK_IS_ON()
DCHECK(CheckContainsQueueForTest(queue));
#endif
}
void TaskQueueSelector::ChangeSetIndex(internal::TaskQueueImpl* queue,
TaskQueue::QueuePriority priority) {
#if DCHECK_IS_ON()
DCHECK(CheckContainsQueueForTest(queue));
#endif
delayed_work_queue_sets_.ChangeSetIndex(queue->delayed_work_queue(),
priority);
immediate_work_queue_sets_.ChangeSetIndex(queue->immediate_work_queue(),
priority);
#if DCHECK_IS_ON()
DCHECK(CheckContainsQueueForTest(queue));
#endif
}
void TaskQueueSelector::RemoveQueueImpl(internal::TaskQueueImpl* queue) {
#if DCHECK_IS_ON()
DCHECK(CheckContainsQueueForTest(queue));
#endif
delayed_work_queue_sets_.RemoveQueue(queue->delayed_work_queue());
immediate_work_queue_sets_.RemoveQueue(queue->immediate_work_queue());
#if DCHECK_IS_ON()
DCHECK(!CheckContainsQueueForTest(queue));
#endif
}
void TaskQueueSelector::WorkQueueSetBecameEmpty(size_t set_index) {
non_empty_set_counts_[set_index]--;
DCHECK_GE(non_empty_set_counts_[set_index], 0);
// There are no delayed or immediate tasks for |set_index| so remove from
// |active_priority_tracker_|.
if (non_empty_set_counts_[set_index] == 0) {
active_priority_tracker_.SetActive(
static_cast<TaskQueue::QueuePriority>(set_index), false);
}
}
void TaskQueueSelector::WorkQueueSetBecameNonEmpty(size_t set_index) {
non_empty_set_counts_[set_index]++;
DCHECK_LE(non_empty_set_counts_[set_index], kMaxNonEmptySetCount);
// There is now a delayed or an immediate task for |set_index|, so add to
// |active_priority_tracker_|.
if (non_empty_set_counts_[set_index] == 1) {
TaskQueue::QueuePriority priority =
static_cast<TaskQueue::QueuePriority>(set_index);
active_priority_tracker_.SetActive(priority, true);
}
}
void TaskQueueSelector::CollectSkippedOverLowerPriorityTasks(
const internal::WorkQueue* selected_work_queue,
std::vector<const Task*>* result) const {
delayed_work_queue_sets_.CollectSkippedOverLowerPriorityTasks(
selected_work_queue, result);
immediate_work_queue_sets_.CollectSkippedOverLowerPriorityTasks(
selected_work_queue, result);
}
#if DCHECK_IS_ON() || !defined(NDEBUG)
bool TaskQueueSelector::CheckContainsQueueForTest(
const internal::TaskQueueImpl* queue) const {
bool contains_delayed_work_queue =
delayed_work_queue_sets_.ContainsWorkQueueForTest(
queue->delayed_work_queue());
bool contains_immediate_work_queue =
immediate_work_queue_sets_.ContainsWorkQueueForTest(
queue->immediate_work_queue());
DCHECK_EQ(contains_delayed_work_queue, contains_immediate_work_queue);
return contains_delayed_work_queue;
}
#endif
WorkQueue* TaskQueueSelector::SelectWorkQueueToService(
SelectTaskOption option) {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
auto highest_priority = GetHighestPendingPriority(option);
if (!highest_priority.has_value())
return nullptr;
// Select the priority from which we will select a task. Usually this is
// the highest priority for which we have work, unless we are starving a lower
// priority.
TaskQueue::QueuePriority priority = highest_priority.value();
// For selecting an immediate queue only, the highest priority can be used as
// a starting priority, but it is required to check work at other priorities.
// For the case where a delayed task is at a higher priority than an immediate
// task, HighestActivePriority(...) returns the priority of the delayed task
// but the resulting queue must be the lower one.
if (option == SelectTaskOption::kSkipDelayedTask) {
WorkQueue* queue =
#if DCHECK_IS_ON()
random_task_selection_
? ChooseImmediateOnlyWithPriority<SetOperationRandom>(priority)
:
#endif
ChooseImmediateOnlyWithPriority<SetOperationOldest>(priority);
return queue;
}
WorkQueue* queue =
#if DCHECK_IS_ON()
random_task_selection_ ? ChooseWithPriority<SetOperationRandom>(priority)
:
#endif
ChooseWithPriority<SetOperationOldest>(priority);
// If we have selected a delayed task while having an immediate task of the
// same priority, increase the starvation count.
if (queue->queue_type() == WorkQueue::QueueType::kDelayed &&
!immediate_work_queue_sets_.IsSetEmpty(priority)) {
immediate_starvation_count_++;
} else {
immediate_starvation_count_ = 0;
}
return queue;
}
Value::Dict TaskQueueSelector::AsValue() const {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
Value::Dict state;
state.Set("immediate_starvation_count", immediate_starvation_count_);
return state;
}
void TaskQueueSelector::SetTaskQueueSelectorObserver(Observer* observer) {
task_queue_selector_observer_ = observer;
}
absl::optional<TaskQueue::QueuePriority>
TaskQueueSelector::GetHighestPendingPriority(SelectTaskOption option) const {
DCHECK_CALLED_ON_VALID_THREAD(associated_thread_->thread_checker);
if (!active_priority_tracker_.HasActivePriority())
return absl::nullopt;
TaskQueue::QueuePriority highest_priority =
active_priority_tracker_.HighestActivePriority();
DCHECK_LT(highest_priority, priority_count());
if (option != SelectTaskOption::kSkipDelayedTask)
return highest_priority;
for (; highest_priority != priority_count(); ++highest_priority) {
if (active_priority_tracker_.IsActive(highest_priority) &&
!immediate_work_queue_sets_.IsSetEmpty(highest_priority)) {
return highest_priority;
}
}
return absl::nullopt;
}
void TaskQueueSelector::SetImmediateStarvationCountForTest(
int immediate_starvation_count) {
immediate_starvation_count_ = immediate_starvation_count;
}
bool TaskQueueSelector::HasTasksWithPriority(
TaskQueue::QueuePriority priority) const {
return !delayed_work_queue_sets_.IsSetEmpty(priority) ||
!immediate_work_queue_sets_.IsSetEmpty(priority);
}
TaskQueueSelector::ActivePriorityTracker::ActivePriorityTracker() = default;
void TaskQueueSelector::ActivePriorityTracker::SetActive(
TaskQueue::QueuePriority priority,
bool is_active) {
DCHECK_LT(priority, SequenceManager::PrioritySettings::kMaxPriorities);
DCHECK_NE(IsActive(priority), is_active);
if (is_active) {
active_priorities_ |= (size_t{1} << static_cast<size_t>(priority));
} else {
active_priorities_ &= ~(size_t{1} << static_cast<size_t>(priority));
}
}
TaskQueue::QueuePriority
TaskQueueSelector::ActivePriorityTracker::HighestActivePriority() const {
DCHECK_NE(active_priorities_, 0u)
<< "CountTrailingZeroBits(0) has undefined behavior";
return static_cast<TaskQueue::QueuePriority>(
bits::CountTrailingZeroBits(active_priorities_));
}
} // namespace internal
} // namespace sequence_manager
} // namespace base