Merge 1. Pull in cpp files in the performance enhanced Khronos RI OVG files which are newly added. I've ignored platform-specific cpp files for linux, macosx, and null operating systems because this local solution has its own platform glue (i.e. facility to target Bitmaps but no full windowing support). I've ignored sfEGLInterface.cpp because this is used as a bridge to go from EGL to Nokia's Platsim which offers an EGL service. That's not relevant to this implementation because this is ARM side code, not Intel side. I just left a comment to sfEGLInterface.cpp in case we need to pick up this later on. The current code compiles on winscw. Prior to this fix, the code works on winscw, and can launch the SVG tiger (tiger.exe). That takes about 20 seconds to render. I hope to always be able to show this icon on each commit, and the plan is for the render time to reduce with this series of submissions. On this commit, the tiger renders ok in 20 seconds.
// Copyright (c) 1997-2009 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 <bitdev.h>
#include <hal.h>
#include "TBMP.H"
#include "tswitch.h"
#include <graphics/fbsdefs.h>
CTSwitch::CTSwitch(CTestStep* aStep):
CTGraphicsBase(aStep),
iBitmap(NULL),
iDevice(NULL),
iGc(NULL),
iAltDevice(NULL),
iAltGc(NULL),
iSrceBuffer(NULL),
iDestBuffer(NULL)
{
INFO_PRINTF1(_L(""));
}
CTSwitch::~CTSwitch()
{
delete iBitmap;
delete iDevice;
delete iGc;
delete iAltDevice;
delete iAltGc;
delete[] iSrceBuffer;
delete[] iDestBuffer;
}
void CTSwitch::RunTestCaseL(TInt aCurTestCase)
{
((CTSwitchStep*)iStep)->SetTestStepID(KUnknownSYMTestCaseIDName);
switch(aCurTestCase)
{
case 1:
((CTSwitchStep*)iStep)->SetTestStepID(_L("GRAPHICS-BITGDI-0065"));
TestL();
break;
case 2:
((CTSwitchStep*)iStep)->SetTestStepID(KNotATestSYMTestCaseIDName);
((CTSwitchStep*)iStep)->CloseTMSGraphicsStep();
TestComplete();
break;
}
((CTSwitchStep*)iStep)->RecordTestResultL();
}
/**
@SYMTestCaseID GRAPHICS-BITGDI-0065
@SYMDEF
@SYMTestCaseDesc Tests display mode switching
@SYMTestPriority normal
@SYMTestStatus Implemented
@SYMTestActions Creates a bitmap then switches between displaymodes and checks bitmap is not corrupted
@SYMTestExpectedResults Test should perform graphics operations succesfully.
*/
void CTSwitch::TestL()
{
INFO_PRINTF1(_L("Testing display mode switching"));
const TInt KNumDispModes = 12;
TDisplayMode displayModeArray[KNumDispModes] =
{
EGray2, EGray4, EGray16, EGray256,
EColor16, EColor256, EColor4K, EColor64K, EColor16M,
EColor16MU, EColor16MA, EColor16MAP
};
const TPtrC displayModeNameArray[KNumDispModes] =
{
_L("EGray2"), _L("EGray4"), _L("EGray16"), _L("EGray256"),
_L("EColor16"), _L("EColor256"), _L("EColor4K"), _L("EColor64K"), _L("EColor16M"),
_L("EColor16MU"), _L("EColor16MA"), _L("EColor16MAP")
};
iBitmap = new(ELeave) CFbsBitmap;
TInt ret = iBitmap->Load(_L("z:\\system\\data\\tbmp.mbm"),EMbmTbmpTcolor,EFalse);
User::LeaveIfError(ret);
iSrceBuffer = new(ELeave) TRgb[iBitmap->SizeInPixels().iWidth];
iDestBuffer = new(ELeave) TRgb[iBitmap->SizeInPixels().iWidth];
for (TInt dispModeIndex = 0; dispModeIndex < KNumDispModes; dispModeIndex++)
{
TDisplayMode dispMode = displayModeArray[dispModeIndex];
if (!SetModeL(dispMode))
continue;
INFO_PRINTF1(displayModeNameArray[dispModeIndex]);
for (TInt altDispModeIndex = 0; altDispModeIndex < KNumDispModes; altDispModeIndex++)
{
if (dispModeIndex == altDispModeIndex)
continue;
FillScreen();
TDisplayMode altDispMode = displayModeArray[altDispModeIndex];
if (SwitchModeL(altDispMode))
{
INFO_PRINTF1(displayModeNameArray[altDispModeIndex]);
INFO_PRINTF1(_L(" "));
CheckSwitch(dispMode,altDispMode);
}
else
WARN_PRINTF1(_L("Not supported"));
}
INFO_PRINTF1(_L("\r\n"));
}
}
TBool CTSwitch::SetModeL(TDisplayMode aDispMode)
{
delete iDevice;
iDevice = NULL;
delete iGc;
iGc = NULL;
TRAPD(err,iDevice = CFbsScreenDevice::NewL(_L("scdv"),aDispMode));
if (err == KErrNotSupported)
return EFalse;
User::LeaveIfError(err);
User::LeaveIfError(iDevice->CreateContext((CGraphicsContext*&)iGc));
iDevice->ChangeScreenDevice(NULL);
iDevice->SetAutoUpdate(ETrue);
return ETrue;
}
void CTSwitch::FillScreen()
{
TSize size = iDevice->SizeInPixels();
TSize bmpSize = iBitmap->SizeInPixels();
for (TInt height = 0; height < size.iHeight; height += bmpSize.iHeight)
for (TInt width = 0; width < size.iWidth; width += bmpSize.iWidth)
iGc->BitBlt(TPoint(width,height),iBitmap);
}
TBool CTSwitch::SwitchModeL(TDisplayMode aDispMode)
{
delete iAltDevice;
iAltDevice = NULL;
delete iAltGc;
iAltGc = NULL;
TRAPD(err,iAltDevice = CFbsScreenDevice::NewL(_L("scdv"),aDispMode));
if (err == KErrNotSupported)
return EFalse;
User::LeaveIfError(err);
User::LeaveIfError(iAltDevice->CreateContext((CGraphicsContext*&)iAltGc));
iAltDevice->SetAutoUpdate(ETrue);
iAltDevice->ChangeScreenDevice(iDevice);
return ETrue;
}
void CTSwitch::CheckSwitch(TDisplayMode aOldDispMode,TDisplayMode aNewDispMode)
{
TSize size = iDevice->SizeInPixels();
TSize bmpSize = iBitmap->SizeInPixels();
TPtr8 srce((TUint8*)iSrceBuffer,bmpSize.iWidth * sizeof(TRgb),bmpSize.iWidth * sizeof(TRgb));
TPtr8 dest((TUint8*)iDestBuffer,bmpSize.iWidth * sizeof(TRgb),bmpSize.iWidth * sizeof(TRgb));
for (TInt yy = 0; yy < size.iHeight; yy++)
{
for (TInt xx = 0; xx < size.iWidth; xx += bmpSize.iWidth)
{
// Width for scanline as wide as bitmap or remaining width of screen, whichever smallest
TUint lineWidth = Min(bmpSize.iWidth,size.iWidth - xx);
// yy%bmpSize.iHeight used if screen height greater than bitmap
// as it is tessellated across the screen
iBitmap->GetScanLine(srce,TPoint(00,yy%bmpSize.iHeight),lineWidth,ERgb);
iAltDevice->GetScanLine(dest,TPoint(xx,yy),lineWidth,ERgb);
CheckBuffers(aOldDispMode,aNewDispMode,lineWidth,(yy * 2 + xx) & 3); // Last parameter is aDitherOffset
}
}
}
void CTSwitch::CheckBuffers(TDisplayMode aOldDispMode, TDisplayMode aNewDispMode, TUint aLineWidth,TInt aDitherOffset)
{
TRgb* srcePtr = iSrceBuffer;
TRgb* destPtr = iDestBuffer;
for (TUint count = 0; count < aLineWidth; count++)
{
TRgb srce = *srcePtr++;
TRgb dest = *destPtr++;
CheckRgbs(aOldDispMode,srce,aNewDispMode,dest,aDitherOffset ^ (count & 1));
}
}
void CTSwitch::CheckRgbs(TDisplayMode aOldDispMode,TRgb aSrceRgb,TDisplayMode aNewDispMode,TRgb aDestRgb,TInt aDitherOffset)
{
ConvertRgb(aSrceRgb,aOldDispMode,aDitherOffset);
ConvertRgb(aSrceRgb,aNewDispMode,1); // 1 suppresses dithering in EGray2 mode
TEST(aSrceRgb == aDestRgb);
}
void CTSwitch::ConvertRgb(TRgb& aRgb,TDisplayMode aDispMode,TInt aDitherOffset)
{
switch (aDispMode)
{
case EGray2:
{
TInt gray4 = aRgb.Gray4();
if (gray4 == 0)
aRgb = KRgbBlack;
else if (gray4 == 1)
{
if (aDitherOffset == 1 || aDitherOffset == 2)
aRgb = KRgbBlack;
else
aRgb = KRgbWhite;
}
else if (gray4 == 2)
{
if (aDitherOffset == 3)
aRgb = KRgbBlack;
else
aRgb = KRgbWhite;
}
else if (gray4 == 3)
aRgb = KRgbWhite;
}
break;
case EGray4:
aRgb = TRgb::Gray4(aRgb.Gray4());
break;
case EGray16:
aRgb = TRgb::Gray16(aRgb.Gray16());
break;
case EGray256:
aRgb = TRgb::Gray256(aRgb.Gray256());
break;
case EColor16:
aRgb = TRgb::Color16(aRgb.Color16());
break;
case EColor256:
aRgb = TRgb::Color256(aRgb.Color256());
break;
case EColor4K:
aRgb = TRgb::Color4K(aRgb.Color4K());
break;
case EColor64K:
aRgb = TRgb::Color64K(aRgb.Color64K());
break;
default:
break;
}
}
//--------------
__CONSTRUCT_STEP__(Switch)
void CTSwitchStep::TestSetupL()
{
FbsStartup();
User::LeaveIfError(RFbsSession::Connect());
}
void CTSwitchStep::TestClose()
{
RFbsSession::Disconnect();
}