third_party/libjingle/source/talk/session/tunnel/pseudotcpchannel.cc - vendor/opensource/webrtc - Git at Google

 /*
  * libjingle
  * Copyright 2004--2006, Google Inc.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are met:
  *
  *  1. Redistributions of source code must retain the above copyright notice,
  *     this list of conditions and the following disclaimer.
  *  2. Redistributions in binary form must reproduce the above copyright notice,
  *     this list of conditions and the following disclaimer in the documentation
  *     and/or other materials provided with the distribution.
  *  3. The name of the author may not be used to endorse or promote products
  *     derived from this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
  * EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
  * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
  * OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
  * OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
  * ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include <string>
 #include "talk/base/basictypes.h"
 #include "talk/base/common.h"
 #include "talk/base/logging.h"
 #include "talk/base/scoped_ptr.h"
 #include "talk/base/stringutils.h"
 #include "talk/p2p/base/candidate.h"
 #include "talk/p2p/base/transportchannel.h"
 #include "pseudotcpchannel.h"

 using namespace talk_base;

 namespace cricket {

 extern const talk_base::ConstantLabel SESSION_STATES[];

 // MSG_WK_* - worker thread messages
 // MSG_ST_* - stream thread messages
 // MSG_SI_* - signal thread messages

 enum {
   MSG_WK_CLOCK = 1,
   MSG_WK_PURGE,
   MSG_ST_EVENT,
   MSG_SI_DESTROYCHANNEL,
   MSG_SI_DESTROY,
 };

 struct EventData : public MessageData {
   int event, error;
   EventData(int ev, int err = 0) : event(ev), error(err) { }
 };

 ///////////////////////////////////////////////////////////////////////////////
 // PseudoTcpChannel::InternalStream
 ///////////////////////////////////////////////////////////////////////////////

 class PseudoTcpChannel::InternalStream : public StreamInterface {
 public:
   InternalStream(PseudoTcpChannel* parent);
   virtual ~InternalStream();

   virtual StreamState GetState() const;
   virtual StreamResult Read(void* buffer, size_t buffer_len,
                                        size_t* read, int* error);
   virtual StreamResult Write(const void* data, size_t data_len,
                                         size_t* written, int* error);
   virtual void Close();

 private:
   // parent_ is accessed and modified exclusively on the event thread, to
   // avoid thread contention.  This means that the PseudoTcpChannel cannot go
   // away until after it receives a Close() from TunnelStream.
   PseudoTcpChannel* parent_;
 };

 ///////////////////////////////////////////////////////////////////////////////
 // PseudoTcpChannel
 // Member object lifetime summaries:
 //   session_ - passed in constructor, cleared when channel_ goes away.
 //   channel_ - created in Connect, destroyed when session_ or tcp_ goes away.
 //   tcp_ - created in Connect, destroyed when channel_ goes away, or connection
 //     closes.
 //   worker_thread_ - created when channel_ is created, purged when channel_ is
 //     destroyed.
 //   stream_ - created in GetStream, destroyed by owner at arbitrary time.
 //   this - created in constructor, destroyed when worker_thread_ and stream_
 //     are both gone.
 ///////////////////////////////////////////////////////////////////////////////

 //
 // Signal thread methods
 //

 PseudoTcpChannel::PseudoTcpChannel(Thread* stream_thread, Session* session)
   : signal_thread_(session->session_manager()->signaling_thread()),
     worker_thread_(NULL),
     stream_thread_(stream_thread),
     session_(session), channel_(NULL), tcp_(NULL), stream_(NULL),
     stream_readable_(false), pending_read_event_(false),
     ready_to_connect_(false) {
   ASSERT(signal_thread_->IsCurrent());
   ASSERT(NULL != session_);
 }

 PseudoTcpChannel::~PseudoTcpChannel() {
   ASSERT(signal_thread_->IsCurrent());
   ASSERT(worker_thread_ == NULL);
   ASSERT(session_ == NULL);
   ASSERT(channel_ == NULL);
   ASSERT(stream_ == NULL);
   ASSERT(tcp_ == NULL);
 }

 bool PseudoTcpChannel::Connect(const std::string& content_name,
                                const std::string& channel_name) {
   ASSERT(signal_thread_->IsCurrent());
   CritScope lock(&cs_);

   if (channel_)
     return false;

   ASSERT(session_ != NULL);
   worker_thread_ = session_->session_manager()->worker_thread();
   content_name_ = content_name;
   channel_ = session_->CreateChannel(content_name, channel_name);
   channel_name_ = channel_name;
   channel_->SetOption(Socket::OPT_DONTFRAGMENT, 1);

   channel_->SignalDestroyed.connect(this,
     &PseudoTcpChannel::OnChannelDestroyed);
   channel_->SignalWritableState.connect(this,
     &PseudoTcpChannel::OnChannelWritableState);
   channel_->SignalReadPacket.connect(this,
     &PseudoTcpChannel::OnChannelRead);
   channel_->SignalRouteChange.connect(this,
     &PseudoTcpChannel::OnChannelConnectionChanged);

   ASSERT(tcp_ == NULL);
   tcp_ = new PseudoTcp(this, 0);
   if (session_->initiator()) {
     // Since we may try several protocols and network adapters that won't work,
     // waiting until we get our first writable notification before initiating
     // TCP negotiation.
     ready_to_connect_ = true;
   }

   return true;
 }

 StreamInterface* PseudoTcpChannel::GetStream() {
   ASSERT(signal_thread_->IsCurrent());
   CritScope lock(&cs_);
   ASSERT(NULL != session_);
   if (!stream_)
     stream_ = new PseudoTcpChannel::InternalStream(this);
   //TODO("should we disallow creation of new stream at some point?");
   return stream_;
 }

 void PseudoTcpChannel::OnChannelDestroyed(TransportChannel* channel) {
   LOG_F(LS_INFO) << "(" << channel->name() << ")";
   ASSERT(signal_thread_->IsCurrent());
   CritScope lock(&cs_);
   ASSERT(channel == channel_);
   signal_thread_->Clear(this, MSG_SI_DESTROYCHANNEL);
   // When MSG_WK_PURGE is received, we know there will be no more messages from
   // the worker thread.
   worker_thread_->Clear(this, MSG_WK_CLOCK);
   worker_thread_->Post(this, MSG_WK_PURGE);
   session_ = NULL;
   channel_ = NULL;
   if ((stream_ != NULL)
       && ((tcp_ == NULL) || (tcp_->State() != PseudoTcp::TCP_CLOSED)))
     stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, 0));
   if (tcp_) {
     tcp_->Close(true);
     AdjustClock();
   }
   SignalChannelClosed(this);
 }

 void PseudoTcpChannel::OnSessionTerminate(Session* session) {
   // When the session terminates before we even connected
   CritScope lock(&cs_);
   if (session_ != NULL && channel_ == NULL) {
     ASSERT(session == session_);
     ASSERT(worker_thread_ == NULL);
     ASSERT(tcp_ == NULL);
     LOG(LS_INFO) << "Destroying unconnected PseudoTcpChannel";
     session_ = NULL;
     if (stream_ != NULL)
       stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, -1));
   }

   // Even though session_ is being destroyed, we mustn't clear the pointer,
   // since we'll need it to tear down channel_.
   //
   // TODO: Is it always the case that if channel_ != NULL then we'll get
   // a channel-destroyed notification?
 }

 void PseudoTcpChannel::GetOption(PseudoTcp::Option opt, int* value) {
   ASSERT(signal_thread_->IsCurrent());
   CritScope lock(&cs_);
   ASSERT(tcp_ != NULL);
   tcp_->GetOption(opt, value);
 }

 void PseudoTcpChannel::SetOption(PseudoTcp::Option opt, int value) {
   ASSERT(signal_thread_->IsCurrent());
   CritScope lock(&cs_);
   ASSERT(tcp_ != NULL);
   tcp_->SetOption(opt, value);
 }

 //
 // Stream thread methods
 //

 StreamState PseudoTcpChannel::GetState() const {
   ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!session_)
     return SS_CLOSED;
   if (!tcp_)
     return SS_OPENING;
   switch (tcp_->State()) {
     case PseudoTcp::TCP_LISTEN:
     case PseudoTcp::TCP_SYN_SENT:
     case PseudoTcp::TCP_SYN_RECEIVED:
       return SS_OPENING;
     case PseudoTcp::TCP_ESTABLISHED:
       return SS_OPEN;
     case PseudoTcp::TCP_CLOSED:
     default:
       return SS_CLOSED;
   }
 }

 StreamResult PseudoTcpChannel::Read(void* buffer, size_t buffer_len,
                                     size_t* read, int* error) {
   ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!tcp_)
     return SR_BLOCK;

   stream_readable_ = false;
   int result = tcp_->Recv(static_cast<char*>(buffer), buffer_len);
   //LOG_F(LS_VERBOSE) << "Recv returned: " << result;
   if (result > 0) {
     if (read)
       *read = result;
     // PseudoTcp doesn't currently support repeated Readable signals.  Simulate
     // them here.
     stream_readable_ = true;
     if (!pending_read_event_) {
       pending_read_event_ = true;
       stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_READ), true);
     }
     return SR_SUCCESS;
   } else if (IsBlockingError(tcp_->GetError())) {
     return SR_BLOCK;
   } else {
     if (error)
       *error = tcp_->GetError();
     return SR_ERROR;
   }
   // This spot is never reached.
 }

 StreamResult PseudoTcpChannel::Write(const void* data, size_t data_len,
                                      size_t* written, int* error) {
   ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!tcp_)
     return SR_BLOCK;
   int result = tcp_->Send(static_cast<const char*>(data), data_len);
   //LOG_F(LS_VERBOSE) << "Send returned: " << result;
   if (result > 0) {
     if (written)
       *written = result;
     return SR_SUCCESS;
   } else if (IsBlockingError(tcp_->GetError())) {
     return SR_BLOCK;
   } else {
     if (error)
       *error = tcp_->GetError();
     return SR_ERROR;
   }
   // This spot is never reached.
 }

 void PseudoTcpChannel::Close() {
   ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
   CritScope lock(&cs_);
   stream_ = NULL;
   // Clear out any pending event notifications
   stream_thread_->Clear(this, MSG_ST_EVENT);
   if (tcp_) {
     tcp_->Close(false);
     AdjustClock();
   } else {
     CheckDestroy();
   }
 }

 //
 // Worker thread methods
 //

 void PseudoTcpChannel::OnChannelWritableState(TransportChannel* channel) {
   LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
   ASSERT(worker_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!channel_) {
     LOG_F(LS_WARNING) << "NULL channel";
     return;
   }
   ASSERT(channel == channel_);
   if (!tcp_) {
     LOG_F(LS_WARNING) << "NULL tcp";
     return;
   }
   if (!ready_to_connect_ || !channel->writable())
     return;

   ready_to_connect_ = false;
   tcp_->Connect();
   AdjustClock();
 }

 void PseudoTcpChannel::OnChannelRead(TransportChannel* channel,
                                      const char* data, size_t size) {
   //LOG_F(LS_VERBOSE) << "(" << size << ")";
   ASSERT(worker_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!channel_) {
     LOG_F(LS_WARNING) << "NULL channel";
     return;
   }
   ASSERT(channel == channel_);
   if (!tcp_) {
     LOG_F(LS_WARNING) << "NULL tcp";
     return;
   }
   tcp_->NotifyPacket(data, size);
   AdjustClock();
 }

 void PseudoTcpChannel::OnChannelConnectionChanged(TransportChannel* channel,
                                                   const Candidate& candidate) {
   LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
   ASSERT(worker_thread_->IsCurrent());
   CritScope lock(&cs_);
   if (!channel_) {
     LOG_F(LS_WARNING) << "NULL channel";
     return;
   }
   ASSERT(channel == channel_);
   if (!tcp_) {
     LOG_F(LS_WARNING) << "NULL tcp";
     return;
   }

   uint16 mtu = 1280;  // safe default
   talk_base::scoped_ptr<Socket> mtu_socket(
       worker_thread_->socketserver()->CreateSocket(SOCK_DGRAM));
   if (mtu_socket->Connect(candidate.address()) < 0 ||
       mtu_socket->EstimateMTU(&mtu) < 0) {
     LOG_F(LS_WARNING) << "Failed to estimate MTU, error="
                       << mtu_socket->GetError();
   }

   LOG_F(LS_VERBOSE) << "Using MTU of " << mtu << " bytes";
   tcp_->NotifyMTU(mtu);
   AdjustClock();
 }

 void PseudoTcpChannel::OnTcpOpen(PseudoTcp* tcp) {
   LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(worker_thread_->IsCurrent());
   ASSERT(tcp == tcp_);
   if (stream_) {
     stream_readable_ = true;
     pending_read_event_ = true;
     stream_thread_->Post(this, MSG_ST_EVENT,
                          new EventData(SE_OPEN | SE_READ | SE_WRITE));
   }
 }

 void PseudoTcpChannel::OnTcpReadable(PseudoTcp* tcp) {
   //LOG_F(LS_VERBOSE);
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(worker_thread_->IsCurrent());
   ASSERT(tcp == tcp_);
   if (stream_) {
     stream_readable_ = true;
     if (!pending_read_event_) {
       pending_read_event_ = true;
       stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_READ));
     }
   }
 }

 void PseudoTcpChannel::OnTcpWriteable(PseudoTcp* tcp) {
   //LOG_F(LS_VERBOSE);
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(worker_thread_->IsCurrent());
   ASSERT(tcp == tcp_);
   if (stream_)
     stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_WRITE));
 }

 void PseudoTcpChannel::OnTcpClosed(PseudoTcp* tcp, uint32 nError) {
   LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(worker_thread_->IsCurrent());
   ASSERT(tcp == tcp_);
   if (stream_)
     stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, nError));
 }

 //
 // Multi-thread methods
 //

 void PseudoTcpChannel::OnMessage(Message* pmsg) {
   if (pmsg->message_id == MSG_WK_CLOCK) {

     ASSERT(worker_thread_->IsCurrent());
     //LOG(LS_INFO) << "PseudoTcpChannel::OnMessage(MSG_WK_CLOCK)";
     CritScope lock(&cs_);
     if (tcp_) {
       tcp_->NotifyClock(PseudoTcp::Now());
       AdjustClock(false);
     }

   } else if (pmsg->message_id == MSG_WK_PURGE) {

     ASSERT(worker_thread_->IsCurrent());
     LOG_F(LS_INFO) << "(MSG_WK_PURGE)";
     // At this point, we know there are no additional worker thread messages.
     CritScope lock(&cs_);
     ASSERT(NULL == session_);
     ASSERT(NULL == channel_);
     worker_thread_ = NULL;
     CheckDestroy();

   } else if (pmsg->message_id == MSG_ST_EVENT) {

     ASSERT(stream_thread_->IsCurrent());
     //LOG(LS_INFO) << "PseudoTcpChannel::OnMessage(MSG_ST_EVENT, "
     //             << data->event << ", " << data->error << ")";
     ASSERT(stream_ != NULL);
     EventData* data = static_cast<EventData*>(pmsg->pdata);
     if (data->event & SE_READ) {
       CritScope lock(&cs_);
       pending_read_event_ = false;
     }
     stream_->SignalEvent(stream_, data->event, data->error);
     delete data;

   } else if (pmsg->message_id == MSG_SI_DESTROYCHANNEL) {

     ASSERT(signal_thread_->IsCurrent());
     LOG_F(LS_INFO) << "(MSG_SI_DESTROYCHANNEL)";
     ASSERT(session_ != NULL);
     ASSERT(channel_ != NULL);
     session_->DestroyChannel(content_name_, channel_->name());

   } else if (pmsg->message_id == MSG_SI_DESTROY) {

     ASSERT(signal_thread_->IsCurrent());
     LOG_F(LS_INFO) << "(MSG_SI_DESTROY)";
     // The message queue is empty, so it is safe to destroy ourselves.
     delete this;

   } else {
     ASSERT(false);
   }
 }

 IPseudoTcpNotify::WriteResult PseudoTcpChannel::TcpWritePacket(
     PseudoTcp* tcp, const char* buffer, size_t len) {
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(tcp == tcp_);
   ASSERT(NULL != channel_);
   int sent = channel_->SendPacket(buffer, len);
   if (sent > 0) {
     //LOG_F(LS_VERBOSE) << "(" << sent << ") Sent";
     return IPseudoTcpNotify::WR_SUCCESS;
   } else if (IsBlockingError(channel_->GetError())) {
     LOG_F(LS_VERBOSE) << "Blocking";
     return IPseudoTcpNotify::WR_SUCCESS;
   } else if (channel_->GetError() == EMSGSIZE) {
     LOG_F(LS_ERROR) << "EMSGSIZE";
     return IPseudoTcpNotify::WR_TOO_LARGE;
   } else {
     PLOG(LS_ERROR, channel_->GetError()) << "PseudoTcpChannel::TcpWritePacket";
     ASSERT(false);
     return IPseudoTcpNotify::WR_FAIL;
   }
 }

 void PseudoTcpChannel::AdjustClock(bool clear) {
   ASSERT(cs_.CurrentThreadIsOwner());
   ASSERT(NULL != tcp_);

   long timeout = 0;
   if (tcp_->GetNextClock(PseudoTcp::Now(), timeout)) {
     ASSERT(NULL != channel_);
     // Reset the next clock, by clearing the old and setting a new one.
     if (clear)
       worker_thread_->Clear(this, MSG_WK_CLOCK);
     worker_thread_->PostDelayed(_max(timeout, 0L), this, MSG_WK_CLOCK);
     return;
   }

   delete tcp_;
   tcp_ = NULL;
   ready_to_connect_ = false;

   if (channel_) {
     // If TCP has failed, no need for channel_ anymore
     signal_thread_->Post(this, MSG_SI_DESTROYCHANNEL);
   }
 }

 void PseudoTcpChannel::CheckDestroy() {
   ASSERT(cs_.CurrentThreadIsOwner());
   if ((worker_thread_ != NULL) || (stream_ != NULL))
     return;
   signal_thread_->Post(this, MSG_SI_DESTROY);
 }

 ///////////////////////////////////////////////////////////////////////////////
 // PseudoTcpChannel::InternalStream
 ///////////////////////////////////////////////////////////////////////////////

 PseudoTcpChannel::InternalStream::InternalStream(PseudoTcpChannel* parent)
   : parent_(parent) {
 }

 PseudoTcpChannel::InternalStream::~InternalStream() {
   Close();
 }

 StreamState PseudoTcpChannel::InternalStream::GetState() const {
   if (!parent_)
     return SS_CLOSED;
   return parent_->GetState();
 }

 StreamResult PseudoTcpChannel::InternalStream::Read(
     void* buffer, size_t buffer_len, size_t* read, int* error) {
   if (!parent_) {
     if (error)
       *error = ENOTCONN;
     return SR_ERROR;
   }
   return parent_->Read(buffer, buffer_len, read, error);
 }

 StreamResult PseudoTcpChannel::InternalStream::Write(
     const void* data, size_t data_len,  size_t* written, int* error) {
   if (!parent_) {
     if (error)
       *error = ENOTCONN;
     return SR_ERROR;
   }
   return parent_->Write(data, data_len, written, error);
 }

 void PseudoTcpChannel::InternalStream::Close() {
   if (!parent_)
     return;
   parent_->Close();
   parent_ = NULL;
 }

 ///////////////////////////////////////////////////////////////////////////////

 } // namespace cricket
	/*
	* libjingle
	* Copyright 2004--2006, Google Inc.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are met:
	*
	* 1. Redistributions of source code must retain the above copyright notice,
	* this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright notice,
	* this list of conditions and the following disclaimer in the documentation
	* and/or other materials provided with the distribution.
	* 3. The name of the author may not be used to endorse or promote products
	* derived from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO
	* EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS;
	* OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
	* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
	* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF
	* ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <string>
	#include "talk/base/basictypes.h"
	#include "talk/base/common.h"
	#include "talk/base/logging.h"
	#include "talk/base/scoped_ptr.h"
	#include "talk/base/stringutils.h"
	#include "talk/p2p/base/candidate.h"
	#include "talk/p2p/base/transportchannel.h"
	#include "pseudotcpchannel.h"

	using namespace talk_base;

	namespace cricket {

	extern const talk_base::ConstantLabel SESSION_STATES[];

	// MSG_WK_* - worker thread messages
	// MSG_ST_* - stream thread messages
	// MSG_SI_* - signal thread messages

	enum {
	MSG_WK_CLOCK = 1,
	MSG_WK_PURGE,
	MSG_ST_EVENT,
	MSG_SI_DESTROYCHANNEL,
	MSG_SI_DESTROY,
	};

	struct EventData : public MessageData {
	int event, error;
	EventData(int ev, int err = 0) : event(ev), error(err) { }
	};

	///////////////////////////////////////////////////////////////////////////////
	// PseudoTcpChannel::InternalStream
	///////////////////////////////////////////////////////////////////////////////

	class PseudoTcpChannel::InternalStream : public StreamInterface {
	public:
	InternalStream(PseudoTcpChannel* parent);
	virtual ~InternalStream();

	virtual StreamState GetState() const;
	virtual StreamResult Read(void* buffer, size_t buffer_len,
	size_t* read, int* error);
	virtual StreamResult Write(const void* data, size_t data_len,
	size_t* written, int* error);
	virtual void Close();

	private:
	// parent_ is accessed and modified exclusively on the event thread, to
	// avoid thread contention. This means that the PseudoTcpChannel cannot go
	// away until after it receives a Close() from TunnelStream.
	PseudoTcpChannel* parent_;
	};

	///////////////////////////////////////////////////////////////////////////////
	// PseudoTcpChannel
	// Member object lifetime summaries:
	// session_ - passed in constructor, cleared when channel_ goes away.
	// channel_ - created in Connect, destroyed when session_ or tcp_ goes away.
	// tcp_ - created in Connect, destroyed when channel_ goes away, or connection
	// closes.
	// worker_thread_ - created when channel_ is created, purged when channel_ is
	// destroyed.
	// stream_ - created in GetStream, destroyed by owner at arbitrary time.
	// this - created in constructor, destroyed when worker_thread_ and stream_
	// are both gone.
	///////////////////////////////////////////////////////////////////////////////

	//
	// Signal thread methods
	//

	PseudoTcpChannel::PseudoTcpChannel(Thread* stream_thread, Session* session)
	: signal_thread_(session->session_manager()->signaling_thread()),
	worker_thread_(NULL),
	stream_thread_(stream_thread),
	session_(session), channel_(NULL), tcp_(NULL), stream_(NULL),
	stream_readable_(false), pending_read_event_(false),
	ready_to_connect_(false) {
	ASSERT(signal_thread_->IsCurrent());
	ASSERT(NULL != session_);
	}

	PseudoTcpChannel::~PseudoTcpChannel() {
	ASSERT(signal_thread_->IsCurrent());
	ASSERT(worker_thread_ == NULL);
	ASSERT(session_ == NULL);
	ASSERT(channel_ == NULL);
	ASSERT(stream_ == NULL);
	ASSERT(tcp_ == NULL);
	}

	bool PseudoTcpChannel::Connect(const std::string& content_name,
	const std::string& channel_name) {
	ASSERT(signal_thread_->IsCurrent());
	CritScope lock(&cs_);

	if (channel_)
	return false;

	ASSERT(session_ != NULL);
	worker_thread_ = session_->session_manager()->worker_thread();
	content_name_ = content_name;
	channel_ = session_->CreateChannel(content_name, channel_name);
	channel_name_ = channel_name;
	channel_->SetOption(Socket::OPT_DONTFRAGMENT, 1);

	channel_->SignalDestroyed.connect(this,
	&PseudoTcpChannel::OnChannelDestroyed);
	channel_->SignalWritableState.connect(this,
	&PseudoTcpChannel::OnChannelWritableState);
	channel_->SignalReadPacket.connect(this,
	&PseudoTcpChannel::OnChannelRead);
	channel_->SignalRouteChange.connect(this,
	&PseudoTcpChannel::OnChannelConnectionChanged);

	ASSERT(tcp_ == NULL);
	tcp_ = new PseudoTcp(this, 0);
	if (session_->initiator()) {
	// Since we may try several protocols and network adapters that won't work,
	// waiting until we get our first writable notification before initiating
	// TCP negotiation.
	ready_to_connect_ = true;
	}

	return true;
	}

	StreamInterface* PseudoTcpChannel::GetStream() {
	ASSERT(signal_thread_->IsCurrent());
	CritScope lock(&cs_);
	ASSERT(NULL != session_);
	if (!stream_)
	stream_ = new PseudoTcpChannel::InternalStream(this);
	//TODO("should we disallow creation of new stream at some point?");
	return stream_;
	}

	void PseudoTcpChannel::OnChannelDestroyed(TransportChannel* channel) {
	LOG_F(LS_INFO) << "(" << channel->name() << ")";
	ASSERT(signal_thread_->IsCurrent());
	CritScope lock(&cs_);
	ASSERT(channel == channel_);
	signal_thread_->Clear(this, MSG_SI_DESTROYCHANNEL);
	// When MSG_WK_PURGE is received, we know there will be no more messages from
	// the worker thread.
	worker_thread_->Clear(this, MSG_WK_CLOCK);
	worker_thread_->Post(this, MSG_WK_PURGE);
	session_ = NULL;
	channel_ = NULL;
	if ((stream_ != NULL)
	&& ((tcp_ == NULL) \|\| (tcp_->State() != PseudoTcp::TCP_CLOSED)))
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, 0));
	if (tcp_) {
	tcp_->Close(true);
	AdjustClock();
	}
	SignalChannelClosed(this);
	}

	void PseudoTcpChannel::OnSessionTerminate(Session* session) {
	// When the session terminates before we even connected
	CritScope lock(&cs_);
	if (session_ != NULL && channel_ == NULL) {
	ASSERT(session == session_);
	ASSERT(worker_thread_ == NULL);
	ASSERT(tcp_ == NULL);
	LOG(LS_INFO) << "Destroying unconnected PseudoTcpChannel";
	session_ = NULL;
	if (stream_ != NULL)
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, -1));
	}

	// Even though session_ is being destroyed, we mustn't clear the pointer,
	// since we'll need it to tear down channel_.
	//
	// TODO: Is it always the case that if channel_ != NULL then we'll get
	// a channel-destroyed notification?
	}

	void PseudoTcpChannel::GetOption(PseudoTcp::Option opt, int* value) {
	ASSERT(signal_thread_->IsCurrent());
	CritScope lock(&cs_);
	ASSERT(tcp_ != NULL);
	tcp_->GetOption(opt, value);
	}

	void PseudoTcpChannel::SetOption(PseudoTcp::Option opt, int value) {
	ASSERT(signal_thread_->IsCurrent());
	CritScope lock(&cs_);
	ASSERT(tcp_ != NULL);
	tcp_->SetOption(opt, value);
	}

	//
	// Stream thread methods
	//

	StreamState PseudoTcpChannel::GetState() const {
	ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!session_)
	return SS_CLOSED;
	if (!tcp_)
	return SS_OPENING;
	switch (tcp_->State()) {
	case PseudoTcp::TCP_LISTEN:
	case PseudoTcp::TCP_SYN_SENT:
	case PseudoTcp::TCP_SYN_RECEIVED:
	return SS_OPENING;
	case PseudoTcp::TCP_ESTABLISHED:
	return SS_OPEN;
	case PseudoTcp::TCP_CLOSED:
	default:
	return SS_CLOSED;
	}
	}

	StreamResult PseudoTcpChannel::Read(void* buffer, size_t buffer_len,
	size_t* read, int* error) {
	ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!tcp_)
	return SR_BLOCK;

	stream_readable_ = false;
	int result = tcp_->Recv(static_cast<char*>(buffer), buffer_len);
	//LOG_F(LS_VERBOSE) << "Recv returned: " << result;
	if (result > 0) {
	if (read)
	*read = result;
	// PseudoTcp doesn't currently support repeated Readable signals. Simulate
	// them here.
	stream_readable_ = true;
	if (!pending_read_event_) {
	pending_read_event_ = true;
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_READ), true);
	}
	return SR_SUCCESS;
	} else if (IsBlockingError(tcp_->GetError())) {
	return SR_BLOCK;
	} else {
	if (error)
	*error = tcp_->GetError();
	return SR_ERROR;
	}
	// This spot is never reached.
	}

	StreamResult PseudoTcpChannel::Write(const void* data, size_t data_len,
	size_t* written, int* error) {
	ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!tcp_)
	return SR_BLOCK;
	int result = tcp_->Send(static_cast<const char*>(data), data_len);
	//LOG_F(LS_VERBOSE) << "Send returned: " << result;
	if (result > 0) {
	if (written)
	*written = result;
	return SR_SUCCESS;
	} else if (IsBlockingError(tcp_->GetError())) {
	return SR_BLOCK;
	} else {
	if (error)
	*error = tcp_->GetError();
	return SR_ERROR;
	}
	// This spot is never reached.
	}

	void PseudoTcpChannel::Close() {
	ASSERT(stream_ != NULL && stream_thread_->IsCurrent());
	CritScope lock(&cs_);
	stream_ = NULL;
	// Clear out any pending event notifications
	stream_thread_->Clear(this, MSG_ST_EVENT);
	if (tcp_) {
	tcp_->Close(false);
	AdjustClock();
	} else {
	CheckDestroy();
	}
	}

	//
	// Worker thread methods
	//

	void PseudoTcpChannel::OnChannelWritableState(TransportChannel* channel) {
	LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
	ASSERT(worker_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!channel_) {
	LOG_F(LS_WARNING) << "NULL channel";
	return;
	}
	ASSERT(channel == channel_);
	if (!tcp_) {
	LOG_F(LS_WARNING) << "NULL tcp";
	return;
	}
	if (!ready_to_connect_ \|\| !channel->writable())
	return;

	ready_to_connect_ = false;
	tcp_->Connect();
	AdjustClock();
	}

	void PseudoTcpChannel::OnChannelRead(TransportChannel* channel,
	const char* data, size_t size) {
	//LOG_F(LS_VERBOSE) << "(" << size << ")";
	ASSERT(worker_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!channel_) {
	LOG_F(LS_WARNING) << "NULL channel";
	return;
	}
	ASSERT(channel == channel_);
	if (!tcp_) {
	LOG_F(LS_WARNING) << "NULL tcp";
	return;
	}
	tcp_->NotifyPacket(data, size);
	AdjustClock();
	}

	void PseudoTcpChannel::OnChannelConnectionChanged(TransportChannel* channel,
	const Candidate& candidate) {
	LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
	ASSERT(worker_thread_->IsCurrent());
	CritScope lock(&cs_);
	if (!channel_) {
	LOG_F(LS_WARNING) << "NULL channel";
	return;
	}
	ASSERT(channel == channel_);
	if (!tcp_) {
	LOG_F(LS_WARNING) << "NULL tcp";
	return;
	}

	uint16 mtu = 1280; // safe default
	talk_base::scoped_ptr<Socket> mtu_socket(
	worker_thread_->socketserver()->CreateSocket(SOCK_DGRAM));
	if (mtu_socket->Connect(candidate.address()) < 0 \|\|
	mtu_socket->EstimateMTU(&mtu) < 0) {
	LOG_F(LS_WARNING) << "Failed to estimate MTU, error="
	<< mtu_socket->GetError();
	}

	LOG_F(LS_VERBOSE) << "Using MTU of " << mtu << " bytes";
	tcp_->NotifyMTU(mtu);
	AdjustClock();
	}

	void PseudoTcpChannel::OnTcpOpen(PseudoTcp* tcp) {
	LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(worker_thread_->IsCurrent());
	ASSERT(tcp == tcp_);
	if (stream_) {
	stream_readable_ = true;
	pending_read_event_ = true;
	stream_thread_->Post(this, MSG_ST_EVENT,
	new EventData(SE_OPEN \| SE_READ \| SE_WRITE));
	}
	}

	void PseudoTcpChannel::OnTcpReadable(PseudoTcp* tcp) {
	//LOG_F(LS_VERBOSE);
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(worker_thread_->IsCurrent());
	ASSERT(tcp == tcp_);
	if (stream_) {
	stream_readable_ = true;
	if (!pending_read_event_) {
	pending_read_event_ = true;
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_READ));
	}
	}
	}

	void PseudoTcpChannel::OnTcpWriteable(PseudoTcp* tcp) {
	//LOG_F(LS_VERBOSE);
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(worker_thread_->IsCurrent());
	ASSERT(tcp == tcp_);
	if (stream_)
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_WRITE));
	}

	void PseudoTcpChannel::OnTcpClosed(PseudoTcp* tcp, uint32 nError) {
	LOG_F(LS_VERBOSE) << "[" << channel_name_ << "]";
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(worker_thread_->IsCurrent());
	ASSERT(tcp == tcp_);
	if (stream_)
	stream_thread_->Post(this, MSG_ST_EVENT, new EventData(SE_CLOSE, nError));
	}

	//
	// Multi-thread methods
	//

	void PseudoTcpChannel::OnMessage(Message* pmsg) {
	if (pmsg->message_id == MSG_WK_CLOCK) {

	ASSERT(worker_thread_->IsCurrent());
	//LOG(LS_INFO) << "PseudoTcpChannel::OnMessage(MSG_WK_CLOCK)";
	CritScope lock(&cs_);
	if (tcp_) {
	tcp_->NotifyClock(PseudoTcp::Now());
	AdjustClock(false);
	}

	} else if (pmsg->message_id == MSG_WK_PURGE) {

	ASSERT(worker_thread_->IsCurrent());
	LOG_F(LS_INFO) << "(MSG_WK_PURGE)";
	// At this point, we know there are no additional worker thread messages.
	CritScope lock(&cs_);
	ASSERT(NULL == session_);
	ASSERT(NULL == channel_);
	worker_thread_ = NULL;
	CheckDestroy();

	} else if (pmsg->message_id == MSG_ST_EVENT) {

	ASSERT(stream_thread_->IsCurrent());
	//LOG(LS_INFO) << "PseudoTcpChannel::OnMessage(MSG_ST_EVENT, "
	// << data->event << ", " << data->error << ")";
	ASSERT(stream_ != NULL);
	EventData* data = static_cast<EventData*>(pmsg->pdata);
	if (data->event & SE_READ) {
	CritScope lock(&cs_);
	pending_read_event_ = false;
	}
	stream_->SignalEvent(stream_, data->event, data->error);
	delete data;

	} else if (pmsg->message_id == MSG_SI_DESTROYCHANNEL) {

	ASSERT(signal_thread_->IsCurrent());
	LOG_F(LS_INFO) << "(MSG_SI_DESTROYCHANNEL)";
	ASSERT(session_ != NULL);
	ASSERT(channel_ != NULL);
	session_->DestroyChannel(content_name_, channel_->name());

	} else if (pmsg->message_id == MSG_SI_DESTROY) {

	ASSERT(signal_thread_->IsCurrent());
	LOG_F(LS_INFO) << "(MSG_SI_DESTROY)";
	// The message queue is empty, so it is safe to destroy ourselves.
	delete this;

	} else {
	ASSERT(false);
	}
	}

	IPseudoTcpNotify::WriteResult PseudoTcpChannel::TcpWritePacket(
	PseudoTcp* tcp, const char* buffer, size_t len) {
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(tcp == tcp_);
	ASSERT(NULL != channel_);
	int sent = channel_->SendPacket(buffer, len);
	if (sent > 0) {
	//LOG_F(LS_VERBOSE) << "(" << sent << ") Sent";
	return IPseudoTcpNotify::WR_SUCCESS;
	} else if (IsBlockingError(channel_->GetError())) {
	LOG_F(LS_VERBOSE) << "Blocking";
	return IPseudoTcpNotify::WR_SUCCESS;
	} else if (channel_->GetError() == EMSGSIZE) {
	LOG_F(LS_ERROR) << "EMSGSIZE";
	return IPseudoTcpNotify::WR_TOO_LARGE;
	} else {
	PLOG(LS_ERROR, channel_->GetError()) << "PseudoTcpChannel::TcpWritePacket";
	ASSERT(false);
	return IPseudoTcpNotify::WR_FAIL;
	}
	}

	void PseudoTcpChannel::AdjustClock(bool clear) {
	ASSERT(cs_.CurrentThreadIsOwner());
	ASSERT(NULL != tcp_);

	long timeout = 0;
	if (tcp_->GetNextClock(PseudoTcp::Now(), timeout)) {
	ASSERT(NULL != channel_);
	// Reset the next clock, by clearing the old and setting a new one.
	if (clear)
	worker_thread_->Clear(this, MSG_WK_CLOCK);
	worker_thread_->PostDelayed(_max(timeout, 0L), this, MSG_WK_CLOCK);
	return;
	}

	delete tcp_;
	tcp_ = NULL;
	ready_to_connect_ = false;

	if (channel_) {
	// If TCP has failed, no need for channel_ anymore
	signal_thread_->Post(this, MSG_SI_DESTROYCHANNEL);
	}
	}

	void PseudoTcpChannel::CheckDestroy() {
	ASSERT(cs_.CurrentThreadIsOwner());
	if ((worker_thread_ != NULL) \|\| (stream_ != NULL))
	return;
	signal_thread_->Post(this, MSG_SI_DESTROY);
	}

	///////////////////////////////////////////////////////////////////////////////
	// PseudoTcpChannel::InternalStream
	///////////////////////////////////////////////////////////////////////////////

	PseudoTcpChannel::InternalStream::InternalStream(PseudoTcpChannel* parent)
	: parent_(parent) {
	}

	PseudoTcpChannel::InternalStream::~InternalStream() {
	Close();
	}

	StreamState PseudoTcpChannel::InternalStream::GetState() const {
	if (!parent_)
	return SS_CLOSED;
	return parent_->GetState();
	}

	StreamResult PseudoTcpChannel::InternalStream::Read(
	void* buffer, size_t buffer_len, size_t* read, int* error) {
	if (!parent_) {
	if (error)
	*error = ENOTCONN;
	return SR_ERROR;
	}
	return parent_->Read(buffer, buffer_len, read, error);
	}

	StreamResult PseudoTcpChannel::InternalStream::Write(
	const void* data, size_t data_len, size_t* written, int* error) {
	if (!parent_) {
	if (error)
	*error = ENOTCONN;
	return SR_ERROR;
	}
	return parent_->Write(data, data_len, written, error);
	}

	void PseudoTcpChannel::InternalStream::Close() {
	if (!parent_)
	return;
	parent_->Close();
	parent_ = NULL;
	}

	///////////////////////////////////////////////////////////////////////////////

	} // namespace cricket