// Copyright (c) 2006-2009 Nokia Corporation and/or its subsidiary(-ies).

// All rights reserved.

// This component and the accompanying materials are made available

// under the terms of "Eclipse Public License v1.0"

// which accompanies this distribution, and is available

// at the URL "http://www.eclipse.org/legal/epl-v10.html".

//

// Initial Contributors:

// Nokia Corporation - initial contribution.

//

// Contributors:

//

// Description:

//

#include <mmf/devvideo/devvideopuconfig.h>

#include "mdfvideodecodehwdeviceadapter.h"

#include "displaymodeutils.h"

#if defined (SYMBIAN_MDFVIDEODECODERHWDEVICE_DEBUG)

#define DEBUG_PRINT RDebug::Print

#else

#define DEBUG_PRINT

#endif // defined (SYMBIAN_MDFVIDEODECODERHWDEVICE_DEBUG)

const TInt KOutputFormatsArraySize = 3;

const TInt KTenFPS = 10;

const TInt KOneSecond = 1000000;

const TInt KInputBufferSize = 8192;

_LIT(KDevVideoHwDeviceDecoderPanicCategory, "DevVideoHwDeviceDecoder");

void DevVideoHwDeviceDecoderPanic(TInt aReason)

	{

	User::Panic(KDevVideoHwDeviceDecoderPanicCategory, aReason);

	}

/* 

 Constructs a new instance of CMdfVideoDecodeHwDeviceAdapter.

 @return    "CMdfVideoDecodeHwDeviceAdapter*"

            A pointer to the newly constructed HwDevice

 */

CMdfVideoDecodeHwDeviceAdapter* CMdfVideoDecodeHwDeviceAdapter::NewL()

	{

	CMdfVideoDecodeHwDeviceAdapter* self = new (ELeave) CMdfVideoDecodeHwDeviceAdapter;

	CleanupStack::PushL(self);

	self->ConstructL();

	CleanupStack::Pop(self);

	return self;	

	}

/*

 Default constructor

*/

CMdfVideoDecodeHwDeviceAdapter::CMdfVideoDecodeHwDeviceAdapter()

	{

	}

void CMdfVideoDecodeHwDeviceAdapter::ConstructL()

	{

	// system clock without HAL

	TInt64 tt64;

	TTime ttime;

	ttime.HomeTime();

	tt64 = ttime.Int64();

	iSystemClock = tt64;

	// reset picture format

	iFormat.iDataFormat = (TImageDataFormat)0;

	// Load the PU Loader plugin

	iPuLoader = static_cast<CMdfPuLoader*>

		(REComSession::CreateImplementationL(TUid::Uid(KUidPuLoaderImplementation), iPuLoaderDtorKey));	

	iState = EProcessingUnitLoaderLoaded;

	}

/*

 Default destructor

*/

CMdfVideoDecodeHwDeviceAdapter::~CMdfVideoDecodeHwDeviceAdapter()

	{

	DEBUG_PRINT(_L("HwDevice: Destroying"));

	// stop playing if necessary

	Stop();

	delete iPlayerEngine;

	delete iScreenDeviceGc;

	// destroy the buffer manager

	delete iBufferManager;

	// destroy the picture header

	delete iPictureHeader;	

		// Unload the DecoderPU

	if (iDecoderPU)

		{

		iPuLoader->UnloadProcessingUnit(iDecoderPU);

		}

	delete iPuLoader;	

	delete iPuData;

	delete iManufacturer;

	REComSession::DestroyedImplementation(iPuLoaderDtorKey);			

	iInputVidFormats.ResetAndDestroy(); // will destroy contents as well

	iOutputVidFormats.Close();

	iPictureRates.Close();

	DEBUG_PRINT(_L("HwDevice: Destroyed"));

	}

/*

 @see CMMFVideoHwDevice::CustomInterface()

 */

TAny* CMdfVideoDecodeHwDeviceAdapter::CustomInterface(TUid aInterface)

	{

	if (aInterface.iUid == KUidDevVideoHwDeviceAdapterSetup)

		{

		return static_cast<MDevVideoHwDeviceAdapterSetup*>(this);

		}

	return NULL;

	}

/*

 @see CMMFVideoPlayHwDevice::PostProcessorInfoLC()

 */

CPostProcessorInfo* CMdfVideoDecodeHwDeviceAdapter::PostProcessorInfoLC()

	{

	// post processor info will be obtained from the post processor plugin, if any

	return NULL;

	}

/*

 @see CMMFVideoPlayHwDevice::GetOutputFormatListL()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetOutputFormatListL(RArray<TUncompressedVideoFormat>& aFormats)

	{

	// TUncompressedVideoFormats is a union - therefore using hard initialisation

	iOutputVidFormats.Reset();

	TUncompressedVideoFormat outputFormats[KOutputFormatsArraySize];

	outputFormats[0].iDataFormat = ERgbRawData;

	outputFormats[0].iRgbFormat = ERgb16bit565;

	iOutputVidFormats.AppendL(outputFormats[0]);

	aFormats.AppendL(outputFormats[0]);

	outputFormats[1].iDataFormat = ERgbFbsBitmap;

	outputFormats[1].iRgbFormat = EFbsBitmapColor16M;

	iOutputVidFormats.AppendL(outputFormats[1]);

	aFormats.AppendL(outputFormats[1]);

	outputFormats[2].iDataFormat = EYuvRawData;

	iOutputVidFormats.AppendL(outputFormats[2]);

	aFormats.AppendL(outputFormats[2]);

	}

/*

 @see CMMFVideoPlayHwDevice::SetOutputFormatL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetOutputFormatL(const TUncompressedVideoFormat& aFormat)

	{

	// check size and format are supported

	if(iOutputVidFormats.Count() == 0) 

		{

		User::Leave(KErrNotReady);

		}

	if(!iOutputVidFormats.Find(aFormat)) 

		{

		User::Leave(KErrNotSupported);

		}

	iFormat = aFormat;

	TDevVideoPlayPuConfig decodeConfig;

	decodeConfig.iImageFormat = iFormat;		

	decodeConfig.iInputBufferSize = KInputBufferSize;	

	TPuConfigVideoPlayback puConfig(decodeConfig);

	User::LeaveIfError(iDecoderPU->Configure(puConfig));

	}

/*

 @see CMMFVideoPlayHwDevice::SetClockSource()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetClockSource(MMMFClockSource* aClock)

	{

	iClockSource = aClock;

	}

/*

 @see CMMFVideoPlayHwDevice::SetVideoDestScreenL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetVideoDestScreenL(TBool aScreen)

	{

	if(aScreen) 

		{

		// NB we expect the output format to have been set before this is called

		if(!iFormat.iDataFormat) 

			{

			User::Leave(KErrNotReady);

			}

		// we support only bitmaps for DSA, not raw data

		if(iFormat.iDataFormat != ERgbFbsBitmap) 

			{

			User::Leave(KErrNotSupported);

			}

		}

	// ETrue = use DSA

	iDSAEnabled = aScreen;

	}

/*

 @see CMMFVideoPlayHwDevice::SetPostProcessTypesL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetPostProcessTypesL(TUint32 /* aPostProcCombination */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetInputCropOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetInputCropOptionsL(const TRect& /* aRect */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetYuvToRgbOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetYuvToRgbOptionsL(const TYuvToRgbOptions& /* aOptions */, const TYuvFormat& /* aYuvFormat */, TRgbFormat /* aRgbFormat */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetYuvToRgbOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetYuvToRgbOptionsL(const TYuvToRgbOptions& /* aOptions */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetRotateOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetRotateOptionsL(TRotationType /* aRotationType */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetScaleOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetScaleOptionsL(const TSize& /* aTargetSize */, TBool /* aAntiAliasFiltering */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetOutputCropOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetOutputCropOptionsL(const TRect& /* aRect */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::SetPostProcSpecificOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetPostProcSpecificOptionsL(const TDesC8& /* aOptions */)

	{

	// the decoder is not configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoPlayHwDevice::Initialize()

 */

void CMdfVideoDecodeHwDeviceAdapter::Initialize()

	{

	__ASSERT_ALWAYS(iProxy, DevVideoHwDeviceDecoderPanic(0));

	TRAPD(err, InitializeL());

	if(err == KErrNone && !iPUInitialized)

		{

		err = KErrNotSupported;		

		}	

	iProxy->MdvppInitializeComplete(this, err);

	}

// private method : body of Initialize()

void CMdfVideoDecodeHwDeviceAdapter::InitializeL()

	{

	// pre-check format

	switch(iFormat.iDataFormat) 

		{

		case 0:

			User::Leave(KErrNotReady);

			break;

		case ERgbRawData:

		case ERgbFbsBitmap:

		case EYuvRawData:

			break;

		default:

			User::Leave(KErrNotSupported);

			break;

		}

	// create and initialise the buffer manager

	iBufferManager = CMdfVideoDecoderBufferManager::NewL();

	iBufferManager->Init(iFormat);

	iBufferManager->SetFrameSize(iFrameSize);

	DEBUG_PRINT(_L("HwDevice: Buffer Manager initialized"));

	// The actual frame rate will come from the VOL headers.

	iFrameRate = KTenFPS;

	// reset the player flags

	iPrimed = EFalse;

	iInputBufferWaiting = EFalse;	

	iInputEnd = EFalse;

	// create the player engine

	iPlayerEngine = CMdfVideoPlayerEngine::NewL(*this);

	RPointerArray<MMdfInputPort> inputPorts;

	// Get ports and set observers

	User::LeaveIfError(iDecoderPU->GetInputPorts(inputPorts));

	if (inputPorts.Count()==0)

		{

		inputPorts.Close();

		User::Leave(KErrNotFound);

		}

	iDecoderPUInputPort = inputPorts[0];

	iDecoderPUInputPort->MipSetObserver(*this);

	inputPorts.Close();

	RPointerArray<MMdfOutputPort> outputPorts;

	User::LeaveIfError(iDecoderPU->GetOutputPorts(outputPorts));

	if (outputPorts.Count()==0)

		{

		outputPorts.Close();

		User::Leave(KErrNotFound);

		}

	iDecoderPUOutputPort = outputPorts[0];

	iDecoderPUOutputPort->MopSetObserver(*this);

	outputPorts.Close();

	iState = EProcessingUnitLoaded;

	DEBUG_PRINT(_L("HwDevice: Decoder Processing Unit Loaded"));

	// Create the buffers that are associated with the input and output ports

	iInputBuffer = &iBufferManager->CreateDataBufferL(iDecoderPUInputPort->MipBufferSize());

	iPUInputBuffer = *iInputBuffer;

	User::LeaveIfError(iDecoderPUInputPort->MipUseBuffer(*iPUInputBuffer));		

	CVideoFrameBuffer& frameBuffer = iBufferManager->CreateFrameBufferL(TMMFDisplayModeUtils::DisplayMode(iFormat.iRgbFormat));

	User::LeaveIfError(iDecoderPUOutputPort->MopUseBuffer(frameBuffer));

	// VD: should not move the set up of the state after sending the Initialize() calls???

	iState = EProcessingUnitInitializing;

	// async call, that calls back to InitializeComplete()

	iDecoderPU->Initialize();	

	DEBUG_PRINT(_L("HwDevice: Initialized OK"));

	}

/*

 @see CMMFVideoPlayHwDevice::StartDirectScreenAccessL()

 */

void CMdfVideoDecodeHwDeviceAdapter::StartDirectScreenAccessL(const TRect& aVideoRect, CFbsScreenDevice& aScreenDevice, const TRegion& aClipRegion)

	{

	// ensure SetVideoDestScreenL() has been called

	if(!iDSAEnabled)

		{

		User::Leave(KErrNotReady);

		}

	DEBUG_PRINT(_L("HwDevice: Starting DSA"));

	iDSAStarted = ETrue;

	// the CDirectScreenAccess must be created by the client app.

	// the CFbsScreenDevice (only) is passed across...

	// we need to blit the bitmap into it, i.e. we need to create our own GC

	if(!iScreenDevice) 

		{		

		User::LeaveIfError(aScreenDevice.CreateContext(iScreenDeviceGc));

		iScreenDevice = &aScreenDevice;

		iScreenDeviceRect = aVideoRect;

		iScreenDeviceGc->SetClippingRegion(aClipRegion);

		}

	}

/*

 @see CMMFVideoPlayHwDevice::SetScreenClipRegion()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetScreenClipRegion(const TRegion& aRegion)

	{

	__ASSERT_ALWAYS(iScreenDeviceGc, DevVideoHwDeviceDecoderPanic(0));

	iScreenDeviceGc->SetClippingRegion(aRegion);

	}

/*

 @see CMMFVideoPlayHwDevice::SetPauseOnClipFail()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetPauseOnClipFail(TBool /* aPause */)

	{

	// not implemented - will pause by default

	}

/*

 @see CMMFVideoPlayHwDevice::AbortDirectScreenAccess()

 */

void CMdfVideoDecodeHwDeviceAdapter::AbortDirectScreenAccess()

	{

	DEBUG_PRINT(_L("HwDevice: Stopping DSA"));

	iDSAStarted = EFalse;

	}

/*

 @see CMMFVideoPlayHwDevice::IsPlaying()

 */

TBool CMdfVideoDecodeHwDeviceAdapter::IsPlaying()

	{

	return (iState == EProcessingUnitExecuting ? ETrue : EFalse);

	}

/*

 @see CMMFVideoPlayHwDevice::Redraw()

 */

void CMdfVideoDecodeHwDeviceAdapter::Redraw()

	{

	if(iDSAStarted) 

		{

		DisplayLastFrameDirect(); 

		}

	}

/*

 @see CMMFVideoPlayHwDevice::Start()

 */

void CMdfVideoDecodeHwDeviceAdapter::Start()

	{

	__ASSERT_ALWAYS(iPlayerEngine, DevVideoHwDeviceDecoderPanic(0));

	__ASSERT_ALWAYS(iDecoderPU, DevVideoHwDeviceDecoderPanic(0));

	if(iState != EProcessingUnitExecuting)

		{		

		CVideoFrameBuffer* frameBuffer = NULL;

		TRAPD(err, frameBuffer = &iBufferManager->GetEmptyFrameBufferL(ETrue));

		if (err != KErrNone)

			{

			iProxy->MdvppFatalError(this, err);

			return;

			}

		iDecoderPUOutputPort->MopReadData(*frameBuffer);

		iDecoderPU->Execute();

		TProcessingUnitState puState = iDecoderPU->State();

		if(puState == EProcessingUnitInvalid) 

			{

			return;	

			}

		iState = EProcessingUnitExecuting;

		// if we are using raw decoding, then play as fast as we can,

		// otherwise use the actual frame rate

		TInt playerFrameRate;

		if(iSynchronize) 

			{

			playerFrameRate = TInt(iFrameRate);

			}

		else 

			{

			playerFrameRate = CMdfVideoPlayerEngine::KUnsynchronized;

			}

		TRAP(err, iPlayerEngine->StartL(playerFrameRate));			

		if(err != KErrNone) 

			{

			// the player failed to start. this is a fatal error

			iProxy->MdvppFatalError(this, err);

			}

		else 

			{			

			iProxy->MdvppNewBuffers();

			}

		}

	}

/*

 @see CMMFVideoPlayHwDevice::Stop()

 */

void CMdfVideoDecodeHwDeviceAdapter::Stop()

	{

	if(iState == EProcessingUnitExecuting)

		{

		iPlayerEngine->Stop();

		iDecoderPU->Stop();		

		iState = EProcessingUnitIdle;

		}

	}

/*

 @see CMMFVideoPlayHwDevice::Pause()

 */

void CMdfVideoDecodeHwDeviceAdapter::Pause()

	{

	Stop();

	}

/*

 @see CMMFVideoPlayHwDevice::Resume()

 */

void CMdfVideoDecodeHwDeviceAdapter::Resume()

	{

	Start();

	}

/*

 @see CMMFVideoPlayHwDevice::SetPosition()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetPosition(const TTimeIntervalMicroSeconds& aPlaybackPosition)

	{

	TPuConfigTimestamp timeStamp(aPlaybackPosition);

	// we have no way report a failure here, and it is not a fatal error so any error is ignored

	iDecoderPU->Configure(timeStamp);

	}

/*

 @see CMMFVideoPlayHwDevice::FreezePicture()

 */

void CMdfVideoDecodeHwDeviceAdapter::FreezePicture(const TTimeIntervalMicroSeconds& /* aTimestamp */)

	{

	// not supported; we have no presentation timestamps

	// however should not cause a fatal error

	}

/*

 @see CMMFVideoPlayHwDevice::ReleaseFreeze()

 */

void CMdfVideoDecodeHwDeviceAdapter::ReleaseFreeze(const TTimeIntervalMicroSeconds& /* aTimestamp */)

	{

	// not supported; we have no presentation timestamps

	// however should not cause a fatal error

	}

/*

 @see CMMFVideoPlayHwDevice::PlaybackPosition()

 */

TTimeIntervalMicroSeconds CMdfVideoDecodeHwDeviceAdapter::PlaybackPosition()

	{

	if(iFrameRate == 0.0) 

		{

		return 0;

		}

	// this is the total number of pictures displayed or discarded

	// NB it is NOT equivalent to the number of pictures decoded, as the

	// player may be running a few frames behind the decoder	

	return ((iPictureCounters.iPicturesDisplayed + iPictureCounters.iPicturesSkipped) * (KOneSecond / (TInt)iFrameRate));

	}

/*

 @see CMMFVideoPlayHwDevice::PictureBufferBytes()

 */

TUint CMdfVideoDecodeHwDeviceAdapter::PictureBufferBytes()

	{

	__ASSERT_ALWAYS(iBufferManager, DevVideoHwDeviceDecoderPanic(0));

	return (iBufferManager->FrameBufferSize() * iBufferManager->MaxFrameBuffers());

	}

/*

 @see CMMFVideoPlayHwDevice::GetPictureCounters()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetPictureCounters(CMMFDevVideoPlay::TPictureCounters& aCounters)

	{

	aCounters = iPictureCounters;

	}

/*

 @see CMMFVideoPlayHwDevice::SetComplexityLevel()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetComplexityLevel(TUint /* aLevel */)

	{

	// separate complexity levels are not available; ignored

	}

/*

 @see CMMFVideoPlayHwDevice::NumComplexityLevels()

 */

TUint CMdfVideoDecodeHwDeviceAdapter::NumComplexityLevels()

	{

	// separate complexity levels are not available; return 1

	return 1;

	}

/*

 @see CMMFVideoPlayHwDevice::GetComplexityLevelInfo()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetComplexityLevelInfo(TUint aLevel, CMMFDevVideoPlay::TComplexityLevelInfo& aInfo)

	{

	// ignore call if aLevel is not 0

	if(aLevel == 0) 

		{

		aInfo = iComplexityLevelInfo;

		}

	}

/*

 @see CMMFVideoPlayHwDevice::ReturnPicture()

 */

void CMdfVideoDecodeHwDeviceAdapter::ReturnPicture(TVideoPicture* aPicture)

	{

	__ASSERT_ALWAYS(iBufferManager, DevVideoHwDeviceDecoderPanic(0));

	// return the frame buffer that has been emptied

	TRAPD(err, iBufferManager->ReturnFrameBufferL(*aPicture, CVideoFrameBuffer::EEmptied));

	if (err == KErrNone)

		{

		if (!iLastFrameBufferReceived)

			{

			// request the next empty frame buffer

			CVideoFrameBuffer* frameBuffer = NULL;

			TRAP(err, frameBuffer = &iBufferManager->GetEmptyFrameBufferL(ETrue));

			if (err == KErrNone)

				{

				CMMFBuffer* buffer = *frameBuffer;

				iDecoderPUOutputPort->MopReadData(*buffer);

				}

			}

		// DoPostPictureNotify() will handle MdvppStreamEnd()	

		}

	else

		{

		iProxy->MdvppFatalError(this, err);

		}

	ASSERT(err == KErrNone);

	DoPostPictureNotify();

	}

/*

 @see CMMFVideoPlayHwDevice::GetSnapshotL()

 */

TBool CMdfVideoDecodeHwDeviceAdapter::GetSnapshotL(TPictureData& /*aPictureData*/, const TUncompressedVideoFormat& /*aFormat*/)

	{

	// not supported - no presentation timestamps

	User::Leave(KErrNotSupported);

	return EFalse;

	}

/*

 @see CMMFVideoPlayHwDevice::GetTimedSnapshotL()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetTimedSnapshotL(TPictureData* /*aPictureData*/, const TUncompressedVideoFormat& /*aFormat*/, const TTimeIntervalMicroSeconds& /*aPresentationTimestamp*/)

	{

	// this method should be called on the post processor not on the decoder

	// ending up here is a programming error and hence a PANIC condition

	DevVideoHwDeviceDecoderPanic(0);

	}

/*

 @see CMMFVideoPlayHwDevice::GetTimedSnapshotL()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetTimedSnapshotL(TPictureData* /*aPictureData*/, const TUncompressedVideoFormat& /*aFormat*/, const TPictureId& /*aPictureId*/)

	{

	// this method should be called on the post processor not on the decoder

	// ending up here is a programming error and hence a PANIC condition

	DevVideoHwDeviceDecoderPanic(0);

	}

/*

 @see CMMFVideoPlayHwDevice::CancelTimedSnapshot()

 */

void CMdfVideoDecodeHwDeviceAdapter::CancelTimedSnapshot()

	{

	// this method should be called on the post processor not on the decoder

	// ending up here is a programming error and hence a PANIC condition

	DevVideoHwDeviceDecoderPanic(0);

	}

/*

 @see CMMFVideoPlayHwDevice::GetSupportedSnapshotFormatsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetSupportedSnapshotFormatsL(RArray<TUncompressedVideoFormat>& /*aFormats*/)

	{

	// this method should be called on the post processor not on the decoder

	// ending up here is a programming error and hence a PANIC condition

	DevVideoHwDeviceDecoderPanic(0);

	}

/*

 @see CMMFVideoPlayHwDevice::InputEnd()

 */

void CMdfVideoDecodeHwDeviceAdapter::InputEnd()

	{

	__ASSERT_ALWAYS(iBufferManager, DevVideoHwDeviceDecoderPanic(0));

	DEBUG_PRINT(_L("HwDevice: Input end"));

	iInputEnd = ETrue;

	// if there isn't an outstanding write to the PU, write

	// an empty buffer	

	if(!iWriteRequestOutstanding) 

		{

		SendLastBuffer();

		}

	}

/*

 @see CMMFVideoDecodeHwDevice::VideoDecoderInfoLC()

 */

CVideoDecoderInfo* CMdfVideoDecodeHwDeviceAdapter::VideoDecoderInfoLC()

	{

	// this is a complicated structure, ensure all fields are

	// filled with some valid value

	//if PU is not loaded panic

	if(iPuData == NULL)	

		{

		DevVideoHwDeviceDecoderPanic(KErrNotReady);	

		}

	// supported formats array

	iInputVidFormats.Reset();

	CCompressedVideoFormat* vidCV = NULL;

	vidCV = CCompressedVideoFormat::NewL(iPuData->InputDataType() , KNullDesC8);

	CleanupStack::PushL(vidCV);

	iInputVidFormats.AppendL(vidCV);

	CleanupStack::Pop(vidCV);	// CCompressedVideo object is destroyed in destructor

	// construct the video decoder info object

	CVideoDecoderInfo* vInfo = CVideoDecoderInfo::NewL(

		iPuUid, 

		*iManufacturer,

		KNullDesC,

		TVersion(KVideoDecoderInfoVersionMaj, KVideoDecoderInfoVersionMin, KVideoDecoderInfoVersionBuild),

		iInputVidFormats.Array(),

		EFalse, // not accelerated

		ETrue, // supports direct screen access

		iMaxPictureSize, 

		KMaxTUint32, // max bitrate supported

		iPuData->MaxPictureRates().Array(),

		EFalse, // picture loss not supported,

		EFalse, // slice loss not supported,

		KVideoDecoderInfoCSInfo,

		KVideoDecoderInfoISInfo );

	CleanupStack::PushL(vInfo);

	return vInfo;

	}

/*

 @see CMMFVideoDecodeHwDevice::GetHeaderInformationL()

 */

TVideoPictureHeader* CMdfVideoDecodeHwDeviceAdapter::GetHeaderInformationL(TVideoDataUnitType aDataUnitType, TVideoDataUnitEncapsulation aEncapsulation, TVideoInputBuffer* aDataUnit)

	{

	// NB this may be called EITHER before OR after the decoder is initialized.

	// ensure at least that SetOutputFormatL() has been called before this, 

	// as the decoder requires it to be able to initialize.

	__ASSERT_ALWAYS(iFormat.iDataFormat, DevVideoHwDeviceDecoderPanic(0));

	TDevVideoHeaderPuConfig header;

	header.iDataUnitType = aDataUnitType;

	header.iDataUnitEncapsulation = aEncapsulation;

	header.iHeaderData.Set(aDataUnit->iData.Ptr(),aDataUnit->iData.Size());

	TPuConfigVideoHeader headerConfig(header);

	// Configure the decoder with the Header Information

	User::LeaveIfError(iDecoderPU->Configure(headerConfig));

	// retrieve the picture information from the config structure

	TPuConfigVideoPictureHeader pict; 

	User::LeaveIfError(iDecoderPU->GetConfig(pict));

	delete iPictureHeader;

	iPictureHeader = NULL;

	// Create a new header from the returned data

	iPictureHeader = new (ELeave)TVideoPictureHeader(

							*TPuConfigVideoPictureHeader::GetStructure(pict));

	iFrameSize = iPictureHeader->iSizeInMemory;

	return iPictureHeader;

	}

/*

 @see CMMFVideoDecodeHwDevice::ConfigureDecoderL()

 */

void CMdfVideoDecodeHwDeviceAdapter::ConfigureDecoderL(const TVideoPictureHeader& /* aVideoPictureHeader */)

	{

	// there is nothing configurable

	User::Leave(KErrNotSupported);

	}

/*

 @see CMMFVideoDecodeHwDevice::ReturnHeader()

 */

void CMdfVideoDecodeHwDeviceAdapter::ReturnHeader(TVideoPictureHeader* aHeader)

	{

	if(aHeader == iPictureHeader) // only free our created header

		{

		delete iPictureHeader;

		iPictureHeader = NULL;	

		}

	}

/*

 @see CMMFVideoDecodeHwDevice::SetInputFormatL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetInputFormatL(const CCompressedVideoFormat& aFormat, TVideoDataUnitType aDataUnitType, TVideoDataUnitEncapsulation aEncapsulation, TBool aDataInOrder)

	{

	// EDuCodedPicture, EDuElementaryStream, aDataInOrder == ETrue

	if(aFormat.MimeType() != iPuData->InputDataType()) 

		{

		User::Leave(KErrNotSupported);	

		}

	if(aDataUnitType != EDuCodedPicture) 

		{

		User::Leave(KErrNotSupported);	

		}

	if(aEncapsulation != EDuElementaryStream) 

		{

		User::Leave(KErrNotSupported);	

		}

	if(!aDataInOrder) 

		{

		User::Leave(KErrNotSupported);	

		}

	}

/*

 @see CMMFVideoDecodeHwDevice::SynchronizeDecoding()

 */

void CMdfVideoDecodeHwDeviceAdapter::SynchronizeDecoding(TBool aSynchronize)

	{

	iSynchronize = aSynchronize;

	}

/*

 @see CMMFVideoDecodeHwDevice::SetBufferOptionsL()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetBufferOptionsL(const CMMFDevVideoPlay::TBufferOptions& aOptions)

	{

	// check values are within the constraints of this device

	if(aOptions.iPreDecoderBufferPeriod != 0) 

		{

		User::Leave(KErrNotSupported);

		}

	if(aOptions.iMaxPostDecodeBufferSize != 0) 

		{

		User::Leave(KErrNotSupported);

		}

	if(aOptions.iPreDecoderBufferPeriod != 0) 

		{

		User::Leave(KErrNotSupported);

		}

	if(aOptions.iPostDecoderBufferPeriod != 0) 

		{

		User::Leave(KErrNotSupported);

		}

	if(aOptions.iMaxInputBufferSize > KVideoDecoderMaxDataBufferSize) 

		{

		User::Leave(KErrNotSupported);

		}

	if(aOptions.iMinNumInputBuffers > 1) 

		{

		User::Leave(KErrNotSupported);

		}

	// input is OK; write it

	iBufferOptions = aOptions;	

	}

/*

 @see CMMFVideoDecodeHwDevice::GetBufferOptions()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetBufferOptions(CMMFDevVideoPlay::TBufferOptions& aOptions)

	{

	aOptions = iBufferOptions;	

	}

/*

 @see CMMFVideoDecodeHwDevice::SetHrdVbvSpec()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetHrdVbvSpec(THrdVbvSpecification /* aHrdVbvSpec */, const TDesC8& /* aHrdVbvParams */)

	{

	// the decoder is not configurable

	// however this should not cause a fatal error

	}

/*

 @see CMMFVideoDecodeHwDevice::SetOutputDevice()

 */

void CMdfVideoDecodeHwDeviceAdapter::SetOutputDevice(CMMFVideoPostProcHwDevice* aDevice)

	{

	// we allow output to be sent to a post-processor,

	// even though this plugin doesn not itself provide one

	iPostProcOutputDevice = aDevice;

	}

/*

 @see CMMFVideoDecodeHwDevice::DecodingPosition()

 */

TTimeIntervalMicroSeconds CMdfVideoDecodeHwDeviceAdapter::DecodingPosition()

	{

	if(iFrameRate == 0.0) 

		{

		return 0;

		}

	// this is the total number of pictures decoded	

	return (iPictureCounters.iPicturesDecoded * (KOneSecond / (TInt)iFrameRate));

	}

/*

 @see CMMFVideoDecodeHwDevice::PreDecoderBufferBytes()

 */

TUint CMdfVideoDecodeHwDeviceAdapter::PreDecoderBufferBytes()

	{

	return 0;

	}

/*

 @see CMMFVideoDecodeHwDevice::GetBitstreamCounters()

 */

void CMdfVideoDecodeHwDeviceAdapter::GetBitstreamCounters(CMMFDevVideoPlay::TBitstreamCounters& aCounters)

	{

	aCounters = iBitstreamCounters;

	}

/*

 @see CMMFVideoDecodeHwDevice::NumFreeBuffers()

 */

TUint CMdfVideoDecodeHwDeviceAdapter::NumFreeBuffers()

	{

	__ASSERT_ALWAYS(iBufferManager, DevVideoHwDeviceDecoderPanic(0));

	if(!FrameBufferAvailable()) 

		{

		// if there are too many output buffers waiting, we refuse an input buffer

		// until some output buffers have been processed.

		return 0;

		}

	else 

		{

		return (iBufferManager->DataBuffersAvailable());

		}

	}

/*

 @see CMMFVideoDecodeHwDevice::GetBufferL()

 This will return a buffer of the requested size, within min/max constraints

 */

TVideoInputBuffer* CMdfVideoDecodeHwDeviceAdapter::GetBufferL(TUint /* aBufferSize */)

	{

	__ASSERT_ALWAYS(iBufferManager, DevVideoHwDeviceDecoderPanic(0));

	TVideoInputBuffer& buf = iBufferManager->GetDataBufferL();

	return &buf;

	}

/*

 @see CMMFVideoDecodeHwDevice::WriteCodedDataL()

 */

void CMdfVideoDecodeHwDeviceAdapter::WriteCodedDataL(TVideoInputBuffer* aInputBuffer)

	{

	// Leave on null input buffer

	if(!aInputBuffer) 

		{

		User::Leave(KErrArgument);

		}

	// increment received buffer count

	iBitstreamCounters.iTotalPackets++;