/*++ Copyright (c) 1999-2000 Microsoft Corporation Module Name: rdsaddin.cpp Abstract: The TSRDP Assistant Session VC Add-In is an executable that is loaded in the session that is created when the TSRDP client plug-in first logs in to the server machine. It acts, primarily, as a proxy between the client VC interface and the Remote Desktop Host COM Object. Channel data is routed from the TSRDP Assistant Session VC Add-In to the Remote Desktop Host COM Object using a named pipe that is created by the Remote Desktop Host COM Object when it enters "listen" mode. In addition to its duties as a proxy, the Add-In also manages a control channel between the client and the server. This control channel is used by the client-side to direct the server side to initiate remote control of the end user's TS session. TODO: We should make the pipe IO synchronous since we now have two IO threads. Author: Tad Brockway 02/00 Revision History: --*/ #ifdef TRC_FILE #undef TRC_FILE #endif #define TRC_FILE "_sesa" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /////////////////////////////////////////////////////// // // Defines // #define CLIENTPIPE_CONNECTTIMEOUT (20 * 1000) // 20 seconds. #define VCBUFFER_RESIZE_DELTA CHANNEL_CHUNK_LENGTH #define RDS_CHECKCONN_TIMEOUT (30 * 1000) //millisec. default value to ping is 30 seconds #define RDC_CONNCHECK_ENTRY L"ConnectionCheck" #define THREADSHUTDOWN_WAITTIMEOUT 30 * 1000 /////////////////////////////////////////////////////// // // Typedefs // typedef struct _IOBuffer { PREMOTEDESKTOP_CHANNELBUFHEADER buffer; DWORD bufSize; DWORD offset; } IOBUFFER; /////////////////////////////////////////////////////// // // Internal Prototypes // DWORD ReturnResultToClient( LONG result ); VOID RemoteControlDesktop( BSTR parms ); BOOL ClientVersionCompatible( DWORD dwMajor, DWORD dwMinor ); VOID ClientAuthenticate( BSTR parms, BSTR blob ); DWORD ProcessControlChannelRequest( IOBUFFER &msg ); DWORD SendMsgToClient( PREMOTEDESKTOP_CHANNELBUFHEADER msg ); VOID HandleVCReadComplete( HANDLE waitableObject, PVOID clientData ); DWORD HandleReceivedVCMsg( IOBUFFER &msg ); VOID HandleVCClientConnect( HANDLE waitableObject, PVOID clientData ); VOID HandleVCClientDisconnect( HANDLE waitableObject, PVOID clientData ); VOID HandleNamedPipeReadComplete( OVERLAPPED &incomingPipeOL, IOBUFFER &incomingPipeBuf ); VOID HandleReceivedPipeMsg( IOBUFFER &msg ); DWORD ConnectVC(); DWORD ConnectClientSessionPipe(); DWORD IssueVCOverlappedRead( IOBUFFER &msg, OVERLAPPED &ol ); DWORD IssueNamedPipeOverlappedRead( IOBUFFER &msg, OVERLAPPED &ol ); void __cdecl NamedPipeReadThread( void* ptr ); VOID WakeUpFunc( HANDLE waitableObject, PVOID clientData ); VOID HandleHelpCenterExit( HANDLE waitableObject, PVOID clientData ); DWORD SendNullDataToClient( ); BOOL GetDwordFromRegistry(PDWORD pdwValue); /////////////////////////////////////////////////////// // // Globals to this Module // CComBSTR g_bstrCmdLineHelpSessionId; WTBLOBJMGR g_WaitObjMgr = NULL; BOOL g_Shutdown = FALSE; HANDLE g_VCHandle = NULL; HANDLE g_ProcHandle = NULL; DWORD g_SessionID = 0; HANDLE g_ProcToken = NULL; HANDLE g_WakeUpForegroundThreadEvent = NULL; DWORD g_PrevTimer = 0; DWORD g_dwTimeOutInterval = 0; HANDLE g_ShutdownEvent = NULL; HANDLE g_RemoteControlDesktopThread = NULL; HANDLE g_NamedPipeReadThread = NULL; HANDLE g_NamedPipeWriteEvent = NULL; // // VC Globals // HANDLE g_ClientIsconnectEvent = NULL; HANDLE g_VCFileHandle = NULL; OVERLAPPED g_VCReadOverlapped = { 0, 0, 0, 0, NULL }; BOOL g_ClientConnected = FALSE; // // Client Session Information // LONG g_ClientSessionID = -1; HANDLE g_ClientSessionPipe = NULL; // // True if the client has been successfully authenticated. // BOOL g_ClientAuthenticated = FALSE; // // Incoming Virtual Channel Buf. // IOBUFFER g_IncomingVCBuf = { NULL, 0, 0 }; // // Global help session manager object, this need to be // global so that when process exit, object destructor // can inform resolver about the disconnect // CComPtr g_HelpSessionManager; // // Help Session Identifier for the Current Client Connection // CComBSTR g_HelpSessionID; // // Client (expert side) rdchost major version // DWORD g_ClientMajor; DWORD g_ClientMinor; // // Handle to Help Center : B2 blocker workaround for BUG:342742 // HANDLE g_hHelpCenterProcess = NULL; //------------------------------------------------------------------ BOOL WINAPI ControlHandler( IN DWORD dwCtrlType ) /*++ Abstract: Parameter: IN dwCtrlType : control type Return: ++*/ { switch( dwCtrlType ) { case CTRL_BREAK_EVENT: // use Ctrl+C or Ctrl+Break to simulate case CTRL_C_EVENT: // SERVICE_CONTROL_STOP in debug mode case CTRL_CLOSE_EVENT: case CTRL_LOGOFF_EVENT: case CTRL_SHUTDOWN_EVENT: SetEvent( g_ShutdownEvent ); g_Shutdown = TRUE; return TRUE; } return FALSE; } DWORD ReturnResultToClient( LONG clientResult ) /*++ Routine Description: Return a result code to the client in the form of a REMOTEDESKTOP_RC_CONTROL_CHANNEL channel REMOTEDESKTOP_CTL_RESULT message. Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error code is returned. --*/ { DC_BEGIN_FN("ReturnResultToClient"); DWORD result; REMOTEDESKTOP_CTL_RESULT_PACKET msg; memcpy(msg.packetHeader.channelName, REMOTEDESKTOP_RC_CONTROL_CHANNEL, sizeof(REMOTEDESKTOP_RC_CONTROL_CHANNEL)); msg.packetHeader.channelBufHeader.channelNameLen = REMOTEDESKTOP_RC_CHANNELNAME_LENGTH; #ifdef USE_MAGICNO msg.packetHeader.channelBufHeader.magicNo = CHANNELBUF_MAGICNO; #endif msg.packetHeader.channelBufHeader.dataLen = sizeof(REMOTEDESKTOP_CTL_RESULT_PACKET) - sizeof(REMOTEDESKTOP_CTL_PACKETHEADER); msg.msgHeader.msgType = REMOTEDESKTOP_CTL_RESULT; msg.result = clientResult; result = SendMsgToClient((PREMOTEDESKTOP_CHANNELBUFHEADER )&msg); DC_END_FN(); return result; } void __cdecl RemoteControlDesktopThread( void* ptr ) /*++ Routine Description: Thread func for Remote Control Arguments: Return Value: This function returns a status back to the Salem client when shadow terminates. It is only allowed to return error codes that are prefixed by SAFERROR_SHADOWEND --*/ { BSTR parms = (BSTR) ptr; DC_BEGIN_FN("RemoteControlDesktopThread"); CComPtr helpSessionManager; CComPtr helpSession; HRESULT hr; DWORD result; LONG errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; // // If we have not resolve the right user session ID // if( g_ClientSessionID == -1 ) { TRC_ALT((TB, L"Invalid user session ID %ld", g_ClientSessionID)); hr = HRESULT_FROM_WIN32(ERROR_INVALID_PASSWORD); errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; ASSERT(FALSE); goto CLEANUPANDEXIT; } CoInitialize(NULL); // // Create a new instance of helpmgr object to get around threading issue // in COM // hr = helpSessionManager.CoCreateInstance(CLSID_RemoteDesktopHelpSessionMgr); if (!SUCCEEDED(hr)) { TRC_ERR((TB, TEXT("Can't create help session manager: %08X"), hr)); // Setup issue errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; ASSERT(FALSE); goto CLEANUPANDEXIT; } // // Set the security level to impersonate. This is required by // the session manager. // hr = CoSetProxyBlanket( (IUnknown *)helpSessionManager, RPC_C_AUTHN_DEFAULT, RPC_C_AUTHZ_DEFAULT, NULL, RPC_C_AUTHN_LEVEL_DEFAULT, RPC_C_IMP_LEVEL_IMPERSONATE, NULL, EOAC_NONE ); if (!SUCCEEDED(hr)) { TRC_ERR((TB, TEXT("CoSetProxyBlanket: %08X"), hr)); ASSERT(FALSE); errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; goto CLEANUPANDEXIT; } // // Retrieve help session object for the incident // hr = helpSessionManager->RetrieveHelpSession( g_HelpSessionID, &helpSession ); if (!SUCCEEDED(hr)) { TRC_ERR((TB, L"RetrieveHelpSession: %08X", hr)); errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; goto CLEANUPANDEXIT; } // // Set shadow configuration to help session RDS setting // Console shadow always reset shadow class back to // original value. // hr = helpSession->EnableUserSessionRdsSetting(TRUE); if( FAILED(hr) ) { TRC_ERR((TB, L"Can't set shadow setting on %ld : %08X.", hr)); errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; goto CLEANUPANDEXIT; } // // Shadow the desktop. // if (!WinStationShadow( SERVERNAME_CURRENT, NULL, //machineName, g_ClientSessionID, TSRDPREMOTEDESKTOP_SHADOWVKEY, TSRDPREMOTEDESKTOP_SHADOWVKEYMODIFIER )) { result = GetLastError(); hr = HRESULT_FROM_WIN32(result); // // Map the error code to a SAF error code. // if( result == ERROR_CTX_SHADOW_ENDED_BY_MODE_CHANGE ) { errReturnCode = SAFERROR_SHADOWEND_CONFIGCHANGE; } else { errReturnCode = SAFERROR_SHADOWEND_UNKNOWN; } } // // No need to reset g_ClientSessionID, we don't support multiple instance. // // // Inform help session object that shadow has completed, NotifyRemoteControl() // internally invoke EnableUserSessionRdsSetting(TRUE) to change // TS shadow class // No need to reset g_ClientSessionID, we don't support multiple instance. // // // Inform help session object that shadow has completed // hr = helpSession->EnableUserSessionRdsSetting( FALSE ); if (FAILED(hr)) { TRC_ERR((TB, L"Can't reset shadow setting on %ld : %08X.", g_ClientSessionID, hr)); // // not a critical error. // } CLEANUPANDEXIT: // // Send the result to the client on failure to shadow. // ReturnResultToClient(errReturnCode); CoUninitialize(); DC_END_FN(); _endthread(); } VOID RemoteControlDesktop( BSTR parms ) /*++ Routine Description: Arguments: Connection Parameters Return Value: --*/ { DC_BEGIN_FN("RemoteControlDesktop"); // // RDCHOST.DLL will not send any control message so there is no checking on // second remote control command. // g_RemoteControlDesktopThread = (HANDLE)_beginthread( RemoteControlDesktopThread, 0, (void *)parms ); if ((uintptr_t)g_RemoteControlDesktopThread == -1 ) { g_RemoteControlDesktopThread = NULL; TRC_ERR((TB, L"Failed to create RemoteControlDesktopThread for session %s - %ld", g_ClientSessionID, GetLastError())); // return error code only when // failed to spawn another thread ReturnResultToClient(SAFERROR_SHADOWEND_UNKNOWN); } DC_END_FN(); } BOOL ClientVersionCompatible( DWORD dwMajor, DWORD dwMinor ) /*++ Routine Description: Verify client (expert) version is compatible with our version. Parameters: dwMajor : Client major version. dwMinor : Client minor version. Returns: None. --*/ { // // Build 2409 or earlier (including B1 release has major version of 1 and minor version of 1 // rdchost/rdsaddin need to deal with versioning, for build 2409 or earlier, we // just make it in-compatible since we need some expert identity from rdchost.dll // #if FEATURE_USERBLOBS if( dwMajor == 1 && dwMinor == 1 ) { return FALSE; } #endif return TRUE; } VOID ClientAuthenticate( BSTR parms, BSTR blob ) /*++ Routine Description: Handle a REMOTEDESKTOP_CTL_AUTHENTICATE request from the client. Arguments: Return Value: This function will return the following results back to the client, based on the following --*/ { DC_BEGIN_FN("ClientAuthenticate"); HRESULT hr; DWORD result = ERROR_NOT_AUTHENTICATED; CComBSTR machineName; CComBSTR assistantAccount; CComBSTR assistantAccountPwd; CComBSTR helpSessionPwd; CComBSTR helpSessionName; CComBSTR protocolSpecificParms; BOOL match; DWORD protocolType; long userTSSessionID; DWORD dwVersion; LONG clientReturnCode = SAFERROR_NOERROR; if( FALSE == ClientVersionCompatible( g_ClientMajor, g_ClientMinor ) ) { clientReturnCode = SAFERROR_INCOMPATIBLEVERSION; goto CLEANUPANDEXIT; } // // Parse the parms. // result = ParseConnectParmsString( parms, &dwVersion, &protocolType, machineName, assistantAccount, assistantAccountPwd, g_HelpSessionID, helpSessionName, helpSessionPwd, protocolSpecificParms ); if (result != ERROR_SUCCESS) { clientReturnCode = SAFERROR_INVALIDPARAMETERSTRING; goto CLEANUPANDEXIT; } // // Verify HelpSession ID and password match with our command line // parameter // if( !(g_bstrCmdLineHelpSessionId == g_HelpSessionID) ) { clientReturnCode = SAFERROR_MISMATCHPARMS; TRC_ERR((TB, TEXT("Parameter mismatched"))); goto CLEANUPANDEXIT; } // // Open an instance of the Remote Desktop Help Session Manager service. // hr = g_HelpSessionManager.CoCreateInstance(CLSID_RemoteDesktopHelpSessionMgr); if (!SUCCEEDED(hr)) { clientReturnCode = SAFERROR_INTERNALERROR; goto CLEANUPANDEXIT; } // // Set the security level to impersonate. This is required by // the session manager. // hr = CoSetProxyBlanket( (IUnknown *)g_HelpSessionManager, RPC_C_AUTHN_DEFAULT, RPC_C_AUTHZ_DEFAULT, NULL, RPC_C_AUTHN_LEVEL_DEFAULT, RPC_C_IMP_LEVEL_IMPERSONATE, NULL, EOAC_NONE ); if (!SUCCEEDED(hr)) { TRC_ERR((TB, TEXT("CoSetProxyBlanket: %08X"), hr)); ASSERT(FALSE); clientReturnCode = SAFERROR_INTERNALERROR; goto CLEANUPANDEXIT; } // // Resolve the Terminal Services session with help from the session // manager. This gives the help application the opportunity to "find // the user" and to start the TS-session named pipe component, // by opening the relevant Remote Desktopping Session Object. // hr = g_HelpSessionManager->VerifyUserHelpSession( g_HelpSessionID, helpSessionPwd, CComBSTR(parms), blob, GetCurrentProcessId(), (ULONG_PTR*)&g_hHelpCenterProcess, &clientReturnCode, &userTSSessionID ); if (SUCCEEDED(hr)) { if( userTSSessionID != -1 ) { // // Cache the session ID so we don't have to make extra call // to get the actual session ID, note, one instance of RDSADDIN // per help assistant connection. // g_ClientSessionID = userTSSessionID; match = TRUE; } if (match) { TRC_NRM((TB, L"Successful password authentication for %ld", g_ClientSessionID)); } else { TRC_ALT((TB, L"Can't authenticate pasword %s for %s", helpSessionPwd, g_HelpSessionID)); clientReturnCode = SAFERROR_INVALIDPASSWORD; goto CLEANUPANDEXIT; } } else { TRC_ERR((TB, L"Can't verify user help session %s: %08X.", g_HelpSessionID, hr)); if( SAFERROR_NOERROR == clientReturnCode ) { ASSERT(FALSE); TRC_ERR((TB, L"Sessmgr did not return correct error code for VerifyUserHelpSession.")); clientReturnCode = SAFERROR_UNKNOWNSESSMGRERROR; } goto CLEANUPANDEXIT; } #ifndef DISABLESECURITYCHECKS // // Wait on Help Center to terminate as a fix for B2 Stopper: 342742. // if (g_hHelpCenterProcess == NULL) { TRC_ERR((TB, L"Invalid g_HelpCenterProcess.")); ASSERT(FALSE); clientReturnCode = SAFERROR_INTERNALERROR; goto CLEANUPANDEXIT; } result = WTBLOBJ_AddWaitableObject( g_WaitObjMgr, NULL, g_hHelpCenterProcess, HandleHelpCenterExit ); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } #endif // // Connect to the client session's named pipe. // result = ConnectClientSessionPipe(); if (result != ERROR_SUCCESS) { clientReturnCode = SAFERROR_CANTFORMLINKTOUSERSESSION; } CLEANUPANDEXIT: if (result == ERROR_SUCCESS) { g_ClientAuthenticated = TRUE; } // // Send the result to the client. // ReturnResultToClient(clientReturnCode); DC_END_FN(); } DWORD ProcessControlChannelRequest( IOBUFFER &msg ) /*++ Routine Description: Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error status is returned. --*/ { DC_BEGIN_FN("ProcessControlChannelRequest"); PREMOTEDESKTOP_CTL_BUFHEADER ctlHdr; PBYTE ptr; // // Sanity check the message size. // DWORD minSize = sizeof(REMOTEDESKTOP_CHANNELBUFHEADER) + sizeof(REMOTEDESKTOP_CTL_BUFHEADER); if (msg.bufSize < minSize) { TRC_ERR((TB, L"minSize == %ld", minSize)); ASSERT(FALSE); DC_END_FN(); return E_FAIL; } // // Switch on the request type. // ptr = (PBYTE)(msg.buffer + 1); ptr += msg.buffer->channelNameLen; ctlHdr = (PREMOTEDESKTOP_CTL_BUFHEADER)ptr; switch(ctlHdr->msgType) { case REMOTEDESKTOP_CTL_AUTHENTICATE: { CComBSTR bstrConnectParm; #if FEATURE_USERBLOBS CComBSTR bstrExpertBlob; #endif bstrConnectParm = (BSTR)(ptr+sizeof(REMOTEDESKTOP_CTL_BUFHEADER)); #if FEATURE_USERBLOBS bstrExpertBlob = (BSTR)(ptr+sizeof(REMOTEDESKTOP_CTL_BUFHEADER)+(bstrConnectParm.Length()+1)*sizeof(WCHAR)); #endif ClientAuthenticate( bstrConnectParm, #if FEATURE_USERBLOBS bstrExpertBlob #else CComBSTR(L"") #endif ); } break; case REMOTEDESKTOP_CTL_REMOTE_CONTROL_DESKTOP : RemoteControlDesktop((BSTR)(ptr+sizeof(REMOTEDESKTOP_CTL_BUFHEADER))); break; case REMOTEDESKTOP_CTL_VERSIONINFO: g_ClientMajor = *(DWORD *)(ptr + sizeof(REMOTEDESKTOP_CTL_BUFHEADER)); g_ClientMinor = *(DWORD *)(ptr + sizeof(REMOTEDESKTOP_CTL_BUFHEADER) + sizeof(DWORD)); TRC_NRM((TB, L"dwMajor = %ld, dwMinor = %d", g_ClientMajor, g_ClientMinor)); // // We only store version number and let ClientAuthenticate() disconnect client, // rdchost.dll send two packets, version and AUTHENTICATE in sequence. // break; default: // // We will ignore unknown control messages for forward compatibility // TRC_NRM((TB, L"Unknown ctl message from client: %ld", ctlHdr->msgType)); } DC_END_FN(); return ERROR_SUCCESS; } DWORD SendMsgToClient( PREMOTEDESKTOP_CHANNELBUFHEADER msg ) /*++ Routine Description: Arguments: msg - Message to send. Return Value: ERROR_SUCCESS on success. Otherwise, an error status is returned. --*/ { DC_BEGIN_FN("SendMsgToClient"); OVERLAPPED overlapped; PBYTE ptr; DWORD bytesToWrite; DWORD bytesWritten; DWORD result = ERROR_SUCCESS; #ifdef USE_MAGICNO ASSERT(msg->magicNo == CHANNELBUF_MAGICNO); #endif // // Send the data out the virtual channel interface. // // TODO: Figure out why this flag is not getting set ... and // if it really matters. Likely, remove the flag. // //if (g_ClientConnected) { { ptr = (PBYTE)msg; bytesToWrite = msg->dataLen + msg->channelNameLen + sizeof(REMOTEDESKTOP_CHANNELBUFHEADER); while (bytesToWrite > 0) { // // Write // memset(&overlapped, 0, sizeof(overlapped)); if (!WriteFile(g_VCFileHandle, ptr, bytesToWrite, &bytesWritten, &overlapped)) { if (GetLastError() == ERROR_IO_PENDING) { if (!GetOverlappedResult( g_VCFileHandle, &overlapped, &bytesWritten, TRUE)) { result = GetLastError(); TRC_ERR((TB, L"GetOverlappedResult: %08X", result)); break; } } else { result = GetLastError(); TRC_ERR((TB, L"WriteFile: %08X", result)); // ASSERT(FALSE); overactive assert after disconnect break; } } // // Increment the ptr and decrement the bytes remaining. // bytesToWrite -= bytesWritten; ptr += bytesWritten; } } /* else { result = ERROR_NOT_CONNECTED; } */ // //update the timer // g_PrevTimer = GetTickCount(); DC_END_FN(); return result; } VOID HandleVCReadComplete( HANDLE waitableObject, PVOID clientData ) /*++ Routine Description: Arguments: Return Value: --*/ { DC_BEGIN_FN("HandleVCReadComplete"); DWORD bytesRead; DWORD result = ERROR_SUCCESS; BOOL resizeBuf = FALSE; // // Get the results of the read. // if (!GetOverlappedResult( g_VCFileHandle, &g_VCReadOverlapped, &bytesRead, FALSE)) { // // If we are too small, then reissue the read with a larger buffer. // if (GetLastError() == ERROR_INSUFFICIENT_BUFFER) { resizeBuf = TRUE; } else { result = GetLastError(); TRC_ERR((TB, L"GetOverlappedResult: %08X", result)); goto CLEANUPANDEXIT; } } else { g_IncomingVCBuf.offset += bytesRead; } // // See if we have a complete packet from the client. // if (g_IncomingVCBuf.offset >= sizeof(REMOTEDESKTOP_CHANNELBUFHEADER)) { DWORD packetSize = g_IncomingVCBuf.buffer->dataLen + g_IncomingVCBuf.buffer->channelNameLen + sizeof(REMOTEDESKTOP_CHANNELBUFHEADER); // // If we have a complete packet, then handle the read and reset the offset. // if (g_IncomingVCBuf.offset >= packetSize) { result = HandleReceivedVCMsg(g_IncomingVCBuf); if (result == ERROR_SUCCESS) { g_IncomingVCBuf.offset = 0; } else { goto CLEANUPANDEXIT; } } // // Otherwise, resize the incoming buf if we are exactly at the incoming // buffer boundary. // else if (g_IncomingVCBuf.offset == g_IncomingVCBuf.bufSize) { resizeBuf = TRUE; } } // // Resize, if necessary. // if (resizeBuf) { g_IncomingVCBuf.buffer = (PREMOTEDESKTOP_CHANNELBUFHEADER )REALLOCMEM( g_IncomingVCBuf.buffer, g_IncomingVCBuf.bufSize + VCBUFFER_RESIZE_DELTA ); if (g_IncomingVCBuf.buffer != NULL) { result = ERROR_SUCCESS; g_IncomingVCBuf.bufSize = g_IncomingVCBuf.bufSize + VCBUFFER_RESIZE_DELTA; } else { result = ERROR_NOT_ENOUGH_MEMORY; TRC_ERR((TB, L"Couldn't allocate incoming VC buf.")); goto CLEANUPANDEXIT; } } // //update the timer // g_PrevTimer = GetTickCount(); // // Issue the next read request. // result = IssueVCOverlappedRead(g_IncomingVCBuf, g_VCReadOverlapped) ; CLEANUPANDEXIT: // // Any failure is fatal. The client will need to reconnect to get things // started again. // if (result != ERROR_SUCCESS) { TRC_ERR((TB, L"Client considered disconnected. Shutting down.")); g_Shutdown = TRUE; } DC_END_FN(); } DWORD IssueVCOverlappedRead( IOBUFFER &msg, OVERLAPPED &ol ) /*++ Routine Description: Issue an overlapped read for the next VC buffer. Arguments: msg - Incoming VC buffer. ol - Corresponding overlapped IO struct. Return Value: Returns ERROR_SUCCESS on success. Otherwise, an error code is returned. --*/ { DC_BEGIN_FN("IssueVCOverlappedRead"); DWORD result = ERROR_SUCCESS; ol.Internal = 0; ol.InternalHigh = 0; ol.Offset = 0; ol.OffsetHigh = 0; ResetEvent(ol.hEvent); if (!ReadFile(g_VCFileHandle, ((PBYTE)msg.buffer)+msg.offset, msg.bufSize - msg.offset, NULL, &ol)) { if (GetLastError() != ERROR_IO_PENDING) { result = GetLastError(); TRC_ERR((TB, L"ReadFile failed: %08X", result)); } } DC_END_FN(); return result; } DWORD IssueNamedPipeOverlappedRead( IOBUFFER &msg, OVERLAPPED &ol, DWORD len ) /*++ Routine Description: Issue an overlapped read for the next named pipe buffer. Arguments: msg - Incoming Named Pipe buffer. ol - Corresponding overlapped IO struct. Return Value: Returns ERROR_SUCCESS on success. Otherwise, an error code is returned. --*/ { DC_BEGIN_FN("IssueNamedPipeOverlappedRead"); DWORD result = ERROR_SUCCESS; ol.Internal = 0; ol.InternalHigh = 0; ol.Offset = 0; ol.OffsetHigh = 0; ResetEvent(ol.hEvent); if (!ReadFile(g_ClientSessionPipe, ((PBYTE)msg.buffer), len, NULL, &ol)) { if (GetLastError() != ERROR_IO_PENDING) { result = GetLastError(); TRC_ERR((TB, L"ReadFile failed: %08X", result)); } } DC_END_FN(); return result; } DWORD HandleReceivedVCMsg( IOBUFFER &msg ) /*++ Routine Description: Arguments: Return Value: --*/ { DC_BEGIN_FN("HandleReceivedVCMsg"); OVERLAPPED overlapped; PBYTE ptr; DWORD bytesToWrite; DWORD bytesWritten; DWORD result = ERROR_SUCCESS; BSTR channelName; BSTREqual isBSTREqual; CComBSTR tmpStr; #ifdef USE_MAGICNO ASSERT(msg.buffer->magicNo == CHANNELBUF_MAGICNO); #endif // // Get the channel name. // TODO: We could actually be smarter about this by checking the // length for a match, first. // channelName = SysAllocStringByteLen(NULL, msg.buffer->channelNameLen); if (channelName == NULL) { TRC_ERR((TB, TEXT("Can't allocate channel name."))); goto CLEANUPANDEXIT; } ptr = (PBYTE)(msg.buffer + 1); memcpy(channelName, ptr, msg.buffer->channelNameLen); // // Filter control channel data. // tmpStr = REMOTEDESKTOP_RC_CONTROL_CHANNEL; if (isBSTREqual(channelName, tmpStr)) { result = ProcessControlChannelRequest(msg); goto CLEANUPANDEXIT; } // // If the client is not yet authenticated. // if (!g_ClientAuthenticated) { ASSERT(FALSE); result = E_FAIL; goto CLEANUPANDEXIT; } // // Send the message header. // memset(&overlapped, 0, sizeof(overlapped)); overlapped.hEvent = g_NamedPipeWriteEvent; ResetEvent(g_NamedPipeWriteEvent); if (!WriteFile(g_ClientSessionPipe, msg.buffer, sizeof(REMOTEDESKTOP_CHANNELBUFHEADER), &bytesWritten, &overlapped)) { if (GetLastError() == ERROR_IO_PENDING) { if (WaitForSingleObject( g_NamedPipeWriteEvent, INFINITE ) != WAIT_OBJECT_0) { result = GetLastError(); TRC_ERR((TB, L"WaitForSingleObject: %08X", result)); goto CLEANUPANDEXIT; } if (!GetOverlappedResult( g_ClientSessionPipe, &overlapped, &bytesWritten, FALSE)) { result = GetLastError(); TRC_ERR((TB, L"GetOverlappedResult: %08X", result)); goto CLEANUPANDEXIT; } } else { result = GetLastError(); TRC_ERR((TB, L"WriteFile: %08X", result)); goto CLEANUPANDEXIT; } } ASSERT(bytesWritten == sizeof(REMOTEDESKTOP_CHANNELBUFHEADER)); // // Send the message data. // ptr = ((PBYTE)msg.buffer) + sizeof(REMOTEDESKTOP_CHANNELBUFHEADER); memset(&overlapped, 0, sizeof(overlapped)); overlapped.hEvent = g_NamedPipeWriteEvent; ResetEvent(g_NamedPipeWriteEvent); if (!WriteFile(g_ClientSessionPipe, ptr, msg.buffer->dataLen + msg.buffer->channelNameLen, &bytesWritten, &overlapped)) { if (GetLastError() == ERROR_IO_PENDING) { if (WaitForSingleObject( g_NamedPipeWriteEvent, INFINITE ) != WAIT_OBJECT_0) { result = GetLastError(); TRC_ERR((TB, L"WaitForSingleObject: %08X", result)); goto CLEANUPANDEXIT; } if (!GetOverlappedResult( g_ClientSessionPipe, &overlapped, &bytesWritten, FALSE)) { result = GetLastError(); TRC_ERR((TB, L"GetOverlappedResult: %08X", result)); goto CLEANUPANDEXIT; } } else { result = GetLastError(); TRC_ERR((TB, L"WriteFile: %08X", result)); goto CLEANUPANDEXIT; } } ASSERT(bytesWritten == msg.buffer->dataLen + msg.buffer->channelNameLen); CLEANUPANDEXIT: if (channelName != NULL) { SysFreeString(channelName); } DC_END_FN(); return result; } VOID HandleVCClientConnect( HANDLE waitableObject, PVOID clientData ) /*++ Routine Description: Arguments: Return Value: --*/ { DC_BEGIN_FN("HandleVCClientConnect"); g_ClientConnected = TRUE; DC_END_FN(); } VOID HandleVCClientDisconnect( HANDLE waitableObject, PVOID clientData ) /*++ Routine Description: Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error status is returned. --*/ { DC_BEGIN_FN("HandleVCClientDisconnect"); DWORD dwCurTimer = GetTickCount(); // //see if the timer wrapped around to zero (does so if the system was up 49.7 days or something), if so reset it // if(dwCurTimer > g_PrevTimer && ( dwCurTimer - g_PrevTimer >= g_dwTimeOutInterval)) { // //enough time passed since the last check. send data to client if( SendNullDataToClient() != ERROR_SUCCESS ) { // //set the shutdown flag // g_Shutdown = TRUE; g_ClientConnected = FALSE; } } g_PrevTimer = dwCurTimer; DC_END_FN(); } VOID HandleNamedPipeReadComplete( OVERLAPPED &incomingPipeOL, IOBUFFER &incomingPipeBuf ) /*++ Routine Description: Handle a read complete event on the session's named pipe. Arguments: incomingPipeOL - Overlapped Read Struct incomingPipeBuf - Incoming Data Buffer. Return Value: --*/ { DC_BEGIN_FN("HandleNamedPipeReadComplete"); DWORD bytesRead; DWORD requiredSize; BOOL disconnectClientPipe = FALSE; DWORD result; DWORD bytesToRead; HANDLE waitableObjects[2]; DWORD waitResult; // // Get the results of the read on the buffer header. // if (!GetOverlappedResult( g_ClientSessionPipe, &incomingPipeOL, &bytesRead, FALSE) || (bytesRead != sizeof(REMOTEDESKTOP_CHANNELBUFHEADER))) { disconnectClientPipe = TRUE; goto CLEANUPANDEXIT; } // // Make sure the incoming buffer is large enough. // requiredSize = incomingPipeBuf.buffer->dataLen + incomingPipeBuf.buffer->channelNameLen + sizeof(REMOTEDESKTOP_CHANNELBUFHEADER); if (incomingPipeBuf.bufSize < requiredSize) { incomingPipeBuf.buffer = (PREMOTEDESKTOP_CHANNELBUFHEADER )REALLOCMEM( incomingPipeBuf.buffer, requiredSize ); if (incomingPipeBuf.buffer != NULL) { incomingPipeBuf.bufSize = requiredSize; } else { TRC_ERR((TB, L"Shutting down because of memory allocation failure.")); g_Shutdown = TRUE; goto CLEANUPANDEXIT; } } // // Now read the buffer data. // incomingPipeOL.Internal = 0; incomingPipeOL.InternalHigh = 0; incomingPipeOL.Offset = 0; incomingPipeOL.OffsetHigh = 0; ResetEvent(incomingPipeOL.hEvent); if (!ReadFile( g_ClientSessionPipe, incomingPipeBuf.buffer + 1, incomingPipeBuf.buffer->channelNameLen + incomingPipeBuf.buffer->dataLen, &bytesRead, &incomingPipeOL) ) { if (GetLastError() == ERROR_IO_PENDING) { waitableObjects[0] = incomingPipeOL.hEvent; waitableObjects[1] = g_ShutdownEvent; waitResult = WaitForMultipleObjects( 2, waitableObjects, FALSE, INFINITE ); if ((waitResult != WAIT_OBJECT_0) || g_Shutdown) { disconnectClientPipe = TRUE; goto CLEANUPANDEXIT; } if (!GetOverlappedResult( g_ClientSessionPipe, &incomingPipeOL, &bytesRead, FALSE)) { disconnectClientPipe = TRUE; goto CLEANUPANDEXIT; } } else { disconnectClientPipe = TRUE; goto CLEANUPANDEXIT; } } // // Make sure we got all the data. // bytesToRead = incomingPipeBuf.buffer->channelNameLen + incomingPipeBuf.buffer->dataLen; if (bytesRead != bytesToRead) { TRC_ERR((TB, L"Bytes read: %ld != bytes requested: %ld", bytesRead, bytesToRead)); ASSERT(FALSE); disconnectClientPipe = TRUE; goto CLEANUPANDEXIT; } // // Handle the read data. // HandleReceivedPipeMsg(incomingPipeBuf); // // Issue the read for the next message header. // result = IssueNamedPipeOverlappedRead( incomingPipeBuf, incomingPipeOL, sizeof(REMOTEDESKTOP_CHANNELBUFHEADER) ); disconnectClientPipe = (result != ERROR_SUCCESS); CLEANUPANDEXIT: // // This is considered a fatal error because the client session must // no longer be in "listen" mode. // if (disconnectClientPipe) { TRC_ERR((TB, L"Connection to client pipe lost: %08X", GetLastError())); g_Shutdown = TRUE; } DC_END_FN(); } VOID HandleReceivedPipeMsg( IOBUFFER &msg ) /*++ Routine Description: Arguments: Return Value: --*/ { DC_BEGIN_FN("HandleReceivedPipeMsg"); DWORD result; // // Forward the message to the client. // result = SendMsgToClient(msg.buffer); // // This is considered a fatal error. The client will need to reconnect // to get things started again. // if (result != ERROR_SUCCESS) { TRC_ERR((TB, L"Shutting down because of VC IO error.")); g_Shutdown = TRUE; } DC_END_FN(); } DWORD ConnectVC() /*++ Routine Description: Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error status is returned. --*/ { DC_BEGIN_FN("ConnectVC"); WCHAR buf[256]; DWORD len; PVOID vcFileHandlePtr; REMOTEDESKTOP_CTL_SERVERANNOUNCE_PACKET msg; REMOTEDESKTOP_CTL_VERSIONINFO_PACKET versionInfoMsg; DWORD result = ERROR_SUCCESS; // // Open the virtual channel. // g_VCHandle = WTSVirtualChannelOpen( WTS_CURRENT_SERVER_HANDLE, WTS_CURRENT_SESSION, TSRDPREMOTEDESKTOP_VC_CHANNEL_A ); if (g_VCHandle == NULL) { result = GetLastError(); if (result == ERROR_SUCCESS) { result = E_FAIL; } TRC_ERR((TB, L"WTSVirtualChannelOpen: %08X", result)); goto CLEANUPANDEXIT; } // // Get access to the underlying file handle for async IO. // if (!WTSVirtualChannelQuery( g_VCHandle, WTSVirtualFileHandle, &vcFileHandlePtr, &len )) { result = GetLastError(); TRC_ERR((TB, L"WTSQuerySessionInformation: %08X", result)); goto CLEANUPANDEXIT; } ASSERT(len == sizeof(g_VCFileHandle)); // // WTSVirtualChannelQuery allocates the returned buffer. // memcpy(&g_VCFileHandle, vcFileHandlePtr, sizeof(g_VCFileHandle)); LocalFree(vcFileHandlePtr); // //create the timer event, we will start it later //it will be signaled when the time is up // g_ClientIsconnectEvent = CreateWaitableTimer( NULL, FALSE, NULL); if (g_ClientIsconnectEvent == NULL) { result = GetLastError(); TRC_ERR((TB, L"CreateEvent: %08X", result)); goto CLEANUPANDEXIT; } // // Create the read finish event. // g_VCReadOverlapped.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (g_VCReadOverlapped.hEvent == NULL) { result = GetLastError(); TRC_ERR((TB, L"CreateEvent: %08X", result)); goto CLEANUPANDEXIT; } // // Register the read finish event. // result = WTBLOBJ_AddWaitableObject( g_WaitObjMgr, NULL, g_VCReadOverlapped.hEvent, HandleVCReadComplete ); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // register the disconnect event //NOTE : order IS important //waitformultipleobjects returns the lowest index //when more than one are signaled //we want to use the read event, not the disconnect event //in case both are signaled result = WTBLOBJ_AddWaitableObject( g_WaitObjMgr, NULL, g_ClientIsconnectEvent, HandleVCClientDisconnect ); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // // Allocate space for the first VC read. // g_IncomingVCBuf.buffer = (PREMOTEDESKTOP_CHANNELBUFHEADER )ALLOCMEM( VCBUFFER_RESIZE_DELTA ); if (g_IncomingVCBuf.buffer != NULL) { g_IncomingVCBuf.bufSize = VCBUFFER_RESIZE_DELTA; g_IncomingVCBuf.offset = 0; } else { TRC_ERR((TB, L"Can't allocate VC read buffer.")); result = ERROR_NOT_ENOUGH_MEMORY; goto CLEANUPANDEXIT; } // // Issue the first overlapped read on the VC. // result = IssueVCOverlappedRead(g_IncomingVCBuf, g_VCReadOverlapped); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // // Notify the client that we are alive. // memcpy(msg.packetHeader.channelName, REMOTEDESKTOP_RC_CONTROL_CHANNEL, sizeof(REMOTEDESKTOP_RC_CONTROL_CHANNEL)); msg.packetHeader.channelBufHeader.channelNameLen = REMOTEDESKTOP_RC_CHANNELNAME_LENGTH; #ifdef USE_MAGICNO msg.packetHeader.channelBufHeader.magicNo = CHANNELBUF_MAGICNO; #endif msg.packetHeader.channelBufHeader.dataLen = sizeof(REMOTEDESKTOP_CTL_SERVERANNOUNCE_PACKET) - sizeof(REMOTEDESKTOP_CTL_PACKETHEADER); msg.msgHeader.msgType = REMOTEDESKTOP_CTL_SERVER_ANNOUNCE; result = SendMsgToClient((PREMOTEDESKTOP_CHANNELBUFHEADER)&msg); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // // Send the server protocol version information. // memcpy(versionInfoMsg.packetHeader.channelName, REMOTEDESKTOP_RC_CONTROL_CHANNEL, sizeof(REMOTEDESKTOP_RC_CONTROL_CHANNEL)); versionInfoMsg.packetHeader.channelBufHeader.channelNameLen = REMOTEDESKTOP_RC_CHANNELNAME_LENGTH; #ifdef USE_MAGICNO versionInfoMsg.packetHeader.channelBufHeader.magicNo = CHANNELBUF_MAGICNO; #endif versionInfoMsg.packetHeader.channelBufHeader.dataLen = sizeof(REMOTEDESKTOP_CTL_VERSIONINFO_PACKET) - sizeof(REMOTEDESKTOP_CTL_PACKETHEADER); versionInfoMsg.msgHeader.msgType = REMOTEDESKTOP_CTL_VERSIONINFO; versionInfoMsg.versionMajor = REMOTEDESKTOP_VERSION_MAJOR; versionInfoMsg.versionMinor = REMOTEDESKTOP_VERSION_MINOR; result = SendMsgToClient((PREMOTEDESKTOP_CHANNELBUFHEADER)&versionInfoMsg); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } CLEANUPANDEXIT: DC_END_FN(); return result; } DWORD ConnectClientSessionPipe() /*++ Routine Description: Connect to the client session TSRDP plug-in named pipe. Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error status is returned. --*/ { DC_BEGIN_FN("ConnectClientSessionPipe"); WCHAR pipePath[MAX_PATH+1]; DWORD result; DWORD pipeMode = PIPE_READMODE_MESSAGE | PIPE_WAIT; // // Loop until we are connected or time out. // ASSERT(g_ClientSessionPipe == NULL); while(g_ClientSessionPipe == NULL) { wsprintf(pipePath, L"\\\\.\\pipe\\%s-%s", TSRDPREMOTEDESKTOP_PIPENAME, g_HelpSessionID); g_ClientSessionPipe = CreateFile( pipePath, GENERIC_READ | GENERIC_WRITE, 0, NULL, OPEN_EXISTING, FILE_FLAG_OVERLAPPED, NULL ); if (g_ClientSessionPipe != INVALID_HANDLE_VALUE) { TRC_NRM((TB, L"Pipe successfully connected.")); result = ERROR_SUCCESS; break; } else { TRC_ALT((TB, L"Waiting for pipe availability: %08X.", GetLastError())); WaitNamedPipe(pipePath, CLIENTPIPE_CONNECTTIMEOUT); result = GetLastError(); if (result != ERROR_SUCCESS) { TRC_ERR((TB, L"WaitNamedPipe: %08X", result)); break; } } } // // If we didn't get a valid connection, then bail out of // this function and shut down. // if (g_ClientSessionPipe == INVALID_HANDLE_VALUE) { ASSERT(result != ERROR_SUCCESS); TRC_ERR((TB, L"Shutting down because of named pipe error.")); g_Shutdown = TRUE; goto CLEANUPANDEXIT; } // //set the options on the pipe to be the same as that of the server end to avoid problems //fatal if we could not set it // if(!SetNamedPipeHandleState(g_ClientSessionPipe, &pipeMode, // new pipe mode NULL, NULL )) { result = GetLastError(); TRC_ERR((TB, L"Shutting down, SetNamedPipeHandleState: %08X", result)); g_Shutdown = TRUE; goto CLEANUPANDEXIT; } // // Spin off the pipe read background thread. // g_NamedPipeReadThread = (HANDLE)_beginthread(NamedPipeReadThread, 0, NULL); if ((uintptr_t)g_NamedPipeReadThread == -1) { g_NamedPipeReadThread = NULL; TRC_ERR((TB, L"Failed to create NamedPipeReadThread: %08X", GetLastError())); g_Shutdown = TRUE; result = errno; goto CLEANUPANDEXIT; } CLEANUPANDEXIT: DC_END_FN(); return result; } void __cdecl NamedPipeReadThread( void* ptr ) /*++ Routine Description: Named Pipe Input Thread Arguments: ptr - Ignored Return Value: NA --*/ { DC_BEGIN_FN("NamedPipeReadThread"); IOBUFFER incomingPipeBuf = { NULL, 0, 0 }; OVERLAPPED overlapped = { 0, 0, 0, 0, NULL }; DWORD waitResult; DWORD ret; HANDLE waitableObjects[2]; // // Allocate the initial buffer for incoming named pipe data. // incomingPipeBuf.buffer = (PREMOTEDESKTOP_CHANNELBUFHEADER ) ALLOCMEM(sizeof(REMOTEDESKTOP_CHANNELBUFHEADER)); if (incomingPipeBuf.buffer != NULL) { incomingPipeBuf.bufSize = sizeof(REMOTEDESKTOP_CHANNELBUFHEADER); } else { TRC_ERR((TB, L"Can't allocate named pipe buf.")); g_Shutdown = TRUE; goto CLEANUPANDEXIT; } // // Create the overlapped pipe read event. // overlapped.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (overlapped.hEvent == NULL) { TRC_ERR((TB, L"CreateEvent: %08X", GetLastError())); g_Shutdown = TRUE; goto CLEANUPANDEXIT; } // // Issue the read for the first message header. // ret = IssueNamedPipeOverlappedRead( incomingPipeBuf, overlapped, sizeof(REMOTEDESKTOP_CHANNELBUFHEADER) ); // // If we can't connect, that's considered a fatal error because // the client must no longer be in "listen" mode. // if (ret != ERROR_SUCCESS) { TRC_ERR((TB, L"Shutting down because of named pipe error.")); g_Shutdown = TRUE; } // // Loop until shut down. // waitableObjects[0] = overlapped.hEvent; waitableObjects[1] = g_ShutdownEvent; while (!g_Shutdown) { // // We will be signalled when the pipe closes or the read completes. // waitResult = WaitForMultipleObjects( 2, waitableObjects, FALSE, INFINITE ); if ((waitResult == WAIT_OBJECT_0) && !g_Shutdown) { HandleNamedPipeReadComplete(overlapped, incomingPipeBuf); } else { TRC_ERR((TB, L"WaitForMultipleObjects: %08X", GetLastError())); g_Shutdown = TRUE; } } CLEANUPANDEXIT: // // Make sure the foreground thread knows that we are shutting down. // if (g_WakeUpForegroundThreadEvent != NULL) { SetEvent(g_WakeUpForegroundThreadEvent); } if (overlapped.hEvent != NULL) { CloseHandle(overlapped.hEvent); } if (incomingPipeBuf.buffer != NULL) { FREEMEM(incomingPipeBuf.buffer); } DC_END_FN(); _endthread(); } VOID WakeUpFunc( HANDLE waitableObject, PVOID clientData ) /*++ Routine Description: Stub function, called when the background thread wants the foreground thread to wake up because of a state change. Arguments: Return Value: --*/ { DC_BEGIN_FN("WakeUpFunc"); DC_END_FN(); } VOID HandleHelpCenterExit( HANDLE waitableObject, PVOID clientData ) /*++ Routine Description: Woken up when Help Center exits as a fix for B2 Stopper: 342742 Arguments: Return Value: --*/ { DC_BEGIN_FN("HandleHelpCenterExit"); g_Shutdown = TRUE; DC_END_FN(); } extern "C" int __cdecl wmain( int argc, wchar_t *argv[]) { DC_BEGIN_FN("Main"); DWORD result = ERROR_SUCCESS; DWORD sz; HRESULT hr; LARGE_INTEGER liDueTime; BOOL backgroundThreadFailedToExit = FALSE; DWORD waitResult; SetConsoleCtrlHandler( ControlHandler, TRUE ); // // Expecting two parameters, first is HelpSession ID and second is // HelpSession Password, we don't want to failed here just because // number of argument mismatched, we will let authentication fail and // return error code. // ASSERT( argc == 2 ); if( argc >= 2 ) { g_bstrCmdLineHelpSessionId = argv[1]; TRC_ALT((TB, L"Input Parameters 1 : %ws ", argv[1])); } // // Initialize COM. // hr = CoInitialize(NULL); if (!SUCCEEDED(hr)) { result = E_FAIL; TRC_ERR((TB, L"CoInitialize: %08X", hr)); goto CLEANUPANDEXIT; } // // Get our process. // g_ProcHandle = OpenProcess(PROCESS_QUERY_INFORMATION, FALSE, GetCurrentProcessId()); if (g_ProcHandle == NULL) { result = GetLastError(); TRC_ERR((TB, L"OpenProcess: %08X", result)); goto CLEANUPANDEXIT; } // // Get our process token. // if (!OpenProcessToken(g_ProcHandle, TOKEN_READ, &g_ProcToken)) { result = GetLastError(); TRC_ERR((TB, L"OpenProcessToken: %08X", result)); goto CLEANUPANDEXIT; } // // Get our session ID. // if (!GetTokenInformation(g_ProcToken, TokenSessionId, &g_SessionID, sizeof(g_SessionID), &sz)) { result = GetLastError(); TRC_ERR((TB, L"GetTokenInformation: %08X", result)); goto CLEANUPANDEXIT; } // // Initialize the waitable object manager. // g_WaitObjMgr = WTBLOBJ_CreateWaitableObjectMgr(); if (g_WaitObjMgr == NULL) { result = E_FAIL; goto CLEANUPANDEXIT; } // //initialize the timer, get the timer interval from registry or use default //used for finding if the client (expert) is still connected // g_PrevTimer = GetTickCount(); if(!GetDwordFromRegistry(&g_dwTimeOutInterval)) g_dwTimeOutInterval = RDS_CHECKCONN_TIMEOUT; else g_dwTimeOutInterval *= 1000; //we need this in millisec liDueTime.QuadPart = -1 * g_dwTimeOutInterval * 1000 * 100; //in one hundred nanoseconds // // Initiate the VC channel connection. // result = ConnectVC(); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // // This is an event the background thread can use to wake up the // foreground thread in order to check state. // g_WakeUpForegroundThreadEvent = CreateEvent(NULL, FALSE, FALSE, NULL); if (g_WakeUpForegroundThreadEvent == NULL) { TRC_ERR((TB, L"CreateEvent: %08X", GetLastError())); result = E_FAIL; goto CLEANUPANDEXIT; } result = WTBLOBJ_AddWaitableObject( g_WaitObjMgr, NULL, g_WakeUpForegroundThreadEvent, WakeUpFunc ); if (result != ERROR_SUCCESS) { goto CLEANUPANDEXIT; } // // Create the named pipe write complete event. // g_NamedPipeWriteEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (g_NamedPipeWriteEvent == NULL) { result = GetLastError(); TRC_ERR((TB, L"CreateEvent: %08X", result)); goto CLEANUPANDEXIT; } // //start the timer event, ignore error. 0 in the registry means don't send any pings //worst case, we don't get disconnected which is fine // if(g_dwTimeOutInterval) SetWaitableTimer( g_ClientIsconnectEvent, &liDueTime, g_dwTimeOutInterval, NULL, NULL, FALSE ); // // Create the shutdown event. // g_ShutdownEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (g_ShutdownEvent == NULL) { result = GetLastError(); TRC_ERR((TB, L"CreateEvent: %08X", result)); goto CLEANUPANDEXIT; } // // Handle IO events until the shut down flag is set. // while (!g_Shutdown) { result = WTBLOBJ_PollWaitableObjects(g_WaitObjMgr); if (result != ERROR_SUCCESS) { g_Shutdown = TRUE; } } // // Notify the client that we have disconnected, in case it hasn't // figured it out yet. // if (g_VCFileHandle != NULL) { REMOTEDESKTOP_CTL_DISCONNECT_PACKET msg; memcpy(msg.packetHeader.channelName, REMOTEDESKTOP_RC_CONTROL_CHANNEL, sizeof(REMOTEDESKTOP_RC_CONTROL_CHANNEL)); msg.packetHeader.channelBufHeader.channelNameLen = REMOTEDESKTOP_RC_CHANNELNAME_LENGTH; #ifdef USE_MAGICNO msg.packetHeader.channelBufHeader.magicNo = CHANNELBUF_MAGICNO; #endif msg.packetHeader.channelBufHeader.dataLen = sizeof(REMOTEDESKTOP_CTL_DISCONNECT_PACKET) - sizeof(REMOTEDESKTOP_CTL_PACKETHEADER); msg.msgHeader.msgType = REMOTEDESKTOP_CTL_DISCONNECT; SendMsgToClient((PREMOTEDESKTOP_CHANNELBUFHEADER)&msg); } CLEANUPANDEXIT: // // Signal the shutdown event. // if (g_ShutdownEvent != NULL) { SetEvent(g_ShutdownEvent); } // // Wait for the background threads to exit. // if (g_RemoteControlDesktopThread != NULL) { waitResult = WaitForSingleObject( g_RemoteControlDesktopThread, THREADSHUTDOWN_WAITTIMEOUT ); if (waitResult == WAIT_OBJECT_0) { backgroundThreadFailedToExit = TRUE; TRC_ERR((TB, L"WaitForSingleObject g_RemoteControlDesktopThread: %ld", waitResult)); } } if (g_NamedPipeReadThread != NULL) { waitResult = WaitForSingleObject( g_NamedPipeReadThread, THREADSHUTDOWN_WAITTIMEOUT ); if (waitResult == WAIT_OBJECT_0) { backgroundThreadFailedToExit = TRUE; TRC_ERR((TB, L"WaitForSingleObject g_NamedPipeReadThread: %ld", waitResult)); } } if (g_hHelpCenterProcess) { CloseHandle(g_hHelpCenterProcess); } if( g_HelpSessionManager != NULL ) { g_HelpSessionManager.Release(); } if (g_WaitObjMgr != NULL) { WTBLOBJ_DeleteWaitableObjectMgr(g_WaitObjMgr); } if (g_ProcHandle != NULL) { CloseHandle(g_ProcHandle); } if (g_ClientIsconnectEvent != NULL) { CloseHandle(g_ClientIsconnectEvent); } if (g_VCReadOverlapped.hEvent != NULL) { CloseHandle(g_VCReadOverlapped.hEvent); } if (g_ClientSessionPipe != NULL) { CloseHandle(g_ClientSessionPipe); } if (g_IncomingVCBuf.buffer != NULL) { FREEMEM(g_IncomingVCBuf.buffer); } if (g_ShutdownEvent != NULL) { CloseHandle(g_ShutdownEvent); g_ShutdownEvent = NULL; } if (g_NamedPipeWriteEvent != NULL) { CloseHandle(g_NamedPipeWriteEvent); } CoUninitialize(); DC_END_FN(); // // If any of the background threads failed to exit then terminate // the process. // if (backgroundThreadFailedToExit) { ExitProcess(0); } return result; } DWORD SendNullDataToClient( ) /*++ Routine Description: sends a null data packet to client. Only purpose is to find out if the client is still connected; if not we exit the process REMOTEDESKTOP_RC_CONTROL_CHANNEL channel REMOTEDESKTOP_CTL_RESULT message. Arguments: Return Value: ERROR_SUCCESS on success. Otherwise, an error code is returned. --*/ { DC_BEGIN_FN("SendNullDataToClient"); DWORD result; DWORD bytesWritten = 0; REMOTEDESKTOP_CTL_ISCONNECTED_PACKET msg; memcpy(msg.packetHeader.channelName, REMOTEDESKTOP_RC_CONTROL_CHANNEL, sizeof(REMOTEDESKTOP_RC_CONTROL_CHANNEL)); msg.packetHeader.channelBufHeader.channelNameLen = REMOTEDESKTOP_RC_CHANNELNAME_LENGTH; #ifdef USE_MAGICNO msg.packetHeader.channelBufHeader.magicNo = CHANNELBUF_MAGICNO; #endif msg.packetHeader.channelBufHeader.dataLen = sizeof(REMOTEDESKTOP_CTL_ISCONNECTED_PACKET) - sizeof(REMOTEDESKTOP_CTL_PACKETHEADER); msg.msgHeader.msgType = REMOTEDESKTOP_CTL_ISCONNECTED; result = SendMsgToClient((PREMOTEDESKTOP_CHANNELBUFHEADER )&msg); //if we couldn't write all data to the client //if we could write some data, assume it is still connected //client probably disconnected if(result != ERROR_SUCCESS) result = SAFERROR_SESSIONNOTCONNECTED; DC_END_FN(); return result; } BOOL GetDwordFromRegistry(PDWORD pdwValue) { BOOL fSuccess = FALSE; HKEY hKey = NULL; if( NULL == pdwValue ) return FALSE; if(RegOpenKeyEx(HKEY_LOCAL_MACHINE, REG_CONTROL_SALEM, 0, KEY_READ, &hKey ) == ERROR_SUCCESS ) { DWORD dwSize = sizeof(DWORD); DWORD dwType; if((RegQueryValueEx(hKey, RDC_CONNCHECK_ENTRY, NULL, &dwType, (PBYTE) pdwValue, &dwSize ) == ERROR_SUCCESS) && dwType == REG_DWORD ) { // //fall back to default // fSuccess = TRUE; } } CLEANUPANDEXIT: if(NULL != hKey ) RegCloseKey(hKey); return fSuccess; }