naiveproxy/base/message_loop/message_loop.cc
2018-12-09 21:59:24 -05:00

669 lines
22 KiB
C++

// 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/message_loop.h"
#include <algorithm>
#include <utility>
#include "base/bind.h"
#include "base/callback_helpers.h"
#include "base/compiler_specific.h"
#include "base/debug/task_annotator.h"
#include "base/logging.h"
#include "base/memory/ptr_util.h"
#include "base/message_loop/message_loop_task_runner.h"
#include "base/message_loop/message_pump_default.h"
#include "base/message_loop/message_pump_for_io.h"
#include "base/message_loop/message_pump_for_ui.h"
#include "base/message_loop/sequenced_task_source.h"
#include "base/run_loop.h"
#include "base/threading/thread_id_name_manager.h"
#include "base/threading/thread_task_runner_handle.h"
#include "base/trace_event/trace_event.h"
#if defined(OS_MACOSX)
#include "base/message_loop/message_pump_mac.h"
#endif
namespace base {
namespace {
MessageLoop::MessagePumpFactory* message_pump_for_ui_factory_ = nullptr;
std::unique_ptr<MessagePump> ReturnPump(std::unique_ptr<MessagePump> pump) {
return pump;
}
} // namespace
class MessageLoop::Controller : public SequencedTaskSource::Observer {
public:
// Constructs a MessageLoopController which controls |message_loop|, notifying
// |task_annotator_| when tasks are queued scheduling work on |message_loop|
// as fits. |message_loop| and |task_annotator_| will not be used after
// DisconnectFromParent() returns.
Controller(MessageLoop* message_loop);
~Controller() override;
// SequencedTaskSource::Observer:
void WillQueueTask(PendingTask* task) final;
void DidQueueTask(bool was_empty) final;
void StartScheduling();
// Disconnects |message_loop_| from this Controller instance (DidQueueTask()
// will no-op from this point forward).
void DisconnectFromParent();
// Shares this Controller's TaskAnnotator with MessageLoop as TaskAnnotator
// requires DidQueueTask(x)/RunTask(x) to be invoked on the same TaskAnnotator
// instance.
debug::TaskAnnotator& task_annotator() { return task_annotator_; }
private:
// A TaskAnnotator which is owned by this Controller to be able to use it
// without locking |message_loop_lock_|. It cannot be owned by MessageLoop
// because this Controller cannot access |message_loop_| safely without the
// lock. Note: the TaskAnnotator API itself is thread-safe.
debug::TaskAnnotator task_annotator_;
// Lock that serializes |message_loop_->ScheduleWork()| and access to all
// members below.
base::Lock message_loop_lock_;
// Points to this Controller's outer MessageLoop instance. Null after
// DisconnectFromParent().
MessageLoop* message_loop_;
// False until StartScheduling() is called.
bool is_ready_for_scheduling_ = false;
// True if DidQueueTask() has been called before StartScheduling(); letting it
// know whether it needs to ScheduleWork() right away or not.
bool pending_schedule_work_ = false;
DISALLOW_COPY_AND_ASSIGN(Controller);
};
MessageLoop::Controller::Controller(MessageLoop* message_loop)
: message_loop_(message_loop) {}
MessageLoop::Controller::~Controller() {
DCHECK(!message_loop_)
<< "DisconnectFromParent() needs to be invoked before destruction.";
}
void MessageLoop::Controller::WillQueueTask(PendingTask* task) {
task_annotator_.WillQueueTask("MessageLoop::PostTask", task);
}
void MessageLoop::Controller::DidQueueTask(bool was_empty) {
// Avoid locking if we don't need to schedule.
if (!was_empty)
return;
AutoLock auto_lock(message_loop_lock_);
if (message_loop_ && is_ready_for_scheduling_)
message_loop_->ScheduleWork();
else
pending_schedule_work_ = true;
}
void MessageLoop::Controller::StartScheduling() {
AutoLock lock(message_loop_lock_);
DCHECK(message_loop_);
DCHECK(!is_ready_for_scheduling_);
is_ready_for_scheduling_ = true;
if (pending_schedule_work_)
message_loop_->ScheduleWork();
}
void MessageLoop::Controller::DisconnectFromParent() {
AutoLock lock(message_loop_lock_);
message_loop_ = nullptr;
}
//------------------------------------------------------------------------------
MessageLoop::MessageLoop(Type type)
: MessageLoop(type, MessagePumpFactoryCallback()) {
BindToCurrentThread();
}
MessageLoop::MessageLoop(std::unique_ptr<MessagePump> pump)
: MessageLoop(TYPE_CUSTOM, BindOnce(&ReturnPump, std::move(pump))) {
BindToCurrentThread();
}
MessageLoop::~MessageLoop() {
// If |pump_| is non-null, this message loop has been bound and should be the
// current one on this thread. Otherwise, this loop is being destructed before
// it was bound to a thread, so a different message loop (or no loop at all)
// may be current.
DCHECK((pump_ && MessageLoopCurrent::IsBoundToCurrentThreadInternal(this)) ||
(!pump_ && !MessageLoopCurrent::IsBoundToCurrentThreadInternal(this)));
// iOS just attaches to the loop, it doesn't Run it.
// TODO(stuartmorgan): Consider wiring up a Detach().
#if !defined(OS_IOS)
// There should be no active RunLoops on this thread, unless this MessageLoop
// isn't bound to the current thread (see other condition at the top of this
// method).
DCHECK(
(!pump_ && !MessageLoopCurrent::IsBoundToCurrentThreadInternal(this)) ||
!RunLoop::IsRunningOnCurrentThread());
#endif // !defined(OS_IOS)
#if defined(OS_WIN)
if (in_high_res_mode_)
Time::ActivateHighResolutionTimer(false);
#endif
// Clean up any unprocessed tasks, but take care: deleting a task could
// result in the addition of more tasks (e.g., via DeleteSoon). We set a
// limit on the number of times we will allow a deleted task to generate more
// tasks. Normally, we should only pass through this loop once or twice. If
// we end up hitting the loop limit, then it is probably due to one task that
// is being stubborn. Inspect the queues to see who is left.
bool tasks_remain;
for (int i = 0; i < 100; ++i) {
DeletePendingTasks();
// If we end up with empty queues, then break out of the loop.
tasks_remain = sequenced_task_source_->HasTasks();
if (!tasks_remain)
break;
}
DCHECK(!tasks_remain);
// Let interested parties have one last shot at accessing this.
for (auto& observer : destruction_observers_)
observer.WillDestroyCurrentMessageLoop();
thread_task_runner_handle_.reset();
// Detach this instance's Controller from |this|. After this point,
// |underlying_task_runner_| may still receive tasks and notify the controller
// but the controller will no-op (and not use this MessageLoop after free).
// |underlying_task_runner_| being ref-counted and potentially kept alive by
// many SingleThreadTaskRunner refs, the best we can do is tell it to shutdown
// after which it will start returning false to PostTasks that happen-after
// this point (note that invoking Shutdown() first would not remove the need
// to DisconnectFromParent() since the controller is invoked *after* a task is
// enqueued and the incoming queue's lock is released (see
// MessageLoopTaskRunner::AddToIncomingQueue()).
// Details : while an "in-progress post tasks" refcount in Controller in lieu
// of |message_loop_lock_| would be an option to handle the "pending post
// tasks on shutdown" case, |message_loop_lock_| would still be required to
// serialize ScheduleWork() call and as such that optimization isn't worth it.
message_loop_controller_->DisconnectFromParent();
underlying_task_runner_->Shutdown();
// OK, now make it so that no one can find us.
if (MessageLoopCurrent::IsBoundToCurrentThreadInternal(this))
MessageLoopCurrent::UnbindFromCurrentThreadInternal(this);
}
// static
MessageLoopCurrent MessageLoop::current() {
return MessageLoopCurrent::Get();
}
// static
bool MessageLoop::InitMessagePumpForUIFactory(MessagePumpFactory* factory) {
if (message_pump_for_ui_factory_)
return false;
message_pump_for_ui_factory_ = factory;
return true;
}
// static
std::unique_ptr<MessagePump> MessageLoop::CreateMessagePumpForType(Type type) {
if (type == MessageLoop::TYPE_UI) {
if (message_pump_for_ui_factory_)
return message_pump_for_ui_factory_();
#if defined(OS_IOS) || defined(OS_MACOSX)
return MessagePumpMac::Create();
#elif defined(OS_NACL) || defined(OS_AIX)
// Currently NaCl and AIX don't have a UI MessageLoop.
// TODO(abarth): Figure out if we need this.
NOTREACHED();
return nullptr;
#else
return std::make_unique<MessagePumpForUI>();
#endif
}
if (type == MessageLoop::TYPE_IO)
return std::unique_ptr<MessagePump>(new MessagePumpForIO());
#if defined(OS_ANDROID)
if (type == MessageLoop::TYPE_JAVA)
return std::unique_ptr<MessagePump>(new MessagePumpForUI());
#endif
DCHECK_EQ(MessageLoop::TYPE_DEFAULT, type);
#if defined(OS_IOS)
// On iOS, a native runloop is always required to pump system work.
return std::make_unique<MessagePumpCFRunLoop>();
#else
return std::make_unique<MessagePumpDefault>();
#endif
}
bool MessageLoop::IsType(Type type) const {
return type_ == type;
}
// TODO(gab): Migrate TaskObservers to RunLoop as part of separating concerns
// between MessageLoop and RunLoop and making MessageLoop a swappable
// implementation detail. http://crbug.com/703346
void MessageLoop::AddTaskObserver(TaskObserver* task_observer) {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
task_observers_.push_back(task_observer);
}
void MessageLoop::RemoveTaskObserver(TaskObserver* task_observer) {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
auto it =
std::find(task_observers_.begin(), task_observers_.end(), task_observer);
DCHECK(it != task_observers_.end());
task_observers_.erase(it);
}
void MessageLoop::SetAddQueueTimeToTasks(bool enable) {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
underlying_task_runner_->SetAddQueueTimeToTasks(enable);
}
bool MessageLoop::IsIdleForTesting() {
// Have unprocessed tasks? (this reloads the work queue if necessary)
if (sequenced_task_source_->HasTasks())
return false;
// Have unprocessed deferred tasks which can be processed at this run-level?
if (pending_task_queue_.deferred_tasks().HasTasks() &&
!RunLoop::IsNestedOnCurrentThread()) {
return false;
}
return true;
}
//------------------------------------------------------------------------------
// static
std::unique_ptr<MessageLoop> MessageLoop::CreateUnbound(
Type type,
MessagePumpFactoryCallback pump_factory) {
return WrapUnique(new MessageLoop(type, std::move(pump_factory)));
}
MessageLoop::MessageLoop(Type type, MessagePumpFactoryCallback pump_factory)
: MessageLoopCurrent(this),
type_(type),
pump_factory_(std::move(pump_factory)),
message_loop_controller_(
new Controller(this)), // Ownership transferred on the next line.
underlying_task_runner_(MakeRefCounted<internal::MessageLoopTaskRunner>(
WrapUnique(message_loop_controller_))),
sequenced_task_source_(underlying_task_runner_.get()),
task_runner_(underlying_task_runner_) {
// If type is TYPE_CUSTOM non-null pump_factory must be given.
DCHECK(type_ != TYPE_CUSTOM || !pump_factory_.is_null());
// Bound in BindToCurrentThread();
DETACH_FROM_THREAD(bound_thread_checker_);
}
void MessageLoop::BindToCurrentThread() {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
DCHECK(!pump_);
if (!pump_factory_.is_null())
pump_ = std::move(pump_factory_).Run();
else
pump_ = CreateMessagePumpForType(type_);
DCHECK(!MessageLoopCurrent::IsSet())
<< "should only have one message loop per thread";
MessageLoopCurrent::BindToCurrentThreadInternal(this);
underlying_task_runner_->BindToCurrentThread();
message_loop_controller_->StartScheduling();
SetThreadTaskRunnerHandle();
thread_id_ = PlatformThread::CurrentId();
scoped_set_sequence_local_storage_map_for_current_thread_ = std::make_unique<
internal::ScopedSetSequenceLocalStorageMapForCurrentThread>(
&sequence_local_storage_map_);
RunLoop::RegisterDelegateForCurrentThread(this);
#if defined(OS_ANDROID)
// On Android, attach to the native loop when there is one.
if (type_ == TYPE_UI || type_ == TYPE_JAVA)
static_cast<MessagePumpForUI*>(pump_.get())->Attach(this);
#endif
}
std::string MessageLoop::GetThreadName() const {
DCHECK_NE(kInvalidThreadId, thread_id_)
<< "GetThreadName() must only be called after BindToCurrentThread()'s "
<< "side-effects have been synchronized with this thread.";
return ThreadIdNameManager::GetInstance()->GetName(thread_id_);
}
void MessageLoop::SetTaskRunner(
scoped_refptr<SingleThreadTaskRunner> task_runner) {
DCHECK(task_runner);
if (thread_id_ == kInvalidThreadId) {
// ThreadTaskRunnerHandle will be set during BindToCurrentThread().
task_runner_ = std::move(task_runner);
} else {
// Once MessageLoop is bound, |task_runner_| may only be altered on the
// bound thread.
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
DCHECK(task_runner->BelongsToCurrentThread());
task_runner_ = std::move(task_runner);
SetThreadTaskRunnerHandle();
}
}
void MessageLoop::Run(bool application_tasks_allowed) {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
if (application_tasks_allowed && !task_execution_allowed_) {
// Allow nested task execution as explicitly requested.
DCHECK(RunLoop::IsNestedOnCurrentThread());
task_execution_allowed_ = true;
pump_->Run(this);
task_execution_allowed_ = false;
} else {
pump_->Run(this);
}
}
void MessageLoop::Quit() {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
pump_->Quit();
}
void MessageLoop::EnsureWorkScheduled() {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
if (sequenced_task_source_->HasTasks())
pump_->ScheduleWork();
}
void MessageLoop::SetThreadTaskRunnerHandle() {
DCHECK_CALLED_ON_VALID_THREAD(bound_thread_checker_);
// Clear the previous thread task runner first, because only one can exist at
// a time.
thread_task_runner_handle_.reset();
thread_task_runner_handle_.reset(new ThreadTaskRunnerHandle(task_runner_));
}
bool MessageLoop::ProcessNextDelayedNonNestableTask() {
if (RunLoop::IsNestedOnCurrentThread())
return false;
while (pending_task_queue_.deferred_tasks().HasTasks()) {
PendingTask pending_task = pending_task_queue_.deferred_tasks().Pop();
if (!pending_task.task.IsCancelled()) {
RunTask(&pending_task);
return true;
}
}
return false;
}
void MessageLoop::RunTask(PendingTask* pending_task) {
DCHECK(task_execution_allowed_);
// Execute the task and assume the worst: It is probably not reentrant.
task_execution_allowed_ = false;
TRACE_TASK_EXECUTION("MessageLoop::RunTask", *pending_task);
for (TaskObserver* task_observer : task_observers_)
task_observer->WillProcessTask(*pending_task);
message_loop_controller_->task_annotator().RunTask("MessageLoop::PostTask",
pending_task);
for (TaskObserver* task_observer : task_observers_)
task_observer->DidProcessTask(*pending_task);
task_execution_allowed_ = true;
}
bool MessageLoop::DeferOrRunPendingTask(PendingTask pending_task) {
if (pending_task.nestable == Nestable::kNestable ||
!RunLoop::IsNestedOnCurrentThread()) {
RunTask(&pending_task);
// Show that we ran a task (Note: a new one might arrive as a
// consequence!).
return true;
}
// We couldn't run the task now because we're in a nested run loop
// and the task isn't nestable.
pending_task_queue_.deferred_tasks().Push(std::move(pending_task));
return false;
}
void MessageLoop::DeletePendingTasks() {
// Delete all currently pending tasks but not tasks potentially posted from
// their destructors. See ~MessageLoop() for the full logic mitigating against
// infite loops when clearing pending tasks. The ScopedClosureRunner below
// will be bound to a task posted at the end of the queue. After it is posted,
// tasks will be deleted one by one, when the bound ScopedClosureRunner is
// deleted and sets |deleted_all_originally_pending|, we know we've deleted
// all originally pending tasks.
bool deleted_all_originally_pending = false;
ScopedClosureRunner capture_deleted_all_originally_pending(BindOnce(
[](bool* deleted_all_originally_pending) {
*deleted_all_originally_pending = true;
},
Unretained(&deleted_all_originally_pending)));
sequenced_task_source_->InjectTask(
BindOnce([](ScopedClosureRunner) {},
std::move(capture_deleted_all_originally_pending)));
while (!deleted_all_originally_pending) {
PendingTask pending_task = sequenced_task_source_->TakeTask();
// New delayed tasks should be deleted after older ones.
if (!pending_task.delayed_run_time.is_null())
pending_task_queue_.delayed_tasks().Push(std::move(pending_task));
}
pending_task_queue_.deferred_tasks().Clear();
// TODO(robliao): Determine if we can move delayed task destruction before
// deferred tasks to maintain the MessagePump DoWork, DoDelayedWork, and
// DoIdleWork processing order.
pending_task_queue_.delayed_tasks().Clear();
}
void MessageLoop::ScheduleWork() {
pump_->ScheduleWork();
}
TimeTicks MessageLoop::CapAtOneDay(TimeTicks next_run_time) {
return std::min(next_run_time, recent_time_ + TimeDelta::FromDays(1));
}
bool MessageLoop::DoWork() {
if (!task_execution_allowed_)
return false;
// Execute oldest task.
while (sequenced_task_source_->HasTasks()) {
PendingTask pending_task = sequenced_task_source_->TakeTask();
if (pending_task.task.IsCancelled())
continue;
if (!pending_task.delayed_run_time.is_null()) {
int sequence_num = pending_task.sequence_num;
TimeTicks delayed_run_time = pending_task.delayed_run_time;
pending_task_queue_.delayed_tasks().Push(std::move(pending_task));
// If we changed the topmost task, then it is time to reschedule.
if (pending_task_queue_.delayed_tasks().Peek().sequence_num ==
sequence_num) {
pump_->ScheduleDelayedWork(delayed_run_time);
}
} else if (DeferOrRunPendingTask(std::move(pending_task))) {
return true;
}
}
// Nothing happened.
return false;
}
bool MessageLoop::DoDelayedWork(TimeTicks* next_delayed_work_time) {
if (!task_execution_allowed_ ||
!pending_task_queue_.delayed_tasks().HasTasks()) {
*next_delayed_work_time = TimeTicks();
return false;
}
// When we "fall behind", there will be a lot of tasks in the delayed work
// queue that are ready to run. To increase efficiency when we fall behind,
// we will only call Time::Now() intermittently, and then process all tasks
// that are ready to run before calling it again. As a result, the more we
// fall behind (and have a lot of ready-to-run delayed tasks), the more
// efficient we'll be at handling the tasks.
TimeTicks next_run_time =
pending_task_queue_.delayed_tasks().Peek().delayed_run_time;
if (next_run_time > recent_time_) {
recent_time_ = TimeTicks::Now(); // Get a better view of Now();
if (next_run_time > recent_time_) {
*next_delayed_work_time = CapAtOneDay(next_run_time);
return false;
}
}
PendingTask pending_task = pending_task_queue_.delayed_tasks().Pop();
if (pending_task_queue_.delayed_tasks().HasTasks()) {
*next_delayed_work_time = CapAtOneDay(
pending_task_queue_.delayed_tasks().Peek().delayed_run_time);
}
return DeferOrRunPendingTask(std::move(pending_task));
}
bool MessageLoop::DoIdleWork() {
if (ProcessNextDelayedNonNestableTask())
return true;
#if defined(OS_WIN)
bool need_high_res_timers = false;
#endif
// Do not report idle metrics if about to quit the loop and/or in a nested
// loop where |!task_execution_allowed_|. In the former case, the loop isn't
// going to sleep and in the latter case DoDelayedWork() will not actually do
// the work this is prepping for.
if (ShouldQuitWhenIdle()) {
pump_->Quit();
} else if (task_execution_allowed_) {
// Only track idle metrics in MessageLoopForUI to avoid too much contention
// logging the histogram (https://crbug.com/860801) -- there's typically
// only one UI thread per process and, for practical purposes, restricting
// the MessageLoop diagnostic metrics to it yields similar information.
if (type_ == TYPE_UI)
pending_task_queue_.ReportMetricsOnIdle();
#if defined(OS_WIN)
// On Windows we activate the high resolution timer so that the wait
// _if_ triggered by the timer happens with good resolution. If we don't
// do this the default resolution is 15ms which might not be acceptable
// for some tasks.
need_high_res_timers = pending_task_queue_.HasPendingHighResolutionTasks();
#endif
}
#if defined(OS_WIN)
if (in_high_res_mode_ != need_high_res_timers) {
in_high_res_mode_ = need_high_res_timers;
Time::ActivateHighResolutionTimer(in_high_res_mode_);
}
#endif
// When we return we will do a kernel wait for more tasks.
return false;
}
#if !defined(OS_NACL)
//------------------------------------------------------------------------------
// MessageLoopForUI
MessageLoopForUI::MessageLoopForUI(Type type) : MessageLoop(type) {
#if defined(OS_ANDROID)
DCHECK(type == TYPE_UI || type == TYPE_JAVA);
#else
DCHECK_EQ(type, TYPE_UI);
#endif
}
// static
MessageLoopCurrentForUI MessageLoopForUI::current() {
return MessageLoopCurrentForUI::Get();
}
// static
bool MessageLoopForUI::IsCurrent() {
return MessageLoopCurrentForUI::IsSet();
}
#if defined(OS_IOS)
void MessageLoopForUI::Attach() {
static_cast<MessagePumpUIApplication*>(pump_.get())->Attach(this);
}
#endif // defined(OS_IOS)
#if defined(OS_ANDROID)
void MessageLoopForUI::Abort() {
static_cast<MessagePumpForUI*>(pump_.get())->Abort();
}
bool MessageLoopForUI::IsAborted() {
return static_cast<MessagePumpForUI*>(pump_.get())->IsAborted();
}
void MessageLoopForUI::QuitWhenIdle(base::OnceClosure callback) {
static_cast<MessagePumpForUI*>(pump_.get())
->QuitWhenIdle(std::move(callback));
}
#endif // defined(OS_ANDROID)
#if defined(OS_WIN)
void MessageLoopForUI::EnableWmQuit() {
static_cast<MessagePumpForUI*>(pump_.get())->EnableWmQuit();
}
#endif // defined(OS_WIN)
#endif // !defined(OS_NACL)
//------------------------------------------------------------------------------
// MessageLoopForIO
// static
MessageLoopCurrentForIO MessageLoopForIO::current() {
return MessageLoopCurrentForIO::Get();
}
// static
bool MessageLoopForIO::IsCurrent() {
return MessageLoopCurrentForIO::IsSet();
}
} // namespace base