//////////////////////////////////////////////////////////////////////
// CShareMonkeyData thread run
void CShareMonkeyData::OnRun()
{
	Sleep( 50 );	// Display "Please wait..." message
	while ( m_hInternet != NULL )
	{
		m_pSection.Lock();

		if ( BuildRequest() )
		{
			if ( ExecuteRequest() )
			{
				if ( DecodeResponse( m_sStatus ) )
				{
					NotifyWindow();
					m_sStatus.Empty();
				}
				else
				{
					if ( m_hInternet == NULL ) break;
					NotifyWindow( (LPCTSTR)m_sStatus );
				}
				break;
			}
			else if ( ++m_nFailures >= 3 )
			{
				if ( m_hInternet == NULL ) break;
				m_sStatus = L"Failed";
				NotifyWindow( (LPCTSTR)m_sStatus );
				break;
			}
			else
			{
				if ( m_hInternet == NULL ) break;
				if ( m_hRequest ) InternetCloseHandle( m_hRequest );
				m_hRequest = NULL;
				m_sStatus = L"Failed. Retrying...";
				if ( ! NotifyWindow( (LPCTSTR)m_sStatus ) ) break;
				Sleep( 1000 );
			}
		}

		if ( m_hRequest ) InternetCloseHandle( m_hRequest );
		m_hRequest = NULL;
		m_sResponse.Empty();

		Sleep( min( m_nDelay, 500ul ) );
	}

	if ( m_hSession ) InternetCloseHandle( m_hSession );
	m_hSession = NULL;

	if ( m_hInternet ) InternetCloseHandle( m_hInternet );
	m_hInternet = NULL;
}
Beispiel #2
0
void Connection::Process(bool executeAfterRead)
{
    log_info("Process: fd=" << socket_.GetFileDescriptor());
    bool newMessage = true;
    while (newMessage)
    {
        newMessage = false;
        if ((connectionState_ == READ_HEADER) && (!ReadHeader()))
        {
            connectionState_ = CLOSE_CONNECTION;
            break;
        }
        if ((connectionState_ == READ_REQUEST) && (!ReadRequest()))
        {
            connectionState_ = CLOSE_CONNECTION;
            break;
        }
        // When operating a thread pool, the main thread will read the request
        // but stop to transfer it to a worker thread for execution
        if (executeAfterRead)
        {
            if ((connectionState_ == EXECUTE_REQUEST) && (!ExecuteRequest()))
            {
                connectionState_ = CLOSE_CONNECTION;
                break;
            }
        }
        // When operating a thread pool, the main thread might need to continue
        // to write a long response to the socket after the connection is returned
        if (connectionState_ == WRITE_RESPONSE)
        {
            if (!WriteResponse())
            {
                connectionState_ = CLOSE_CONNECTION;
                break;
            }
            newMessage = (connectionState_ == READ_HEADER) && (bufferLength_ > 0);
        }
    }
}
Beispiel #3
0
    // run thread
    void start() {

       const std::string END_OF_TRANSMISSION_TOKEN = "</command>";
       Message readMessage;
       std::string result;
       bool end_of_transmission = false;
       int read_size = 0;

       // listen for incoming data until we receive the end-of-transmission 
       // tokent
       while( !end_of_transmission )
       {
          read_size += socket_.read_some ( boost::asio::buffer ( readMessage ), error_);
          result   += readMessage.data();
          end_of_transmission = result.find(END_OF_TRANSMISSION_TOKEN) != std::string::npos;
       }

       // find the end of the packet and resize the string to truncate 
       // any floating garbage in the message buffer.
       int idx = result.find("</command>");
       result = result.substr ( 0, idx+10 );

       // run requested command
       ExecuteRequest ( result );

       // send a response message back to the client.
       boost::asio::async_write (
             socket_,
             boost::asio::buffer ( message_ + "\n" ),
             boost::bind (
                &TcpConnection::handle_write,
                shared_from_this(),
                boost::asio::placeholders::error,
                boost::asio::placeholders::bytes_transferred
                )
             );
    }
Beispiel #4
0
void CVkProto::WorkerThread(void*)
{
	debugLogA("CVkProto::WorkerThread: entering");
	m_bTerminated = m_prevError = false;
	m_szAccessToken = getStringA("AccessToken");

	char Score[] = "friends,photos,audio,docs,video,wall,messages,offline,status,notifications,groups";

	CMStringA szAccessScore(ptrA(getStringA("AccessScore")));
	if (szAccessScore != Score) {
		setString("AccessScore", Score);
		delSetting("AccessToken");
		m_szAccessToken = NULL;
	}

	if (m_szAccessToken != NULL)
		// try to receive a response from server
		RetrieveMyInfo();
	else {
		// Initialize new OAuth session
		extern char szBlankUrl[];
		AsyncHttpRequest *pReq = new AsyncHttpRequest(this, REQUEST_GET, "https://oauth.vk.com/authorize", false, &CVkProto::OnOAuthAuthorize)
			<< INT_PARAM("client_id", VK_APP_ID)
			<< CHAR_PARAM("scope", Score)
			<< CHAR_PARAM("redirect_uri", szBlankUrl)
			<< CHAR_PARAM("display", "mobile")
			<< CHAR_PARAM("response_type", "token")
			<< VER_API;
		pReq->m_bApiReq = false;
		pReq->bIsMainConn = true;
		Push(pReq);
	}

	m_hAPIConnection = NULL;

	while (true) {
		WaitForSingleObject(m_evRequestsQueue, 1000);
		if (m_bTerminated)
			break;

		AsyncHttpRequest *pReq;
		bool need_sleep = false;
		while (true) {
			{
				mir_cslock lck(m_csRequestsQueue);
				if (m_arRequestsQueue.getCount() == 0)
					break;

				pReq = m_arRequestsQueue[0];
				m_arRequestsQueue.remove(0);
				need_sleep = (m_arRequestsQueue.getCount() > 1) && (pReq->m_bApiReq); // more than two to not gather
			}
			if (m_bTerminated)
				break;
			ExecuteRequest(pReq);
			if (need_sleep) { // There can be maximum 3 requests to API methods per second from a client
				Sleep(330);	// (c) https://vk.com/dev/api_requests
				debugLogA("CVkProto::WorkerThread: need sleep");
			}
		}
	}

	if (m_hAPIConnection) {
		debugLogA("CVkProto::WorkerThread: Netlib_CloseHandle(m_hAPIConnection) beg");
		Netlib_CloseHandle(m_hAPIConnection);
		debugLogA("CVkProto::WorkerThread: Netlib_CloseHandle(m_hAPIConnection) end");
	}

	m_hAPIConnection = NULL;
	m_hWorkerThread = 0;
	debugLogA("CVkProto::WorkerThread: leaving m_bTerminated = %d", m_bTerminated ? 1 : 0);
}
Beispiel #5
0
void 
FatParser::ReadAsync(
	PGPUInt8			*buf, 
	PGPUInt64			pos, 
	PGPUInt32			nBytes, 
	GenericCallbackInfo	*upInfo)
{
	DualErr		derr;
	PGPUInt16	blockSize;

	pgpAssertAddrValid(buf, PGPUInt8);
	pgpAssertAddrValid(upInfo, GenericCallbackInfo);
	pgpAssertAddrValid(upInfo->callback, PGPUInt8);

	pgpAssertAddrValid(mFragArray, FileFrag);
	pgpAssert(mHost.Mounted());
	pgpAssert(mNumFragsInUse > 0);

	pgpAssert(!mFatParserReq.isInUse);
	mFatParserReq.isInUse = TRUE;

	blockSize = mHost.GetBlockSize();

	if (pos + nBytes > mBytesFile)
		derr = DualErr(kPGDMinorError_OOBFileRequest);

	// Prepare the request for execution.
	if (derr.IsntError())
	{
		PGPBoolean doneWithRequest;

		mFatParserReq.op = kFPOP_Read;
		mFatParserReq.upInfo = upInfo;

		mFatParserReq.downInfo.callback = FatParserCallback;
		mFatParserReq.downInfo.refData[0] = (PGPUInt32) this;

		// We start out by initializing the request so that all possible
		// pieces of the request are marked as completed.
		
		mFatParserReq.read.readHeader	= TRUE;
		mFatParserReq.read.readMiddle	= TRUE;
		mFatParserReq.read.readTail		= TRUE;

		// Now we analyze the request and determine what pieces must be
		// read so that the entire request can be marked as done.
		
		if (pos%blockSize > 0)
		{
			PGPUInt32 bytesInHeader;

			// The request has a header - that is, it doesn't begin on a
			// block boundary.
			
			bytesInHeader = min(nBytes, blockSize - (PGPUInt32) 
				(pos%blockSize));

			mFatParserReq.read.readHeader	= FALSE;
			mFatParserReq.read.bufHeader	= buf;
			mFatParserReq.read.posHeader	= pos;
			mFatParserReq.read.nBytesHeader	= bytesInHeader;

			buf		+= bytesInHeader;
			pos		+= bytesInHeader;
			nBytes	-= bytesInHeader;
		}

		if (nBytes >= blockSize)
		{
			PGPUInt32 bytesInMiddle;

			// The request has a middle - that is, a section that begins and
			// ends on a block boundary and is more than one block in length.
			
			bytesInMiddle = nBytes - nBytes%blockSize;

			mFatParserReq.read.readMiddle	= FALSE;
			mFatParserReq.read.bufMiddle	= buf;
			mFatParserReq.read.posMiddle	= pos;
			mFatParserReq.read.nBytesMiddle	= bytesInMiddle;

			buf		+= bytesInMiddle;
			pos		+= bytesInMiddle;
			nBytes	-= bytesInMiddle;
		}

		if (nBytes > 0)
		{
			// The request has a tail - that is, it doesn't end on a
			// block boundary.
			
			mFatParserReq.read.readTail		= FALSE;
			mFatParserReq.read.bufTail		= buf;
			mFatParserReq.read.posTail		= pos;
			mFatParserReq.read.nBytesTail	= nBytes;
		}

		// Execute the request.
		ExecuteRequest(&doneWithRequest);

		// Should always have stuff to do at this point. But if we don't, then
		// don't hang the computer by not calling back.

		if (doneWithRequest)
		{
			pgpAssert(FALSE);
			ScheduleAsyncCallback();
		}
	}

	// Callback on error.
	if (derr.IsError())
	{
		ScheduleAsyncCallback(derr);
	}
}
Beispiel #6
0
void 
FatParser::FatParserCallbackAux()
{
	DualErr		derr;
	PGPBoolean	doneWithRequest;
	PGPUInt8	*buf;
	PGPUInt16	blockSize;
	PGPUInt32	nBytes;
	PGPUInt64	pos;

	pgpAssert(mFatParserReq.isInUse);
	blockSize = mHost.GetBlockSize();	

	derr = mFatParserReq.downInfo.derr;

	if (derr.IsntError())
	{
		// Before passing the request to 'ExecuteRequest' we perform some pre-
		// processing on the data manipulated by the piece of the request that
		// was just processed.

		switch (mFatParserReq.op)
		{

		case kFPOP_Read:
			if (!mFatParserReq.read.readHeader)
			{			
				// We read in the header block. Copy just what the caller needs
				// into his buffer.
				
				mFatParserReq.read.readHeader = TRUE;

				buf		= mFatParserReq.read.bufHeader;
				pos		= mFatParserReq.read.posHeader;
				nBytes	= mFatParserReq.read.nBytesHeader;

				pgpAssertAddrValid(buf, PGPUInt8);

				pgpCopyMemory(mDataBuf + pos%blockSize, buf, nBytes);
			}
			else if (!mFatParserReq.read.readMiddle)
			{
				PGPUInt32 bytesRead;

				// We read in a piece of the middle. Copy it into the output
				// buffer, and if there is still more middle left then adjust
				// the variables.
				
				buf			= mFatParserReq.read.bufMiddle;
				pos			= mFatParserReq.read.posMiddle;
				nBytes		= mFatParserReq.read.nBytesMiddle;
				bytesRead	= mFatParserReq.read.sizeCurrentRead;

				pgpAssertAddrValid(buf, PGPUInt8);

				if (nBytes - bytesRead > 0)
				{
					mFatParserReq.read.bufMiddle		+= bytesRead;
					mFatParserReq.read.posMiddle		+= bytesRead;
					mFatParserReq.read.nBytesMiddle		-= bytesRead;
				}
				else
				{
					mFatParserReq.read.readMiddle = TRUE;
				}
			}
			else if (!mFatParserReq.read.readTail)
			{
				// We read in the tail block. Copy just what the caller needs
				// into his buffer.

				mFatParserReq.read.readTail = TRUE;

				buf = mFatParserReq.read.bufTail;
				nBytes = mFatParserReq.read.nBytesTail;

				pgpAssertAddrValid(buf, PGPUInt8);

				pgpCopyMemory(mDataBuf, buf, nBytes);
			}
			break;

		case kFPOP_Write:
			if (!mFatParserReq.write.readHeader)
			{
				// No pre-processing needed here.
				mFatParserReq.write.readHeader = TRUE;
			}
			else if (!mFatParserReq.write.wroteHeader)
			{
				// No pre-processing needed here.
				mFatParserReq.write.wroteHeader = TRUE;
			}
			else if (!mFatParserReq.write.wroteMiddle)
			{
				PGPUInt32 bytesWritten;

				// We wrote out a piece of the middle. Copy it into the output
				// buffer, and if there is still more middle left then adjust
				// the variables.
				
				buf				= mFatParserReq.write.bufMiddle;
				pos				= mFatParserReq.write.posMiddle;
				nBytes			= mFatParserReq.write.nBytesMiddle;
				bytesWritten	= mFatParserReq.write.sizeCurrentWrite;

				pgpAssertAddrValid(buf, PGPUInt8);

				if (nBytes - bytesWritten > 0)
				{
					mFatParserReq.write.bufMiddle		+= bytesWritten;
					mFatParserReq.write.posMiddle		+= bytesWritten;
					mFatParserReq.write.nBytesMiddle	-= bytesWritten;
				}
				else
				{
					mFatParserReq.write.wroteMiddle = TRUE;
				}
			}
			else if (!mFatParserReq.write.readTail)
			{
				// No pre-processing needed here.
				mFatParserReq.write.readTail = TRUE;
			}
			else if (!mFatParserReq.write.wroteTail)
			{
				// No pre-processing needed here.
				mFatParserReq.write.wroteTail = TRUE;
			}
			break;

		default:
			pgpAssert(FALSE);
			break;
		}

		// Perform further processing on this request, if needed.
		ExecuteRequest(&doneWithRequest);
	}

	// Callback if we're done or on error.
	if (doneWithRequest || derr.IsError())
	{
		ScheduleAsyncCallback(derr);
	}
}
Beispiel #7
0
void 
PGPdisk::WriteAsync(
	PGPUInt8			*buf, 
	PGPUInt64			pos, 
	PGPUInt32			nBytes, 
	GenericCallbackInfo	*upInfo)
{
	PGPBoolean doneWithRequest;

	pgpAssertAddrValid(upInfo, GenericCallbackInfo);
	pgpAssertAddrValid(upInfo->callback, PGPUInt8);
	pgpAssertAddrValid(buf, PGPUInt8);

	pgpAssert(Mounted());

	pgpAssert(!mPGPdiskReq.isInUse);
	mPGPdiskReq.isInUse = TRUE;

	// Prepare the request for execution.
	mPGPdiskReq.op = kPGDOP_Write;
	mPGPdiskReq.upInfo = upInfo;

	mPGPdiskReq.downInfo.callback = PGPdiskCallback;
	mPGPdiskReq.downInfo.refData[0] = (PGPUInt32) this;

	// We start out by initializing the request so that all possible
	// pieces of the request are marked as completed.

	mPGPdiskReq.write.readHeader	= TRUE;
	mPGPdiskReq.write.wroteHeader	= TRUE;
	mPGPdiskReq.write.wroteMiddle	= TRUE;
	mPGPdiskReq.write.readTail		= TRUE;
	mPGPdiskReq.write.wroteTail		= TRUE;

	// Now we analyze the request and determine what pieces must be
	// written so that the entire request can be marked as done.

	if (pos%kDefaultBlockSize > 0)
	{
		PGPUInt32 bytesInHeader;

		// The request has a header - that is, it doesn't begin on a
		// block boundary.

		bytesInHeader = min(nBytes, kDefaultBlockSize - 
			(PGPUInt32) (pos%kDefaultBlockSize));

		mPGPdiskReq.write.readHeader	= FALSE;
		mPGPdiskReq.write.wroteHeader	= FALSE;
		mPGPdiskReq.write.bufHeader		= buf;
		mPGPdiskReq.write.posHeader		= pos;
		mPGPdiskReq.write.nBytesHeader	= bytesInHeader;

		buf		+= bytesInHeader;
		pos		+= bytesInHeader;
		nBytes	-= bytesInHeader;
	}

	if (nBytes >= kDefaultBlockSize)
	{
		PGPUInt32 bytesInMiddle;

		// The request has a middle - that is, a section that begins and
		// ends on a block boundary and is more than one block in length.

		bytesInMiddle = nBytes - nBytes%kDefaultBlockSize;

		mPGPdiskReq.write.wroteMiddle	= FALSE;
		mPGPdiskReq.write.bufMiddle		= buf;
		mPGPdiskReq.write.posMiddle		= pos;
		mPGPdiskReq.write.nBytesMiddle	= bytesInMiddle;

		buf		+= bytesInMiddle;
		pos		+= bytesInMiddle;
		nBytes	-= bytesInMiddle;
	}

	if (nBytes > 0)
	{
		// The request has a tail - that is, it doesn't end on a
		// block boundary.

		mPGPdiskReq.write.readTail		= FALSE;
		mPGPdiskReq.write.wroteTail		= FALSE;
		mPGPdiskReq.write.bufTail		= buf;
		mPGPdiskReq.write.posTail		= pos;
		mPGPdiskReq.write.nBytesTail	= nBytes;
	}

	// Execute the request.
	ExecuteRequest(&doneWithRequest);

	// Should always have stuff to do at this point. But if we don't, then
	// don't hang the computer by not calling back.

	if (doneWithRequest)
	{
		pgpAssert(FALSE);
		ScheduleAsyncCallback();
	}
}
Beispiel #8
0
void 
PGPdisk::PGPdiskCallbackAux()
{
	DualErr		derr;
	PGPBoolean	doneWithRequest;
	PGPUInt8	*buf;
	PGPUInt32	nBytes;
	PGPUInt64	pos;

	pgpAssert(mPGPdiskReq.isInUse);

	derr = mPGPdiskReq.downInfo.derr;

	if (derr.IsntError())
	{
		// Before passing the request to 'ExecuteRequest' we perform some pre-
		// processing on the data manipulated by the piece of the request that
		// was just processed.

		switch (mPGPdiskReq.op)
		{

		case kPGDOP_Read:
			if (!mPGPdiskReq.read.readHeader)
			{
				// We read in the header block. Decrypt and copy just what the
				// caller needs into his buffer.

				mPGPdiskReq.read.readHeader = TRUE;

				buf		= mPGPdiskReq.read.bufHeader;
				pos		= mPGPdiskReq.read.posHeader;
				nBytes	= mPGPdiskReq.read.nBytesHeader;

				pgpAssertAddrValid(buf, PGPUInt8);

				SmartCipherBlocks(pos/kDefaultBlockSize, 1, mDataBuf, 
					mDataBuf, kCipherOp_Decrypt);

				pgpCopyMemory(mDataBuf + pos%kDefaultBlockSize, buf, nBytes);
			}
			else if (!mPGPdiskReq.read.readMiddle)
			{
				PGPUInt32 bytesRead;

				// We read in a piece of the middle. Decrypt it, copy it into
				// the output buffer, and if there is still more middle left
				// then adjust the variables.

				buf		= mPGPdiskReq.read.bufMiddle;
				pos		= mPGPdiskReq.read.posMiddle;
				nBytes	= mPGPdiskReq.read.nBytesMiddle;

				pgpAssertAddrValid(buf, PGPUInt8);

				bytesRead = min(nBytes, kPGDBlocksPerOp*kDefaultBlockSize);

				SmartCipherBlocks(pos/kDefaultBlockSize, 
					bytesRead/kDefaultBlockSize, mDataBuf, buf, 
					kCipherOp_Decrypt);

				if (nBytes - bytesRead > 0)
				{
					mPGPdiskReq.read.bufMiddle		+= bytesRead;
					mPGPdiskReq.read.posMiddle		+= bytesRead;
					mPGPdiskReq.read.nBytesMiddle	-= bytesRead;
				}
				else
				{
					mPGPdiskReq.read.readMiddle = TRUE;
				}
			}
			else if (!mPGPdiskReq.read.readTail)
			{
				// We read in the tail block. Decrypt and copy just what the
				// caller needs into his buffer.

				mPGPdiskReq.read.readTail = TRUE;

				buf		= mPGPdiskReq.read.bufTail;
				pos		= mPGPdiskReq.read.posTail;
				nBytes	= mPGPdiskReq.read.nBytesTail;

				pgpAssertAddrValid(buf, PGPUInt8);

				SmartCipherBlocks(pos/kDefaultBlockSize, 1, mDataBuf, 
					mDataBuf, kCipherOp_Decrypt);

				pgpCopyMemory(mDataBuf, buf, nBytes);
			}
			break;

		case kPGDOP_Write:
			if (!mPGPdiskReq.write.readHeader)
			{
				// No pre-processing needed here.
				mPGPdiskReq.write.readHeader = TRUE;
			}
			else if (!mPGPdiskReq.write.wroteHeader)
			{
				// No pre-processing needed here.
				mPGPdiskReq.write.wroteHeader = TRUE;
			}
			else if (!mPGPdiskReq.write.wroteMiddle)
			{
				PGPUInt32 bytesWritten;

				// We wrote out a piece of the middle. If there is still more
				// middle left to write out then adjust the variables.

				buf		= mPGPdiskReq.write.bufMiddle;
				pos		= mPGPdiskReq.write.posMiddle;
				nBytes	= mPGPdiskReq.write.nBytesMiddle;

				pgpAssertAddrValid(buf, PGPUInt8);

				bytesWritten = min(nBytes, kPGDBlocksPerOp*kDefaultBlockSize);

				if (nBytes - bytesWritten > 0)
				{
					mPGPdiskReq.write.bufMiddle		+= bytesWritten;
					mPGPdiskReq.write.posMiddle		+= bytesWritten;
					mPGPdiskReq.write.nBytesMiddle	-= bytesWritten;
				}
				else
				{
					mPGPdiskReq.write.wroteMiddle = TRUE;
				}
			}
			else if (!mPGPdiskReq.write.readTail)
			{
				// No pre-processing needed here.
				mPGPdiskReq.write.readTail = TRUE;
			}
			else if (!mPGPdiskReq.write.wroteTail)
			{
				// No pre-processing needed here.
				mPGPdiskReq.write.wroteTail = TRUE;
			}
			break;

		default:
			pgpAssert(FALSE);
			break;
		}

		// Perform further processing on this request, if needed.
		ExecuteRequest(&doneWithRequest);
	}

	// Callback if we're done or on error.
	if (doneWithRequest || derr.IsError())
	{
		ScheduleAsyncCallback(derr);
	}
}
Beispiel #9
0
void CBitprintsDownloader::OnRun()
{
	while ( m_hInternet != NULL )
	{
		m_pSection.Lock();

		if ( m_pFiles.IsEmpty() )
		{
			m_pSection.Unlock();
			break;
		}

		m_nFileIndex = m_pFiles.RemoveHead();

		m_pSection.Unlock();

		m_pDlg->OnNextFile( m_nFileIndex );

		if ( BuildRequest() )
		{
			m_pDlg->OnRequesting( m_nFileIndex, m_sFileName );

			if ( ExecuteRequest() )
			{
				if ( DecodeResponse() )
				{
					m_pDlg->OnSuccess( m_nFileIndex );
				}
				else
				{
					if ( m_hInternet == NULL ) break;
					m_pDlg->OnFailure( m_nFileIndex, L"Not Found" );
				}
			}
			else if ( ++m_nFailures >= 3 )
			{
				if ( m_hInternet == NULL ) break;
				m_pDlg->OnFailure( m_nFileIndex, L"Aborting" );
				break;
			}
			else
			{
				if ( m_hInternet == NULL ) break;

				if ( m_hRequest ) InternetCloseHandle( m_hRequest );
				m_hRequest = NULL;

				m_pDlg->OnFailure( m_nFileIndex, L"Failed" );

				Sleep( 1000 );
			}
		}

		m_pDlg->OnFinishedFile( m_nFileIndex );

		if ( m_hRequest ) InternetCloseHandle( m_hRequest );
		m_hRequest = NULL;

		m_sResponse.Empty();

		if ( m_pXML ) delete m_pXML;
		m_pXML = NULL;

		Sleep( min( m_nDelay, 500ul ) );
	}

	if ( m_hSession != NULL && ! m_bFinished ) InternetCloseHandle( m_hSession );
	m_hSession = NULL;

	m_bFinished = TRUE;
}
Beispiel #10
0
//---------------------------------------------------------------------------
int TTrdItf_GTJA::GetStkAccount(char *LogType, char *Logid, char *ZJ, char *SH, char *SZ)//获得主股东账号
{
	char szFunid[] = "410301";

	if(InitRequest(szFunid, true) != 0)
		return -1;

	KCBPCLI_SetValue(FHandle, "inputtype", LogType);//登录类型	inputtype	char(1)	Y	见备注
	KCBPCLI_SetValue(FHandle, "inputid", Logid);//登录标识	inputid	char(64)	Y	见备注

	int nReturnCode = ExecuteRequest(szFunid);
	if( nReturnCode != 0 && nReturnCode != 100 ) //nReturnCode = 0 全部返回了,=100表示还有数据
	{
		return nReturnCode;
	}
	char szTmpbuf[20];
	if( KCBPCLI_SQLMoreResults(FHandle) == 0 )
	{

		try
		{
			bool bFlag[2] = {false, false};
			while( !KCBPCLI_RsFetchRow(FHandle) )
			{
				if( KCBPCLI_RsGetColByName( FHandle, "market", szTmpbuf ) == 0)
				{
					if(lstrcmpi(szTmpbuf, "1") == 0 && !bFlag[0])
					{
						bFlag[0] = true;
						if( KCBPCLI_RsGetColByName( FHandle, "secuid", SH) != 0)
							return -1;
					}
					else if(lstrcmpi(szTmpbuf,this->FGTJASet.bencrypt==true ? "2":"0") == 0 && !bFlag[1])
					{
						bFlag[1] = true;
						if( KCBPCLI_RsGetColByName( FHandle, "secuid", SZ) != 0)
							return -1;
					}
				}
				else
					return -1;

				if(KCBPCLI_RsGetColByName( FHandle, "fundid", ZJ ) != 0)
					return -1;

				if(KCBPCLI_RsGetColByName( FHandle, "custid", FCustid ) != 0)
					return -1;

				if(KCBPCLI_RsGetColByName( FHandle, "bankcode", FBankCode ) != 0)
					return -1;

				//ODS('M',PLUGINNAME,"银行代码:%s", FBankCode);

				if(bFlag[0] && bFlag[1])
					break;
			}
		}
		__finally
		{
			KCBPCLI_SQLCloseCursor(FHandle);
		}
	}
	else
		return -1;
Beispiel #11
0
int CHttpClient::HttpPost(LPCTSTR strUrl, LPCTSTR strPostData, string &strResponse)
{
    return ExecuteRequest(_T("POST"), strUrl, strPostData, strResponse);
}