content/browser/message_port_service.cc - platform/external/chromium_org - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "content/browser/message_port_service.h"

 #include "content/browser/message_port_message_filter.h"
 #include "content/common/message_port_messages.h"

 namespace content {

 struct MessagePortService::MessagePort {
   // |filter| and |route_id| are what we need to send messages to the port.
   // |filter| is just a weak pointer since we get notified when its process has
   // gone away and remove it.
   MessagePortMessageFilter* filter;
   int route_id;
   // A globally unique id for this message port.
   int message_port_id;
   // The globally unique id of the entangled message port.
   int entangled_message_port_id;
   // If true, all messages to this message port are queued and not delivered.
   // This is needed so that when a message port is sent between processes all
   // pending message get transferred. There are two possibilities for pending
   // messages: either they are already received by the child process, or they're
   // in-flight. This flag ensures that the latter type get flushed through the
   // system.
   // This flag should only be set to true in response to
   // MessagePortHostMsg_QueueMessages.
   bool queue_messages;
   QueuedMessages queued_messages;
 };

 MessagePortService* MessagePortService::GetInstance() {
   return Singleton<MessagePortService>::get();
 }

 MessagePortService::MessagePortService()
     : next_message_port_id_(0) {
 }

 MessagePortService::~MessagePortService() {
 }

 void MessagePortService::UpdateMessagePort(
     int message_port_id,
     MessagePortMessageFilter* filter,
     int routing_id) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }

   MessagePort& port = message_ports_[message_port_id];
   port.filter = filter;
   port.route_id = routing_id;
 }

 void MessagePortService::OnMessagePortMessageFilterClosing(
     MessagePortMessageFilter* filter) {
   // Check if the (possibly) crashed process had any message ports.
   for (MessagePorts::iterator iter = message_ports_.begin();
        iter != message_ports_.end();) {
     MessagePorts::iterator cur_item = iter++;
     if (cur_item->second.filter == filter) {
       Erase(cur_item->first);
     }
   }
 }

 void MessagePortService::Create(int route_id,
                                 MessagePortMessageFilter* filter,
                                 int* message_port_id) {
   *message_port_id = ++next_message_port_id_;

   MessagePort port;
   port.filter = filter;
   port.route_id = route_id;
   port.message_port_id = *message_port_id;
   port.entangled_message_port_id = MSG_ROUTING_NONE;
   port.queue_messages = false;
   message_ports_[*message_port_id] = port;
 }

 void MessagePortService::Destroy(int message_port_id) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }

   DCHECK(message_ports_[message_port_id].queued_messages.empty());
   Erase(message_port_id);
 }

 void MessagePortService::Entangle(int local_message_port_id,
                                   int remote_message_port_id) {
   if (!message_ports_.count(local_message_port_id) ||
       !message_ports_.count(remote_message_port_id)) {
     NOTREACHED();
     return;
   }

   DCHECK(message_ports_[remote_message_port_id].entangled_message_port_id ==
       MSG_ROUTING_NONE);
   message_ports_[remote_message_port_id].entangled_message_port_id =
       local_message_port_id;
 }

 void MessagePortService::PostMessage(
     int sender_message_port_id,
     const base::string16& message,
     const std::vector<int>& sent_message_port_ids) {
   if (!message_ports_.count(sender_message_port_id)) {
     NOTREACHED();
     return;
   }

   int entangled_message_port_id =
       message_ports_[sender_message_port_id].entangled_message_port_id;
   if (entangled_message_port_id == MSG_ROUTING_NONE)
     return;  // Process could have crashed.

   if (!message_ports_.count(entangled_message_port_id)) {
     NOTREACHED();
     return;
   }

   PostMessageTo(entangled_message_port_id, message, sent_message_port_ids);
 }

 void MessagePortService::PostMessageTo(
     int message_port_id,
     const base::string16& message,
     const std::vector<int>& sent_message_port_ids) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }
   for (size_t i = 0; i < sent_message_port_ids.size(); ++i) {
     if (!message_ports_.count(sent_message_port_ids[i])) {
       NOTREACHED();
       return;
     }
   }

   MessagePort& entangled_port = message_ports_[message_port_id];

   std::vector<MessagePort*> sent_ports(sent_message_port_ids.size());
   for (size_t i = 0; i < sent_message_port_ids.size(); ++i)
     sent_ports[i] = &message_ports_[sent_message_port_ids[i]];

   if (entangled_port.queue_messages) {
     entangled_port.queued_messages.push_back(
         std::make_pair(message, sent_message_port_ids));
     return;
   }

   if (!entangled_port.filter) {
     NOTREACHED();
     return;
   }

   // If a message port was sent around, the new location will need a routing
   // id.  Instead of having the created port send us a sync message to get it,
   // send along with the message.
   std::vector<int> new_routing_ids(sent_message_port_ids.size());
   for (size_t i = 0; i < sent_message_port_ids.size(); ++i) {
     new_routing_ids[i] = entangled_port.filter->GetNextRoutingID();
     sent_ports[i]->filter = entangled_port.filter;

     // Update the entry for the sent port as it can be in a different process.
     sent_ports[i]->route_id = new_routing_ids[i];
   }

   // Now send the message to the entangled port.
   entangled_port.filter->Send(new MessagePortMsg_Message(
       entangled_port.route_id, message, sent_message_port_ids,
       new_routing_ids));
 }

 void MessagePortService::QueueMessages(int message_port_id) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }

   MessagePort& port = message_ports_[message_port_id];
   if (port.filter) {
     port.filter->Send(new MessagePortMsg_MessagesQueued(port.route_id));
     port.queue_messages = true;
     port.filter = NULL;
   }
 }

 void MessagePortService::SendQueuedMessages(
     int message_port_id,
     const QueuedMessages& queued_messages) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }

   // Send the queued messages to the port again.  This time they'll reach the
   // new location.
   MessagePort& port = message_ports_[message_port_id];
   port.queue_messages = false;
   port.queued_messages.insert(port.queued_messages.begin(),
                               queued_messages.begin(),
                               queued_messages.end());
   SendQueuedMessagesIfPossible(message_port_id);
 }

 void MessagePortService::SendQueuedMessagesIfPossible(int message_port_id) {
   if (!message_ports_.count(message_port_id)) {
     NOTREACHED();
     return;
   }

   MessagePort& port = message_ports_[message_port_id];
   if (port.queue_messages || !port.filter)
     return;

   for (QueuedMessages::iterator iter = port.queued_messages.begin();
        iter != port.queued_messages.end(); ++iter) {
     PostMessageTo(message_port_id, iter->first, iter->second);
   }
   port.queued_messages.clear();
 }

 void MessagePortService::Erase(int message_port_id) {
   MessagePorts::iterator erase_item = message_ports_.find(message_port_id);
   DCHECK(erase_item != message_ports_.end());

   int entangled_id = erase_item->second.entangled_message_port_id;
   if (entangled_id != MSG_ROUTING_NONE) {
     // Do the disentanglement (and be paranoid about the other side existing
     // just in case something unusual happened during entanglement).
     if (message_ports_.count(entangled_id)) {
       message_ports_[entangled_id].entangled_message_port_id = MSG_ROUTING_NONE;
     }
   }
   message_ports_.erase(erase_item);
 }

 }  // namespace content
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "content/browser/message_port_service.h"

	#include "content/browser/message_port_message_filter.h"
	#include "content/common/message_port_messages.h"

	namespace content {

	struct MessagePortService::MessagePort {
	// \|filter\| and \|route_id\| are what we need to send messages to the port.
	// \|filter\| is just a weak pointer since we get notified when its process has
	// gone away and remove it.
	MessagePortMessageFilter* filter;
	int route_id;
	// A globally unique id for this message port.
	int message_port_id;
	// The globally unique id of the entangled message port.
	int entangled_message_port_id;
	// If true, all messages to this message port are queued and not delivered.
	// This is needed so that when a message port is sent between processes all
	// pending message get transferred. There are two possibilities for pending
	// messages: either they are already received by the child process, or they're
	// in-flight. This flag ensures that the latter type get flushed through the
	// system.
	// This flag should only be set to true in response to
	// MessagePortHostMsg_QueueMessages.
	bool queue_messages;
	QueuedMessages queued_messages;
	};

	MessagePortService* MessagePortService::GetInstance() {
	return Singleton<MessagePortService>::get();
	}

	MessagePortService::MessagePortService()
	: next_message_port_id_(0) {
	}

	MessagePortService::~MessagePortService() {
	}

	void MessagePortService::UpdateMessagePort(
	int message_port_id,
	MessagePortMessageFilter* filter,
	int routing_id) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}

	MessagePort& port = message_ports_[message_port_id];
	port.filter = filter;
	port.route_id = routing_id;
	}

	void MessagePortService::OnMessagePortMessageFilterClosing(
	MessagePortMessageFilter* filter) {
	// Check if the (possibly) crashed process had any message ports.
	for (MessagePorts::iterator iter = message_ports_.begin();
	iter != message_ports_.end();) {
	MessagePorts::iterator cur_item = iter++;
	if (cur_item->second.filter == filter) {
	Erase(cur_item->first);
	}
	}
	}

	void MessagePortService::Create(int route_id,
	MessagePortMessageFilter* filter,
	int* message_port_id) {
	*message_port_id = ++next_message_port_id_;

	MessagePort port;
	port.filter = filter;
	port.route_id = route_id;
	port.message_port_id = *message_port_id;
	port.entangled_message_port_id = MSG_ROUTING_NONE;
	port.queue_messages = false;
	message_ports_[*message_port_id] = port;
	}

	void MessagePortService::Destroy(int message_port_id) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}

	DCHECK(message_ports_[message_port_id].queued_messages.empty());
	Erase(message_port_id);
	}

	void MessagePortService::Entangle(int local_message_port_id,
	int remote_message_port_id) {
	if (!message_ports_.count(local_message_port_id) \|\|
	!message_ports_.count(remote_message_port_id)) {
	NOTREACHED();
	return;
	}

	DCHECK(message_ports_[remote_message_port_id].entangled_message_port_id ==
	MSG_ROUTING_NONE);
	message_ports_[remote_message_port_id].entangled_message_port_id =
	local_message_port_id;
	}

	void MessagePortService::PostMessage(
	int sender_message_port_id,
	const base::string16& message,
	const std::vector<int>& sent_message_port_ids) {
	if (!message_ports_.count(sender_message_port_id)) {
	NOTREACHED();
	return;
	}

	int entangled_message_port_id =
	message_ports_[sender_message_port_id].entangled_message_port_id;
	if (entangled_message_port_id == MSG_ROUTING_NONE)
	return; // Process could have crashed.

	if (!message_ports_.count(entangled_message_port_id)) {
	NOTREACHED();
	return;
	}

	PostMessageTo(entangled_message_port_id, message, sent_message_port_ids);
	}

	void MessagePortService::PostMessageTo(
	int message_port_id,
	const base::string16& message,
	const std::vector<int>& sent_message_port_ids) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}
	for (size_t i = 0; i < sent_message_port_ids.size(); ++i) {
	if (!message_ports_.count(sent_message_port_ids[i])) {
	NOTREACHED();
	return;
	}
	}

	MessagePort& entangled_port = message_ports_[message_port_id];

	std::vector<MessagePort*> sent_ports(sent_message_port_ids.size());
	for (size_t i = 0; i < sent_message_port_ids.size(); ++i)
	sent_ports[i] = &message_ports_[sent_message_port_ids[i]];

	if (entangled_port.queue_messages) {
	entangled_port.queued_messages.push_back(
	std::make_pair(message, sent_message_port_ids));
	return;
	}

	if (!entangled_port.filter) {
	NOTREACHED();
	return;
	}

	// If a message port was sent around, the new location will need a routing
	// id. Instead of having the created port send us a sync message to get it,
	// send along with the message.
	std::vector<int> new_routing_ids(sent_message_port_ids.size());
	for (size_t i = 0; i < sent_message_port_ids.size(); ++i) {
	new_routing_ids[i] = entangled_port.filter->GetNextRoutingID();
	sent_ports[i]->filter = entangled_port.filter;

	// Update the entry for the sent port as it can be in a different process.
	sent_ports[i]->route_id = new_routing_ids[i];
	}

	// Now send the message to the entangled port.
	entangled_port.filter->Send(new MessagePortMsg_Message(
	entangled_port.route_id, message, sent_message_port_ids,
	new_routing_ids));
	}

	void MessagePortService::QueueMessages(int message_port_id) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}

	MessagePort& port = message_ports_[message_port_id];
	if (port.filter) {
	port.filter->Send(new MessagePortMsg_MessagesQueued(port.route_id));
	port.queue_messages = true;
	port.filter = NULL;
	}
	}

	void MessagePortService::SendQueuedMessages(
	int message_port_id,
	const QueuedMessages& queued_messages) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}

	// Send the queued messages to the port again. This time they'll reach the
	// new location.
	MessagePort& port = message_ports_[message_port_id];
	port.queue_messages = false;
	port.queued_messages.insert(port.queued_messages.begin(),
	queued_messages.begin(),
	queued_messages.end());
	SendQueuedMessagesIfPossible(message_port_id);
	}

	void MessagePortService::SendQueuedMessagesIfPossible(int message_port_id) {
	if (!message_ports_.count(message_port_id)) {
	NOTREACHED();
	return;
	}

	MessagePort& port = message_ports_[message_port_id];
	if (port.queue_messages \|\| !port.filter)
	return;

	for (QueuedMessages::iterator iter = port.queued_messages.begin();
	iter != port.queued_messages.end(); ++iter) {
	PostMessageTo(message_port_id, iter->first, iter->second);
	}
	port.queued_messages.clear();
	}

	void MessagePortService::Erase(int message_port_id) {
	MessagePorts::iterator erase_item = message_ports_.find(message_port_id);
	DCHECK(erase_item != message_ports_.end());

	int entangled_id = erase_item->second.entangled_message_port_id;
	if (entangled_id != MSG_ROUTING_NONE) {
	// Do the disentanglement (and be paranoid about the other side existing
	// just in case something unusual happened during entanglement).
	if (message_ports_.count(entangled_id)) {
	message_ports_[entangled_id].entangled_message_port_id = MSG_ROUTING_NONE;
	}
	}
	message_ports_.erase(erase_item);
	}

	} // namespace content