ultimatepp/bazaar/Serial/SerialWindows.cpp

#include "Serial.h"

#ifdef WIN32

#include <tchar.h>
typedef DWORD REGSAM;

#ifdef USE_SETUPAPI
#include <setupapi.h>
#endif

NAMESPACE_UPP

dword Serial::stdBauds[] =
{
	50, 75, 110, 134, 150, 200,
	300, 600, 1200, 1800, 2400,
	4800, 9600, 19200,
	38400, 57600, 115200, 128000, 256000
};

int Serial::stdBaudsCount = sizeof ( Serial::stdBauds ) / sizeof ( dword );

// constructor
Serial::Serial()
{
	isError = false;
	errCode = Ok;
	fd = INVALID_HANDLE_VALUE;
}

Serial::Serial ( String const &port, unsigned long speed, byte parity, byte bits, byte stopBits )
{
	isError = false;
	errCode = Ok;
	fd = INVALID_HANDLE_VALUE;
	Open ( port, speed, parity, bits, stopBits );
}

// destructor
Serial::~Serial()
{
	Close();
}

// open the port
bool Serial::Open ( String const &port, dword speed, byte parity, byte bits, byte stopBits )
{
	// open the device
	fd = CreateFile ( "\\\\.\\" + port, GENERIC_READ | GENERIC_WRITE, 0, 0, OPEN_EXISTING, 0, 0 );

	if ( fd == INVALID_HANDLE_VALUE )
	{
		isError = true;
		errCode = DeviceError;
		return false;
	}

	DCB dcb;

	char dcbSz[50];
	COMMTIMEOUTS cmt;

	// clear dcb and set length
	FillMemory ( &dcb, sizeof ( dcb ), 0 );
	dcb.DCBlength = sizeof ( dcb );

	// check baud is valid

	if ( GetStandardBaudRates().Find ( speed ) < 0 )
	{
		Close();
		isError = true;
		errCode = InvalidSpeed;
		return false;
	}

	// check parity */
	char cParity;

	switch ( parity )
	{

		case ParityNone :
			cParity = 'n';
			break;

		case ParityEven :
			cParity = 'e';
			break;

		case ParityOdd :
			cParity = 'o';
			break;

		case ParityMark :

		case ParitySpace :

		default:
			{
				Close();
				isError = true;
				errCode = InvalidParity;
				return false;
			}
	}

	// check data bits

	if ( bits < 5 || bits > 8 )
	{
		Close();
		isError = true;
		errCode = InvalidSize;
		return false;
	}

	// check stop bits

	if ( stopBits < 1 || stopBits > 2 )
	{
		Close();
		isError = true;
		errCode = InvalidStopBits;
		return false;
	}

	// build dcb
	sprintf_s ( dcbSz, 49, "%d,%c,%d,%d", speed, cParity, bits, stopBits );

	if ( !BuildCommDCB ( dcbSz, &dcb ) )
	{
		Close();
		isError = true;
		errCode = DeviceError;
		return false;
	}

	/*
	    dcb.BaudRate = speed;
	    if(stopBits == 1)
		    dcb.StopBits = ONESTOPBIT;
	    else
		    dcb.StopBits = TWOSTOPBITS;
	    switch(parity)
	    {
	        case ParityNone:
			    dcb.Parity = PARITY_NONE;
			    break;
	        case ParityEven:
			    dcb.Parity = PARITY_EVEN;
			    break;
	        case ParityOdd:
			    dcb.Parity = PARITY_ODD;
			    break;
			default:
				break;
	    }
	    switch(bits)
	    {
	        case 5:
			    dcb.ByteSize = DATABITS_5;
			    break;
	        case 7:
			    dcb.ByteSize = DATABITS_7;
			    break;
	        case 8:
			    dcb.ByteSize = DATABITS_8;
			    break;
			default:
				break;
	    }
	    dcb.fDtrControl = 0;
	    dcb.fRtsControl = 0;
	*/


	// set dcb to serial port */

	if ( !SetCommState ( fd, &dcb ) )
	{
		Close();
		isError = true;
		errCode = DeviceError;
		return false;
	}

	// set input and output bufffer sizes

	if ( !SetupComm ( fd, 1024, 1024 ) )
	{
		Close();
		isError = true;
		errCode = DeviceError;
		return false;
	}

	// set timeouts to 0 -- non blocking
	cmt.ReadIntervalTimeout = MAXDWORD;

	cmt.ReadTotalTimeoutMultiplier = 0;

	cmt.ReadTotalTimeoutConstant = 0;

	cmt.WriteTotalTimeoutMultiplier = 0;

	cmt.WriteTotalTimeoutConstant = MAXDWORD;

	if ( !SetCommTimeouts ( fd, &cmt ) )
	{
		Close();
		isError = true;
		errCode = DeviceError;
		return false;
	}

	return true;
}

// close the port
void Serial::Close ( void )
{
	if ( fd == INVALID_HANDLE_VALUE )
		return;

	// cancel pending i/o
	CancelIo ( fd );

	// close the device
	CloseHandle ( fd );

	fd = INVALID_HANDLE_VALUE;
}

// flush data
bool Serial::FlushInput ( void )
{
	return PurgeComm ( fd, PURGE_RXCLEAR );
}

bool Serial::FlushOutput ( void )
{
	return PurgeComm ( fd, PURGE_TXCLEAR );
}

bool Serial::FlushAll ( void )
{
	return PurgeComm ( fd, PURGE_RXCLEAR ) & PurgeComm ( fd, PURGE_TXCLEAR );
}

// read a single byte, block 'timeout' milliseconds
bool Serial::Read ( byte &c, uint32_t timeout )
{
	char buf[1];
	unsigned long count = 0;

	uint32_t tim = ( uint32_t ) msecs() + timeout;

	for ( ;; )
	{
		count = 0;
		ReadFile ( fd, buf, 1, &count, NULL );

		if ( !count )
		{
			if ( ( uint32_t ) msecs() > tim )
				return false;

			continue;
		}

		c = ( byte ) buf[0];

		return true;
	}
}

bool Serial::Read ( char &c, uint32_t timeout )
{
	char buf[1];
	unsigned long count = 0;

	uint32_t tim = ( uint32_t ) msecs() + timeout;

	for ( ;; )
	{
		count = 0;
		ReadFile ( fd, buf, 1, &count, NULL );

		if ( !count )
		{
			if ( ( uint32_t ) msecs() > tim )
				return false;

			continue;
		}

		c = buf[0];

		return true;
	}
}

// write a single byte
bool Serial::Write ( char c, uint32_t timeout )
{
	unsigned long count = 0;

	if ( !timeout )
	{
		WriteFile ( fd, &c, 1, &count, NULL );
		return count == 1;
	}

	else
	{
		uint32_t tim = msecs() + timeout;

		for ( ;; )
		{
			WriteFile ( fd, &c, 1, &count, NULL );
			if ( count == 1 )
				return true;

			if ( ( uint32_t ) msecs() > tim )
				break;
		}

		return false;
	}
}


// read data, requested amount, blocks 'timeout' milliseconds
// if reqSize == 0 just read all available data, waiting for 'timeout' if != 0
String Serial::Read ( size_t reqSize, uint32_t timeout )
{
	char buf[1001];
	String res;

	unsigned long count = 0;
	unsigned long n;
	uint32_t tim = ( uint32_t ) msecs() + timeout;

	if ( reqSize )
	{
		n = min ( reqSize, ( size_t ) 1000 );

		while ( reqSize )
		{
			count = 0;
			ReadFile ( fd, buf, n, &count, NULL );

			if ( !count )
			{
				if ( ( uint32_t ) msecs() > tim )
					break;

				continue;
			}

			tim = ( uint32_t ) msecs() + timeout;

			if ( count )
			{
				reqSize -= count;
				res.Cat ( buf, count );
			}

			n = min ( reqSize, ( size_t ) 1000 );
		}
	}

	else
	{
		for ( ;; )
		{
			count = 0;
			ReadFile ( fd, buf, 1000, &count, NULL );

			if ( !count )
			{
				if ( ( uint32_t ) msecs() > tim )
					break;

				continue;
			}

			tim = ( uint32_t ) msecs() + timeout;

			if ( count )
				res.Cat ( buf, count );
		}
	}

	return res;
}

// writes data
bool Serial::Write ( String const &data, uint32_t timeout )
{
	unsigned long count = 0;

	int dLen = data.GetCount();

	if ( !timeout )
	{
		WriteFile ( fd, ~data, dLen, &count, NULL );
		return count == dLen;
	}

	uint32_t tim = msecs() + timeout;

	const char *dPos = ~data;

	for ( ;; )
	{
		WriteFile ( fd, dPos, dLen, &count, NULL );
		if ( count == dLen )
			return true;

		if ( count > 0 )
		{
			dPos += count;
			dLen -= count;
			continue;
		}

		if ( ( uint32_t ) msecs() >= tim )
			break;
	}

	return false;

}

// check if opened
bool Serial::IsOpened ( void ) const
{
	return fd != INVALID_HANDLE_VALUE;
}

///////////////////////////////////////////////////////////////////////////////////////////////////////
#ifdef USE_SETUPAPI

// ENUMERATE PORTS USING SETUPAPI

#ifndef GUID_DEVINTERFACE_COMPORT
DEFINE_GUID ( GUID_DEVINTERFACE_COMPORT, 0x86E0D1E0L, 0x8089, 0x11D0, 0x9C, 0xE4, 0x08, 0x00, 0x3E, 0x30, 0x1F, 0x73 );
#endif

typedef HKEY ( __stdcall SETUPDIOPENDEVREGKEY ) ( HDEVINFO, PSP_DEVINFO_DATA, DWORD, DWORD, DWORD, REGSAM );
typedef BOOL ( __stdcall SETUPDICLASSGUIDSFROMNAME ) ( LPCTSTR, LPGUID, DWORD, PDWORD );
typedef BOOL ( __stdcall SETUPDIDESTROYDEVICEINFOLIST ) ( HDEVINFO );
typedef BOOL ( __stdcall SETUPDIENUMDEVICEINFO ) ( HDEVINFO, DWORD, PSP_DEVINFO_DATA );
typedef HDEVINFO ( __stdcall SETUPDIGETCLASSDEVS ) ( LPGUID, LPCTSTR, HWND, DWORD );
typedef BOOL ( __stdcall SETUPDIGETDEVICEREGISTRYPROPERTY ) ( HDEVINFO, PSP_DEVINFO_DATA, DWORD, PDWORD, PBYTE, DWORD, PDWORD );

class CAutoHModule
{

	public:
		CAutoHModule() : m_hModule ( NULL ), m_dwError ( ERROR_SUCCESS ) {}

		explicit CAutoHModule ( HMODULE hModule ) : m_hModule ( hModule ), m_dwError ( GetLastError() ) {}

		explicit CAutoHModule ( HMODULE hModule, DWORD dwError ) : m_hModule ( hModule ),	m_dwError ( dwError ) {}

		~CAutoHModule()
		{
			if ( m_hModule != NULL )
			{
				FreeLibrary ( m_hModule );
				m_hModule = NULL;
			}

			SetLastError ( m_dwError );
		}

		operator HMODULE()
		{
			return m_hModule;
		}

		HMODULE m_hModule;
		DWORD m_dwError;
};

static HMODULE LoadLibraryFromSystem32 ( LPCTSTR lpFileName )
{
	//Get the Windows System32 directory
	TCHAR szFullPath[_MAX_PATH];
	szFullPath[0] = _T ( '\0' );

	if ( ::GetSystemDirectory ( szFullPath, _countof ( szFullPath ) ) == 0 )
		return NULL;

	//Setup the full path and delegate to LoadLibrary
#pragma warning(suppress: 6102) //There is a bug with the SAL annotation of GetSystemDirectory in the Windows 8.1 SDK
	_tcscat_s ( szFullPath, _countof ( szFullPath ), _T ( "\\" ) );

	_tcscat_s ( szFullPath, _countof ( szFullPath ), lpFileName );

	return LoadLibrary ( szFullPath );
}

static BOOL RegQueryValueString ( HKEY kKey, LPCTSTR lpValueName, LPTSTR& pszValue )
{
	//Initialize the output parameter
	pszValue = NULL;

	//First query for the size of the registry value
	DWORD dwType = 0;
	DWORD dwDataSize = 0;
	LONG nError = RegQueryValueEx ( kKey, lpValueName, NULL, &dwType, NULL, &dwDataSize );

	if ( nError != ERROR_SUCCESS )
	{
		SetLastError ( nError );
		return FALSE;
	}

	//Ensure the value is a string

	if ( dwType != REG_SZ )
	{
		SetLastError ( ERROR_INVALID_DATA );
		return FALSE;
	}

	//Allocate enough bytes for the return value
	DWORD dwAllocatedSize = dwDataSize + sizeof ( TCHAR ); //+sizeof(TCHAR) is to allow us to NULL terminate the data if it is not null terminated in the registry

	pszValue = reinterpret_cast<LPTSTR> ( LocalAlloc ( LMEM_FIXED, dwAllocatedSize ) );

	if ( pszValue == NULL )
		return FALSE;

	//Recall RegQueryValueEx to return the data
	pszValue[0] = _T ( '\0' );

	DWORD dwReturnedSize = dwAllocatedSize;

	nError = RegQueryValueEx ( kKey, lpValueName, NULL, &dwType, reinterpret_cast<LPBYTE> ( pszValue ), &dwReturnedSize );

	if ( nError != ERROR_SUCCESS )
	{
		LocalFree ( pszValue );
		pszValue = NULL;
		SetLastError ( nError );
		return FALSE;
	}

	//Handle the case where the data just returned is the same size as the allocated size. This could occur where the data
	//has been updated in the registry with a non null terminator between the two calls to ReqQueryValueEx above. Rather than
	//return a potentially non-null terminated block of data, just fail the method call

	if ( dwReturnedSize >= dwAllocatedSize )
	{
		SetLastError ( ERROR_INVALID_DATA );
		return FALSE;
	}

	//NULL terminate the data if it was not returned NULL terminated because it is not stored null terminated in the registry

	if ( pszValue[dwReturnedSize/sizeof ( TCHAR ) - 1] != _T ( '\0' ) )
		pszValue[dwReturnedSize/sizeof ( TCHAR ) ] = _T ( '\0' );

	return TRUE;
}

static BOOL IsNumeric ( LPCSTR pszString, BOOL bIgnoreColon )
{
	size_t nLen = strlen ( pszString );

	if ( nLen == 0 )
		return FALSE;

	//What will be the return value from this function (assume the best)
	BOOL bNumeric = TRUE;

	for ( size_t i = 0; i < nLen && bNumeric; i++ )
	{
		bNumeric = ( isdigit ( static_cast<int> ( pszString[i] ) ) != 0 );

		if ( bIgnoreColon && ( pszString[i] == ':' ) )
			bNumeric = TRUE;
	}

	return bNumeric;
}

static BOOL IsNumeric ( LPCWSTR pszString, BOOL bIgnoreColon )
{
	size_t nLen = wcslen ( pszString );

	if ( nLen == 0 )
		return FALSE;

	//What will be the return value from this function (assume the best)
	BOOL bNumeric = TRUE;

	for ( size_t i = 0; i < nLen && bNumeric; i++ )
	{
		bNumeric = ( iswdigit ( pszString[i] ) != 0 );

		if ( bIgnoreColon && ( pszString[i] == L':' ) )
			bNumeric = TRUE;
	}

	return bNumeric;
}

static BOOL QueryRegistryPortName ( HKEY hDeviceKey, int& nPort )
{
	//What will be the return value from the method (assume the worst)
	BOOL bAdded = FALSE;

	//Read in the name of the port
	LPTSTR pszPortName = NULL;

	if ( RegQueryValueString ( hDeviceKey, _T ( "PortName" ), pszPortName ) )
	{
		//If it looks like "COMX" then
		//add it to the array which will be returned
		size_t nLen = _tcslen ( pszPortName );

		if ( nLen > 3 )
		{
			if ( ( _tcsnicmp ( pszPortName, _T ( "COM" ), 3 ) == 0 ) && IsNumeric ( ( pszPortName + 3 ), FALSE ) )
			{
				//Work out the port number
				nPort = _ttoi ( pszPortName + 3 );

				bAdded = TRUE;
			}
		}

		LocalFree ( pszPortName );
	}

	return bAdded;
}

// get a list of all serial ports
ArrayMap<String, String> Serial::GetSerialPorts ( void )
{
	ArrayMap<String, String> res;

	//Get the various function pointers we require from setupapi.dll
	CAutoHModule setupAPI ( LoadLibraryFromSystem32 ( _T ( "SETUPAPI.DLL" ) ) );

	if ( setupAPI == NULL )
		return res;

	SETUPDIOPENDEVREGKEY* lpfnSETUPDIOPENDEVREGKEY = reinterpret_cast<SETUPDIOPENDEVREGKEY*> ( GetProcAddress ( setupAPI, "SetupDiOpenDevRegKey" ) );

	/*
	#if defined _UNICODE
	*/
	SETUPDIGETCLASSDEVS* lpfnSETUPDIGETCLASSDEVS = reinterpret_cast<SETUPDIGETCLASSDEVS*> ( GetProcAddress ( setupAPI, "SetupDiGetClassDevsW" ) );

	SETUPDIGETDEVICEREGISTRYPROPERTY* lpfnSETUPDIGETDEVICEREGISTRYPROPERTY = reinterpret_cast<SETUPDIGETDEVICEREGISTRYPROPERTY*> ( GetProcAddress ( setupAPI, "SetupDiGetDeviceRegistryPropertyW" ) );

	/*
	#else
		SETUPDIGETCLASSDEVS* lpfnSETUPDIGETCLASSDEVS = reinterpret_cast<SETUPDIGETCLASSDEVS*>(GetProcAddress(setupAPI, "SetupDiGetClassDevsA"));

		SETUPDIGETDEVICEREGISTRYPROPERTY* lpfnSETUPDIGETDEVICEREGISTRYPROPERTY = reinterpret_cast<SETUPDIGETDEVICEREGISTRYPROPERTY*>(GetProcAddress(setupAPI, "SetupDiGetDeviceRegistryPropertyA"));

	#endif
	*/
	SETUPDIDESTROYDEVICEINFOLIST* lpfnSETUPDIDESTROYDEVICEINFOLIST = reinterpret_cast<SETUPDIDESTROYDEVICEINFOLIST*> ( GetProcAddress ( setupAPI, "SetupDiDestroyDeviceInfoList" ) );

	SETUPDIENUMDEVICEINFO* lpfnSETUPDIENUMDEVICEINFO = reinterpret_cast<SETUPDIENUMDEVICEINFO*> ( GetProcAddress ( setupAPI, "SetupDiEnumDeviceInfo" ) );

	if ( ( lpfnSETUPDIOPENDEVREGKEY == NULL ) || ( lpfnSETUPDIDESTROYDEVICEINFOLIST == NULL ) ||
		 ( lpfnSETUPDIENUMDEVICEINFO == NULL ) || ( lpfnSETUPDIGETCLASSDEVS == NULL ) || ( lpfnSETUPDIGETDEVICEREGISTRYPROPERTY == NULL ) )
	{
		//Set the error to report
		setupAPI.m_dwError = ERROR_CALL_NOT_IMPLEMENTED;

		return res;
	}

	//Now create a "device information set" which is required to enumerate all the ports
	GUID guid = GUID_DEVINTERFACE_COMPORT;

	HDEVINFO hDevInfoSet = lpfnSETUPDIGETCLASSDEVS ( &guid, NULL, NULL, DIGCF_PRESENT | DIGCF_DEVICEINTERFACE );

	if ( hDevInfoSet == INVALID_HANDLE_VALUE )
	{
		//Set the error to report
		setupAPI.m_dwError = GetLastError();

		return res;
	}

	//Finally do the enumeration
	BOOL bMoreItems = TRUE;

	int nIndex = 0;

	SP_DEVINFO_DATA devInfo;

	while ( bMoreItems )
	{
		//Enumerate the current device
		devInfo.cbSize = sizeof ( SP_DEVINFO_DATA );
		bMoreItems = lpfnSETUPDIENUMDEVICEINFO ( hDevInfoSet, nIndex, &devInfo );

		if ( bMoreItems )
		{
			//Did we find a serial port for this device
			BOOL bAdded = FALSE;
			String port, friendly;

			//Get the registry key which stores the ports settings
			HKEY hDeviceKey = lpfnSETUPDIOPENDEVREGKEY ( hDevInfoSet, &devInfo, DICS_FLAG_GLOBAL, 0, DIREG_DEV, KEY_QUERY_VALUE );

			if ( hDeviceKey != INVALID_HANDLE_VALUE )
			{
				int nPort = 0;

				if ( QueryRegistryPortName ( hDeviceKey, nPort ) )
				{
					port = Format ( "COM%d", nPort );
					bAdded = TRUE;
				}

				//Close the key now that we are finished with it
				RegCloseKey ( hDeviceKey );
			}

			//If the port was a serial port, then also try to get its friendly name

			if ( bAdded )
			{
				TCHAR szFriendlyName[1024];
				szFriendlyName[0] = _T ( '\0' );
				DWORD dwSize = sizeof ( szFriendlyName );
				DWORD dwType = 0;

				if ( lpfnSETUPDIGETDEVICEREGISTRYPROPERTY ( hDevInfoSet, &devInfo, SPDRP_DEVICEDESC, &dwType, reinterpret_cast<PBYTE> ( szFriendlyName ), dwSize, &dwSize ) && ( dwType == REG_SZ ) )
					friendly = szFriendlyName;
				else
					friendly = "";

				res.Add ( port, friendly );
			}
		}

		++nIndex;
	}

	//Free up the "device information set" now that we are finished with it
	lpfnSETUPDIDESTROYDEVICEINFOLIST ( hDevInfoSet );

	return res;
}

#else

// ENUMERATE PORTS BY REGISTI ENTRIES

// get a list of all serial ports
ArrayMap<String, String> Serial::GetSerialPorts ( void )
{
	ArrayMap<String, String> res;

	HKEY hSERIALCOMM;

	if ( RegOpenKeyEx ( HKEY_LOCAL_MACHINE, _T ( "HARDWARE\\DEVICEMAP\\SERIALCOMM" ), 0, KEY_QUERY_VALUE, &hSERIALCOMM ) == ERROR_SUCCESS )
	{
		//Get the max value name and max value lengths
		DWORD dwMaxValueNameLen;
		DWORD dwMaxValueLen;
		DWORD dwQueryInfo = RegQueryInfoKey ( hSERIALCOMM, NULL, NULL, NULL, NULL, NULL, NULL, NULL, &dwMaxValueNameLen, &dwMaxValueLen, NULL, NULL );

		if ( dwQueryInfo == ERROR_SUCCESS )
		{
			DWORD dwMaxValueNameSizeInChars = dwMaxValueNameLen + 1; //Include space for the NULL terminator
			DWORD dwMaxValueNameSizeInBytes = dwMaxValueNameSizeInChars * sizeof ( TCHAR );
			DWORD dwMaxValueDataSizeInChars = dwMaxValueLen / sizeof ( TCHAR ) + 1; //Include space for the NULL terminator
			DWORD dwMaxValueDataSizeInBytes = dwMaxValueDataSizeInChars * sizeof ( TCHAR );

			//Allocate some space for the value name and value data
			TCHAR *valueName = (TCHAR *)malloc(dwMaxValueNameSizeInBytes + 1);
			TCHAR *valueData = (TCHAR *)malloc(dwMaxValueDataSizeInChars + 1);

			//Enumerate all the values underneath HKEY_LOCAL_MACHINE\HARDWARE\DEVICEMAP\SERIALCOMM
			DWORD dwIndex = 0;
			DWORD dwType;
			DWORD dwValueNameSize = dwMaxValueNameSizeInChars;
			DWORD dwDataSize = dwMaxValueDataSizeInBytes;
			memset (valueName, 0, dwMaxValueNameSizeInBytes );
			memset (valueData, 0, dwMaxValueDataSizeInBytes );
			TCHAR* szValueName = valueName;
			BYTE* byValue = (BYTE *)valueData;
			LONG nEnum = RegEnumValue (hSERIALCOMM, dwIndex, szValueName, &dwValueNameSize, NULL, &dwType, byValue, &dwDataSize );

			while ( nEnum == ERROR_SUCCESS )
			{
				//If the value is of the correct type, then add it to the array
				if ( dwType == REG_SZ )
				{
					TCHAR* szPort = reinterpret_cast<TCHAR*> ( byValue );
					res.Add(szPort, szPort);
				}

				//Prepare for the next time around
				dwValueNameSize = dwMaxValueNameSizeInChars;
				dwDataSize = dwMaxValueDataSizeInBytes;
				memset (valueName, 0, dwMaxValueNameSizeInBytes );
				memset (valueData, 0, dwMaxValueDataSizeInBytes );
				++dwIndex;
				nEnum = RegEnumValue (hSERIALCOMM, dwIndex, szValueName, &dwValueNameSize, NULL, &dwType, byValue, &dwDataSize );
			}
			
			free(valueName);
			free(valueData);
		}

		//Close the registry key now that we are finished with it
		RegCloseKey ( hSERIALCOMM );

		if ( dwQueryInfo != ERROR_SUCCESS )
			SetLastError ( dwQueryInfo );
	}

	return res;
}
#endif

END_UPP_NAMESPACE

#endif