libbrillo/brillo/message_loops/base_message_loop.cc - nest-cam/4320010/libbrillo - Git at Google

 // Copyright 2015 The Chromium OS 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 <brillo/message_loops/base_message_loop.h>

 #include <fcntl.h>
 #include <sys/stat.h>
 #include <sys/types.h>
 #include <unistd.h>

 #ifndef __ANDROID_HOST__
 // Used for MISC_MAJOR. Only required for the target and not always available
 // for the host.
 #include <linux/major.h>
 #endif

 #include <vector>

 #include <base/bind.h>
 #include <base/files/file_path.h>
 #include <base/files/file_util.h>
 #include <base/run_loop.h>
 #include <base/strings/string_number_conversions.h>
 #include <base/strings/string_split.h>

 #include <brillo/location_logging.h>
 #include <brillo/strings/string_utils.h>

 using base::Closure;

 namespace {

 const char kMiscMinorPath[] = "/proc/misc";
 const char kBinderDriverName[] = "binder";

 }  // namespace

 namespace brillo {

 const int BaseMessageLoop::kInvalidMinor = -1;
 const int BaseMessageLoop::kUninitializedMinor = -2;

 BaseMessageLoop::BaseMessageLoop() {
   CHECK(!base::MessageLoop::current())
       << "You can't create a base::MessageLoopForIO when another "
          "base::MessageLoop is already created for this thread.";
   owned_base_loop_.reset(new base::MessageLoopForIO);
   base_loop_ = owned_base_loop_.get();
 }

 BaseMessageLoop::BaseMessageLoop(base::MessageLoopForIO* base_loop)
     : base_loop_(base_loop) {}

 BaseMessageLoop::~BaseMessageLoop() {
   for (auto& io_task : io_tasks_) {
     DVLOG_LOC(io_task.second.location(), 1)
         << "Removing file descriptor watcher task_id " << io_task.first
         << " leaked on BaseMessageLoop, scheduled from this location.";
     io_task.second.StopWatching();
   }

   // Note all pending canceled delayed tasks when destroying the message loop.
   size_t lazily_deleted_tasks = 0;
   for (const auto& delayed_task : delayed_tasks_) {
     if (delayed_task.second.closure.is_null()) {
       lazily_deleted_tasks++;
     } else {
       DVLOG_LOC(delayed_task.second.location, 1)
           << "Removing delayed task_id " << delayed_task.first
           << " leaked on BaseMessageLoop, scheduled from this location.";
     }
   }
   if (lazily_deleted_tasks) {
     LOG(INFO) << "Leaking " << lazily_deleted_tasks << " canceled tasks.";
   }
 }

 MessageLoop::TaskId BaseMessageLoop::PostDelayedTask(
     const tracked_objects::Location& from_here,
     const Closure &task,
     base::TimeDelta delay) {
   TaskId task_id =  NextTaskId();
   bool base_scheduled = base_loop_->task_runner()->PostDelayedTask(
       from_here,
       base::Bind(&BaseMessageLoop::OnRanPostedTask,
                  weak_ptr_factory_.GetWeakPtr(),
                  task_id),
       delay);
   DVLOG_LOC(from_here, 1) << "Scheduling delayed task_id " << task_id
                           << " to run in " << delay << ".";
   if (!base_scheduled)
     return MessageLoop::kTaskIdNull;

   delayed_tasks_.emplace(task_id,
                          DelayedTask{from_here, task_id, std::move(task)});
   return task_id;
 }

 MessageLoop::TaskId BaseMessageLoop::WatchFileDescriptor(
     const tracked_objects::Location& from_here,
     int fd,
     WatchMode mode,
     bool persistent,
     const Closure &task) {
   // base::MessageLoopForIO CHECKS that "fd >= 0", so we handle that case here.
   if (fd < 0)
     return MessageLoop::kTaskIdNull;

   base::MessageLoopForIO::Mode base_mode = base::MessageLoopForIO::WATCH_READ;
   switch (mode) {
     case MessageLoop::kWatchRead:
       base_mode = base::MessageLoopForIO::WATCH_READ;
       break;
     case MessageLoop::kWatchWrite:
       base_mode = base::MessageLoopForIO::WATCH_WRITE;
       break;
     default:
       return MessageLoop::kTaskIdNull;
   }

   TaskId task_id =  NextTaskId();
   auto it_bool = io_tasks_.emplace(
       std::piecewise_construct,
       std::forward_as_tuple(task_id),
       std::forward_as_tuple(
           from_here, this, task_id, fd, base_mode, persistent, task));
   // This should always insert a new element.
   DCHECK(it_bool.second);
   bool scheduled = it_bool.first->second.StartWatching();
   DVLOG_LOC(from_here, 1)
       << "Watching fd " << fd << " for "
       << (mode == MessageLoop::kWatchRead ? "reading" : "writing")
       << (persistent ? " persistently" : " just once")
       << " as task_id " << task_id
       << (scheduled ? " successfully" : " failed.");

   if (!scheduled) {
     io_tasks_.erase(task_id);
     return MessageLoop::kTaskIdNull;
   }

 #ifndef __ANDROID_HOST__
   // Determine if the passed fd is the binder file descriptor. For that, we need
   // to check that is a special char device and that the major and minor device
   // numbers match. The binder file descriptor can't be removed and added back
   // to an epoll group when there's work available to be done by the file
   // descriptor due to bugs in the binder driver (b/26524111) when used with
   // epoll. Therefore, we flag the binder fd and never attempt to remove it.
   // This may cause the binder file descriptor to be attended with higher
   // priority and cause starvation of other events.
   struct stat buf;
   if (fstat(fd, &buf) == 0 &&
       S_ISCHR(buf.st_mode) &&
       major(buf.st_rdev) == MISC_MAJOR &&
       minor(buf.st_rdev) == GetBinderMinor()) {
     it_bool.first->second.RunImmediately();
   }
 #endif

   return task_id;
 }

 bool BaseMessageLoop::CancelTask(TaskId task_id) {
   if (task_id == kTaskIdNull)
     return false;
   auto delayed_task_it = delayed_tasks_.find(task_id);
   if (delayed_task_it == delayed_tasks_.end()) {
     // This might be an IOTask then.
     auto io_task_it = io_tasks_.find(task_id);
     if (io_task_it == io_tasks_.end())
       return false;
     return io_task_it->second.CancelTask();
   }
   // A DelayedTask was found for this task_id at this point.

   // Check if the callback was already canceled but we have the entry in
   // delayed_tasks_ since it didn't fire yet in the message loop.
   if (delayed_task_it->second.closure.is_null())
     return false;

   DVLOG_LOC(delayed_task_it->second.location, 1)
       << "Removing task_id " << task_id << " scheduled from this location.";
   // We reset to closure to a null Closure to release all the resources
   // used by this closure at this point, but we don't remove the task_id from
   // delayed_tasks_ since we can't tell base::MessageLoopForIO to not run it.
   delayed_task_it->second.closure = Closure();

   return true;
 }

 bool BaseMessageLoop::RunOnce(bool may_block) {
   run_once_ = true;
   base::RunLoop run_loop;  // Uses the base::MessageLoopForIO implicitly.
   base_run_loop_ = &run_loop;
   if (!may_block)
     run_loop.RunUntilIdle();
   else
     run_loop.Run();
   base_run_loop_ = nullptr;
   // If the flag was reset to false, it means a closure was run.
   if (!run_once_)
     return true;

   run_once_ = false;
   return false;
 }

 void BaseMessageLoop::Run() {
   base::RunLoop run_loop;  // Uses the base::MessageLoopForIO implicitly.
   base_run_loop_ = &run_loop;
   run_loop.Run();
   base_run_loop_ = nullptr;
 }

 void BaseMessageLoop::BreakLoop() {
   if (base_run_loop_ == nullptr) {
     DVLOG(1) << "Message loop not running, ignoring BreakLoop().";
     return;  // Message loop not running, nothing to do.
   }
   base_run_loop_->Quit();
 }

 Closure BaseMessageLoop::QuitClosure() const {
   if (base_run_loop_ == nullptr)
     return base::Bind(&base::DoNothing);
   return base_run_loop_->QuitClosure();
 }

 MessageLoop::TaskId BaseMessageLoop::NextTaskId() {
   TaskId res;
   do {
     res = ++last_id_;
     // We would run out of memory before we run out of task ids.
   } while (!res ||
            delayed_tasks_.find(res) != delayed_tasks_.end() ||
            io_tasks_.find(res) != io_tasks_.end());
   return res;
 }

 void BaseMessageLoop::OnRanPostedTask(MessageLoop::TaskId task_id) {
   auto task_it = delayed_tasks_.find(task_id);
   DCHECK(task_it != delayed_tasks_.end());
   if (!task_it->second.closure.is_null()) {
     DVLOG_LOC(task_it->second.location, 1)
         << "Running delayed task_id " << task_id
         << " scheduled from this location.";
     // Mark the task as canceled while we are running it so CancelTask returns
     // false.
     Closure closure = std::move(task_it->second.closure);
     task_it->second.closure = Closure();
     closure.Run();

     // If the |run_once_| flag is set, it is because we are instructed to run
     // only once callback.
     if (run_once_) {
       run_once_ = false;
       BreakLoop();
     }
   }
   delayed_tasks_.erase(task_it);
 }

 void BaseMessageLoop::OnFileReadyPostedTask(MessageLoop::TaskId task_id) {
   auto task_it = io_tasks_.find(task_id);
   // Even if this task was canceled while we were waiting in the message loop
   // for this method to run, the entry in io_tasks_ should still be present, but
   // won't do anything.
   DCHECK(task_it != io_tasks_.end());
   task_it->second.OnFileReadyPostedTask();
 }

 int BaseMessageLoop::ParseBinderMinor(
     const std::string& file_contents) {
   int result = kInvalidMinor;
   // Split along '\n', then along the ' '. Note that base::SplitString trims all
   // white spaces at the beginning and end after splitting.
   std::vector<std::string> lines =
       base::SplitString(file_contents, "\n", base::TRIM_WHITESPACE,
                         base::SPLIT_WANT_ALL);
   for (const std::string& line : lines) {
     if (line.empty())
       continue;
     std::string number;
     std::string name;
     if (!string_utils::SplitAtFirst(line, " ", &number, &name, false))
       continue;

     if (name == kBinderDriverName && base::StringToInt(number, &result))
       break;
   }
   return result;
 }

 unsigned int BaseMessageLoop::GetBinderMinor() {
   if (binder_minor_ != kUninitializedMinor)
     return binder_minor_;

   std::string proc_misc;
   if (!base::ReadFileToString(base::FilePath(kMiscMinorPath), &proc_misc))
     return binder_minor_;
   binder_minor_ = ParseBinderMinor(proc_misc);
   return binder_minor_;
 }

 BaseMessageLoop::IOTask::IOTask(const tracked_objects::Location& location,
                                 BaseMessageLoop* loop,
                                 MessageLoop::TaskId task_id,
                                 int fd,
                                 base::MessageLoopForIO::Mode base_mode,
                                 bool persistent,
                                 const Closure& task)
     : location_(location), loop_(loop), task_id_(task_id),
       fd_(fd), base_mode_(base_mode), persistent_(persistent), closure_(task) {}

 bool BaseMessageLoop::IOTask::StartWatching() {
   return loop_->base_loop_->WatchFileDescriptor(
       fd_, persistent_, base_mode_, &fd_watcher_, this);
 }

 void BaseMessageLoop::IOTask::StopWatching() {
   // This is safe to call even if we are not watching for it.
   fd_watcher_.StopWatchingFileDescriptor();
 }

 void BaseMessageLoop::IOTask::OnFileCanReadWithoutBlocking(int /* fd */) {
   OnFileReady();
 }

 void BaseMessageLoop::IOTask::OnFileCanWriteWithoutBlocking(int /* fd */) {
   OnFileReady();
 }

 void BaseMessageLoop::IOTask::OnFileReady() {
   // For file descriptors marked with the immediate_run flag, we don't call
   // StopWatching() and wait, instead we dispatch the callback immediately.
   if (immediate_run_) {
     posted_task_pending_ = true;
     OnFileReadyPostedTask();
     return;
   }

   // When the file descriptor becomes available we stop watching for it and
   // schedule a task to run the callback from the main loop. The callback will
   // run using the same scheduler used to run other delayed tasks, avoiding
   // starvation of the available posted tasks if there are file descriptors
   // always available. The new posted task will use the same TaskId as the
   // current file descriptor watching task an could be canceled in either state,
   // when waiting for the file descriptor or waiting in the main loop.
   StopWatching();
   bool base_scheduled = loop_->base_loop_->task_runner()->PostTask(
       location_,
       base::Bind(&BaseMessageLoop::OnFileReadyPostedTask,
                  loop_->weak_ptr_factory_.GetWeakPtr(),
                  task_id_));
   posted_task_pending_ = true;
   if (base_scheduled) {
     DVLOG_LOC(location_, 1)
         << "Dispatching task_id " << task_id_ << " for "
         << (base_mode_ == base::MessageLoopForIO::WATCH_READ ?
             "reading" : "writing")
         << " file descriptor " << fd_ << ", scheduled from this location.";
   } else {
     // In the rare case that PostTask() fails, we fall back to run it directly.
     // This would indicate a bigger problem with the message loop setup.
     LOG(ERROR) << "Error on base::MessageLoopForIO::PostTask().";
     OnFileReadyPostedTask();
   }
 }

 void BaseMessageLoop::IOTask::OnFileReadyPostedTask() {
   // We can't access |this| after running the |closure_| since it could call
   // CancelTask on its own task_id, so we copy the members we need now.
   BaseMessageLoop* loop_ptr = loop_;
   DCHECK(posted_task_pending_ = true);
   posted_task_pending_ = false;

   // If this task was already canceled, the closure will be null and there is
   // nothing else to do here. This execution doesn't count a step for RunOnce()
   // unless we have a callback to run.
   if (closure_.is_null()) {
     loop_->io_tasks_.erase(task_id_);
     return;
   }

   DVLOG_LOC(location_, 1)
       << "Running task_id " << task_id_ << " for "
       << (base_mode_ == base::MessageLoopForIO::WATCH_READ ?
           "reading" : "writing")
       << " file descriptor " << fd_ << ", scheduled from this location.";

   if (persistent_) {
     // In the persistent case we just run the callback. If this callback cancels
     // the task id, we can't access |this| anymore, so we re-start watching the
     // file descriptor before running the callback, unless this is a fd where
     // we didn't stop watching the file descriptor when it became available.
     if (!immediate_run_)
       StartWatching();
     closure_.Run();
   } else {
     // This will destroy |this|, the fd_watcher and therefore stop watching this
     // file descriptor.
     Closure closure_copy = std::move(closure_);
     loop_->io_tasks_.erase(task_id_);
     // Run the closure from the local copy we just made.
     closure_copy.Run();
   }

   if (loop_ptr->run_once_) {
     loop_ptr->run_once_ = false;
     loop_ptr->BreakLoop();
   }
 }

 bool BaseMessageLoop::IOTask::CancelTask() {
   if (closure_.is_null())
     return false;

   DVLOG_LOC(location_, 1)
       << "Removing task_id " << task_id_ << " scheduled from this location.";

   if (!posted_task_pending_) {
     // Destroying the FileDescriptorWatcher implicitly stops watching the file
     // descriptor. This will delete our instance.
     loop_->io_tasks_.erase(task_id_);
     return true;
   }
   // The IOTask is waiting for the message loop to run its delayed task, so
   // it is not watching for the file descriptor. We release the closure
   // resources now but keep the IOTask instance alive while we wait for the
   // callback to run and delete the IOTask.
   closure_ = Closure();
   return true;
 }

 }  // namespace brillo
	// Copyright 2015 The Chromium OS 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 <brillo/message_loops/base_message_loop.h>

	#include <fcntl.h>
	#include <sys/stat.h>
	#include <sys/types.h>
	#include <unistd.h>

	#ifndef __ANDROID_HOST__
	// Used for MISC_MAJOR. Only required for the target and not always available
	// for the host.
	#include <linux/major.h>
	#endif

	#include <vector>

	#include <base/bind.h>
	#include <base/files/file_path.h>
	#include <base/files/file_util.h>
	#include <base/run_loop.h>
	#include <base/strings/string_number_conversions.h>
	#include <base/strings/string_split.h>

	#include <brillo/location_logging.h>
	#include <brillo/strings/string_utils.h>

	using base::Closure;

	namespace {

	const char kMiscMinorPath[] = "/proc/misc";
	const char kBinderDriverName[] = "binder";

	} // namespace

	namespace brillo {

	const int BaseMessageLoop::kInvalidMinor = -1;
	const int BaseMessageLoop::kUninitializedMinor = -2;

	BaseMessageLoop::BaseMessageLoop() {
	CHECK(!base::MessageLoop::current())
	<< "You can't create a base::MessageLoopForIO when another "
	"base::MessageLoop is already created for this thread.";
	owned_base_loop_.reset(new base::MessageLoopForIO);
	base_loop_ = owned_base_loop_.get();
	}

	BaseMessageLoop::BaseMessageLoop(base::MessageLoopForIO* base_loop)
	: base_loop_(base_loop) {}

	BaseMessageLoop::~BaseMessageLoop() {
	for (auto& io_task : io_tasks_) {
	DVLOG_LOC(io_task.second.location(), 1)
	<< "Removing file descriptor watcher task_id " << io_task.first
	<< " leaked on BaseMessageLoop, scheduled from this location.";
	io_task.second.StopWatching();
	}

	// Note all pending canceled delayed tasks when destroying the message loop.
	size_t lazily_deleted_tasks = 0;
	for (const auto& delayed_task : delayed_tasks_) {
	if (delayed_task.second.closure.is_null()) {
	lazily_deleted_tasks++;
	} else {
	DVLOG_LOC(delayed_task.second.location, 1)
	<< "Removing delayed task_id " << delayed_task.first
	<< " leaked on BaseMessageLoop, scheduled from this location.";
	}
	}
	if (lazily_deleted_tasks) {
	LOG(INFO) << "Leaking " << lazily_deleted_tasks << " canceled tasks.";
	}
	}

	MessageLoop::TaskId BaseMessageLoop::PostDelayedTask(
	const tracked_objects::Location& from_here,
	const Closure &task,
	base::TimeDelta delay) {
	TaskId task_id = NextTaskId();
	bool base_scheduled = base_loop_->task_runner()->PostDelayedTask(
	from_here,
	base::Bind(&BaseMessageLoop::OnRanPostedTask,
	weak_ptr_factory_.GetWeakPtr(),
	task_id),
	delay);
	DVLOG_LOC(from_here, 1) << "Scheduling delayed task_id " << task_id
	<< " to run in " << delay << ".";
	if (!base_scheduled)
	return MessageLoop::kTaskIdNull;

	delayed_tasks_.emplace(task_id,
	DelayedTask{from_here, task_id, std::move(task)});
	return task_id;
	}

	MessageLoop::TaskId BaseMessageLoop::WatchFileDescriptor(
	const tracked_objects::Location& from_here,
	int fd,
	WatchMode mode,
	bool persistent,
	const Closure &task) {
	// base::MessageLoopForIO CHECKS that "fd >= 0", so we handle that case here.
	if (fd < 0)
	return MessageLoop::kTaskIdNull;

	base::MessageLoopForIO::Mode base_mode = base::MessageLoopForIO::WATCH_READ;
	switch (mode) {
	case MessageLoop::kWatchRead:
	base_mode = base::MessageLoopForIO::WATCH_READ;
	break;
	case MessageLoop::kWatchWrite:
	base_mode = base::MessageLoopForIO::WATCH_WRITE;
	break;
	default:
	return MessageLoop::kTaskIdNull;
	}

	TaskId task_id = NextTaskId();
	auto it_bool = io_tasks_.emplace(
	std::piecewise_construct,
	std::forward_as_tuple(task_id),
	std::forward_as_tuple(
	from_here, this, task_id, fd, base_mode, persistent, task));
	// This should always insert a new element.
	DCHECK(it_bool.second);
	bool scheduled = it_bool.first->second.StartWatching();
	DVLOG_LOC(from_here, 1)
	<< "Watching fd " << fd << " for "
	<< (mode == MessageLoop::kWatchRead ? "reading" : "writing")
	<< (persistent ? " persistently" : " just once")
	<< " as task_id " << task_id
	<< (scheduled ? " successfully" : " failed.");

	if (!scheduled) {
	io_tasks_.erase(task_id);
	return MessageLoop::kTaskIdNull;
	}

	#ifndef __ANDROID_HOST__
	// Determine if the passed fd is the binder file descriptor. For that, we need
	// to check that is a special char device and that the major and minor device
	// numbers match. The binder file descriptor can't be removed and added back
	// to an epoll group when there's work available to be done by the file
	// descriptor due to bugs in the binder driver (b/26524111) when used with
	// epoll. Therefore, we flag the binder fd and never attempt to remove it.
	// This may cause the binder file descriptor to be attended with higher
	// priority and cause starvation of other events.
	struct stat buf;
	if (fstat(fd, &buf) == 0 &&
	S_ISCHR(buf.st_mode) &&
	major(buf.st_rdev) == MISC_MAJOR &&
	minor(buf.st_rdev) == GetBinderMinor()) {
	it_bool.first->second.RunImmediately();
	}
	#endif

	return task_id;
	}

	bool BaseMessageLoop::CancelTask(TaskId task_id) {
	if (task_id == kTaskIdNull)
	return false;
	auto delayed_task_it = delayed_tasks_.find(task_id);
	if (delayed_task_it == delayed_tasks_.end()) {
	// This might be an IOTask then.
	auto io_task_it = io_tasks_.find(task_id);
	if (io_task_it == io_tasks_.end())
	return false;
	return io_task_it->second.CancelTask();
	}
	// A DelayedTask was found for this task_id at this point.

	// Check if the callback was already canceled but we have the entry in
	// delayed_tasks_ since it didn't fire yet in the message loop.
	if (delayed_task_it->second.closure.is_null())
	return false;

	DVLOG_LOC(delayed_task_it->second.location, 1)
	<< "Removing task_id " << task_id << " scheduled from this location.";
	// We reset to closure to a null Closure to release all the resources
	// used by this closure at this point, but we don't remove the task_id from
	// delayed_tasks_ since we can't tell base::MessageLoopForIO to not run it.
	delayed_task_it->second.closure = Closure();

	return true;
	}

	bool BaseMessageLoop::RunOnce(bool may_block) {
	run_once_ = true;
	base::RunLoop run_loop; // Uses the base::MessageLoopForIO implicitly.
	base_run_loop_ = &run_loop;
	if (!may_block)
	run_loop.RunUntilIdle();
	else
	run_loop.Run();
	base_run_loop_ = nullptr;
	// If the flag was reset to false, it means a closure was run.
	if (!run_once_)
	return true;

	run_once_ = false;
	return false;
	}

	void BaseMessageLoop::Run() {
	base::RunLoop run_loop; // Uses the base::MessageLoopForIO implicitly.
	base_run_loop_ = &run_loop;
	run_loop.Run();
	base_run_loop_ = nullptr;
	}

	void BaseMessageLoop::BreakLoop() {
	if (base_run_loop_ == nullptr) {
	DVLOG(1) << "Message loop not running, ignoring BreakLoop().";
	return; // Message loop not running, nothing to do.
	}
	base_run_loop_->Quit();
	}

	Closure BaseMessageLoop::QuitClosure() const {
	if (base_run_loop_ == nullptr)
	return base::Bind(&base::DoNothing);
	return base_run_loop_->QuitClosure();
	}

	MessageLoop::TaskId BaseMessageLoop::NextTaskId() {
	TaskId res;
	do {
	res = ++last_id_;
	// We would run out of memory before we run out of task ids.
	} while (!res \|\|
	delayed_tasks_.find(res) != delayed_tasks_.end() \|\|
	io_tasks_.find(res) != io_tasks_.end());
	return res;
	}

	void BaseMessageLoop::OnRanPostedTask(MessageLoop::TaskId task_id) {
	auto task_it = delayed_tasks_.find(task_id);
	DCHECK(task_it != delayed_tasks_.end());
	if (!task_it->second.closure.is_null()) {
	DVLOG_LOC(task_it->second.location, 1)
	<< "Running delayed task_id " << task_id
	<< " scheduled from this location.";
	// Mark the task as canceled while we are running it so CancelTask returns
	// false.
	Closure closure = std::move(task_it->second.closure);
	task_it->second.closure = Closure();
	closure.Run();

	// If the \|run_once_\| flag is set, it is because we are instructed to run
	// only once callback.
	if (run_once_) {
	run_once_ = false;
	BreakLoop();
	}
	}
	delayed_tasks_.erase(task_it);
	}

	void BaseMessageLoop::OnFileReadyPostedTask(MessageLoop::TaskId task_id) {
	auto task_it = io_tasks_.find(task_id);
	// Even if this task was canceled while we were waiting in the message loop
	// for this method to run, the entry in io_tasks_ should still be present, but
	// won't do anything.
	DCHECK(task_it != io_tasks_.end());
	task_it->second.OnFileReadyPostedTask();
	}

	int BaseMessageLoop::ParseBinderMinor(
	const std::string& file_contents) {
	int result = kInvalidMinor;
	// Split along '\n', then along the ' '. Note that base::SplitString trims all
	// white spaces at the beginning and end after splitting.
	std::vector<std::string> lines =
	base::SplitString(file_contents, "\n", base::TRIM_WHITESPACE,
	base::SPLIT_WANT_ALL);
	for (const std::string& line : lines) {
	if (line.empty())
	continue;
	std::string number;
	std::string name;
	if (!string_utils::SplitAtFirst(line, " ", &number, &name, false))
	continue;

	if (name == kBinderDriverName && base::StringToInt(number, &result))
	break;
	}
	return result;
	}

	unsigned int BaseMessageLoop::GetBinderMinor() {
	if (binder_minor_ != kUninitializedMinor)
	return binder_minor_;

	std::string proc_misc;
	if (!base::ReadFileToString(base::FilePath(kMiscMinorPath), &proc_misc))
	return binder_minor_;
	binder_minor_ = ParseBinderMinor(proc_misc);
	return binder_minor_;
	}

	BaseMessageLoop::IOTask::IOTask(const tracked_objects::Location& location,
	BaseMessageLoop* loop,
	MessageLoop::TaskId task_id,
	int fd,
	base::MessageLoopForIO::Mode base_mode,
	bool persistent,
	const Closure& task)
	: location_(location), loop_(loop), task_id_(task_id),
	fd_(fd), base_mode_(base_mode), persistent_(persistent), closure_(task) {}

	bool BaseMessageLoop::IOTask::StartWatching() {
	return loop_->base_loop_->WatchFileDescriptor(
	fd_, persistent_, base_mode_, &fd_watcher_, this);
	}

	void BaseMessageLoop::IOTask::StopWatching() {
	// This is safe to call even if we are not watching for it.
	fd_watcher_.StopWatchingFileDescriptor();
	}

	void BaseMessageLoop::IOTask::OnFileCanReadWithoutBlocking(int /* fd */) {
	OnFileReady();
	}

	void BaseMessageLoop::IOTask::OnFileCanWriteWithoutBlocking(int /* fd */) {
	OnFileReady();
	}

	void BaseMessageLoop::IOTask::OnFileReady() {
	// For file descriptors marked with the immediate_run flag, we don't call
	// StopWatching() and wait, instead we dispatch the callback immediately.
	if (immediate_run_) {
	posted_task_pending_ = true;
	OnFileReadyPostedTask();
	return;
	}

	// When the file descriptor becomes available we stop watching for it and
	// schedule a task to run the callback from the main loop. The callback will
	// run using the same scheduler used to run other delayed tasks, avoiding
	// starvation of the available posted tasks if there are file descriptors
	// always available. The new posted task will use the same TaskId as the
	// current file descriptor watching task an could be canceled in either state,
	// when waiting for the file descriptor or waiting in the main loop.
	StopWatching();
	bool base_scheduled = loop_->base_loop_->task_runner()->PostTask(
	location_,
	base::Bind(&BaseMessageLoop::OnFileReadyPostedTask,
	loop_->weak_ptr_factory_.GetWeakPtr(),
	task_id_));
	posted_task_pending_ = true;
	if (base_scheduled) {
	DVLOG_LOC(location_, 1)
	<< "Dispatching task_id " << task_id_ << " for "
	<< (base_mode_ == base::MessageLoopForIO::WATCH_READ ?
	"reading" : "writing")
	<< " file descriptor " << fd_ << ", scheduled from this location.";
	} else {
	// In the rare case that PostTask() fails, we fall back to run it directly.
	// This would indicate a bigger problem with the message loop setup.
	LOG(ERROR) << "Error on base::MessageLoopForIO::PostTask().";
	OnFileReadyPostedTask();
	}
	}

	void BaseMessageLoop::IOTask::OnFileReadyPostedTask() {
	// We can't access \|this\| after running the \|closure_\| since it could call
	// CancelTask on its own task_id, so we copy the members we need now.
	BaseMessageLoop* loop_ptr = loop_;
	DCHECK(posted_task_pending_ = true);
	posted_task_pending_ = false;

	// If this task was already canceled, the closure will be null and there is
	// nothing else to do here. This execution doesn't count a step for RunOnce()
	// unless we have a callback to run.
	if (closure_.is_null()) {
	loop_->io_tasks_.erase(task_id_);
	return;
	}

	DVLOG_LOC(location_, 1)
	<< "Running task_id " << task_id_ << " for "
	<< (base_mode_ == base::MessageLoopForIO::WATCH_READ ?
	"reading" : "writing")
	<< " file descriptor " << fd_ << ", scheduled from this location.";

	if (persistent_) {
	// In the persistent case we just run the callback. If this callback cancels
	// the task id, we can't access \|this\| anymore, so we re-start watching the
	// file descriptor before running the callback, unless this is a fd where
	// we didn't stop watching the file descriptor when it became available.
	if (!immediate_run_)
	StartWatching();
	closure_.Run();
	} else {
	// This will destroy \|this\|, the fd_watcher and therefore stop watching this
	// file descriptor.
	Closure closure_copy = std::move(closure_);
	loop_->io_tasks_.erase(task_id_);
	// Run the closure from the local copy we just made.
	closure_copy.Run();
	}

	if (loop_ptr->run_once_) {
	loop_ptr->run_once_ = false;
	loop_ptr->BreakLoop();
	}
	}

	bool BaseMessageLoop::IOTask::CancelTask() {
	if (closure_.is_null())
	return false;

	DVLOG_LOC(location_, 1)
	<< "Removing task_id " << task_id_ << " scheduled from this location.";

	if (!posted_task_pending_) {
	// Destroying the FileDescriptorWatcher implicitly stops watching the file
	// descriptor. This will delete our instance.
	loop_->io_tasks_.erase(task_id_);
	return true;
	}
	// The IOTask is waiting for the message loop to run its delayed task, so
	// it is not watching for the file descriptor. We release the closure
	// resources now but keep the IOTask instance alive while we wait for the
	// callback to run and delete the IOTask.
	closure_ = Closure();
	return true;
	}

	} // namespace brillo