path: root/utils/vmpi/ThreadedTCPSocket.cpp

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
// $NoKeywords: $
//
//=============================================================================//
// ThreadedTCPSocket.cpp : Defines the entry point for the console application.
//

#include <winsock2.h>
#include <mswsock.h>
#include "IThreadedTCPSocket.h"
#include "utllinkedlist.h"
#include "threadhelpers.h"
#include "iphelpers.h"
#include "tier1/strtools.h"


#define SEND_KEEPALIVE_INTERVAL	3000
#define KEEPALIVE_TIMEOUT		25000	// The sockets timeout after this long.

#define KEEPALIVE_SENTINEL		-12345	// When first 4 bytes of a packet = this, then it's just a keepalive.


static int g_KeepaliveSentinel = KEEPALIVE_SENTINEL;
bool g_bHandleTimeouts = true;

// If true, it'll set the socket thread priorities lower than normal.
bool g_bSetTCPSocketThreadPriorities = true;

// We get crashes at runtime if they don't link in the multithreaded runtime libraries,
// so raise a ruckus if they're using singlethreaded libraries.
#ifndef _MT
	#pragma message( "**** WARNING **** ThreadedTCPSocket requires multithreaded runtime libraries to be used.\n" )
	class MTChecker
	{
	public:
		MTChecker() { Assert( false ); }
	} g_MTChecker;
#endif



// ------------------------------------------------------------------------------------------------ //
// Static helpers.
// ------------------------------------------------------------------------------------------------ //
static SOCKET TCPBind( const CIPAddr *pAddr )
{
	// Create a socket to send and receive through.
	SOCKET sock = WSASocket( AF_INET, SOCK_STREAM, IPPROTO_TCP, NULL, 0, WSA_FLAG_OVERLAPPED );
	if ( sock == INVALID_SOCKET )
	{
		Assert( false );
		return INVALID_SOCKET;
	}

	// bind to it!
	sockaddr_in addr;
	IPAddrToSockAddr( pAddr, &addr );

	int status = bind( sock, (sockaddr*)&addr, sizeof(addr) );
	if ( status == 0 )
	{
		return sock;
	}
	else
	{
		closesocket( sock );
		return INVALID_SOCKET;
	}
}



// ------------------------------------------------------------------------------------------------ //
// CTCPPacket.
// ------------------------------------------------------------------------------------------------ //

int CTCPPacket::GetUserData() const
{
	return m_UserData;
}

void CTCPPacket::SetUserData( int userData )
{
	m_UserData = userData;
}

void CTCPPacket::Release()
{
	free( this );
}


// ------------------------------------------------------------------------------------------------ //
// CThreadedTCPSocket.
// ------------------------------------------------------------------------------------------------ //
class CThreadedTCPSocket : public IThreadedTCPSocket
{
public:
	
	static IThreadedTCPSocket* Create( SOCKET iSocket, CIPAddr remoteAddr, ITCPSocketHandler *pHandler )
	{
		CThreadedTCPSocket *pRet = new CThreadedTCPSocket;
		if ( pRet->Init( iSocket, remoteAddr, pHandler ) )
		{
			return pRet;
		}
		else
		{
			pRet->Release();
			return NULL;
		}
	}


// IThreadedTCPSocket implementation.
public:

	virtual void Release()
	{
		delete this;
	}

	virtual CIPAddr GetRemoteAddr() const
	{
		return m_RemoteAddr;
	}

	virtual bool IsValid()
	{
		return !CheckErrorSignal();
	}

	virtual bool Send( const void *pData, int len )
	{
		const void *pChunks[1] = { pData };
		return SendChunks( pChunks, &len, 1 );
	}

	virtual bool SendChunks( void const * const *pChunks, const int *pChunkLengths, int nChunks )
	{
		if ( CheckErrorSignal() )
			return false;

		return InternalSend( pChunks, pChunkLengths, nChunks, true );
	}


// Initialization.
private:

	CThreadedTCPSocket()
	{
		m_Socket = INVALID_SOCKET;
		m_pHandler = NULL;
		memset( &m_SendOverlapped, 0, sizeof( m_SendOverlapped ) );
		memset( &m_RecvOverlapped, 0, sizeof( m_RecvOverlapped ) );
		m_bWaitingForSendCompletion = false;
		m_nBytesToReceive = -1;
		m_bWaitingForSize = false;
		m_bErrorSignal = false;
		m_pRecvBuffer = NULL;
	}

	virtual ~CThreadedTCPSocket()
	{
		Term();
	}

	bool Init( SOCKET iSocket, CIPAddr remoteAddr, ITCPSocketHandler *pHandler )
	{
		m_Socket = iSocket;
		m_RemoteAddr = remoteAddr;
		m_pHandler = pHandler;

		SetInitialSocketOptions();

		// Create all the event objects we'll use to communicate.
		m_hExitThreadsEvent.Init( true, false );
		m_hSendCompletionEvent.Init( false, false );
		m_hReadyToSendEvent.Init( false, false );
		m_hRecvEvent.Init( false, false );

		m_SendOverlapped.hEvent = m_hSendCompletionEvent.GetEventHandle();
		m_RecvOverlapped.hEvent = m_hRecvEvent.GetEventHandle();

		// Create our threads.
		DWORD dwSendThreadID, dwRecvThreadID;
		m_hSendThread = CreateThread( NULL, 0, &CThreadedTCPSocket::StaticSendThreadFn, this, CREATE_SUSPENDED, &dwSendThreadID );
		m_hRecvThread = CreateThread( NULL, 0, &CThreadedTCPSocket::StaticRecvThreadFn, this, CREATE_SUSPENDED, &dwRecvThreadID );
		if ( !m_hSendThread || !m_hRecvThread )
		{
			return false;
		}

		if ( g_bSetTCPSocketThreadPriorities )
		{
			SetThreadPriority( m_hSendThread, THREAD_PRIORITY_LOWEST );
			SetThreadPriority( m_hRecvThread, THREAD_PRIORITY_LOWEST );
		}
		
		ThreadSetDebugName( (ThreadId_t)dwSendThreadID, "TCPSend" );
		ThreadSetDebugName( (ThreadId_t)dwRecvThreadID, "TCPRecv" );

		// Make sure to init the handler before the threads actually run, so it isn't handed data before initializing.
		m_pHandler->Init( this );

		ResumeThread( m_hSendThread );
		ResumeThread( m_hRecvThread );

		return true;
	}

	void Term()
	{
		// Signal our threads to exit.
		m_hExitThreadsEvent.SetEvent();
		if ( m_hSendThread )
		{
			WaitForSingleObject( m_hSendThread, INFINITE );
			CloseHandle( m_hSendThread );
			m_hSendThread = NULL;
		}
		
		if ( m_hRecvThread )
		{
			WaitForSingleObject( m_hRecvThread, INFINITE );
			CloseHandle( m_hRecvThread );
			m_hRecvThread = NULL;
		}
		m_hExitThreadsEvent.ResetEvent();


		if ( m_Socket != INVALID_SOCKET )
		{
			closesocket( m_Socket );
			m_Socket = INVALID_SOCKET;
		}
	}

	// Set the initial socket options that we want.
	void SetInitialSocketOptions()
	{
		// Set nodelay to improve latency.
		BOOL val = TRUE;
		setsockopt( m_Socket, IPPROTO_TCP, TCP_NODELAY, (const char FAR *)&val, sizeof(BOOL) );

		// Make it linger for 3 seconds when it exits.
		LINGER linger;
		linger.l_onoff = 1;
		linger.l_linger = 3;
		setsockopt( m_Socket, SOL_SOCKET, SO_LINGER, (char*)&linger, sizeof( linger ) );
	}


// Send thread functionality.
private:

	// This function copies off the payload and adds a SendChunk_t to the list of chunks to be sent.
	// It also fires the ReadyToSend event so the thread will pick it up.
	bool InternalSend( void const * const *pChunks, const int *pChunkLengths, int nChunks, bool bPrependLength )
	{
		int totalLength = 0;
		for ( int i=0; i < nChunks; i++ )
			totalLength += pChunkLengths[i];

		if ( bPrependLength )
		{
			if ( totalLength == 0 )
				return true;

			totalLength += 4;
		}

		// Copy all the data into a SendData_t.
		SendData_t *pSendData = (SendData_t*)malloc( sizeof( SendData_t ) - 1 + totalLength );
		pSendData->m_Len = totalLength;

		char *pOut = pSendData->m_Payload;
		if ( bPrependLength )
		{
			*((int*)pOut) = totalLength - 4;	// The length we prepend is the size of the data, not data size + integer for length.
			pOut += 4;
		}
		for ( int i=0; i < nChunks; i++ )
		{
			memcpy( pOut, pChunks[i], pChunkLengths[i] );
			pOut += pChunkLengths[i];
		}

		CCriticalSectionLock csLock( &m_SendCS );
		csLock.Lock();
			
			m_SendDatas.AddToTail( pSendData );
			m_hReadyToSendEvent.SetEvent(); // Notify the thread that there is data to send.
		
		csLock.Unlock();

		return true;
	}

	void SendThread_HandleTimeout()
	{
		// Timeout.. send a keepalive.			
		// But only if we're not already sending something.
		CCriticalSectionLock csLock( &m_SendCS );
		csLock.Lock();
			int count = m_SendDatas.Count();
		csLock.Unlock();

		if ( count == 0 )
		{
			void *pBuf[1] = { &g_KeepaliveSentinel };
			int len[1] = { sizeof( g_KeepaliveSentinel ) };
			InternalSend( pBuf, len, 1, false );
		}
	}

	bool SendThread_HandleSendCompletionEvent()
	{
		Assert( m_bWaitingForSendCompletion );
		m_bWaitingForSendCompletion = false;

		// A send operation just completed. Now do the next one.
		DWORD cbTransfer, flags;
		if ( !WSAGetOverlappedResult( m_Socket, &m_SendOverlapped, &cbTransfer, TRUE, &flags ) )
		{
			HandleError( WSAGetLastError() );
			return false;
		}

		if ( cbTransfer != m_nBytesToTransfer )
		{
			char str[512];
			Q_snprintf( str, sizeof( str ), "Invalid # bytes transferred (%d) in send thread (should be %d)", cbTransfer, m_nBytesToTransfer );
			HandleError( ITCPSocketHandler::SocketError, str );
			return false;
		}

		// Remove the block we just sent.
		CCriticalSectionLock csLock( &m_SendCS );
		csLock.Lock();

			SendData_t *pSendData = m_SendDatas[ m_SendDatas.Head() ];
			free( pSendData );
			m_SendDatas.Remove( m_SendDatas.Head() );
			
			m_bWaitingForSendCompletion = false;
			
			// Set our send event if there's anything else to send.
			if ( m_SendDatas.Count() > 0 )
				m_hReadyToSendEvent.SetEvent();

		csLock.Unlock();
		return true;
	}

	bool SendThread_HandleReadyToSendEvent()
	{
		// We've got at least one buffer that's ready to be sent.
		// NOTE: don't send anything until our current send is completed.
		CCriticalSectionLock csLock( &m_SendCS );
		csLock.Lock();
			
		Assert( !m_bWaitingForSendCompletion );

		// Send it off!
		SendData_t *pSendData = m_SendDatas[ m_SendDatas.Head() ];
		WSABUF buf = { pSendData->m_Len, pSendData->m_Payload };

		m_nBytesToTransfer = pSendData->m_Len;
		m_bWaitingForSendCompletion = true;
		
		csLock.Unlock();

		DWORD dwNumBytesSent = 0;
		DWORD ret = WSASend( m_Socket, &buf, 1, &dwNumBytesSent, 0, &m_SendOverlapped, NULL );
		DWORD err = WSAGetLastError();
		if ( ret == 0 || ( ret == SOCKET_ERROR && err == WSA_IO_PENDING ) )
		{
			// Either way, the operation completed successfully, and m_hSendCompletionEvent is now set.
			return true;
		}
		else 
		{
			HandleError( err );
			return false;
		}

		return true;
	}
	
	DWORD SendThreadFn()
	{
		while ( 1 )
		{
			HANDLE handles[]  =
			{
				m_hExitThreadsEvent.GetEventHandle(),
				m_hSendCompletionEvent.GetEventHandle(),
				m_hReadyToSendEvent.GetEventHandle()
			};
			int nHandles = ARRAYSIZE( handles );
			
			// While waiting for send completion, don't handle "ready to send" events.
			if ( m_bWaitingForSendCompletion )
				--nHandles;

			DWORD waitValue = WaitForMultipleObjects( nHandles, handles, FALSE, SEND_KEEPALIVE_INTERVAL );
			switch ( waitValue )
			{
				case WAIT_TIMEOUT:
				{
					if ( g_bHandleTimeouts )
					{
						// We haven't sent anything in a bit. Send out a keepalive.
						SendThread_HandleTimeout();
					}
				}
				break;

				case WAIT_OBJECT_0:
				{
					// The main thread is signaling us to exit.
					return 0;
				}

				case WAIT_OBJECT_0 + 1:
				{
					if ( !SendThread_HandleSendCompletionEvent() )
						return 1;
				}
				break;
			
				case WAIT_OBJECT_0 + 2:
				{
					if ( !SendThread_HandleReadyToSendEvent() )
						return 1;
				}
				break;

				case WAIT_FAILED:
				{
					// Uh oh. We're dead. Cleanup and signal an error.
					HandleError( GetLastError() );
					return 1;
				}

				default:
				{
					char str[512];
					Q_snprintf( str, sizeof( str ), "Unknown return value (%lu) from WaitForMultipleObjects", waitValue );
					HandleError( ITCPSocketHandler::SocketError, str );
					return 0;
				}
			}
		}

		return 0;
	}

	static DWORD WINAPI StaticSendThreadFn( LPVOID pParameter )
	{
		return ((CThreadedTCPSocket*)pParameter)->SendThreadFn();
	}


// Receive thread functionality.
private:

	bool RecvThread_WaitToReceiveSize()
	{
		return RecvThread_InternalRecv( &m_NextPacketLen, sizeof( m_NextPacketLen ), false, true );
	}


	bool RecvThread_InternalHandleRecvCompletion( DWORD dwTransfer )
	{
		int cbTransfer = (int)dwTransfer;
		int nBytesWanted = m_nBytesToReceive - m_nBytesReceivedSoFar;
		if ( cbTransfer > nBytesWanted )
		{
			char str[512];
			Q_snprintf( str, sizeof( str ), "Invalid # bytes received (%d) in recv thread (should be %d)", cbTransfer, m_nBytesToReceive );
			HandleError( ITCPSocketHandler::SocketError, str );
			return false;
		}
		else if ( cbTransfer < nBytesWanted )
		{
			// We have to reissue the receive command because it didn't receive all the data.
			m_nBytesReceivedSoFar += cbTransfer;
			
			char *pDest = (char*)&m_NextPacketLen;
			if ( !m_bWaitingForSize )
			{
				Assert( m_pRecvBuffer );
				pDest = m_pRecvBuffer->m_Data;
			}

			return RecvThread_InternalRecv( &pDest[m_nBytesReceivedSoFar], m_nBytesToReceive - m_nBytesReceivedSoFar, true );
		}

		if ( m_bWaitingForSize )
		{
			// If we were waiting for size, now wait for the data.
			if ( m_NextPacketLen == KEEPALIVE_SENTINEL )
			{
				// Ok, it was just a keepalive. Wait for size again.
				return RecvThread_WaitToReceiveSize();
			}
			else
			{
				if ( m_NextPacketLen < 1 || m_NextPacketLen > 1024*1024*75 )
				{
					char str[512];
					Q_snprintf( str, sizeof( str ), "Invalid packet size in RecvThread (size = %d)", m_NextPacketLen );
					HandleError( ITCPSocketHandler::SocketError, str );
					return false;
				}
				else
				{
					Assert( !m_pRecvBuffer );
					m_pRecvBuffer = (CTCPPacket*)malloc( sizeof( CTCPPacket ) - 1 + m_NextPacketLen );
					m_pRecvBuffer->m_UserData = 0;
					m_pRecvBuffer->m_Len = m_NextPacketLen;

					return RecvThread_InternalRecv( m_pRecvBuffer->m_Data, m_pRecvBuffer->m_Len, false, false );
				}					
			}
		}
		else
		{
			// Got a packet! Give it to the app.
			m_pHandler->OnPacketReceived( m_pRecvBuffer );
			m_pRecvBuffer = NULL;

			return RecvThread_WaitToReceiveSize();
		}
	}

	bool RecvThread_HandleRecvCompletionEvent()
	{
		// A send operation just completed. Now do the next one.
		DWORD cbTransfer, flags;
		if ( !WSAGetOverlappedResult( m_Socket, &m_RecvOverlapped, &cbTransfer, TRUE, &flags ) )
		{
			HandleError( WSAGetLastError() );
			return false;
		}

		return RecvThread_InternalHandleRecvCompletion( cbTransfer );
	}

	bool RecvThread_InternalRecv( void *pDest, int destSize, bool bContinuation, bool bWaitingForSize = false )
	{
		WSABUF buf = { destSize, (char*)pDest };

		if ( !bContinuation )
		{
			// If this is not a continuation of whatever we were receiving before, then 
			m_bWaitingForSize = bWaitingForSize;
			m_nBytesToReceive = destSize;
			m_nBytesReceivedSoFar = 0;
		}

		DWORD dwFlags = 0;
		DWORD nBytesReceived = 0;
		DWORD ret = WSARecv( m_Socket, &buf, 1, &nBytesReceived, &dwFlags, &m_RecvOverlapped, NULL );
		DWORD dwLastError = WSAGetLastError();
		if ( ret == 0 || ( ret == SOCKET_ERROR && dwLastError == WSA_IO_PENDING ) )
		{
			// Note: m_hRecvEvent is in a signaled state, so the RecvThread will pick up the results next time around.
			return true;
		}
		else
		{
			HandleError( dwLastError );
			return false;
		}			
	}
		

	
	DWORD RecvThreadFn()
	{
		// Start us off by setting up to receive the first packet size.
		if ( !RecvThread_WaitToReceiveSize() )
			return 1;

		HANDLE handles[] =
		{
			m_hExitThreadsEvent.GetEventHandle(),
			m_hRecvEvent.GetEventHandle()
		};

		while ( 1 )
		{
			DWORD waitValue = WaitForMultipleObjects( ARRAYSIZE( handles ), handles, FALSE, KEEPALIVE_TIMEOUT );
			switch ( waitValue )
			{
				case WAIT_TIMEOUT:
				{
					if ( g_bHandleTimeouts )
					{
						HandleError( ITCPSocketHandler::ConnectionTimedOut, "Connection timed out" );
						return 1;
					}
				}
				break;

				case WAIT_OBJECT_0:
				{
					// We're being told to exit.
					return 0;
				}

				case WAIT_OBJECT_0 + 1:
				{
					// Just finished receiving something.
					if ( !RecvThread_HandleRecvCompletionEvent() )
						return 1;
				}
				break;

				case WAIT_FAILED:
				{
					// Uh oh. We're dead. Cleanup and signal an error.
					HandleError( GetLastError() );
					return 1;
				}

				default:
				{
					char str[512];
					Q_snprintf( str, sizeof( str ), "Unknown return value (%lu) from WaitForMultipleObjects", waitValue );
					HandleError( ITCPSocketHandler::SocketError, str );
					return 1;
				}
			}
		}

		return 0;
	}

	static DWORD WINAPI StaticRecvThreadFn( LPVOID pParameter )
	{
		return ((CThreadedTCPSocket*)pParameter)->RecvThreadFn();
	}



// Error handling.
private:

	// This checks to see if either thread has signaled an error. If so, it shuts down the socket and returns true.
	bool CheckErrorSignal()
	{
		return m_bErrorSignal;
	}

	// This is called from any of the threads and signals that something went awry. It shuts down the object
	// and makes it return false from all of its functions.
	void HandleError( DWORD errorValue )
	{
		char *lpMsgBuf;
		
		FormatMessage( 
			FORMAT_MESSAGE_ALLOCATE_BUFFER | 
			FORMAT_MESSAGE_FROM_SYSTEM | 
			FORMAT_MESSAGE_IGNORE_INSERTS,
			NULL,
			GetLastError(),
			MAKELANGID(LANG_NEUTRAL, SUBLANG_DEFAULT), // Default language
			(char*)&lpMsgBuf,
			0,
			NULL 
		);
		
		// Windows likes to stick a carriage return in there and we don't want it so get rid of it.
		int len = strlen( lpMsgBuf );
		while ( len > 0 && ( lpMsgBuf[len-1] == '\n' || lpMsgBuf[len-1] == '\r' ) )
		{
			--len;
			lpMsgBuf[len] = 0;
		}

		HandleError( ITCPSocketHandler::SocketError, lpMsgBuf );

		LocalFree( lpMsgBuf );	
	}


	void HandleError( int errorCode, const char *pErrorString )
	{
		//Assert( false );
		
		// Tell the app.
		m_pHandler->OnError( errorCode, pErrorString );

		// Tell the threads to exit.
		m_hExitThreadsEvent.SetEvent();
		
		// Notify the main thread so it can call Term() when it gets a chance.
		m_bErrorSignal = true;
	}


private:

	// Data for the send thread.
	typedef struct
	{
		//WSAOVERLAPPED m_Overlapped;
		int m_Len;
		char m_Payload[1];
	} SendData_t;

	HANDLE m_hSendThread;
		WSAOVERLAPPED m_SendOverlapped;
		CEvent m_hReadyToSendEvent;
		CEvent m_hSendCompletionEvent;
		
		CCriticalSection m_SendCS;
			DWORD m_nBytesToTransfer;
			bool m_bWaitingForSendCompletion;
			CUtlLinkedList<SendData_t*, int> m_SendDatas;	// Added to the tail, popped off the head for sending.


	// Data for the recv thread.
	HANDLE m_hRecvThread;
		int m_nBytesToReceive;			// This stores how many bytes we want to receive for the next packet.
		int m_nBytesReceivedSoFar;		// This stores how many bytes we've received so far.
		bool m_bWaitingForSize;			// This tells if we're trying to receive the next packet length or the next packet's data.

		int m_NextPacketLen;			// Data is received INTO here before it receives each packet. This 
										// holds the length of each incoming packet.

		WSAOVERLAPPED m_RecvOverlapped;
		CEvent m_hRecvEvent;
		CTCPPacket *m_pRecvBuffer;		// This is allocated for each packet we're receiving and given to the
										// app when the packet is done being received.

	
	volatile bool m_bErrorSignal;

	
	CEvent m_hExitThreadsEvent;

	ITCPSocketHandler *m_pHandler;

	SOCKET m_Socket;
	CIPAddr m_RemoteAddr;
};


// ------------------------------------------------------------------------------------------------ //
// CTCPConnectSocket_Listener
// ------------------------------------------------------------------------------------------------ //
class CTCPConnectSocket_Listener : public ITCPConnectSocket
{
public:
						CTCPConnectSocket_Listener()
						{
							m_Socket = INVALID_SOCKET;
						}


	virtual				~CTCPConnectSocket_Listener()
	{
		if ( m_Socket != INVALID_SOCKET )
		{
			closesocket( m_Socket );
		}
	}	


	// The main function to create one of these suckers.
	static ITCPConnectSocket* Create( 
		IHandlerCreator *pHandlerCreator,
		const unsigned short port,
		int nQueueLength
		)
	{
		CTCPConnectSocket_Listener *pRet = new CTCPConnectSocket_Listener;
		if ( !pRet )
			return NULL;

		if ( nQueueLength < 0 )
		{
			Error( "CTCPConnectSocket_Listener::Create - SOMAXCONN not allowed - causes some XP SP2 systems to stop receiving any network data (systemwide)." );
		}

		// Bind it to a socket and start listening.
		CIPAddr addr( 0, 0, 0, 0, port ); // INADDR_ANY
		pRet->m_Socket = TCPBind( &addr );
		if ( pRet->m_Socket == INVALID_SOCKET || 
			listen( pRet->m_Socket, nQueueLength == -1 ? SOMAXCONN : nQueueLength ) != 0 )
		{
			pRet->Release();
			return false;
		}

		pRet->m_pHandler = pHandlerCreator;
		return pRet;
	}


// ITCPConnectSocket implementation.
public:

	virtual void Release()
	{
		delete this;
	}
	
	virtual bool Update( IThreadedTCPSocket **pSocket, unsigned long milliseconds )
	{
		*pSocket = NULL;
		if ( m_Socket == INVALID_SOCKET )
			return false;

		// We're still ok.. just wait until the socket becomes writable (is connected) or we timeout.
		fd_set readSet;
		readSet.fd_count = 1;
		readSet.fd_array[0] = m_Socket;
		TIMEVAL timeVal = {0, milliseconds*1000};

		// Wait until it connects.
		int status = select( 0, &readSet, NULL, NULL, &timeVal );
		if ( status > 0 )
		{
			sockaddr_in addr;
			int addrSize = sizeof( addr );

			// Now accept the final connection.
			SOCKET newSock = accept( m_Socket, (struct sockaddr*)&addr, &addrSize );
			if ( newSock == INVALID_SOCKET )
			{
				Assert( false );
				return true;
			}
			else
			{
				CIPAddr connectedAddr;
				SockAddrToIPAddr( &addr, &connectedAddr );

				IThreadedTCPSocket *pRet = CThreadedTCPSocket::Create( newSock, connectedAddr, m_pHandler->CreateNewHandler() );
				if ( !pRet )
				{
					Assert( false );
					closesocket( m_Socket );
					m_Socket = INVALID_SOCKET;
					return false;
				}

				*pSocket = pRet;
				return true;
			}
		}
		else if ( status == SOCKET_ERROR )
		{
			closesocket( m_Socket );
			m_Socket = INVALID_SOCKET;
			return false;
		}
		else
		{
			return true;
		}
	}


private:
	SOCKET m_Socket;	
	
	IHandlerCreator *m_pHandler;
};	



ITCPConnectSocket* ThreadedTCP_CreateListener( 
	IHandlerCreator *pHandlerCreator,
	const unsigned short port,
	int nQueueLength
	)
{
	return CTCPConnectSocket_Listener::Create( pHandlerCreator, port, nQueueLength );
}



// ------------------------------------------------------------------------------------------------ //
// CTCPConnectSocket_Connector
// ------------------------------------------------------------------------------------------------ //
class CTCPConnectSocket_Connector : public ITCPConnectSocket
{
public:
	
	CTCPConnectSocket_Connector()
	{
		m_bConnected = false;
		m_Socket = INVALID_SOCKET;
		m_bError = false;
	}

	virtual ~CTCPConnectSocket_Connector()
	{
		if ( m_Socket != INVALID_SOCKET )
		{
			closesocket( m_Socket );
		}
	}

	static ITCPConnectSocket* Create(
		const CIPAddr &connectAddr,
		const CIPAddr &localAddr,
		IHandlerCreator *pHandlerCreator
		)
	{
		CTCPConnectSocket_Connector *pRet = new CTCPConnectSocket_Connector;
	
		pRet->m_Socket = TCPBind( &localAddr );
		if ( pRet->m_Socket == INVALID_SOCKET )
		{
			pRet->Release();
			return NULL;
		}

		sockaddr_in addr;
		IPAddrToSockAddr( &connectAddr, &addr );

		// We don't want the connect() call to block.
		DWORD val = 1;	   
		int status = ioctlsocket( pRet->m_Socket, FIONBIO, &val );
		if ( status != 0 )
		{
			Assert( false );
			pRet->Release();
			return NULL;
		}

		pRet->m_RemoteAddr = connectAddr;
		pRet->m_pHandlerCreator = pHandlerCreator;

		int ret = connect( pRet->m_Socket, (struct sockaddr*)&addr, sizeof( addr ) );
		if ( ret == 0 )
		{
			pRet->m_bConnected = true;
			return pRet;
		}
		else if ( ret == SOCKET_ERROR && WSAGetLastError() == WSAEWOULDBLOCK )
		{
			return pRet;
		}
		else
		{
			Assert( false );
			pRet->Release();
			return NULL;
		}		
	}	


// ITCPConnectSocket implementation.
public:

	virtual void Release()
	{
		delete this;
	}
	

	virtual bool Update( IThreadedTCPSocket **pSocket, unsigned long milliseconds )
	{
		*pSocket = NULL;

		// If we got an error previously, keep returning false.
		if ( m_bError )
			return false;

		// If this condition holds, then we already returned a valid socket and we're just waiting to be released.
		if ( m_Socket == INVALID_SOCKET )
			return true;

		// Ok, see if we're connected now.
		if ( !m_bConnected )
		{
			TIMEVAL timeVal = { 0, milliseconds*1000 };
			
			fd_set writeSet;
			writeSet.fd_count = 1;
			writeSet.fd_array[0] = m_Socket;

			int ret = select( 0, NULL, &writeSet, NULL, &timeVal );
			if ( ret > 0 )
			{
				m_bConnected = true;
			}
			else if ( ret == SOCKET_ERROR )
			{
				return EnterErrorMode();
			}
		}

		if ( m_bConnected )
		{
			// Ok, return a connected socket for them.
			
			// Make our socket blocking again.
			DWORD val = 0;
			int status = ioctlsocket( m_Socket, FIONBIO, &val );
			if ( status != 0 )
			{
				Assert( false );
				m_bError = true;
				closesocket( m_Socket );
				m_Socket = INVALID_SOCKET;
				return false;
			}

			IThreadedTCPSocket *pRet = CThreadedTCPSocket::Create( m_Socket, m_RemoteAddr, m_pHandlerCreator->CreateNewHandler() );
			if ( pRet )
			{
				m_Socket = INVALID_SOCKET;
				*pSocket = pRet;
				return true;
			}
			else
			{
				return EnterErrorMode();
			}
		}
		else
		{
			// Still waiting..
			return true;
		}
	}

	// Shutdown the socket and start returning false from Update().
	bool EnterErrorMode()
	{
		Assert( false );
		m_bError = true;
		closesocket( m_Socket );
		m_Socket = INVALID_SOCKET;
		return false;
	}


private:
	
	bool m_bError;
	bool m_bConnected;

	SOCKET m_Socket;
	CIPAddr m_RemoteAddr;

	IHandlerCreator *m_pHandlerCreator;
};


ITCPConnectSocket* ThreadedTCP_CreateConnector( 
	const CIPAddr &addr,
	const CIPAddr &localAddr,
	IHandlerCreator *pHandlerCreator
	)
{
	return CTCPConnectSocket_Connector::Create( addr, localAddr, pHandlerCreator );
}


void ThreadedTCP_EnableTimeouts( bool bEnable )
{
	g_bHandleTimeouts = bEnable;
}


void ThreadedTCP_SetTCPSocketThreadPriorities( bool bSetTCPSocketThreadPriorities )
{
	g_bSetTCPSocketThreadPriorities = bSetTCPSocketThreadPriorities;
}