DWORD TrayIconThread(LPVOID pvarg)
{
LPCTSTR szClassName = _T("ZTrayIcon");
WNDCLASS wc;
/*while(!IsAPIReady(SH_SHELL))
{}*/
WaitForAPIReady(SH_SHELL, INFINITE);
if(hTrayIcon == NULL)
{
ZeroMemory(&wc, sizeof(wc));
wc.lpfnWndProc = IconProc;
wc.hInstance = GetModuleHandle(NULL);
wc.lpszClassName = szClassName;
wc.hCursor = NULL;
wc.hbrBackground = NULL;
RegisterClass(&wc);
hTrayIcon = CreateWindow(szClassName, _T(""), WS_POPUP | WS_CLIPCHILDREN, 0, 0, 0, 0, NULL, NULL, wc.hInstance, NULL);
MSG msg;
while(GetMessage(&msg, NULL, 0, 0))
{
TranslateMessage(&msg);
DispatchMessage(&msg);
}
hTrayIcon = NULL;
}
RETAILMSG(1, (TEXT("\n\rExitIconProc -> TrayIconThread\n\r")));
return 0;
}
RESULT
LayerManager::Draw()
{
RESULT rval = S_OK;
ResourceListIterator ppLayer;
//
// Render the Layer and any children.
//
// CHR(Renderer.EnableDepthTest ( true ));
CHR(Renderer.EnableDepthTest ( false ));
CHR(Renderer.EnableLighting ( false ));
// CHR(Renderer.EnableAlphaBlend( true ));
CHR(Renderer.EnableAlphaTest ( false )); // Alpha Test on iPhone (3G) is not any faster than Alpha Blend.
CHR(Renderer.EnableTexturing ( true ));
for (ppLayer = m_resourceList.begin(); ppLayer != m_resourceList.end(); ++ppLayer)
{
Layer* pLayer = *ppLayer;
DEBUGCHK(pLayer);
// Only draw root layers in this method.
// They in turn draw their children.
// We can have multiple roots (e.g. the game world and the UI).
if (pLayer->IsRootLayer())
{
CHR(Draw( pLayer, GameCamera.GetViewMatrix() ));
}
}
Exit:
if (FAILED(rval))
{
RETAILMSG(ZONE_ERROR, "ERROR: LayerManager::Draw(): rval = 0x%x", rval);
DEBUGCHK(0);
}
return rval;
}
/**
* @fn PwrCon_get_reset_statys(void)
* @note This funciton read the reset status which means what trigger reset the system in the last time
*/
RESET_STATUS PwrCon_get_reset_status(void)
{
RESET_STATUS RstStatus = RST_UNKNOWN;
assert(g_pSysConReg->NORMAL_CFG);
RstStatus = g_pSysConReg->RST_STAT;
switch(RstStatus)
{
case RST_HW_RESET:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : H/W Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
case RST_WARM_RESET:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : Warm Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
case RST_WDT_RESET:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : Watch Dog Timer Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
case RST_SLEEP_WAKEUP:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : Sleep/Wakeup Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
case RST_ESLEEP_WAKEUP:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : eSleep/Wakeup Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
case RST_SW_RESET:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:INF] %s() : S/W Reset [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
default:
RETAILMSG(PWC_ZONE_TEMP, (_T("[PWRCON:ERR] %s() : Unknown RST_STAT [0x%08x]\n"), _T(__FUNCTION__), g_pSysConReg->RST_STAT));
break;
}
RETAILMSG(PWC_ZONE_ENTER, (_T("[PWRCON] %s() = %d\n"), _T(__FUNCTION__), RstStatus));
return RstStatus;
}
/**
* @fn DWORD FIMGSE2D::CalculateXYIncrFormat(DWORD uDividend, DWORD uDivisor)
* @brief This function returns x_incr or y_incr vaule in register format
* @input this function accept real pixel coordinate, ex) (0,0)~(9,9) means that 10pixel by pixel image
* @return Result value
*/
DWORD FIMGSE2D::CalculateXYIncrFormat(DWORD uDividend, DWORD uDivisor)
{
int i;
DWORD uQuotient;
DWORD uUnderPoint=0;
if(uDivisor == 0)
{
uDivisor = 1; //< this will prevent data abort. but result is incorrect.
}
uQuotient = (DWORD)(uDividend/uDivisor);
// Quotient should be less than MAX_XCOORD or MAX_YCOORD.
if(uQuotient > MAX_2DHW_XCOORD)
{
RETAILMSG(DISP_ZONE_WARNING, (TEXT("Increment value to stretch can not exceed %d, Value will be set as 1.0\n"), MAX_2DHW_XCOORD));
return ((1<<11) | 0 );
}
uDividend-=(uQuotient*uDivisor);
/// Now under point is calculated.
for (i=0; i<12; i++)
{
uDividend <<= 1;
uUnderPoint <<= 1;
if (uDividend >= uDivisor)
{
uUnderPoint = uUnderPoint | 1;
uDividend -= uDivisor;
}
DEBUGMSG(DISP_ZONE_2D, (TEXT("uDivend:%x(%d), uDivisor:%x(%d), uUnderPoint:%x(%d)\n"), uDividend, uDividend, uDivisor, uDivisor,uUnderPoint, uUnderPoint));
}
uUnderPoint = (uUnderPoint + 1) >> 1;
return ( uUnderPoint|(uQuotient<<11) );
}
static DWORD WINAPI
DetectFSCUIReadyThread(
VOID *pPddContext
)
{
HANDLE hUIReady;
DWORD code;
hUIReady = OpenEvent(EVENT_ALL_ACCESS, FALSE, TEXT("SYSTEM/BackCarUIReady"));
if(NULL == hUIReady)
{
RETAILMSG(TRUE, (TEXT("Open SYSTEM/BackCarUIReady Failed\r\n")));
return -1;
}
code = WaitForSingleObject(hUIReady, INFINITE);
CloseHandle(hUIReady);
return 0;
}
/**
* @fn FIMGSE2D::GetCompensatedOffset(PRECTL prclSrc, PRECTL prclDst, ROT_TYPE m_iRotate)
* @param prclSrc Source Rectangle
* @param prclDst Destination Rectangle
* @param m_iRotate Rotatation Degree. See also ROT_TYPE type
* @note This funciton performs getting offset for stretchblt algorithm compensation
* @sa ROT_TYPE
*
**/
LONG FIMGSE2D::GetCompensatedOffset(DWORD usSrcValue, DWORD usDstValue)
{
/// Calculate X,Y Offset
float fIncrement;
float fStretchRatio;
float fReferPoint = 0.5;
LONG i =0;
fIncrement = (float)usSrcValue / (float)usDstValue;
fStretchRatio = (float)usDstValue / (float)usSrcValue;
do
{
if(fReferPoint > 1) break;
fReferPoint += fIncrement;
i++;
} while(1);
RETAILMSG(DISP_ZONE_2D,(TEXT("\n fIncr : %5.6f, fSR: %5.6f, i : %d, Offset : %d"), fIncrement, fStretchRatio, i, (LONG)(fStretchRatio - i)));
return (fStretchRatio < 1) ? 0 : (LONG)(fStretchRatio - i);
}
int Cat9555::GetCAT9555(int channel,unsigned char port,unsigned char *level)
{
if(channel==0) h= CreateFile(TEXT("CAT1:"), (GENERIC_READ|GENERIC_WRITE), (FILE_SHARE_READ|FILE_SHARE_WRITE), 0, OPEN_EXISTING, 0, 0);
if(channel==1) h= CreateFile(TEXT("CTA1:"), (GENERIC_READ|GENERIC_WRITE), (FILE_SHARE_READ|FILE_SHARE_WRITE), 0, OPEN_EXISTING, 0, 0);
if(channel==2) h= CreateFile(TEXT("ACT1:"), (GENERIC_READ|GENERIC_WRITE), (FILE_SHARE_READ|FILE_SHARE_WRITE), 0, OPEN_EXISTING, 0, 0);
if(h == INVALID_HANDLE_VALUE)
{
RETAILMSG(1, (L"open gpio device failed\r\n"));
exit(-1);
}
if(channel==0) DeviceIoControl(h, IOCTL_CAT9555_READ, &port, sizeof(unsigned char), level, sizeof(unsigned char), NULL, NULL);
if(channel==1) DeviceIoControl(h, IOCTL_CAT95552_READ, &port, sizeof(unsigned char), level, sizeof(unsigned char), NULL, NULL);
if(channel==2) DeviceIoControl(h, IOCTL_CAT95553_READ, &port, sizeof(unsigned char), level, sizeof(unsigned char), NULL, NULL);
CloseHandle(h);
return 1;
}
static BOOL RegOpenCreateStr(LPCTSTR lpSubKey, LPCTSTR lpName, LPTSTR lpData, DWORD dwCnt, BOOL bCreate)
{
HKEY hKey;
DWORD dwValue, dwType = REG_MULTI_SZ;
BOOL bRet = TRUE;
if (ERROR_SUCCESS != RegCreateKeyEx(HKEY_LOCAL_MACHINE,
lpSubKey,
0,
NULL,
0, // REG_OPTION_NON_VOLATILE
0,
0,
&hKey,
&dwValue))
{
return FALSE;
}
if (FALSE == bCreate && REG_CREATED_NEW_KEY == dwValue)
{
bRet = FALSE;
}
else if (REG_OPENED_EXISTING_KEY == dwValue)
{
if (ERROR_SUCCESS == RegQueryValueEx(hKey, lpName, 0, &dwType, (BYTE *)lpData, &dwCnt))
RETAILMSG(0, (_T("%s\r\n"), lpData));
else
bRet = FALSE;
}
else
{
bRet = FALSE;
}
RegCloseKey(hKey);
return bRet;
}
RESULT
Animation::CallbackOnFinished( ICallback& callback )
{
RESULT rval = S_OK;
if (callback.IsNull())
{
RETAILMSG(ZONE_ERROR, "ERROR: Animation::CallbackOnFinished( \"%s\", 0x%x ): Callback is NULL",
m_name.c_str(), (UINT32)&callback);
SAFE_DELETE(m_pCallbackOnFinished);
rval = E_INVALID_ARG;
goto Exit;
}
SAFE_DELETE(m_pCallbackOnFinished);
m_pCallbackOnFinished = callback.Clone();
Exit:
return rval;
}
RESULT
GradientEffect::Init()
{
RETAILMSG(ZONE_SHADER, "GradientEffect::Init()");
RESULT rval = S_OK;
if (s_GradientShadersLoaded)
{
return S_OK;
}
CHR(OpenGLESEffect::Init());
CHR(ShaderMan.CreateShader( "GradientEffect", s_GradientVertexShaderName, s_GradientFragmentShaderName, &s_hGradientShader ));
// Save uniform handles.
s_GradientShaderProgram = ShaderMan.GetShaderProgramID( s_hGradientShader );
VERIFYGL(glUseProgram(s_GradientShaderProgram));
VERIFYGL(s_uModelViewMatrix = glGetUniformLocation(s_GradientShaderProgram, "uMatModelView"));
VERIFYGL(s_uProjectionMatrix = glGetUniformLocation(s_GradientShaderProgram, "uMatProjection"));
VERIFYGL(s_uTexture = glGetUniformLocation(s_GradientShaderProgram, "uTexture"));
VERIFYGL(s_uStartColor = glGetUniformLocation(s_GradientShaderProgram, "uStartColor"));
VERIFYGL(s_uStartPoint = glGetUniformLocation(s_GradientShaderProgram, "uStartPoint"));
VERIFYGL(s_uEndColor = glGetUniformLocation(s_GradientShaderProgram, "uEndColor"));
VERIFYGL(s_uEndPoint = glGetUniformLocation(s_GradientShaderProgram, "uEndPoint"));
VERIFYGL(s_uGlobalColor = glGetUniformLocation(s_GradientShaderProgram, "uGlobalColor"));
VERIFYGL(s_uWidth = glGetUniformLocation(s_GradientShaderProgram, "uWidth"));
VERIFYGL(s_uHeight = glGetUniformLocation(s_GradientShaderProgram, "uHeight"));
// VERIFYGL(s_uTexCoordOffset = glGetUniformLocation(s_GradientShaderProgram, "uTexCoordOffset"));
s_GradientShadersLoaded = true;
Exit:
return rval;
}
/*************************************************************************************
// Function: BspGetBatteryFlag
// Purpose: Give a AC status to upper layer
// Returns: TRUE--ACOnline FALSE--ACOff
//***********************************************************************************/
UCHAR
BspGetBatteryFlag_old (void)
{
// return PDD_BATTERY_ON;
if(BspBatteryDetect())
{
if(BspChargerDetect())
return PDD_BATTERY_CHARGING;
else if(BspAdapterDetect()||BspUSBChargerDetect())
{
RETAILMSG(0, (TEXT("++PDD_BATTERY_EOC \r\n")));
BspCorrectVoltageGauge();
return PDD_BATTERY_EOC;
}
else
return PDD_BATTERY_ON;
}
else
{
return PDD_NO_BATTERY;
}
}//endof BspGetBatteryStatus
BOOL LED_Deinit(DWORD dwContext)
{
PDRVCONTEXT pDrv = (PDRVCONTEXT)dwContext;
RETAILMSG(RETAIL_ON, (DTAG TEXT("LED_Deinit++ dwContext: %x\r\n"), dwContext));
// Verify that the context handle is valid
if(pDrv && (pDrv->dwSize != sizeof(DRVCONTEXT))){
return 0;
}
// terminate thread
KillFlag = true;
SetEvent(pDrv->hEvent);
FreeIntChainHandler(pDrv->hIsrHandle);
InterruptDisable(pDrv->dwSysIntr);
KernelIoControl(IOCTL_HAL_RELEASE_SYSINTR, &pDrv->dwSysIntr, sizeof(DWORD), NULL, 0, NULL);
CloseHandle(pDrv->hEvent);
DeleteStaticMapping((LPVOID)isr_info.pGPIORegs, sizeof(GPIOREG));
return true;
}
BOOL GetARM2BackCarStatus(UCHAR *pOutBuffer,DWORD outSize,DWORD *pOutSize)
{
UINT32 g_u4Param1,g_u4Param2,g_u4Param3;
DWORD dwRet;
UINT32 u4ModuleID,u4MessageID;
HWSendMessage(MSG_COMBINE(MODULE_BCAR, MSG_WINCE_APP_READY),0, 0, 0);
dwRet = WaitForSingleObject(g_hBackCarIntrEvt, INFINITE);
HWGetMessage(MODULE_BCAR, &u4ModuleID, &g_u4Param1, &g_u4Param2, &g_u4Param3);
u4MessageID = GETMESSAGEID(u4ModuleID);
if(u4MessageID == MSG_ARM2_RESPONSE)
RETAILMSG(TRUE, (TEXT("[FSC][INFO]Rev ARM2 Responese\r\n")));
memcpy(pOutBuffer,(UCHAR *)&g_u4Param1,4);
memcpy(pOutBuffer+4,(UCHAR *)&g_u4Param2,4);
*pOutSize = 8;
InterruptDone(g_dwBackCarSysIntr);
return TRUE;
}
static DWORD WINAPI mfc_demo_thread(LPVOID pPARAM)
{
MFCDEC_DEMO_THREAD_PARAM *p_mfc_demo_param;
int idx;
if (pPARAM == NULL) {
return 0x0FFFF;
}
p_mfc_demo_param = (MFCDEC_DEMO_THREAD_PARAM *) pPARAM;
idx = p_mfc_demo_param->demofile_idx;
RETAILMSG(1, (L"\n[MFC_DEMO] Playing \'%s\' file", array_pszFileNames[idx][0]));
#define NUM_PIP_VIDEOS 1
mfcdec_demo(p_mfc_demo_param->hWnd,
array_pszFileNames[idx],
array_codec_modes[idx],
NUM_PIP_VIDEOS,
&(p_mfc_demo_param->fForceExit));
return 0;
}
BOOL WSM_AddLogData(LPTSTR strBuf)
{
int nlen = 0;
int nGlbBufferLen = 0;
int nspare = 0;
EnterCriticalSection(&g_csLock);
// 버퍼 사이즈 할당이 되지 않았다면, 기본사이즈로 할당
if(g_pBuffer == NULL)
{
if( WSM_SetLogBufSize(DEFAULT_LOGBUF_SIZE) == FALSE )
{
return FALSE;
}
}
nlen = _tcslen(strBuf) * sizeof(TCHAR);
nGlbBufferLen =_tcslen(g_pBuffer) * sizeof(TCHAR);
nspare = g_dwBufSize - nGlbBufferLen;
RETAILMSG(1, (TEXT("[WSM] g_dwBufSize(%d), nlen(%d), nspare(%d), nGlbBufferLen(%d) \r\n"), g_dwBufSize, nlen, nspare, nGlbBufferLen ));
if( nspare < nlen)
{
wcscpy(&g_pBuffer[0], &g_pBuffer[nlen - nspare]);
}
wcscat(g_pBuffer, strBuf);
LeaveCriticalSection(&g_csLock);
return TRUE;
}
//------------------------------------------------------------------------------
//
// Function: SetPowerState
//
// Sets the device power state
//
BOOL SetPowerState(
KeypadDevice_t *pDevice,
CEDEVICE_POWER_STATE power)
{
BOOL rc = FALSE;
DEBUGMSG(ZONE_FUNCTION, (
L"+SetPowerState(0x%08X, 0x%08x)\r\n", pDevice, power
));
switch (power)
{
case D0:
case D1:
case D2:
case D3:
case D4:
break;
default:
RETAILMSG(ZONE_WARN, (L"WARN: KPD::SetPowerState: "
L"Invalid power state (%d)\r\n", power
));
goto cleanUp;
}
pDevice->powerState = power;
rc = TRUE;
cleanUp:
DEBUGMSG(ZONE_FUNCTION, (
L"-SetPowerState(0x%08X, 0x%08x)\r\n", pDevice, power
));
return rc;
}
static BOOL dispBitmap(HDC hDC, LPCTSTR lpszFileName)
{
HANDLE hFile = CreateFile(lpszFileName,
GENERIC_READ, FILE_SHARE_READ,
NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL);
if (INVALID_HANDLE_VALUE == hFile)
return FALSE;
DISPBITMAP dispBmp;
dispBmp.nCount = (int)GetFileSize(hFile, NULL);
dispBmp.x = dispBmp.y = 0;
dispBmp.pBuffer = new BYTE [dispBmp.nCount];
if (NULL == dispBmp.pBuffer)
{
CloseHandle(hFile);
return FALSE;
}
DWORD dwNumberOfBytesRead;
ReadFile(hFile, dispBmp.pBuffer, dispBmp.nCount, &dwNumberOfBytesRead, NULL);
if (dispBmp.nCount != dwNumberOfBytesRead)
{
CloseHandle(hFile);
delete [] dispBmp.pBuffer;
return FALSE;
}
dispBmp.pUpdate = NULL;
dispBmp.bIsWait = TRUE;
int nRet = ExtEscape(hDC, DRVESC_DISP_BITMAP, sizeof(dispBmp), (LPCSTR)&dispBmp, 0, NULL);
RETAILMSG(0, (_T("+ DRVESC_DISP_BITMAP %d\r\n"), nRet));
delete [] dispBmp.pBuffer;
CloseHandle(hFile);
return TRUE;
}
RESULT
RippleEffect::Init()
{
RETAILMSG(ZONE_RENDER, "RippleEffect::Init()");
RESULT rval = S_OK;
if (s_RippleShadersLoaded)
{
return S_OK;
}
CHR(OpenGLESEffect::Init());
CHR(ShaderMan.CreateShader( "RippleEffect", s_RippleVertexShaderName, s_RippleFragmentShaderName, &s_hRippleShader ));
// Save uniform handles.
s_RippleShaderProgram = ShaderMan.GetShaderProgramID( s_hRippleShader );
VERIFYGL(glUseProgram(s_RippleShaderProgram));
VERIFYGL(s_uModelViewMatrix = glGetUniformLocation(s_RippleShaderProgram, "uMatModelView"));
VERIFYGL(s_uProjectionMatrix = glGetUniformLocation(s_RippleShaderProgram, "uMatProjection"));
VERIFYGL(s_uTexture = glGetUniformLocation(s_RippleShaderProgram, "uTexture"));
VERIFYGL(s_uGlobalColor = glGetUniformLocation(s_RippleShaderProgram, "uGlobalColor"));
VERIFYGL(s_uAmplitude = glGetUniformLocation(s_RippleShaderProgram, "uAmplitude"));
VERIFYGL(s_uTime = glGetUniformLocation(s_RippleShaderProgram, "uTime"));
VERIFYGL(s_uRadius = glGetUniformLocation(s_RippleShaderProgram, "uRadius"));
VERIFYGL(s_uOrigin = glGetUniformLocation(s_RippleShaderProgram, "uOrigin"));
VERIFYGL(s_uHalfWaveLength = glGetUniformLocation(s_RippleShaderProgram, "uHalfWaveLength"));
VERIFYGL(s_uNumWaves = glGetUniformLocation(s_RippleShaderProgram, "uNumWaves"));
VERIFYGL(s_uColor = glGetUniformLocation(s_RippleShaderProgram, "uColor"));
s_RippleShadersLoaded = true;
Exit:
return rval;
}
void INC_MSG_PRINTF(INC_INT8 nFlag, INC_INT8* pFormat, ...)
{
va_list Ap;
INC_UINT16 nSize;
INC_INT8 acTmpBuff[256] = {0};
va_start(Ap, pFormat);
nSize = vsprintf(acTmpBuff, pFormat, Ap);
va_end(Ap);
//RETAILMSG(nFlag, (TEXT("%s"), wcstring));
#ifdef INC_KERNEL_SPACE
if(nFlag)
printk("%s", acTmpBuff);
#else
printf("%s", acTmpBuff);
//TODO Serial code here...
///////////////////////////////////////////////////
// .NET 버전일 경우 wchar_t로 변환
INC_INT8 logstr[256] = {0};
wchar_t wcstring[1024] = {0};
mbstowcs(wcstring, acTmpBuff, strlen(acTmpBuff)+1);
RETAILMSG(nFlag, (TEXT("%s"), wcstring));
///////////////////////////////////////////////////
if(m_hINC_LogFile && nFlag){
SYSTEMTIME time;
GetLocalTime(&time);
sprintf(logstr, "[%02d.%02d %02d:%02d:%02d] %s",
time.wMonth, time.wDay, time.wHour, time.wMinute, time.wSecond, acTmpBuff);
fwrite(logstr, sizeof(char), strlen(logstr)+1, m_hINC_LogFile);
}
#endif
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
// UnattendedMode Management
////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
BOOL SetUnattendedMode(BOOL bMode)
{
HANDLE hWSMDrv = NULL;
BOOL bRet = TRUE;
DWORD dwBytesReturned = 0;
if( !bInitCS )
{
InitializeCriticalSection(&g_csLock);
bInitCS = TRUE;
}
EnterCriticalSection(&g_csLock);
hWSMDrv = CreateFile(WIFI_SERVICE_MANAGER_DRIVER_NAME, GENERIC_READ | GENERIC_WRITE, 0, NULL, OPEN_EXISTING, FILE_ATTRIBUTE_NORMAL, NULL);
if( hWSMDrv != INVALID_HANDLE_VALUE )
{
if( !DeviceIoControl(hWSMDrv, IOCTL_WIFISVCMGR_SET_UNATTENDEDMODE, &bMode, sizeof(bMode), NULL, 0, &dwBytesReturned, NULL) )
{
bRet = FALSE;
RETAILMSG(1, (TEXT("[NETUI] SetUnattendedMode - DeviceIoControl Failed! \r\n") ));
}
CloseHandle(hWSMDrv);
}
else
{
bRet = FALSE;
}
LeaveCriticalSection(&g_csLock);
return bRet;
}
RESULT
LayerManager::CreateLayer( IN const Settings* pSettings, IN const string& settingsPath, INOUT Layer** ppLayer )
{
RESULT rval = S_OK;
string name;
if (!pSettings || "" == settingsPath || !ppLayer)
{
RETAILMSG(ZONE_ERROR, "ERROR: LayerManager::CreateLayer(): invalid argument");
return E_INVALID_ARG;
}
Layer *pLayer = new Layer();
CPR(pLayer);
name = pSettings->GetString( settingsPath + ".Name" );
pLayer->Init( name );
// Caller must AddRef()
*ppLayer = pLayer;
Exit:
return rval;
}
RippleEffect::RippleEffect( const RippleEffect& rhs ) :
OpenGLESEffect(),
m_pRippledVertices(NULL),
m_numRippledVertices(0),
m_rows(DEFAULT_ROWS),
m_columns(DEFAULT_COLUMNS),
m_padding(DEFAULT_PADDING),
m_fWaveLength(DEFAULT_WAVE_LENGTH),
m_fNumWaves(DEFAULT_NUM_WAVES),
m_fAmplitude(DEFAULT_AMPLITUDE),
m_fSpeed(DEFAULT_SPEED),
m_fRadius(DEFAULT_RADIUS),
m_color(DEFAULT_COLOR),
m_origin(0,0)
{
RETAILMSG(ZONE_OBJECT | ZONE_VERBOSE, "RippleEffect( %4d ) (copy ctor)", m_ID);
ATOMIC_INCREMENT( RippleEffect::s_NumInstances );
m_name = "RippleEffect";
memset(&m_frame, 0, sizeof(m_frame));
*this = rhs;
}
void C_DM9000::EDeviceRegisterIoSpace(void)
{
NIC_DEVICE_OBJECT::EDeviceRegisterIoSpace();
U32 val;
val = DeviceReadPort(0x2a);
val |= DeviceReadPort(0x2b)<<8;
val |= DeviceReadPort(0x28)<<16;
val |= DeviceReadPort(0x29)<<24;
DEBUG_PRINT((
TEXT("[dm9: Chip signature is %08X\r\n"), val
));
RETAILMSG(1, (TEXT("[dm9: Chip signature is %08X\r\n"), val));
if( (DeviceReadPort(DM9_VIDL) != LOW_BYTE(DM9000_VID)) ||
(DeviceReadPort(DM9_VIDH) != HIGH_BYTE(DM9000_VID)) ||
(DeviceReadPort(DM9_PIDL) != LOW_BYTE(DM9000_PID)) ||
(DeviceReadPort(DM9_PIDH) != HIGH_BYTE(DM9000_PID)) )
THROW((ERR_STRING("Unknown device")));
}
GPIODriver::GPIODriver()
{
if(hGpio == INVALID_HANDLE_VALUE)
hGpio = CreateFile(GPIO_DEVICE_NAME, GENERIC_WRITE|GENERIC_READ,0,NULL,OPEN_EXISTING,0,NULL);
if (hGpio == INVALID_HANDLE_VALUE)
{
RETAILMSG(1,(TEXT("Failed open gioD: device driver!\r\n")));
}
// Allocate memory for our handler...
pContext = (DEVICE_CONTEXT_GPIO*)LocalAlloc(
LPTR, sizeof(DEVICE_CONTEXT_GPIO)
);
if (pContext == NULL)
{
DEBUGMSG(1, (L"GPIOOpen LocalAlloc failed\r\n"));
CloseHandle(hGpio);
}
// Save device handle
pContext->hDevice = hGpio;
}
DWORD GIO_Read(DWORD hOpenContext, LPVOID pBuffer, DWORD Count)
{
// depending on Single or Bulk mode, returns status of GPIO(s)[High/Low]
DWORD value=~0;
if(bulk_active)
{
for(int n=0;n<16;n++)
{
value |= ((getDatum(n)==1)?1:0)<<n;
}
}
else
{
value=getDatum(active_port);
}
if(Count!=4)
{
RETAILMSG(DEBUG_GPIO, (TEXT("GPIO_Control: GPIO_Read needs four buffer bytes ( sizeof(DWORD) )\r\n")));
return FALSE;
}
*(DWORD *)pBuffer =value;
return TRUE;
}
BOOL SizeImg_Write(SIZE_IMG_IDX size_idx, unsigned char *pImg, int width, int height, int x_pos, int y_pos)
{
int i; // Loop counter
unsigned short *p_size_img;
if ((height < SIZE_IMG_HEIGHT) || (width < SIZE_IMG_WIDTH))
return FALSE;
pImg += ((y_pos * width) << 1);
switch (size_idx) {
case SIZE_IMG_QVGA: // QVGA
case SIZE_IMG_VGA: // VGA
case SIZE_IMG_SD: // SD
break;
case SIZE_IMG_UNDEF: // undef
return FALSE;
default:
RETAILMSG(1,(L"\nInvalid size_val value, %d\n", size_idx));
return FALSE;
}
p_size_img = size_img[size_idx];
pImg += (x_pos << 1);
for (i=0; i<SIZE_IMG_HEIGHT; i++) {
memcpy(pImg, p_size_img, SIZE_IMG_WIDTH*2);
p_size_img += SIZE_IMG_WIDTH;
pImg += (width << 1);
}
return TRUE;
}
/*
** Function Name : MFC_IOControl
**
** Function Description : This function support any process of MFC instance.
*/
BOOL
MFC_IOControl(
DWORD OpenHandle,
DWORD dwIoControlCode,
PBYTE pInBuf,
DWORD nInBufSize,
PBYTE pOutBuf,
DWORD nOutBufSize,
PDWORD pBytesReturned
)
{
MFC_HANDLE *handle;
MFCInstCtx *pMfcInst;
MFC_ARGS *args;
int ret = MFCINST_RET_OK;
unsigned char *p_buf = NULL;
int n_bufsize = 0;
PVOID pMarshalledInBuf = NULL;
static CEDEVICE_POWER_STATE mfc_pwr_state;
BOOL result = TRUE;
handle = (MFC_HANDLE *) OpenHandle;
/////////////////////
// Parameter Check //
/////////////////////
if (handle == NULL)
{
LOG_MSG(LOG_TRACE, "MFC_IOControl", "OpenHandle == NULL\n");
return FALSE;
}
if (handle != gMfcHandlePower)
{
if (pInBuf == NULL)
{
LOG_MSG(LOG_TRACE, "MFC_IOControl", "pInBuf == NULL\n");
return FALSE;
}
if (nInBufSize == 0)
{
LOG_MSG(LOG_TRACE, "MFC_IOControl", "nInBufSize == 0\n");
return FALSE;
}
if ((pOutBuf != NULL) || (nOutBufSize != 0) || (pBytesReturned != NULL))
{
LOG_MSG(LOG_TRACE, "MFC_IOControl", "others.....\n");
return FALSE;
}
}
pMfcInst = handle->mfc_inst;
MFC_Mutex_Lock();
switch ( dwIoControlCode )
{
case IOCTL_POWER_CAPABILITIES:
{
RETAILMSG(1, (L"[MFC IOCTL_POWER_CAPABILITIES]\n"));
PPOWER_CAPABILITIES ppc;
if ( !pBytesReturned || !pOutBuf || (nOutBufSize < sizeof(POWER_CAPABILITIES)) ) {
SetLastError (ERROR_INVALID_PARAMETER);
MFC_Mutex_Release();
return FALSE;
}
__try
{
ppc = (PPOWER_CAPABILITIES)pOutBuf;
memset(ppc, 0, sizeof(POWER_CAPABILITIES));
// support D0, D4
ppc->DeviceDx = DX_MASK(D0) | DX_MASK(D4);
// no wake
// no inrush
// Report our nominal power consumption in uAmps rather than mWatts.
ppc->Flags = POWER_CAP_PREFIX_MICRO | POWER_CAP_UNIT_AMPS;
*pBytesReturned = sizeof(POWER_CAPABILITIES);
RETAILMSG(1, (L"[MFC IOCTL_POWER_CAPABILITIES] leaving...\n"));
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
RETAILMSG(1, (L"[MFC IOCTL_POWER_CAPABILITIES] exception...\n"));
MFC_Mutex_Release();
return FALSE;
}
break;
}
case IOCTL_POWER_SET:
CEDEVICE_POWER_STATE NewDx;
//if caller is not kernel mode, do not allow setting power state
if (GetDirectCallerProcessId() != GetCurrentProcessId())
{
RETAILMSG(1, (L"[MFC IOCTL_POWER_SET] User mode access denied\r\n"));
MFC_Mutex_Release();
return ERROR_ACCESS_DENIED;
}
__try
{
if (pOutBuf == NULL)
{
return FALSE;
}
NewDx = *(PCEDEVICE_POWER_STATE) pOutBuf;
switch ( NewDx )
{
case D0: // Power Up
*(PCEDEVICE_POWER_STATE)pOutBuf = process_MFC_PowerUp(OpenHandle, &mfc_pwr_state);
break;
case D4: // Power Down
*(PCEDEVICE_POWER_STATE)pOutBuf = process_MFC_PowerDown(OpenHandle, &mfc_pwr_state);
break;
default:
MFC_Mutex_Release();
return FALSE;
}
*pBytesReturned = sizeof(CEDEVICE_POWER_STATE);
}
__except(EXCEPTION_EXECUTE_HANDLER)
{
RETAILMSG(1, (L"[MFC IOCTL_POWER_SET] exception...\n"));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_MPEG4_ENC_INIT:
case IOCTL_MFC_H264_ENC_INIT:
case IOCTL_MFC_H263_ENC_INIT:
{
MFC_CODECMODE codec_mode;
enc_info_t enc_info;
if (dwIoControlCode == IOCTL_MFC_MPEG4_ENC_INIT)
codec_mode = MP4_ENC;
else if (dwIoControlCode == IOCTL_MFC_H264_ENC_INIT)
codec_mode = AVC_ENC;
else
codec_mode = H263_ENC;
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_H263_ENC_INIT.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
// Input arguments for IOCTL_MFC_xxx_ENC_INIT
enc_info.width = args->enc_init.in_width;
enc_info.height = args->enc_init.in_height;
enc_info.frameRateRes = args->enc_init.in_frameRateRes;
enc_info.frameRateDiv = args->enc_init.in_frameRateDiv;
enc_info.gopNum = args->enc_init.in_gopNum;
enc_info.bitrate = args->enc_init.in_bitrate;
enc_info.intraqp = args->enc_init.in_intraqp;
enc_info.qpmax = args->enc_init.in_qpmax;
enc_info.gamma = args->enc_init.in_gamma;
///////////////////////////////////
/// Initialize MFC Instance ///
///////////////////////////////////
Mfc_Clk_On();
ret = MFCInst_Enc_Init(pMfcInst, codec_mode, &enc_info);
Mfc_Clk_Off();
// Output arguments for IOCTL_MFC_xxx_ENC_INIT
args->enc_init.ret_code = ret;
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_H263_ENC_INIT.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
}
case IOCTL_MFC_MPEG4_ENC_EXE:
case IOCTL_MFC_H264_ENC_EXE:
case IOCTL_MFC_H263_ENC_EXE:
{
int nStrmLen, nHdrLen;
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_H263_ENC_EXE.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
MFCInst_GetFramBuf(pMfcInst, &p_buf, &n_bufsize);
CleanInvalidateCacheRange((PBYTE )p_buf, (PBYTE )(p_buf + n_bufsize) );
// nStrmLen is size of output stream data
Mfc_Clk_On();
ret = MFCInst_Encode(pMfcInst, &nStrmLen, &nHdrLen);
Mfc_Clk_Off();
MFCInst_GetLineBuf(pMfcInst, &p_buf, &n_bufsize);
InvalidateCacheRange((PBYTE )p_buf, (PBYTE )(p_buf + n_bufsize) );
// Output arguments for IOCTL_MFC_xxx_ENC_EXE
args->enc_exe.ret_code = ret;
if (ret == MFCINST_RET_OK) {
args->enc_exe.out_encoded_size = nStrmLen;
args->enc_exe.out_header_size = nHdrLen;
}
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_H263_ENC_EXE.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
}
case IOCTL_MFC_MPEG4_DEC_INIT:
case IOCTL_MFC_H263_DEC_INIT:
case IOCTL_MFC_H264_DEC_INIT:
case IOCTL_MFC_VC1_DEC_INIT:
{
MFC_CODECMODE codec_mode;
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_VC1_DEC_INIT.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
if (dwIoControlCode == IOCTL_MFC_MPEG4_DEC_INIT) {
codec_mode = MP4_DEC;
}
else if (dwIoControlCode == IOCTL_MFC_H263_DEC_INIT) {
codec_mode = MP4_DEC;
}
else if (dwIoControlCode == IOCTL_MFC_H264_DEC_INIT) {
codec_mode = AVC_DEC;
}
else {
codec_mode = VC1_DEC;
}
/////////////////////////////////
// Initialize MFC Instance //
/////////////////////////////////
Mfc_Clk_On();
ret = MFCInst_Dec_Init(pMfcInst, codec_mode, args->dec_init.in_strmSize);
Mfc_Clk_Off();
// Output arguments for IOCTL_MFC_xxx_DEC_INIT
args->dec_init.ret_code = ret;
if (ret == MFCINST_RET_OK) {
args->dec_init.out_width = pMfcInst->width;
args->dec_init.out_height = pMfcInst->height;
}
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_VC1_DEC_INIT.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
}
case IOCTL_MFC_MPEG4_DEC_EXE:
case IOCTL_MFC_H263_DEC_EXE:
case IOCTL_MFC_H264_DEC_EXE:
case IOCTL_MFC_VC1_DEC_EXE:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_VC1_DEC_EXE.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
MFCInst_GetLineBuf(pMfcInst, &p_buf, &n_bufsize);
CleanInvalidateCacheRange((PBYTE )p_buf, (PBYTE )(p_buf + n_bufsize) );
Mfc_Clk_On();
ret = MFCInst_Decode(pMfcInst, args->dec_exe.in_strmSize);
Mfc_Clk_Off();
// Output arguments for IOCTL_MFC_xxx_DEC_EXE
args->dec_exe.ret_code = ret;
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_VC1_DEC_EXE.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_GET_LINE_BUF_ADDR:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_GET_LINE_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
ret = MFCInst_GetLineBuf(pMfcInst, &p_buf, &n_bufsize);
if (ret != MFCINST_RET_OK)
{
goto GetLineBuffCleanup;
}
if (handle->pStrmBuf == NULL)
{
// Map the Line buffer for this instance to the caller's address space
//
handle->hUsrProc = (HANDLE) GetDirectCallerProcessId();
handle->pStrmBuf = (PBYTE) VirtualAllocEx(handle->hUsrProc,
NULL,
n_bufsize,
MEM_RESERVE,
PAGE_NOACCESS);
if (handle->pStrmBuf == NULL)
{
RETAILMSG(1, (L"DD::MFC VirtualAllocEx(pStrmBuf) returns FALSE.\n"));
ret = MFCINST_ERR_MEMORY_ALLOCATION_FAIL;
goto GetLineBuffCleanup;
}
result = VirtualCopyEx(handle->hUsrProc,
handle->pStrmBuf,
(HANDLE) GetCurrentProcessId(),
p_buf,
n_bufsize,
PAGE_READWRITE );
if (result == FALSE){
RETAILMSG(1, (L"DD::MFC VirtualCopyEx(pStrmBuf) returns FALSE.\n"));
VirtualFreeEx(handle->hUsrProc, handle->pStrmBuf, 0, MEM_RELEASE);
handle->pStrmBuf = NULL;
ret = MFCINST_ERR_MEMORY_ALLOCATION_FAIL;
goto GetLineBuffCleanup;
}
}
// Output arguments for IOCTL_MFC_GET_FRAM_BUF_ADDR
args->get_buf_addr.out_buf_size = n_bufsize;
args->get_buf_addr.out_buf_addr = (int) handle->pStrmBuf;
GetLineBuffCleanup:
args->get_buf_addr.ret_code = ret;
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_GET_LINE_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_GET_FRAM_BUF_ADDR:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_GET_FRAM_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
// Decoder case
ret = MFCInst_GetFramBuf(pMfcInst, &p_buf, &n_bufsize);
if (ret != MFCINST_RET_OK)
{
goto GetFrameBuffCleanup;
}
// Check Paramter
if (pMfcInst->run_index * n_bufsize < 0 ||
(pMfcInst->run_index * n_bufsize) > (int)(pMfcInst->nFramBufSize))
{
RETAILMSG(1, (L"[MFC ERROR] IOCTL_MFC_GET_FRAM_BUF_ADDR: Run Index out of range.\r\n"));
ret = MFCINST_ERR_ETC;
goto GetFrameBuffCleanup;
}
if (handle->pFramBuf == NULL)
{
// Map the Frame buffer for this instance to the caller's address space
//
handle->hUsrProc = (HANDLE) GetDirectCallerProcessId();
handle->pFramBuf = (PBYTE) VirtualAllocEx(handle->hUsrProc,
NULL,
pMfcInst->nFramBufSize,
MEM_RESERVE,
PAGE_NOACCESS);
if (handle->pFramBuf == NULL)
{
RETAILMSG(1, (L"DD::MFC VirtualAllocEx(pFramBuf) returns FALSE.\n"));
ret = MFCINST_ERR_MEMORY_ALLOCATION_FAIL;
goto GetFrameBuffCleanup;
}
result= VirtualCopyEx(handle->hUsrProc, // HANDLE hDstProc
handle->pFramBuf,
(HANDLE) GetCurrentProcessId(), // HANDLE hSrcProc
pMfcInst->pFramBuf,
pMfcInst->nFramBufSize,
PAGE_READWRITE);
if (result == FALSE)
{
RETAILMSG(1, (L"DD::MFC VirtualCopyEx(pFramBuf) returns FALSE.\n"));
VirtualFreeEx(handle->hUsrProc, handle->pFramBuf, 0, MEM_RELEASE);
handle->pFramBuf = NULL;
ret = MFCINST_ERR_MEMORY_ALLOCATION_FAIL;
goto GetFrameBuffCleanup;
}
}
if (pMfcInst->run_index >= 0)
{
args->get_buf_addr.out_buf_addr = (int) (handle->pFramBuf + (pMfcInst->run_index * n_bufsize));
#if (MFC_ROTATE_ENABLE == 1)
// If PostRotMode is enabled, then the output YUV buffer will be different.
// In VC-1 mode, the rotated output will be the original one.
if ( (pMfcInst->codec_mode != VC1_DEC) && (pMfcInst->PostRotMode & 0x0010) )
{
args->get_buf_addr.out_buf_addr = (int) (handle->pFramBuf + (pMfcInst->frambufCnt * n_bufsize));
}
#endif
}
else
{
args->get_buf_addr.out_buf_addr = 0;
}
args->get_buf_addr.out_buf_size = n_bufsize;
GetFrameBuffCleanup:
args->get_buf_addr.ret_code = ret;
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_GET_FRAM_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_GET_PHY_FRAM_BUF_ADDR:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_GET_PHY_FRAM_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
// Decoder case
ret = MFCInst_GetFramBufPhysical(pMfcInst, &p_buf, &n_bufsize);
// Output arguments for IOCTL_MFC_xxx_DEC_EXE
args->get_buf_addr.ret_code = ret;
if (ret == MFCINST_RET_OK)
{
// Output arguments for IOCTL_MFC_GET_FRAM_BUF_ADDR
args->get_buf_addr.out_buf_addr = (int) p_buf;
args->get_buf_addr.out_buf_size = n_bufsize;
}
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_GET_PHY_FRAM_BUF_ADDR.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_GET_MPEG4_ASP_PARAM:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_GET_MPEG4_ASP_PARAM.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
#if (defined(DIVX_ENABLE) && (DIVX_ENABLE == 1))
ret = MFCINST_RET_OK;
args->mpeg4_asp_param.ret_code = MFCINST_RET_OK;
args->mpeg4_asp_param.mp4asp_vop_time_res = pMfcInst->RET_DEC_SEQ_INIT_BAK_MP4ASP_VOP_TIME_RES;
args->mpeg4_asp_param.byte_consumed = pMfcInst->RET_DEC_PIC_RUN_BAK_BYTE_CONSUMED;
args->mpeg4_asp_param.mp4asp_fcode = pMfcInst->RET_DEC_PIC_RUN_BAK_MP4ASP_FCODE;
args->mpeg4_asp_param.mp4asp_time_base_last = pMfcInst->RET_DEC_PIC_RUN_BAK_MP4ASP_TIME_BASE_LAST;
args->mpeg4_asp_param.mp4asp_nonb_time_last = pMfcInst->RET_DEC_PIC_RUN_BAK_MP4ASP_NONB_TIME_LAST;
args->mpeg4_asp_param.mp4asp_trd = pMfcInst->RET_DEC_PIC_RUN_BAK_MP4ASP_MP4ASP_TRD;
#if (_WIN32_WCE >= 600)
if (handle->pFramBuf != NULL){
args->mpeg4_asp_param.mv_addr = ((unsigned int) handle->pFramBuf) + (pMfcInst->mv_mbyte_addr - pMfcInst->phyadrFramBuf);
args->mpeg4_asp_param.mb_type_addr = args->mpeg4_asp_param.mv_addr + 25920;
args->mpeg4_asp_param.mv_size = 25920; // '25920' is the maximum MV size (=45*36*16)
args->mpeg4_asp_param.mb_type_size = 1620; // '1620' is the maximum MBTYE size (=45*36*1)
}
#else
args->mpeg4_asp_param.mv_addr = ((unsigned int) pMfcInst->pFramBuf) + (pMfcInst->mv_mbyte_addr - pMfcInst->phyadrFramBuf);
args->mpeg4_asp_param.mb_type_addr = args->mpeg4_asp_param.mv_addr + 25920;
args->mpeg4_asp_param.mv_size = 25920;
args->mpeg4_asp_param.mb_type_size = 1620;
#endif
InvalidateCacheRange((PBYTE )args->mpeg4_asp_param.mv_addr, (PBYTE )(args->mpeg4_asp_param.mv_addr + args->mpeg4_asp_param.mv_size) );
InvalidateCacheRange((PBYTE )args->mpeg4_asp_param.mb_type_addr , (PBYTE )(args->mpeg4_asp_param.mb_type_addr + args->mpeg4_asp_param.mb_type_size) );
#endif
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_GET_MPEG4_ASP_PARAM.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_GET_CONFIG:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_GET_CONFIG.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
ret = MFC_GetConfigParams(pMfcInst, args);
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_GET_CONFIG.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
case IOCTL_MFC_SET_CONFIG:
if(FAILED(CeOpenCallerBuffer(&pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR, TRUE)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeOpenCallerBuffer failed in IOCTL_MFC_SET_CONFIG.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
args = (MFC_ARGS *)pMarshalledInBuf;
Mfc_Clk_On();
ret = MFC_SetConfigParams(pMfcInst, args);
Mfc_Clk_Off();
if(FAILED(CeCloseCallerBuffer(pMarshalledInBuf, pInBuf, nInBufSize, ARG_IO_PTR)))
{
RETAILMSG(1, (TEXT("MFC_IOControl: CeCloseCallerBuffer failed in IOCTL_MFC_SET_CONFIG.\r\n")));
MFC_Mutex_Release();
return FALSE;
}
break;
default:
RETAILMSG(1, (L"[MFC IOControl] Requested ioctl command is not defined. (ioctl cmd=0x%X)\n", dwIoControlCode));
MFC_Mutex_Release();
return FALSE;
}
MFC_Mutex_Release();
switch (ret)
{
case MFCINST_RET_OK:
return TRUE;
default:
return FALSE;
}
return FALSE;
}
// This is the task-bar wndproc.
LRESULT CALLBACK TaskBarWndProc(HWND hwnd, UINT msg, WPARAM wp, LPARAM lp)
{
DEBUGMSG(ZONE_TRACEMSGHF, (TEXT("Taskbar Window Msg=%x wp=%x lp=%x\r\n"), msg, wp, lp));
switch(msg)
{
// 5sec housekeeping timer
case WM_TIMER:
DoHibernate(); // check free-memory level & notify apps if neccesary
DoPowerCheck(hwnd); // check battery levels & pop-up warning if reqd
break;
case WM_SYSKEYDOWN:
case WM_KEYDOWN:
{
DEBUGMSG(ZONE_TRACEMSG, (TEXT("Taskbar Window WM_KEYDOWN\r\n")));
// For now we're sending Ctrl-Esc, Alt-Esc, Alt-Tab, Ctrl-Alt-Del/Bksp all to TaskMan
// A fuller shell would implement a Start-Menu on Alt-Esc for example.
switch (wp)
{
case VK_DELETE:
case VK_BACK:
// Send Ctrl-Alt-Bksp to Taskman. NOTE: GWES doesn't send us Ctrl-Alt-Del
DEBUGMSG(ZONE_TRACEMSG, (TEXT("Taskbar Window WM_KEYDOWN, VK_BACK or VK_DELETE\r\n")));
if (GetKeyState(VK_CONTROL) && GetKeyState(VK_MENU))
Show_TaskMan();
break;
case VK_TAB:
// Send Alt-Tab to TaskMan
DEBUGMSG(ZONE_TRACEMSG, (TEXT("Taskbar Window WM_KEYDOWN, VK_TAB\r\n")));
if (GetKeyState(VK_MENU))
Show_TaskMan();
break;
case VK_ESCAPE:
// Send Ctrl-Esc & Alt-Esc to TaskMan
DEBUGMSG(ZONE_TRACEMSG, (TEXT("Taskbar Window WM_KEYDOWN, VK_ESCAPE\r\n")));
if(GetKeyState(VK_CONTROL) || GetKeyState(VK_MENU))
Show_TaskMan();
break;
default:
return DefWindowProc(hwnd, msg, wp, lp);
}
}
break;
case WM_HANDLESHELLNOTIFYICON:
// Private message posted by the callback in minserver.cpp when it
// gets a Shell_NotifyIcon call. wParam is NIM_ADD/DELETE etc
// lParam is a PNOTIFYICONDATA (we are responsible for freeing)
// For now just print a debug message to show we got the data
// correctly.
PNOTIFYICONDATA pnid;
pnid = (PNOTIFYICONDATA)lp;
RETAILMSG(1, (L"got Shell_NotifyIcon(nim=%d, nid(hwnd=0x%08x uId=%d uFlags=%d uCBMsg=%d hIcon=0x%08x, szTip=%s\r\n",
wp, pnid->hWnd, pnid->uID, pnid->uFlags, pnid->uCallbackMessage, pnid->hIcon, (pnid->szTip ? pnid->szTip : L"null")));
// ----- Insert real processing of this API here -----
MyFree(pnid);
break;
case WM_HANDLESHADDTORECENTDOCS:
// Private message posted by the callback in minserver.cpp when it
// gets a SHAddToRecentDocs call. wParam is SHARD_PATH
// lParam is a the path (we are responsible for freeing)
// For now just print a debug message to show we got the data
// correctly
RETAILMSG(1, (L"got SHAddToRecentDocs(uFlags=%d, path=%s)\r\n", wp, (lp ? (PTSTR)lp : L"null")));
// ----- Insert real processing of this API here -----
MyFree((PVOID)lp);
break;
default:
// This window will get GWE messages on window-create/delete etc.
// If it wants to display Win9x/NT-like task buttons etc., it
// should handle these messages
return DefWindowProc(hwnd, msg, wp, lp);
}
return 0;
}
/*
** Function Name : MFC_Open
**
** Function Description : This function open MFC instace and return instance handle.
*/
DWORD
MFC_Open(
DWORD InitHandle,
DWORD dwAccess,
DWORD dwShareMode
)
{
MFC_HANDLE *handle;
// Mutex Lock
MFC_Mutex_Lock();
// Allocate & Clear MFC Handle
handle = (MFC_HANDLE *) malloc(sizeof(MFC_HANDLE));
if (!handle)
{
RETAILMSG(1, (L"\n[MFC_Open Error] Momory Allocation Fail.\n"));
MFC_Mutex_Release();
return 0;
}
memset(handle, 0, sizeof(MFC_HANDLE));
// Increment OpenHandle Count
InterlockedIncrement(&_openhandle_count);
//
if (_openhandle_count == 1) // Handle for Power Control
{
// Save Specific Handle for Power Control
gMfcHandlePower = handle;
RETAILMSG(1, (L"\n[MFC_Open] Power Manager Handle Opened...\n"));
}
else if (_openhandle_count >= 2) // Handle for User Application
{
// Create MFC Instance
handle->mfc_inst = MFCInst_Create();
if (!handle->mfc_inst)
{
RETAILMSG(1, (L"\n[MFC_Open Error] MFC Instance Creattion Fail.\n"));
InterlockedDecrement(&_openhandle_count);
free(handle);
MFC_Mutex_Release();
return 0;
}
if (_openhandle_count == 2) // First Handle for User Application
{
// MFC HW Init
Mfc_Pwr_On();
Mfc_Clk_On();
if (MFC_HW_Init() == FALSE)
{
Mfc_Clk_Off();
Mfc_Pwr_Off();
MFCInst_Delete(handle->mfc_inst);
InterlockedDecrement(&_openhandle_count);
MFC_Mutex_Release();
return 0;
}
Mfc_Clk_Off();
}
}
// Mutex Release
MFC_Mutex_Release();
return (DWORD) handle;
}
/********************************************************************************
//ACLineStatus -- 0 Offline 1 Online 255 Unknown status
//
//
//*******************************************************************************/
BOOL WINAPI
BatteryPDDGetStatus(
PSYSTEM_POWER_STATUS_EX2 pstatus, PBOOL pfBatteriesChangedSinceLastCall)
{
BOOL fOk = TRUE;
SYSTEM_POWER_STATUS_EX2 sps;
BOOL ACStatus=FALSE;
UCHAR ucBatteryPer = 0;
UINT32 BATTERY_AUTOSLEEP_VOLTAGE_PERCENT ;
UINT32 PERCENT_CRITICAL2LOW;
BATTERY_AUTOSLEEP_VOLTAGE_PERCENT= ( (g_stBattParam.u32AutoSleepVbat - BATTERY_MIN_VOLTAGE)* 100/(BATTERY_MAX_VOLTAGE - BATTERY_MIN_VOLTAGE)+1) ;
PERCENT_CRITICAL2LOW = BATTERY_AUTOSLEEP_VOLTAGE_PERCENT + 4;
DPNOK(BATTERY_AUTOSLEEP_VOLTAGE_PERCENT);
DPNOK(PERCENT_CRITICAL2LOW);
SETFNAME(_T("BatteryPDDGetStatus"));
RETAILMSG(ZONE_REG_PRINT, (TEXT("+BatteryPDDGetStatus... \r\n")));
DEBUGCHK(pstatus != NULL);
DEBUGCHK(pfBatteriesChangedSinceLastCall != NULL);
/* Fill ACLineStatus part */
sps.ACLineStatus = AC_LINE_UNKNOWN;
if(BspGetACStatus())
{
sps.ACLineStatus = AC_LINE_ONLINE;
}
else
{
sps.ACLineStatus = AC_LINE_OFFLINE;
}
/* Fill Battery status part */
battery_status = BspGetBatteryFlag();
if (PDD_NO_BATTERY == battery_status )
{
BspNotifyLed(FALSE);
sps.BatteryFlag = BATTERY_FLAG_NO_BATTERY;
sps.BatteryLifePercent = BATTERY_PERCENTAGE_UNKNOWN;
}
else if (PDD_BATTERY_CHARGING == battery_status )
{
RETAILMSG(ZONE_REG_PRINT, (TEXT("+Battery status PDD_BATTERY_CHARGING... \r\n")));
BspFuelGaugeResetBatStatusInPercent();
BspNotifyLed(FALSE);
sps.BatteryFlag = BATTERY_FLAG_CHARGING;
sps.BatteryLifePercent = BATTERY_PERCENTAGE_UNKNOWN;
// //[david.modify] 2008-05-31 14:49
// ڴ˴óʱҲʾٷֱ
//=======================================================
if(CHARGING_BIT&g_stBattParam.u32Debug) {
ucBatteryPer = BspFuelGaugeGetBatStatusInPercent();
if(ucBatteryPer >= PERCENT_CRITICAL2LOW)
{
sps.BatteryFlag = BATTERY_FLAG_HIGH;
BspNotifyLed(FALSE);
}
else if (( ucBatteryPer <PERCENT_CRITICAL2LOW) && (ucBatteryPer >=BATTERY_AUTOSLEEP_VOLTAGE_PERCENT))
{
sps.BatteryFlag = BATTERY_FLAG_LOW;
BspNotifyLed(TRUE);
}
else if(ucBatteryPer<=BATTERY_AUTOSLEEP_VOLTAGE_PERCENT)
{
sps.BatteryFlag = BATTERY_FLAG_CRITICAL;
BspNotifyLed(TRUE);
}
sps.BatteryLifePercent = ucBatteryPer;
}
//=======================================================
}
else
{
if(PDD_BATTERY_EOC == battery_status)
{
RETAILMSG(0, (TEXT("+Battery status PDD_BATTERY_EOC... \r\n")));
BspFuelGaugeResetBatStatusInPercent();
BspNotifyLed(FALSE);
sps.BatteryFlag = BATTERY_FLAG_HIGH;
sps.BatteryLifePercent = 100;
} //end if PDD_BATTERY_EOC == battery_status
else
{
RETAILMSG(0, (TEXT("+Get Battery status PDD_BATTERY_ON... \r\n")));
ucBatteryPer = BspFuelGaugeGetBatStatusInPercent();
if(ucBatteryPer >= PERCENT_CRITICAL2LOW)
{
///// //Awisc.Chen add 2008-07-14 18:36 start
#if 0//awisc add for test
DPSTR("ucBatteryPer >= 20");
sps.BatteryFlag = BATTERY_FLAG_CRITICAL;
BspNotifyLed(TRUE);
//[david.modify] 2008-05-31 14:39
if(g_stBattParam.u32LowPowerSleep) {
BspBattCriticalLow();}
#endif
///// //Awisc.Chen add 2008-07-14 18:35 end
sps.BatteryFlag = BATTERY_FLAG_HIGH; //Awisc.Chen delete 2008-07-14 18:36
BspNotifyLed(FALSE); //Awisc.Chen delete 2008-07-14 18:36
}
else if (( ucBatteryPer <PERCENT_CRITICAL2LOW) && (ucBatteryPer >=BATTERY_AUTOSLEEP_VOLTAGE_PERCENT))
{
sps.BatteryFlag = BATTERY_FLAG_LOW;
BspNotifyLed(TRUE);
}
else if(ucBatteryPer<=BATTERY_AUTOSLEEP_VOLTAGE_PERCENT)
{
DPSTR("BATTERY_FLAG_CRITICAL");
sps.BatteryFlag = BATTERY_FLAG_CRITICAL;
BspNotifyLed(TRUE);
//[david.modify] 2008-05-31 14:39
if(g_stBattParam.u32LowPowerSleep) {
BspBattCriticalLow();
}
}
sps.BatteryLifePercent = ucBatteryPer;
} //end else PDD_BATTERY_ONLY
}//end else PDD_BATTERY_CHARGING == battery_status
sps.Reserved1 = 0;
sps.BatteryLifeTime = BATTERY_LIFE_UNKNOWN;
sps.BatteryFullLifeTime = BATTERY_LIFE_UNKNOWN;
sps.Reserved2 = 0;
sps.BackupBatteryFlag = BATTERY_FLAG_UNKNOWN;
sps.BackupBatteryLifePercent = 0;
sps.Reserved3 = 0;
sps.BackupBatteryLifeTime = BATTERY_LIFE_UNKNOWN;
sps.BackupBatteryFullLifeTime = BATTERY_LIFE_UNKNOWN;
sps.BatteryChemistry = BATTERY_CHEMISTRY_LIPOLY;
// sps.BatteryVoltage = (unsigned long) (voltage_percent * 4.1); ;
sps.BatteryCurrent = 0;
sps.BatteryAverageCurrent = 0;
sps.BatteryAverageInterval = 0;
sps.BatterymAHourConsumed = 0;
sps.BatteryTemperature = 0;//temperature;
sps.BackupBatteryVoltage = 0;
memcpy(&gpStatus->sps, &sps, sizeof(gpStatus->sps));
// get battery status information from the shared structure
LockBattery();
memcpy(pstatus, &gpStatus->sps, sizeof(*pstatus));
*pfBatteriesChangedSinceLastCall = gpStatus->fChanged;
if(*pfBatteriesChangedSinceLastCall) {
gpStatus->fChanged = FALSE; // reset changed flag if it's set
}
UnlockBattery();
DEBUGMSG(ZONE_PDD, (_T("%s: returning %d\r\n"), TEXT(__FUNCTION__), fOk));
return (fOk);
}
