mojo/system/raw_channel.cc - platform/external/chromium_org - Git at Google

 // Copyright 2014 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 "mojo/system/raw_channel.h"

 #include <string.h>

 #include <algorithm>

 #include "base/bind.h"
 #include "base/location.h"
 #include "base/logging.h"
 #include "base/message_loop/message_loop.h"
 #include "base/stl_util.h"
 #include "mojo/system/message_in_transit.h"

 namespace mojo {
 namespace system {

 const size_t kReadSize = 4096;

 RawChannel::ReadBuffer::ReadBuffer() : buffer_(kReadSize), num_valid_bytes_(0) {
 }

 RawChannel::ReadBuffer::~ReadBuffer() {}

 void RawChannel::ReadBuffer::GetBuffer(char** addr, size_t* size) {
   DCHECK_GE(buffer_.size(), num_valid_bytes_ + kReadSize);
   *addr = &buffer_[0] + num_valid_bytes_;
   *size = kReadSize;
 }

 RawChannel::WriteBuffer::WriteBuffer() : offset_(0) {}

 RawChannel::WriteBuffer::~WriteBuffer() {
   STLDeleteElements(&message_queue_);
 }

 void RawChannel::WriteBuffer::GetBuffers(std::vector<Buffer>* buffers) const {
   buffers->clear();

   size_t bytes_to_write = GetTotalBytesToWrite();
   if (bytes_to_write == 0)
     return;

   MessageInTransit* message = message_queue_.front();
   if (!message->secondary_buffer_size()) {
     // Only write from the main buffer.
     DCHECK_LT(offset_, message->main_buffer_size());
     DCHECK_LE(bytes_to_write, message->main_buffer_size());
     Buffer buffer = {
         static_cast<const char*>(message->main_buffer()) + offset_,
         bytes_to_write};
     buffers->push_back(buffer);
     return;
   }

   if (offset_ >= message->main_buffer_size()) {
     // Only write from the secondary buffer.
     DCHECK_LT(offset_ - message->main_buffer_size(),
               message->secondary_buffer_size());
     DCHECK_LE(bytes_to_write, message->secondary_buffer_size());
     Buffer buffer = {
         static_cast<const char*>(message->secondary_buffer()) +
             (offset_ - message->main_buffer_size()),
         bytes_to_write};
     buffers->push_back(buffer);
     return;
   }

   // Write from both buffers.
   DCHECK_EQ(bytes_to_write, message->main_buffer_size() - offset_ +
                                 message->secondary_buffer_size());
   Buffer buffer1 = {
       static_cast<const char*>(message->main_buffer()) + offset_,
       message->main_buffer_size() - offset_};
   buffers->push_back(buffer1);
   Buffer buffer2 = {
       static_cast<const char*>(message->secondary_buffer()),
       message->secondary_buffer_size()};
   buffers->push_back(buffer2);
 }

 size_t RawChannel::WriteBuffer::GetTotalBytesToWrite() const {
   if (message_queue_.empty())
     return 0;

   MessageInTransit* message = message_queue_.front();
   DCHECK_LT(offset_, message->total_size());
   return message->total_size() - offset_;
 }

 RawChannel::RawChannel()
     : message_loop_for_io_(NULL),
       delegate_(NULL),
       read_stopped_(false),
       write_stopped_(false),
       weak_ptr_factory_(this) {
 }

 RawChannel::~RawChannel() {
   DCHECK(!read_buffer_);
   DCHECK(!write_buffer_);

   // No need to take the |write_lock_| here -- if there are still weak pointers
   // outstanding, then we're hosed anyway (since we wouldn't be able to
   // invalidate them cleanly, since we might not be on the I/O thread).
   DCHECK(!weak_ptr_factory_.HasWeakPtrs());
 }

 bool RawChannel::Init(Delegate* delegate) {
   DCHECK(delegate);

   DCHECK(!delegate_);
   delegate_ = delegate;

   CHECK_EQ(base::MessageLoop::current()->type(), base::MessageLoop::TYPE_IO);
   DCHECK(!message_loop_for_io_);
   message_loop_for_io_ =
       static_cast<base::MessageLoopForIO*>(base::MessageLoop::current());

   // No need to take the lock. No one should be using us yet.
   DCHECK(!read_buffer_);
   read_buffer_.reset(new ReadBuffer);
   DCHECK(!write_buffer_);
   write_buffer_.reset(new WriteBuffer);

   if (!OnInit()) {
     delegate_ = NULL;
     message_loop_for_io_ = NULL;
     read_buffer_.reset();
     write_buffer_.reset();
     return false;
   }

   return ScheduleRead() == IO_PENDING;
 }

 void RawChannel::Shutdown() {
   DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

   base::AutoLock locker(write_lock_);

   LOG_IF(WARNING, !write_buffer_->message_queue_.empty())
       << "Shutting down RawChannel with write buffer nonempty";

   // Reset the delegate so that it won't receive further calls.
   delegate_ = NULL;
   read_stopped_ = true;
   write_stopped_ = true;
   weak_ptr_factory_.InvalidateWeakPtrs();

   OnShutdownNoLock(read_buffer_.Pass(), write_buffer_.Pass());
 }

 // Reminder: This must be thread-safe.
 bool RawChannel::WriteMessage(scoped_ptr<MessageInTransit> message) {
   DCHECK(message);

   // TODO(vtl)
   if (message->has_platform_handles()) {
     NOTIMPLEMENTED();
     return false;
   }

   base::AutoLock locker(write_lock_);
   if (write_stopped_)
     return false;

   if (!write_buffer_->message_queue_.empty()) {
     write_buffer_->message_queue_.push_back(message.release());
     return true;
   }

   write_buffer_->message_queue_.push_front(message.release());
   DCHECK_EQ(write_buffer_->offset_, 0u);

   size_t bytes_written = 0;
   IOResult io_result = WriteNoLock(&bytes_written);
   if (io_result == IO_PENDING)
     return true;

   bool result = OnWriteCompletedNoLock(io_result == IO_SUCCEEDED,
                                        bytes_written);
   if (!result) {
     // Even if we're on the I/O thread, don't call |OnFatalError()| in the
     // nested context.
     message_loop_for_io_->PostTask(
         FROM_HERE,
         base::Bind(&RawChannel::CallOnFatalError,
                    weak_ptr_factory_.GetWeakPtr(),
                    Delegate::FATAL_ERROR_FAILED_WRITE));
   }

   return result;
 }

 // Reminder: This must be thread-safe.
 bool RawChannel::IsWriteBufferEmpty() {
   base::AutoLock locker(write_lock_);
   return write_buffer_->message_queue_.empty();
 }

 RawChannel::ReadBuffer* RawChannel::read_buffer() {
   DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);
   return read_buffer_.get();
 }

 RawChannel::WriteBuffer* RawChannel::write_buffer_no_lock() {
   write_lock_.AssertAcquired();
   return write_buffer_.get();
 }

 void RawChannel::OnReadCompleted(bool result, size_t bytes_read) {
   DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

   if (read_stopped_) {
     NOTREACHED();
     return;
   }

   IOResult io_result = result ? IO_SUCCEEDED : IO_FAILED;

   // Keep reading data in a loop, and dispatch messages if enough data is
   // received. Exit the loop if any of the following happens:
   //   - one or more messages were dispatched;
   //   - the last read failed, was a partial read or would block;
   //   - |Shutdown()| was called.
   do {
     if (io_result != IO_SUCCEEDED) {
       read_stopped_ = true;
       CallOnFatalError(Delegate::FATAL_ERROR_FAILED_READ);
       return;
     }

     read_buffer_->num_valid_bytes_ += bytes_read;

     // Dispatch all the messages that we can.
     bool did_dispatch_message = false;
     // Tracks the offset of the first undispatched message in |read_buffer_|.
     // Currently, we copy data to ensure that this is zero at the beginning.
     size_t read_buffer_start = 0;
     size_t remaining_bytes = read_buffer_->num_valid_bytes_;
     size_t message_size;
     // Note that we rely on short-circuit evaluation here:
     //   - |read_buffer_start| may be an invalid index into
     //     |read_buffer_->buffer_| if |remaining_bytes| is zero.
     //   - |message_size| is only valid if |GetNextMessageSize()| returns true.
     // TODO(vtl): Use |message_size| more intelligently (e.g., to request the
     // next read).
     // TODO(vtl): Validate that |message_size| is sane.
     while (remaining_bytes > 0 &&
            MessageInTransit::GetNextMessageSize(
                &read_buffer_->buffer_[read_buffer_start], remaining_bytes,
                &message_size) &&
            remaining_bytes >= message_size) {
       MessageInTransit::View
           message_view(message_size, &read_buffer_->buffer_[read_buffer_start]);
       DCHECK_EQ(message_view.total_size(), message_size);

       // Dispatch the message.
       DCHECK(delegate_);
       delegate_->OnReadMessage(message_view);
       if (read_stopped_) {
         // |Shutdown()| was called in |OnReadMessage()|.
         // TODO(vtl): Add test for this case.
         return;
       }
       did_dispatch_message = true;

       // Update our state.
       read_buffer_start += message_size;
       remaining_bytes -= message_size;
     }

     if (read_buffer_start > 0) {
       // Move data back to start.
       read_buffer_->num_valid_bytes_ = remaining_bytes;
       if (read_buffer_->num_valid_bytes_ > 0) {
         memmove(&read_buffer_->buffer_[0],
                 &read_buffer_->buffer_[read_buffer_start], remaining_bytes);
       }
       read_buffer_start = 0;
     }

     if (read_buffer_->buffer_.size() - read_buffer_->num_valid_bytes_ <
             kReadSize) {
       // Use power-of-2 buffer sizes.
       // TODO(vtl): Make sure the buffer doesn't get too large (and enforce the
       // maximum message size to whatever extent necessary).
       // TODO(vtl): We may often be able to peek at the header and get the real
       // required extra space (which may be much bigger than |kReadSize|).
       size_t new_size = std::max(read_buffer_->buffer_.size(), kReadSize);
       while (new_size < read_buffer_->num_valid_bytes_ + kReadSize)
         new_size *= 2;

       // TODO(vtl): It's suboptimal to zero out the fresh memory.
       read_buffer_->buffer_.resize(new_size, 0);
     }

     // (1) If we dispatched any messages, stop reading for now (and let the
     // message loop do its thing for another round).
     // TODO(vtl): Is this the behavior we want? (Alternatives: i. Dispatch only
     // a single message. Risks: slower, more complex if we want to avoid lots of
     // copying. ii. Keep reading until there's no more data and dispatch all the
     // messages we can. Risks: starvation of other users of the message loop.)
     // (2) If we didn't max out |kReadSize|, stop reading for now.
     bool schedule_for_later = did_dispatch_message || bytes_read < kReadSize;
     bytes_read = 0;
     io_result = schedule_for_later ? ScheduleRead() : Read(&bytes_read);
   } while (io_result != IO_PENDING);
 }

 void RawChannel::OnWriteCompleted(bool result, size_t bytes_written) {
   DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

   bool did_fail = false;
   {
     base::AutoLock locker(write_lock_);
     DCHECK_EQ(write_stopped_, write_buffer_->message_queue_.empty());

     if (write_stopped_) {
       NOTREACHED();
       return;
     }

     did_fail = !OnWriteCompletedNoLock(result, bytes_written);
   }

   if (did_fail)
     CallOnFatalError(Delegate::FATAL_ERROR_FAILED_WRITE);
 }

 void RawChannel::CallOnFatalError(Delegate::FatalError fatal_error) {
   DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);
   // TODO(vtl): Add a "write_lock_.AssertNotAcquired()"?
   if (delegate_)
     delegate_->OnFatalError(fatal_error);
 }

 bool RawChannel::OnWriteCompletedNoLock(bool result, size_t bytes_written) {
   write_lock_.AssertAcquired();

   DCHECK(!write_stopped_);
   DCHECK(!write_buffer_->message_queue_.empty());

   if (result) {
     if (bytes_written < write_buffer_->GetTotalBytesToWrite()) {
       // Partial (or no) write.
       write_buffer_->offset_ += bytes_written;
     } else {
       // Complete write.
       DCHECK_EQ(bytes_written, write_buffer_->GetTotalBytesToWrite());
       delete write_buffer_->message_queue_.front();
       write_buffer_->message_queue_.pop_front();
       write_buffer_->offset_ = 0;
     }

     if (write_buffer_->message_queue_.empty())
       return true;

     // Schedule the next write.
     if (ScheduleWriteNoLock() == IO_PENDING)
       return true;
   }

   write_stopped_ = true;
   STLDeleteElements(&write_buffer_->message_queue_);
   write_buffer_->offset_ = 0;
   return false;
 }

 }  // namespace system
 }  // namespace mojo
	// Copyright 2014 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 "mojo/system/raw_channel.h"

	#include <string.h>

	#include <algorithm>

	#include "base/bind.h"
	#include "base/location.h"
	#include "base/logging.h"
	#include "base/message_loop/message_loop.h"
	#include "base/stl_util.h"
	#include "mojo/system/message_in_transit.h"

	namespace mojo {
	namespace system {

	const size_t kReadSize = 4096;

	RawChannel::ReadBuffer::ReadBuffer() : buffer_(kReadSize), num_valid_bytes_(0) {
	}

	RawChannel::ReadBuffer::~ReadBuffer() {}

	void RawChannel::ReadBuffer::GetBuffer(char** addr, size_t* size) {
	DCHECK_GE(buffer_.size(), num_valid_bytes_ + kReadSize);
	*addr = &buffer_[0] + num_valid_bytes_;
	*size = kReadSize;
	}

	RawChannel::WriteBuffer::WriteBuffer() : offset_(0) {}

	RawChannel::WriteBuffer::~WriteBuffer() {
	STLDeleteElements(&message_queue_);
	}

	void RawChannel::WriteBuffer::GetBuffers(std::vector<Buffer>* buffers) const {
	buffers->clear();

	size_t bytes_to_write = GetTotalBytesToWrite();
	if (bytes_to_write == 0)
	return;

	MessageInTransit* message = message_queue_.front();
	if (!message->secondary_buffer_size()) {
	// Only write from the main buffer.
	DCHECK_LT(offset_, message->main_buffer_size());
	DCHECK_LE(bytes_to_write, message->main_buffer_size());
	Buffer buffer = {
	static_cast<const char*>(message->main_buffer()) + offset_,
	bytes_to_write};
	buffers->push_back(buffer);
	return;
	}

	if (offset_ >= message->main_buffer_size()) {
	// Only write from the secondary buffer.
	DCHECK_LT(offset_ - message->main_buffer_size(),
	message->secondary_buffer_size());
	DCHECK_LE(bytes_to_write, message->secondary_buffer_size());
	Buffer buffer = {
	static_cast<const char*>(message->secondary_buffer()) +
	(offset_ - message->main_buffer_size()),
	bytes_to_write};
	buffers->push_back(buffer);
	return;
	}

	// Write from both buffers.
	DCHECK_EQ(bytes_to_write, message->main_buffer_size() - offset_ +
	message->secondary_buffer_size());
	Buffer buffer1 = {
	static_cast<const char*>(message->main_buffer()) + offset_,
	message->main_buffer_size() - offset_};
	buffers->push_back(buffer1);
	Buffer buffer2 = {
	static_cast<const char*>(message->secondary_buffer()),
	message->secondary_buffer_size()};
	buffers->push_back(buffer2);
	}

	size_t RawChannel::WriteBuffer::GetTotalBytesToWrite() const {
	if (message_queue_.empty())
	return 0;

	MessageInTransit* message = message_queue_.front();
	DCHECK_LT(offset_, message->total_size());
	return message->total_size() - offset_;
	}

	RawChannel::RawChannel()
	: message_loop_for_io_(NULL),
	delegate_(NULL),
	read_stopped_(false),
	write_stopped_(false),
	weak_ptr_factory_(this) {
	}

	RawChannel::~RawChannel() {
	DCHECK(!read_buffer_);
	DCHECK(!write_buffer_);

	// No need to take the \|write_lock_\| here -- if there are still weak pointers
	// outstanding, then we're hosed anyway (since we wouldn't be able to
	// invalidate them cleanly, since we might not be on the I/O thread).
	DCHECK(!weak_ptr_factory_.HasWeakPtrs());
	}

	bool RawChannel::Init(Delegate* delegate) {
	DCHECK(delegate);

	DCHECK(!delegate_);
	delegate_ = delegate;

	CHECK_EQ(base::MessageLoop::current()->type(), base::MessageLoop::TYPE_IO);
	DCHECK(!message_loop_for_io_);
	message_loop_for_io_ =
	static_cast<base::MessageLoopForIO*>(base::MessageLoop::current());

	// No need to take the lock. No one should be using us yet.
	DCHECK(!read_buffer_);
	read_buffer_.reset(new ReadBuffer);
	DCHECK(!write_buffer_);
	write_buffer_.reset(new WriteBuffer);

	if (!OnInit()) {
	delegate_ = NULL;
	message_loop_for_io_ = NULL;
	read_buffer_.reset();
	write_buffer_.reset();
	return false;
	}

	return ScheduleRead() == IO_PENDING;
	}

	void RawChannel::Shutdown() {
	DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

	base::AutoLock locker(write_lock_);

	LOG_IF(WARNING, !write_buffer_->message_queue_.empty())
	<< "Shutting down RawChannel with write buffer nonempty";

	// Reset the delegate so that it won't receive further calls.
	delegate_ = NULL;
	read_stopped_ = true;
	write_stopped_ = true;
	weak_ptr_factory_.InvalidateWeakPtrs();

	OnShutdownNoLock(read_buffer_.Pass(), write_buffer_.Pass());
	}

	// Reminder: This must be thread-safe.
	bool RawChannel::WriteMessage(scoped_ptr<MessageInTransit> message) {
	DCHECK(message);

	// TODO(vtl)
	if (message->has_platform_handles()) {
	NOTIMPLEMENTED();
	return false;
	}

	base::AutoLock locker(write_lock_);
	if (write_stopped_)
	return false;

	if (!write_buffer_->message_queue_.empty()) {
	write_buffer_->message_queue_.push_back(message.release());
	return true;
	}

	write_buffer_->message_queue_.push_front(message.release());
	DCHECK_EQ(write_buffer_->offset_, 0u);

	size_t bytes_written = 0;
	IOResult io_result = WriteNoLock(&bytes_written);
	if (io_result == IO_PENDING)
	return true;

	bool result = OnWriteCompletedNoLock(io_result == IO_SUCCEEDED,
	bytes_written);
	if (!result) {
	// Even if we're on the I/O thread, don't call \|OnFatalError()\| in the
	// nested context.
	message_loop_for_io_->PostTask(
	FROM_HERE,
	base::Bind(&RawChannel::CallOnFatalError,
	weak_ptr_factory_.GetWeakPtr(),
	Delegate::FATAL_ERROR_FAILED_WRITE));
	}

	return result;
	}

	// Reminder: This must be thread-safe.
	bool RawChannel::IsWriteBufferEmpty() {
	base::AutoLock locker(write_lock_);
	return write_buffer_->message_queue_.empty();
	}

	RawChannel::ReadBuffer* RawChannel::read_buffer() {
	DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);
	return read_buffer_.get();
	}

	RawChannel::WriteBuffer* RawChannel::write_buffer_no_lock() {
	write_lock_.AssertAcquired();
	return write_buffer_.get();
	}

	void RawChannel::OnReadCompleted(bool result, size_t bytes_read) {
	DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

	if (read_stopped_) {
	NOTREACHED();
	return;
	}

	IOResult io_result = result ? IO_SUCCEEDED : IO_FAILED;

	// Keep reading data in a loop, and dispatch messages if enough data is
	// received. Exit the loop if any of the following happens:
	// - one or more messages were dispatched;
	// - the last read failed, was a partial read or would block;
	// - \|Shutdown()\| was called.
	do {
	if (io_result != IO_SUCCEEDED) {
	read_stopped_ = true;
	CallOnFatalError(Delegate::FATAL_ERROR_FAILED_READ);
	return;
	}

	read_buffer_->num_valid_bytes_ += bytes_read;

	// Dispatch all the messages that we can.
	bool did_dispatch_message = false;
	// Tracks the offset of the first undispatched message in \|read_buffer_\|.
	// Currently, we copy data to ensure that this is zero at the beginning.
	size_t read_buffer_start = 0;
	size_t remaining_bytes = read_buffer_->num_valid_bytes_;
	size_t message_size;
	// Note that we rely on short-circuit evaluation here:
	// - \|read_buffer_start\| may be an invalid index into
	// \|read_buffer_->buffer_\| if \|remaining_bytes\| is zero.
	// - \|message_size\| is only valid if \|GetNextMessageSize()\| returns true.
	// TODO(vtl): Use \|message_size\| more intelligently (e.g., to request the
	// next read).
	// TODO(vtl): Validate that \|message_size\| is sane.
	while (remaining_bytes > 0 &&
	MessageInTransit::GetNextMessageSize(
	&read_buffer_->buffer_[read_buffer_start], remaining_bytes,
	&message_size) &&
	remaining_bytes >= message_size) {
	MessageInTransit::View
	message_view(message_size, &read_buffer_->buffer_[read_buffer_start]);
	DCHECK_EQ(message_view.total_size(), message_size);

	// Dispatch the message.
	DCHECK(delegate_);
	delegate_->OnReadMessage(message_view);
	if (read_stopped_) {
	// \|Shutdown()\| was called in \|OnReadMessage()\|.
	// TODO(vtl): Add test for this case.
	return;
	}
	did_dispatch_message = true;

	// Update our state.
	read_buffer_start += message_size;
	remaining_bytes -= message_size;
	}

	if (read_buffer_start > 0) {
	// Move data back to start.
	read_buffer_->num_valid_bytes_ = remaining_bytes;
	if (read_buffer_->num_valid_bytes_ > 0) {
	memmove(&read_buffer_->buffer_[0],
	&read_buffer_->buffer_[read_buffer_start], remaining_bytes);
	}
	read_buffer_start = 0;
	}

	if (read_buffer_->buffer_.size() - read_buffer_->num_valid_bytes_ <
	kReadSize) {
	// Use power-of-2 buffer sizes.
	// TODO(vtl): Make sure the buffer doesn't get too large (and enforce the
	// maximum message size to whatever extent necessary).
	// TODO(vtl): We may often be able to peek at the header and get the real
	// required extra space (which may be much bigger than \|kReadSize\|).
	size_t new_size = std::max(read_buffer_->buffer_.size(), kReadSize);
	while (new_size < read_buffer_->num_valid_bytes_ + kReadSize)
	new_size *= 2;

	// TODO(vtl): It's suboptimal to zero out the fresh memory.
	read_buffer_->buffer_.resize(new_size, 0);
	}

	// (1) If we dispatched any messages, stop reading for now (and let the
	// message loop do its thing for another round).
	// TODO(vtl): Is this the behavior we want? (Alternatives: i. Dispatch only
	// a single message. Risks: slower, more complex if we want to avoid lots of
	// copying. ii. Keep reading until there's no more data and dispatch all the
	// messages we can. Risks: starvation of other users of the message loop.)
	// (2) If we didn't max out \|kReadSize\|, stop reading for now.
	bool schedule_for_later = did_dispatch_message \|\| bytes_read < kReadSize;
	bytes_read = 0;
	io_result = schedule_for_later ? ScheduleRead() : Read(&bytes_read);
	} while (io_result != IO_PENDING);
	}

	void RawChannel::OnWriteCompleted(bool result, size_t bytes_written) {
	DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);

	bool did_fail = false;
	{
	base::AutoLock locker(write_lock_);
	DCHECK_EQ(write_stopped_, write_buffer_->message_queue_.empty());

	if (write_stopped_) {
	NOTREACHED();
	return;
	}

	did_fail = !OnWriteCompletedNoLock(result, bytes_written);
	}

	if (did_fail)
	CallOnFatalError(Delegate::FATAL_ERROR_FAILED_WRITE);
	}

	void RawChannel::CallOnFatalError(Delegate::FatalError fatal_error) {
	DCHECK_EQ(base::MessageLoop::current(), message_loop_for_io_);
	// TODO(vtl): Add a "write_lock_.AssertNotAcquired()"?
	if (delegate_)
	delegate_->OnFatalError(fatal_error);
	}

	bool RawChannel::OnWriteCompletedNoLock(bool result, size_t bytes_written) {
	write_lock_.AssertAcquired();

	DCHECK(!write_stopped_);
	DCHECK(!write_buffer_->message_queue_.empty());

	if (result) {
	if (bytes_written < write_buffer_->GetTotalBytesToWrite()) {
	// Partial (or no) write.
	write_buffer_->offset_ += bytes_written;
	} else {
	// Complete write.
	DCHECK_EQ(bytes_written, write_buffer_->GetTotalBytesToWrite());
	delete write_buffer_->message_queue_.front();
	write_buffer_->message_queue_.pop_front();
	write_buffer_->offset_ = 0;
	}

	if (write_buffer_->message_queue_.empty())
	return true;

	// Schedule the next write.
	if (ScheduleWriteNoLock() == IO_PENDING)
	return true;
	}

	write_stopped_ = true;
	STLDeleteElements(&write_buffer_->message_queue_);
	write_buffer_->offset_ = 0;
	return false;
	}

	} // namespace system
	} // namespace mojo