ipc/ipc_channel_reader.cc - chromium/src - Git at Google

 // Copyright (c) 2012 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 "ipc/ipc_channel_reader.h"

 #include <stddef.h>

 #include <algorithm>

 #include "base/logging.h"
 #include "base/threading/thread_task_runner_handle.h"
 #include "ipc/ipc_listener.h"
 #include "ipc/ipc_logging.h"
 #include "ipc/ipc_message.h"
 #include "ipc/ipc_message_attachment_set.h"
 #include "ipc/ipc_message_macros.h"

 namespace IPC {
 namespace internal {

 #if BUILDFLAG(IPC_MESSAGE_LOG_ENABLED)

 namespace {
 std::string GetMessageText(const Message& message) {
   std::string name;
   Logging::GetInstance()->GetMessageText(
       message.type(), &name, &message, nullptr);
   return name;
 }
 }  // namespace

 #define EMIT_TRACE_EVENT(message)                                       \
   TRACE_EVENT_WITH_FLOW1(                                               \
       "ipc,toplevel", "ChannelReader::DispatchInputData",               \
       (message).flags(), TRACE_EVENT_FLAG_FLOW_IN, "name",              \
       GetMessageText(message));
 #else
 #define EMIT_TRACE_EVENT(message)                                              \
   TRACE_EVENT_WITH_FLOW2("ipc,toplevel", "ChannelReader::DispatchInputData",   \
                          (message).flags(), TRACE_EVENT_FLAG_FLOW_IN, "class", \
                          IPC_MESSAGE_ID_CLASS((message).type()), "line",       \
                          IPC_MESSAGE_ID_LINE((message).type()));
 #endif  // BUILDFLAG(IPC_MESSAGE_LOG_ENABLED)

 ChannelReader::ChannelReader(Listener* listener)
   : listener_(listener),
     max_input_buffer_size_(Channel::kMaximumReadBufferSize) {
   memset(input_buf_, 0, sizeof(input_buf_));
 }

 ChannelReader::~ChannelReader() = default;

 ChannelReader::DispatchState ChannelReader::ProcessIncomingMessages() {
   while (true) {
     int bytes_read = 0;
     ReadState read_state = ReadData(input_buf_, Channel::kReadBufferSize,
                                     &bytes_read);
     if (read_state == READ_FAILED)
       return DISPATCH_ERROR;
     if (read_state == READ_PENDING)
       return DISPATCH_FINISHED;

     DCHECK(bytes_read > 0);
     if (!TranslateInputData(input_buf_, bytes_read))
       return DISPATCH_ERROR;
   }
 }

 ChannelReader::DispatchState ChannelReader::AsyncReadComplete(int bytes_read) {
   if (!TranslateInputData(input_buf_, bytes_read))
     return DISPATCH_ERROR;

   return DISPATCH_FINISHED;
 }

 bool ChannelReader::IsInternalMessage(const Message& m) {
   return m.routing_id() == MSG_ROUTING_NONE &&
       m.type() >= Channel::CLOSE_FD_MESSAGE_TYPE &&
       m.type() <= Channel::HELLO_MESSAGE_TYPE;
 }

 bool ChannelReader::IsHelloMessage(const Message& m) {
   return m.routing_id() == MSG_ROUTING_NONE &&
       m.type() == Channel::HELLO_MESSAGE_TYPE;
 }

 void ChannelReader::CleanUp() {
 }

 void ChannelReader::DispatchMessage(Message* m) {
   EMIT_TRACE_EVENT(*m);
   listener_->OnMessageReceived(*m);
   HandleDispatchError(*m);
 }

 bool ChannelReader::TranslateInputData(const char* input_data,
                                        int input_data_len) {
   const char* p;
   const char* end;

   // Possibly combine with the overflow buffer to make a larger buffer.
   if (input_overflow_buf_.empty()) {
     p = input_data;
     end = input_data + input_data_len;
   } else {
     if (!CheckMessageSize(input_overflow_buf_.size() + input_data_len))
       return false;
     input_overflow_buf_.append(input_data, input_data_len);
     p = input_overflow_buf_.data();
     end = p + input_overflow_buf_.size();
   }

   size_t next_message_size = 0;

   // Dispatch all complete messages in the data buffer.
   while (p < end) {
     Message::NextMessageInfo info;
     Message::FindNext(p, end, &info);
     if (info.message_found) {
       int pickle_len = static_cast<int>(info.pickle_end - p);
       Message translated_message(p, pickle_len);

       if (!HandleTranslatedMessage(&translated_message))
         return false;

       p = info.message_end;
     } else {
       // Last message is partial.
       next_message_size = info.message_size;
       if (!CheckMessageSize(next_message_size))
         return false;
       break;
     }
   }

   // Account for the case where last message's byte is in the next data chunk.
   size_t next_message_buffer_size = next_message_size ?
       next_message_size + Channel::kReadBufferSize - 1:
       0;

   // Save any partial data in the overflow buffer.
   if (p != input_overflow_buf_.data())
     input_overflow_buf_.assign(p, end - p);

   if (!input_overflow_buf_.empty()) {
     // We have something in the overflow buffer, which means that we will
     // append the next data chunk (instead of parsing it directly). So we
     // resize the buffer to fit the next message, to avoid repeatedly
     // growing the buffer as we receive all message' data chunks.
     if (next_message_buffer_size > input_overflow_buf_.capacity()) {
       input_overflow_buf_.reserve(next_message_buffer_size);
     }
   }

   // Trim the buffer if we can
   if (next_message_buffer_size < max_input_buffer_size_ &&
       input_overflow_buf_.size() < max_input_buffer_size_ &&
       input_overflow_buf_.capacity() > max_input_buffer_size_) {
     // std::string doesn't really have a method to shrink capacity to
     // a specific value, so we have to swap with another string.
     std::string trimmed_buf;
     trimmed_buf.reserve(max_input_buffer_size_);
     if (trimmed_buf.capacity() > max_input_buffer_size_) {
       // Since we don't control how much space reserve() actually reserves,
       // we have to go other way around and change the max size to avoid
       // getting into the outer if() again.
       max_input_buffer_size_ = trimmed_buf.capacity();
     }
     trimmed_buf.assign(input_overflow_buf_.data(),
                        input_overflow_buf_.size());
     input_overflow_buf_.swap(trimmed_buf);
   }

   if (input_overflow_buf_.empty() && !DidEmptyInputBuffers())
     return false;
   return true;
 }

 bool ChannelReader::HandleTranslatedMessage(Message* translated_message) {
   // Immediately handle internal messages.
   if (IsInternalMessage(*translated_message)) {
     EMIT_TRACE_EVENT(*translated_message);
     HandleInternalMessage(*translated_message);
     HandleDispatchError(*translated_message);
     return true;
   }

   return HandleExternalMessage(translated_message);
 }

 bool ChannelReader::HandleExternalMessage(Message* external_message) {
   if (!GetAttachments(external_message))
     return false;

   DispatchMessage(external_message);
   return true;
 }

 void ChannelReader::HandleDispatchError(const Message& message) {
   if (message.dispatch_error())
     listener_->OnBadMessageReceived(message);
 }

 bool ChannelReader::CheckMessageSize(size_t size) {
   if (size <= Channel::kMaximumMessageSize) {
     return true;
   }
   input_overflow_buf_.clear();
   LOG(ERROR) << "IPC message is too big: " << size;
   return false;
 }

 }  // namespace internal
 }  // namespace IPC
	// Copyright (c) 2012 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 "ipc/ipc_channel_reader.h"

	#include <stddef.h>

	#include <algorithm>

	#include "base/logging.h"
	#include "base/threading/thread_task_runner_handle.h"
	#include "ipc/ipc_listener.h"
	#include "ipc/ipc_logging.h"
	#include "ipc/ipc_message.h"
	#include "ipc/ipc_message_attachment_set.h"
	#include "ipc/ipc_message_macros.h"

	namespace IPC {
	namespace internal {

	#if BUILDFLAG(IPC_MESSAGE_LOG_ENABLED)

	namespace {
	std::string GetMessageText(const Message& message) {
	std::string name;
	Logging::GetInstance()->GetMessageText(
	message.type(), &name, &message, nullptr);
	return name;
	}
	} // namespace

	#define EMIT_TRACE_EVENT(message) \
	TRACE_EVENT_WITH_FLOW1( \
	"ipc,toplevel", "ChannelReader::DispatchInputData", \
	(message).flags(), TRACE_EVENT_FLAG_FLOW_IN, "name", \
	GetMessageText(message));
	#else
	#define EMIT_TRACE_EVENT(message) \
	TRACE_EVENT_WITH_FLOW2("ipc,toplevel", "ChannelReader::DispatchInputData", \
	(message).flags(), TRACE_EVENT_FLAG_FLOW_IN, "class", \
	IPC_MESSAGE_ID_CLASS((message).type()), "line", \
	IPC_MESSAGE_ID_LINE((message).type()));
	#endif // BUILDFLAG(IPC_MESSAGE_LOG_ENABLED)

	ChannelReader::ChannelReader(Listener* listener)
	: listener_(listener),
	max_input_buffer_size_(Channel::kMaximumReadBufferSize) {
	memset(input_buf_, 0, sizeof(input_buf_));
	}

	ChannelReader::~ChannelReader() = default;

	ChannelReader::DispatchState ChannelReader::ProcessIncomingMessages() {
	while (true) {
	int bytes_read = 0;
	ReadState read_state = ReadData(input_buf_, Channel::kReadBufferSize,
	&bytes_read);
	if (read_state == READ_FAILED)
	return DISPATCH_ERROR;
	if (read_state == READ_PENDING)
	return DISPATCH_FINISHED;

	DCHECK(bytes_read > 0);
	if (!TranslateInputData(input_buf_, bytes_read))
	return DISPATCH_ERROR;
	}
	}

	ChannelReader::DispatchState ChannelReader::AsyncReadComplete(int bytes_read) {
	if (!TranslateInputData(input_buf_, bytes_read))
	return DISPATCH_ERROR;

	return DISPATCH_FINISHED;
	}

	bool ChannelReader::IsInternalMessage(const Message& m) {
	return m.routing_id() == MSG_ROUTING_NONE &&
	m.type() >= Channel::CLOSE_FD_MESSAGE_TYPE &&
	m.type() <= Channel::HELLO_MESSAGE_TYPE;
	}

	bool ChannelReader::IsHelloMessage(const Message& m) {
	return m.routing_id() == MSG_ROUTING_NONE &&
	m.type() == Channel::HELLO_MESSAGE_TYPE;
	}

	void ChannelReader::CleanUp() {
	}

	void ChannelReader::DispatchMessage(Message* m) {
	EMIT_TRACE_EVENT(*m);
	listener_->OnMessageReceived(*m);
	HandleDispatchError(*m);
	}

	bool ChannelReader::TranslateInputData(const char* input_data,
	int input_data_len) {
	const char* p;
	const char* end;

	// Possibly combine with the overflow buffer to make a larger buffer.
	if (input_overflow_buf_.empty()) {
	p = input_data;
	end = input_data + input_data_len;
	} else {
	if (!CheckMessageSize(input_overflow_buf_.size() + input_data_len))
	return false;
	input_overflow_buf_.append(input_data, input_data_len);
	p = input_overflow_buf_.data();
	end = p + input_overflow_buf_.size();
	}

	size_t next_message_size = 0;

	// Dispatch all complete messages in the data buffer.
	while (p < end) {
	Message::NextMessageInfo info;
	Message::FindNext(p, end, &info);
	if (info.message_found) {
	int pickle_len = static_cast<int>(info.pickle_end - p);
	Message translated_message(p, pickle_len);

	if (!HandleTranslatedMessage(&translated_message))
	return false;

	p = info.message_end;
	} else {
	// Last message is partial.
	next_message_size = info.message_size;
	if (!CheckMessageSize(next_message_size))
	return false;
	break;
	}
	}

	// Account for the case where last message's byte is in the next data chunk.
	size_t next_message_buffer_size = next_message_size ?
	next_message_size + Channel::kReadBufferSize - 1:
	0;

	// Save any partial data in the overflow buffer.
	if (p != input_overflow_buf_.data())
	input_overflow_buf_.assign(p, end - p);

	if (!input_overflow_buf_.empty()) {
	// We have something in the overflow buffer, which means that we will
	// append the next data chunk (instead of parsing it directly). So we
	// resize the buffer to fit the next message, to avoid repeatedly
	// growing the buffer as we receive all message' data chunks.
	if (next_message_buffer_size > input_overflow_buf_.capacity()) {
	input_overflow_buf_.reserve(next_message_buffer_size);
	}
	}

	// Trim the buffer if we can
	if (next_message_buffer_size < max_input_buffer_size_ &&
	input_overflow_buf_.size() < max_input_buffer_size_ &&
	input_overflow_buf_.capacity() > max_input_buffer_size_) {
	// std::string doesn't really have a method to shrink capacity to
	// a specific value, so we have to swap with another string.
	std::string trimmed_buf;
	trimmed_buf.reserve(max_input_buffer_size_);
	if (trimmed_buf.capacity() > max_input_buffer_size_) {
	// Since we don't control how much space reserve() actually reserves,
	// we have to go other way around and change the max size to avoid
	// getting into the outer if() again.
	max_input_buffer_size_ = trimmed_buf.capacity();
	}
	trimmed_buf.assign(input_overflow_buf_.data(),
	input_overflow_buf_.size());
	input_overflow_buf_.swap(trimmed_buf);
	}

	if (input_overflow_buf_.empty() && !DidEmptyInputBuffers())
	return false;
	return true;
	}

	bool ChannelReader::HandleTranslatedMessage(Message* translated_message) {
	// Immediately handle internal messages.
	if (IsInternalMessage(*translated_message)) {
	EMIT_TRACE_EVENT(*translated_message);
	HandleInternalMessage(*translated_message);
	HandleDispatchError(*translated_message);
	return true;
	}

	return HandleExternalMessage(translated_message);
	}

	bool ChannelReader::HandleExternalMessage(Message* external_message) {
	if (!GetAttachments(external_message))
	return false;

	DispatchMessage(external_message);
	return true;
	}

	void ChannelReader::HandleDispatchError(const Message& message) {
	if (message.dispatch_error())
	listener_->OnBadMessageReceived(message);
	}

	bool ChannelReader::CheckMessageSize(size_t size) {
	if (size <= Channel::kMaximumMessageSize) {
	return true;
	}
	input_overflow_buf_.clear();
	LOG(ERROR) << "IPC message is too big: " << size;
	return false;
	}

	} // namespace internal
	} // namespace IPC