base/message_loop/message_pump_android.cc - cobalt - Git at Google

 // Copyright 2012 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/message_loop/message_pump_android.h"

 #include <android/looper.h>
 #include <errno.h>
 #include <fcntl.h>
 #include <jni.h>
 #include <sys/eventfd.h>
 #include <sys/timerfd.h>
 #include <sys/types.h>
 #include <unistd.h>
 #include <utility>

 #include "base/android/jni_android.h"
 #include "base/android/scoped_java_ref.h"
 #include "base/check_op.h"
 #include "base/notreached.h"
 #include "base/numerics/safe_conversions.h"
 #include "base/run_loop.h"
 #include "build/build_config.h"

 namespace base {

 namespace {

 // https://crbug.com/873588. The stack may not be aligned when the ALooper calls
 // into our code due to the inconsistent ABI on older Android OS versions.
 #if defined(ARCH_CPU_X86)
 #define STACK_ALIGN __attribute__((force_align_arg_pointer))
 #else
 #define STACK_ALIGN
 #endif

 STACK_ALIGN int NonDelayedLooperCallback(int fd, int events, void* data) {
   if (events & ALOOPER_EVENT_HANGUP)
     return 0;

   DCHECK(events & ALOOPER_EVENT_INPUT);
   MessagePumpForUI* pump = reinterpret_cast<MessagePumpForUI*>(data);
   pump->OnNonDelayedLooperCallback();
   return 1;  // continue listening for events
 }

 STACK_ALIGN int DelayedLooperCallback(int fd, int events, void* data) {
   if (events & ALOOPER_EVENT_HANGUP)
     return 0;

   DCHECK(events & ALOOPER_EVENT_INPUT);
   MessagePumpForUI* pump = reinterpret_cast<MessagePumpForUI*>(data);
   pump->OnDelayedLooperCallback();
   return 1;  // continue listening for events
 }

 // A bit added to the |non_delayed_fd_| to keep it signaled when we yield to
 // native work below.
 constexpr uint64_t kTryNativeWorkBeforeIdleBit = uint64_t(1) << 32;
 }  // namespace

 MessagePumpForUI::MessagePumpForUI()
     : env_(base::android::AttachCurrentThread()) {
   // The Android native ALooper uses epoll to poll our file descriptors and wake
   // us up. We use a simple level-triggered eventfd to signal that non-delayed
   // work is available, and a timerfd to signal when delayed work is ready to
   // be run.
   non_delayed_fd_ = eventfd(0, EFD_NONBLOCK | EFD_CLOEXEC);
   CHECK_NE(non_delayed_fd_, -1);
   DCHECK_EQ(TimeTicks::GetClock(), TimeTicks::Clock::LINUX_CLOCK_MONOTONIC);

   delayed_fd_ = checked_cast<int>(
       timerfd_create(CLOCK_MONOTONIC, TFD_NONBLOCK | TFD_CLOEXEC));
   CHECK_NE(delayed_fd_, -1);

   looper_ = ALooper_prepare(0);
   DCHECK(looper_);
   // Add a reference to the looper so it isn't deleted on us.
   ALooper_acquire(looper_);
   ALooper_addFd(looper_, non_delayed_fd_, 0, ALOOPER_EVENT_INPUT,
                 &NonDelayedLooperCallback, reinterpret_cast<void*>(this));
   ALooper_addFd(looper_, delayed_fd_, 0, ALOOPER_EVENT_INPUT,
                 &DelayedLooperCallback, reinterpret_cast<void*>(this));
 }

 MessagePumpForUI::~MessagePumpForUI() {
   DCHECK_EQ(ALooper_forThread(), looper_);
   ALooper_removeFd(looper_, non_delayed_fd_);
   ALooper_removeFd(looper_, delayed_fd_);
   ALooper_release(looper_);
   looper_ = nullptr;

   close(non_delayed_fd_);
   close(delayed_fd_);
 }

 void MessagePumpForUI::OnDelayedLooperCallback() {
   // There may be non-Chromium callbacks on the same ALooper which may have left
   // a pending exception set, and ALooper does not check for this between
   // callbacks. Check here, and if there's already an exception, just skip this
   // iteration without clearing the fd. If the exception ends up being non-fatal
   // then we'll just get called again on the next polling iteration.
   if (base::android::HasException(env_))
     return;

   // ALooper_pollOnce may call this after Quit() if OnNonDelayedLooperCallback()
   // resulted in Quit() in the same round.
   if (ShouldQuit())
     return;

   // Clear the fd.
   uint64_t value;
   long ret = read(delayed_fd_, &value, sizeof(value));

   // TODO(mthiesse): Figure out how it's possible to hit EAGAIN here.
   // According to http://man7.org/linux/man-pages/man2/timerfd_create.2.html
   // EAGAIN only happens if no timer has expired. Also according to the man page
   // poll only returns readable when a timer has expired. So this function will
   // only be called when a timer has expired, but reading reveals no timer has
   // expired...
   // Quit() and ScheduleDelayedWork() are the only other functions that touch
   // the timerfd, and they both run on the same thread as this callback, so
   // there are no obvious timing or multi-threading related issues.
   DPCHECK(ret >= 0 || errno == EAGAIN);
   DoDelayedLooperWork();
 }

 void MessagePumpForUI::DoDelayedLooperWork() {
   delayed_scheduled_time_.reset();

   Delegate::NextWorkInfo next_work_info = delegate_->DoWork();

   if (ShouldQuit())
     return;

   if (next_work_info.is_immediate()) {
     ScheduleWork();
     return;
   }

   DoIdleWork();
   if (!next_work_info.delayed_run_time.is_max())
     ScheduleDelayedWork(next_work_info);
 }

 void MessagePumpForUI::OnNonDelayedLooperCallback() {
   // There may be non-Chromium callbacks on the same ALooper which may have left
   // a pending exception set, and ALooper does not check for this between
   // callbacks. Check here, and if there's already an exception, just skip this
   // iteration without clearing the fd. If the exception ends up being non-fatal
   // then we'll just get called again on the next polling iteration.
   if (base::android::HasException(env_))
     return;

   // ALooper_pollOnce may call this after Quit() if OnDelayedLooperCallback()
   // resulted in Quit() in the same round.
   if (ShouldQuit())
     return;

   // We're about to process all the work requested by ScheduleWork().
   // MessagePump users are expected to do their best not to invoke
   // ScheduleWork() again before DoWork() returns a non-immediate
   // NextWorkInfo below. Hence, capturing the file descriptor's value now and
   // resetting its contents to 0 should be okay. The value currently stored
   // should be greater than 0 since work having been scheduled is the reason
   // we're here. See http://man7.org/linux/man-pages/man2/eventfd.2.html
   uint64_t value = 0;
   long ret = read(non_delayed_fd_, &value, sizeof(value));
   DPCHECK(ret >= 0);
   DCHECK_GT(value, 0U);
   bool do_idle_work = value == kTryNativeWorkBeforeIdleBit;
   DoNonDelayedLooperWork(do_idle_work);
 }

 void MessagePumpForUI::DoNonDelayedLooperWork(bool do_idle_work) {
   // Note: We can't skip DoWork() even if |do_idle_work| is true here (i.e. no
   // additional ScheduleWork() since yielding to native) as delayed tasks might
   // have come in and we need to re-sample |next_work_info|.

   // Runs all application tasks scheduled to run.
   Delegate::NextWorkInfo next_work_info;
   do {
     if (ShouldQuit())
       return;

     next_work_info = delegate_->DoWork();
     // If we are prioritizing native, and the next work would normally run
     // immediately, skip the next work and let the native work items have a
     // chance to run. This is useful when user input is waiting for native to
     // have a chance to run.
     if (next_work_info.is_immediate() && next_work_info.yield_to_native) {
       ScheduleWork();
       return;
     }
   } while (next_work_info.is_immediate());

   // Do not resignal |non_delayed_fd_| if we're quitting (this pump doesn't
   // allow nesting so needing to resume in an outer loop is not an issue
   // either).
   if (ShouldQuit())
     return;

   // Before declaring this loop idle, yield to native work items and arrange to
   // be called again (unless we're already in that second call).
   if (!do_idle_work) {
     ScheduleWorkInternal(/*do_idle_work=*/true);
     return;
   }

   // We yielded to native work items already and they didn't generate a
   // ScheduleWork() request so we can declare idleness. It's possible for a
   // ScheduleWork() request to come in racily while this method unwinds, this is
   // fine and will merely result in it being re-invoked shortly after it
   // returns.
   // TODO(scheduler-dev): this doesn't account for tasks that don't ever call
   // SchedulerWork() but still keep the system non-idle (e.g., the Java Handler
   // API). It would be better to add an API to query the presence of native
   // tasks instead of relying on yielding once + kTryNativeWorkBeforeIdleBit.
   DCHECK(do_idle_work);

   if (ShouldQuit())
     return;

   // At this point, the java looper might not be idle - it's impossible to know
   // pre-Android-M, so we may end up doing Idle work while java tasks are still
   // queued up. Note that this won't cause us to fail to run java tasks using
   // QuitWhenIdle, as the JavaHandlerThread will finish running all currently
   // scheduled tasks before it quits. Also note that we can't just add an idle
   // callback to the java looper, as that will fire even if application tasks
   // are still queued up.
   DoIdleWork();
   if (!next_work_info.delayed_run_time.is_max()) {
     ScheduleDelayedWork(next_work_info);
   }
 }

 void MessagePumpForUI::DoIdleWork() {
   if (delegate_->DoIdleWork()) {
     // If DoIdleWork() resulted in any work, we're not idle yet. We need to pump
     // the loop here because we may in fact be idle after doing idle work
     // without any new tasks being queued.
     ScheduleWork();
   }
 }

 void MessagePumpForUI::Run(Delegate* delegate) {
   CHECK(false) << "Unexpected call to Run()";
 }

 void MessagePumpForUI::Attach(Delegate* delegate) {
   DCHECK(!quit_);

   // Since the Looper is controlled by the UI thread or JavaHandlerThread, we
   // can't use Run() like we do on other platforms or we would prevent Java
   // tasks from running. Instead we create and initialize a run loop here, then
   // return control back to the Looper.

   SetDelegate(delegate);
   run_loop_ = std::make_unique<RunLoop>();
   // Since the RunLoop was just created above, BeforeRun should be guaranteed to
   // return true (it only returns false if the RunLoop has been Quit already).
   if (!run_loop_->BeforeRun())
     NOTREACHED();
 }

 void MessagePumpForUI::Quit() {
   if (quit_)
     return;

   quit_ = true;

   int64_t value;
   // Clear any pending timer.
   read(delayed_fd_, &value, sizeof(value));
   // Clear the eventfd.
   read(non_delayed_fd_, &value, sizeof(value));

   if (run_loop_) {
     run_loop_->AfterRun();
     run_loop_ = nullptr;
   }
   if (on_quit_callback_) {
     std::move(on_quit_callback_).Run();
   }
 }

 void MessagePumpForUI::ScheduleWork() {
   ScheduleWorkInternal(/*do_idle_work=*/false);
 }

 void MessagePumpForUI::ScheduleWorkInternal(bool do_idle_work) {
   // Write (add) |value| to the eventfd. This tells the Looper to wake up and
   // call our callback, allowing us to run tasks. This also allows us to detect,
   // when we clear the fd, whether additional work was scheduled after we
   // finished performing work, but before we cleared the fd, as we'll read back
   // >=2 instead of 1 in that case. See the eventfd man pages
   // (http://man7.org/linux/man-pages/man2/eventfd.2.html) for details on how
   // the read and write APIs for this file descriptor work, specifically without
   // EFD_SEMAPHORE.
   // Note: Calls with |do_idle_work| set to true may race with potential calls
   // where the parameter is false. This is fine as write() is adding |value|,
   // not overwriting the existing value, and as such racing calls would merely
   // have their values added together. Since idle work is only executed when the
   // value read equals kTryNativeWorkBeforeIdleBit, a race would prevent idle
   // work from being run and trigger another call to this method with
   // |do_idle_work| set to true.
   uint64_t value = do_idle_work ? kTryNativeWorkBeforeIdleBit : 1;
   long ret = write(non_delayed_fd_, &value, sizeof(value));
   DPCHECK(ret >= 0);
 }

 void MessagePumpForUI::ScheduleDelayedWork(
     const Delegate::NextWorkInfo& next_work_info) {
   if (ShouldQuit())
     return;

   if (delayed_scheduled_time_ &&
       *delayed_scheduled_time_ == next_work_info.delayed_run_time) {
     return;
   }

   DCHECK(!next_work_info.is_immediate());
   delayed_scheduled_time_ = next_work_info.delayed_run_time;
   int64_t nanos =
       next_work_info.delayed_run_time.since_origin().InNanoseconds();
   struct itimerspec ts;
   ts.it_interval.tv_sec = 0;  // Don't repeat.
   ts.it_interval.tv_nsec = 0;
   ts.it_value.tv_sec =
       static_cast<time_t>(nanos / TimeTicks::kNanosecondsPerSecond);
   ts.it_value.tv_nsec = nanos % TimeTicks::kNanosecondsPerSecond;

   long ret = timerfd_settime(delayed_fd_, TFD_TIMER_ABSTIME, &ts, nullptr);
   DPCHECK(ret >= 0);
 }

 void MessagePumpForUI::QuitWhenIdle(base::OnceClosure callback) {
   DCHECK(!on_quit_callback_);
   DCHECK(run_loop_);
   on_quit_callback_ = std::move(callback);
   run_loop_->QuitWhenIdle();
   // Pump the loop in case we're already idle.
   ScheduleWork();
 }

 MessagePump::Delegate* MessagePumpForUI::SetDelegate(Delegate* delegate) {
   return std::exchange(delegate_, delegate);
 }

 bool MessagePumpForUI::SetQuit(bool quit) {
   return std::exchange(quit_, quit);
 }

 }  // namespace base
	// Copyright 2012 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/message_loop/message_pump_android.h"

	#include <android/looper.h>
	#include <errno.h>
	#include <fcntl.h>
	#include <jni.h>
	#include <sys/eventfd.h>
	#include <sys/timerfd.h>
	#include <sys/types.h>
	#include <unistd.h>
	#include <utility>

	#include "base/android/jni_android.h"
	#include "base/android/scoped_java_ref.h"
	#include "base/check_op.h"
	#include "base/notreached.h"
	#include "base/numerics/safe_conversions.h"
	#include "base/run_loop.h"
	#include "build/build_config.h"

	namespace base {

	namespace {

	// https://crbug.com/873588. The stack may not be aligned when the ALooper calls
	// into our code due to the inconsistent ABI on older Android OS versions.
	#if defined(ARCH_CPU_X86)
	#define STACK_ALIGN __attribute__((force_align_arg_pointer))
	#else
	#define STACK_ALIGN
	#endif

	STACK_ALIGN int NonDelayedLooperCallback(int fd, int events, void* data) {
	if (events & ALOOPER_EVENT_HANGUP)
	return 0;

	DCHECK(events & ALOOPER_EVENT_INPUT);
	MessagePumpForUI* pump = reinterpret_cast<MessagePumpForUI*>(data);
	pump->OnNonDelayedLooperCallback();
	return 1; // continue listening for events
	}

	STACK_ALIGN int DelayedLooperCallback(int fd, int events, void* data) {
	if (events & ALOOPER_EVENT_HANGUP)
	return 0;

	DCHECK(events & ALOOPER_EVENT_INPUT);
	MessagePumpForUI* pump = reinterpret_cast<MessagePumpForUI*>(data);
	pump->OnDelayedLooperCallback();
	return 1; // continue listening for events
	}

	// A bit added to the \|non_delayed_fd_\| to keep it signaled when we yield to
	// native work below.
	constexpr uint64_t kTryNativeWorkBeforeIdleBit = uint64_t(1) << 32;
	} // namespace

	MessagePumpForUI::MessagePumpForUI()
	: env_(base::android::AttachCurrentThread()) {
	// The Android native ALooper uses epoll to poll our file descriptors and wake
	// us up. We use a simple level-triggered eventfd to signal that non-delayed
	// work is available, and a timerfd to signal when delayed work is ready to
	// be run.
	non_delayed_fd_ = eventfd(0, EFD_NONBLOCK \| EFD_CLOEXEC);
	CHECK_NE(non_delayed_fd_, -1);
	DCHECK_EQ(TimeTicks::GetClock(), TimeTicks::Clock::LINUX_CLOCK_MONOTONIC);

	delayed_fd_ = checked_cast<int>(
	timerfd_create(CLOCK_MONOTONIC, TFD_NONBLOCK \| TFD_CLOEXEC));
	CHECK_NE(delayed_fd_, -1);

	looper_ = ALooper_prepare(0);
	DCHECK(looper_);
	// Add a reference to the looper so it isn't deleted on us.
	ALooper_acquire(looper_);
	ALooper_addFd(looper_, non_delayed_fd_, 0, ALOOPER_EVENT_INPUT,
	&NonDelayedLooperCallback, reinterpret_cast<void*>(this));
	ALooper_addFd(looper_, delayed_fd_, 0, ALOOPER_EVENT_INPUT,
	&DelayedLooperCallback, reinterpret_cast<void*>(this));
	}

	MessagePumpForUI::~MessagePumpForUI() {
	DCHECK_EQ(ALooper_forThread(), looper_);
	ALooper_removeFd(looper_, non_delayed_fd_);
	ALooper_removeFd(looper_, delayed_fd_);
	ALooper_release(looper_);
	looper_ = nullptr;

	close(non_delayed_fd_);
	close(delayed_fd_);
	}

	void MessagePumpForUI::OnDelayedLooperCallback() {
	// There may be non-Chromium callbacks on the same ALooper which may have left
	// a pending exception set, and ALooper does not check for this between
	// callbacks. Check here, and if there's already an exception, just skip this
	// iteration without clearing the fd. If the exception ends up being non-fatal
	// then we'll just get called again on the next polling iteration.
	if (base::android::HasException(env_))
	return;

	// ALooper_pollOnce may call this after Quit() if OnNonDelayedLooperCallback()
	// resulted in Quit() in the same round.
	if (ShouldQuit())
	return;

	// Clear the fd.
	uint64_t value;
	long ret = read(delayed_fd_, &value, sizeof(value));

	// TODO(mthiesse): Figure out how it's possible to hit EAGAIN here.
	// According to http://man7.org/linux/man-pages/man2/timerfd_create.2.html
	// EAGAIN only happens if no timer has expired. Also according to the man page
	// poll only returns readable when a timer has expired. So this function will
	// only be called when a timer has expired, but reading reveals no timer has
	// expired...
	// Quit() and ScheduleDelayedWork() are the only other functions that touch
	// the timerfd, and they both run on the same thread as this callback, so
	// there are no obvious timing or multi-threading related issues.
	DPCHECK(ret >= 0 \|\| errno == EAGAIN);
	DoDelayedLooperWork();
	}

	void MessagePumpForUI::DoDelayedLooperWork() {
	delayed_scheduled_time_.reset();

	Delegate::NextWorkInfo next_work_info = delegate_->DoWork();

	if (ShouldQuit())
	return;

	if (next_work_info.is_immediate()) {
	ScheduleWork();
	return;
	}

	DoIdleWork();
	if (!next_work_info.delayed_run_time.is_max())
	ScheduleDelayedWork(next_work_info);
	}

	void MessagePumpForUI::OnNonDelayedLooperCallback() {
	// There may be non-Chromium callbacks on the same ALooper which may have left
	// a pending exception set, and ALooper does not check for this between
	// callbacks. Check here, and if there's already an exception, just skip this
	// iteration without clearing the fd. If the exception ends up being non-fatal
	// then we'll just get called again on the next polling iteration.
	if (base::android::HasException(env_))
	return;

	// ALooper_pollOnce may call this after Quit() if OnDelayedLooperCallback()
	// resulted in Quit() in the same round.
	if (ShouldQuit())
	return;

	// We're about to process all the work requested by ScheduleWork().
	// MessagePump users are expected to do their best not to invoke
	// ScheduleWork() again before DoWork() returns a non-immediate
	// NextWorkInfo below. Hence, capturing the file descriptor's value now and
	// resetting its contents to 0 should be okay. The value currently stored
	// should be greater than 0 since work having been scheduled is the reason
	// we're here. See http://man7.org/linux/man-pages/man2/eventfd.2.html
	uint64_t value = 0;
	long ret = read(non_delayed_fd_, &value, sizeof(value));
	DPCHECK(ret >= 0);
	DCHECK_GT(value, 0U);
	bool do_idle_work = value == kTryNativeWorkBeforeIdleBit;
	DoNonDelayedLooperWork(do_idle_work);
	}

	void MessagePumpForUI::DoNonDelayedLooperWork(bool do_idle_work) {
	// Note: We can't skip DoWork() even if \|do_idle_work\| is true here (i.e. no
	// additional ScheduleWork() since yielding to native) as delayed tasks might
	// have come in and we need to re-sample \|next_work_info\|.

	// Runs all application tasks scheduled to run.
	Delegate::NextWorkInfo next_work_info;
	do {
	if (ShouldQuit())
	return;

	next_work_info = delegate_->DoWork();
	// If we are prioritizing native, and the next work would normally run
	// immediately, skip the next work and let the native work items have a
	// chance to run. This is useful when user input is waiting for native to
	// have a chance to run.
	if (next_work_info.is_immediate() && next_work_info.yield_to_native) {
	ScheduleWork();
	return;
	}
	} while (next_work_info.is_immediate());

	// Do not resignal \|non_delayed_fd_\| if we're quitting (this pump doesn't
	// allow nesting so needing to resume in an outer loop is not an issue
	// either).
	if (ShouldQuit())
	return;

	// Before declaring this loop idle, yield to native work items and arrange to
	// be called again (unless we're already in that second call).
	if (!do_idle_work) {
	ScheduleWorkInternal(/do_idle_work=/true);
	return;
	}

	// We yielded to native work items already and they didn't generate a
	// ScheduleWork() request so we can declare idleness. It's possible for a
	// ScheduleWork() request to come in racily while this method unwinds, this is
	// fine and will merely result in it being re-invoked shortly after it
	// returns.
	// TODO(scheduler-dev): this doesn't account for tasks that don't ever call
	// SchedulerWork() but still keep the system non-idle (e.g., the Java Handler
	// API). It would be better to add an API to query the presence of native
	// tasks instead of relying on yielding once + kTryNativeWorkBeforeIdleBit.
	DCHECK(do_idle_work);

	if (ShouldQuit())
	return;

	// At this point, the java looper might not be idle - it's impossible to know
	// pre-Android-M, so we may end up doing Idle work while java tasks are still
	// queued up. Note that this won't cause us to fail to run java tasks using
	// QuitWhenIdle, as the JavaHandlerThread will finish running all currently
	// scheduled tasks before it quits. Also note that we can't just add an idle
	// callback to the java looper, as that will fire even if application tasks
	// are still queued up.
	DoIdleWork();
	if (!next_work_info.delayed_run_time.is_max()) {
	ScheduleDelayedWork(next_work_info);
	}
	}

	void MessagePumpForUI::DoIdleWork() {
	if (delegate_->DoIdleWork()) {
	// If DoIdleWork() resulted in any work, we're not idle yet. We need to pump
	// the loop here because we may in fact be idle after doing idle work
	// without any new tasks being queued.
	ScheduleWork();
	}
	}

	void MessagePumpForUI::Run(Delegate* delegate) {
	CHECK(false) << "Unexpected call to Run()";
	}

	void MessagePumpForUI::Attach(Delegate* delegate) {
	DCHECK(!quit_);

	// Since the Looper is controlled by the UI thread or JavaHandlerThread, we
	// can't use Run() like we do on other platforms or we would prevent Java
	// tasks from running. Instead we create and initialize a run loop here, then
	// return control back to the Looper.

	SetDelegate(delegate);
	run_loop_ = std::make_unique<RunLoop>();
	// Since the RunLoop was just created above, BeforeRun should be guaranteed to
	// return true (it only returns false if the RunLoop has been Quit already).
	if (!run_loop_->BeforeRun())
	NOTREACHED();
	}

	void MessagePumpForUI::Quit() {
	if (quit_)
	return;

	quit_ = true;

	int64_t value;
	// Clear any pending timer.
	read(delayed_fd_, &value, sizeof(value));
	// Clear the eventfd.
	read(non_delayed_fd_, &value, sizeof(value));

	if (run_loop_) {
	run_loop_->AfterRun();
	run_loop_ = nullptr;
	}
	if (on_quit_callback_) {
	std::move(on_quit_callback_).Run();
	}
	}

	void MessagePumpForUI::ScheduleWork() {
	ScheduleWorkInternal(/do_idle_work=/false);
	}

	void MessagePumpForUI::ScheduleWorkInternal(bool do_idle_work) {
	// Write (add) \|value\| to the eventfd. This tells the Looper to wake up and
	// call our callback, allowing us to run tasks. This also allows us to detect,
	// when we clear the fd, whether additional work was scheduled after we
	// finished performing work, but before we cleared the fd, as we'll read back
	// >=2 instead of 1 in that case. See the eventfd man pages
	// (http://man7.org/linux/man-pages/man2/eventfd.2.html) for details on how
	// the read and write APIs for this file descriptor work, specifically without
	// EFD_SEMAPHORE.
	// Note: Calls with \|do_idle_work\| set to true may race with potential calls
	// where the parameter is false. This is fine as write() is adding \|value\|,
	// not overwriting the existing value, and as such racing calls would merely
	// have their values added together. Since idle work is only executed when the
	// value read equals kTryNativeWorkBeforeIdleBit, a race would prevent idle
	// work from being run and trigger another call to this method with
	// \|do_idle_work\| set to true.
	uint64_t value = do_idle_work ? kTryNativeWorkBeforeIdleBit : 1;
	long ret = write(non_delayed_fd_, &value, sizeof(value));
	DPCHECK(ret >= 0);
	}

	void MessagePumpForUI::ScheduleDelayedWork(
	const Delegate::NextWorkInfo& next_work_info) {
	if (ShouldQuit())
	return;

	if (delayed_scheduled_time_ &&
	*delayed_scheduled_time_ == next_work_info.delayed_run_time) {
	return;
	}

	DCHECK(!next_work_info.is_immediate());
	delayed_scheduled_time_ = next_work_info.delayed_run_time;
	int64_t nanos =
	next_work_info.delayed_run_time.since_origin().InNanoseconds();
	struct itimerspec ts;
	ts.it_interval.tv_sec = 0; // Don't repeat.
	ts.it_interval.tv_nsec = 0;
	ts.it_value.tv_sec =
	static_cast<time_t>(nanos / TimeTicks::kNanosecondsPerSecond);
	ts.it_value.tv_nsec = nanos % TimeTicks::kNanosecondsPerSecond;

	long ret = timerfd_settime(delayed_fd_, TFD_TIMER_ABSTIME, &ts, nullptr);
	DPCHECK(ret >= 0);
	}

	void MessagePumpForUI::QuitWhenIdle(base::OnceClosure callback) {
	DCHECK(!on_quit_callback_);
	DCHECK(run_loop_);
	on_quit_callback_ = std::move(callback);
	run_loop_->QuitWhenIdle();
	// Pump the loop in case we're already idle.
	ScheduleWork();
	}

	MessagePump::Delegate* MessagePumpForUI::SetDelegate(Delegate* delegate) {
	return std::exchange(delegate_, delegate);
	}

	bool MessagePumpForUI::SetQuit(bool quit) {
	return std::exchange(quit_, quit);
	}

	} // namespace base