Fix def files so that the implementation agnostic interface definition has no non-standards defined entry points, and change the eglrefimpl specific implementation to place its private entry points high up in the ordinal order space in the implementation region, not the standards based entrypoints region.
// 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 <fntstore.h>
#include <bitmap.h>
#include <bitstd.h>
#include <bitdev.h>
#include "BITPANIC.H"
#include <bitdraw.h>
#include <graphics/fbsrasterizer.h>
#include "bitgcextradata.h"
/** Clears a rectangular area.
The cleared area is filled with the current brush colour.The function
provides a concrete implementation of the pure virtual function
CBitmapContext::Clear(const TRect& aRect). The function
behaviour is the same as documented in that class. */
EXPORT_C void CFbsBitGc::Clear(const TRect& aRect)
{
if (CheckDevice(aRect))
return;
TRect rcpy(aRect);
rcpy.Move(iOrigin);
if (UserClipRect(rcpy))
return;
TBrushStyle tempbrushstyle = iBrushStyle;
iBrushStyle = ESolidBrush;
SetupDevice();
iDevice->DrawingBegin();
RectFill(rcpy);
iDevice->DrawingEnd();
iBrushStyle = tempbrushstyle;
}
/** Clears the whole bitmap or a rectangular area of a bitmap.
The cleared area is filled with the current brush colour.
The function provides a concrete implementation of the pure virtual function
CBitmapContext::Clear(). The function behaviour is the same as documented
in that class.
@see CBitmapContext::Clear() */
EXPORT_C void CFbsBitGc::Clear()
{
TRect deviceRect;
iDevice->iDrawDevice->GetDrawRect(deviceRect);
if ((iOrigin.iX!=0) || (iOrigin.iY!=0))
{
deviceRect.Move(-iOrigin);
}
Clear(deviceRect);
}
/** Draws a single point.
The point is drawn with the current pen settings using the current
drawing mode.The function provides a concrete implementation of the
pure virtual function CGraphicsContext::Plot(). The
function behaviour is the same as documented in that class. */
EXPORT_C void CFbsBitGc::Plot(const TPoint& aPoint)
{
if (iPenStyle == ENullPen || (iPenSize.iWidth == 0 && iPenSize.iHeight == 0))
return;
CheckDevice();
TRect plotRect(aPoint + iOrigin,TSize(1,1));
plotRect.Grow((iPenSize.iWidth >> 1) + 1,(iPenSize.iHeight >> 1) + 1);
if (!plotRect.Intersects(iUserClipRect))
return;
SetupDevice();
iDevice->DrawingBegin();
DoPlot(aPoint);
iDevice->DrawingEnd();
}
void CFbsBitGc::DoPlot(const TPoint& aPoint)
{
CFbsDrawDevice* drawDevice = iDevice->iDrawDevice;
const TSize oneByOne(1,1);
const TPoint point(aPoint + iOrigin);
TRect temp(point,oneByOne);
if (iPenSize.iWidth > 1 || iPenSize.iHeight > 1)
temp.Grow(iPenSize.iWidth >> 1,iPenSize.iHeight >> 1);
AddRect(temp);
const CGraphicsContext::TPenStyle penStyle = iPenStyle;
iPenStyle = CGraphicsContext::ESolidPen;
#if defined(_DEBUG)
TRect deviceRect;
drawDevice->GetDrawRect(deviceRect);
#endif
const TInt limit = iDefaultRegionPtr->Count();
for (TInt count = 0; count < limit; count++)
{
iClipRect = (*iDefaultRegionPtr)[count];
if (!iClipRect.Intersects(temp))
continue;
iClipRect.Intersection(temp);
if (UserClipRect(iClipRect))
continue;
if (iPenSize == oneByOne)
{
if (iClipRect.Contains(point))
{
BG_ASSERT_DEBUG(point.iX >= deviceRect.iTl.iX, EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(point.iY >= deviceRect.iTl.iY, EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(point.iX <= deviceRect.iBr.iX, EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(point.iY <= deviceRect.iBr.iY, EBitgdiPanicOutOfBounds);
drawDevice->WriteRgb(point.iX,point.iY,iPenColor,iDrawMode);
}
}
else if (iPenSize.iWidth > 0 && iPenSize.iHeight > 0)
PenDrawClipped(point);
drawDevice->UpdateRegion(iClipRect);
}
iPenStyle = penStyle;
}
/** Sets the shadow area.
@param aRegion The region defining the shadow area. */
EXPORT_C void CFbsBitGc::ShadowArea(const TRegion* aRegion)
{
ShadowFadeArea(aRegion,CFbsDrawDevice::EShadow);
}
/** Sets the fade area.
@param aRegion The region defining the fade area. */
EXPORT_C void CFbsBitGc::FadeArea(const TRegion* aRegion)
{
ShadowFadeArea(aRegion,CFbsDrawDevice::EFade);
}
void CFbsBitGc::ShadowFadeArea(const TRegion* aRegion,TInt8 aShadowMode)
{
if (!aRegion || aRegion->CheckError())
return;
CFbsDrawDevice* drawDevice = iDevice->iDrawDevice;
CheckDevice();
TRect deviceRect;
drawDevice->GetDrawRect(deviceRect);
TInt8 shadowMode = iShadowMode;
iShadowMode = aShadowMode;
CGraphicsAccelerator* ga = GraphicsAccelerator();
SetupDevice();
iDevice->DrawingBegin();
const TInt limit = aRegion->Count();
TInt count;
//use Graphics accelerator if available
if(ga)
{
if(iShadowMode & CFbsDrawDevice::EFade)
{
TInt gaOperationResult = KErrUnknown;
iDevice->DrawingEnd();
TGopFadeParams gopFadeParams;
gopFadeParams.iScale = iFadeWhiteMap-iFadeBlackMap+1;
gopFadeParams.iOffset = iFadeBlackMap;
for (count = 0; count < limit; count++)
{
iClipRect = (*aRegion)[count];
iClipRect.Move(iOrigin);
if(!iClipRect.Intersects(deviceRect))
continue;
iClipRect.Intersection(deviceRect);
AddRect(iClipRect);
gaOperationResult = ga->Operation(TGopFadeRect(iClipRect,gopFadeParams));
if(gaOperationResult != KErrNone)
break;
}
if(gaOperationResult == KErrNone)
goto finish;
iDevice->DrawingBegin();
}
}
//use graphics contex
for (count = 0; count < limit; count++)
{
iClipRect = (*aRegion)[count];
iClipRect.Move(iOrigin);
if(!iClipRect.Intersects(deviceRect))
continue;
iClipRect.Intersection(deviceRect);
AddRect(iClipRect);
drawDevice->ShadowArea(iClipRect);
drawDevice->UpdateRegion(iClipRect);
}
iDevice->DrawingEnd();
finish:
iShadowMode = shadowMode;
}
// if iBrushBitmap is an extended bitmap, PrepareRasterizerForExtendedBitmap() must have been called before this method
void CFbsBitGc::ClipFillLine(TPoint aLeft,TPoint aRight)
{
if (iBrushStyle == ENullBrush ||
aLeft.iY < iClipRect.iTl.iY || aLeft.iY >= iClipRect.iBr.iY)
return;
aLeft.iX = Max(aLeft.iX,iClipRect.iTl.iX);
aRight.iX = Min(aRight.iX,iClipRect.iBr.iX-1);
if (aLeft.iX > aRight.iX)
return;
BG_ASSERT_DEBUG(iUserClipRect.Contains(aLeft),EBitgdiPanicOutOfBounds);
TInt xcoord = aLeft.iX;
TInt length = aRight.iX - aLeft.iX + 1;
TPoint origin(iOrigin + iBrushOrigin);
BG_ASSERT_DEBUG(aLeft.iX + length <= iUserClipRect.iBr.iX,EBitgdiPanicOutOfBounds);
CFbsDrawDevice* drawDevice = iDevice->iDrawDevice;
switch(iBrushStyle)
{
case ESolidBrush:
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
return;
case EPatternedBrush:
{
CBitwiseBitmap* brushBitmap = iBrushBitmap.Address();
BG_ASSERT_ALWAYS(iBrushUsed,EBitgdiPanicInvalidBitmap);
BG_ASSERT_ALWAYS(brushBitmap != NULL,EBitgdiPanicInvalidBitmap);
TRect sourcerect(aLeft,TSize(length,1));
sourcerect.Move(-origin);
DoBitBlt(aLeft,brushBitmap,iBrushBitmap.DataAddress(),iBrushBitmap.DataStride(),sourcerect);
return;
}
case EHorizontalHatchBrush:
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
if (Abs((aLeft.iY - origin.iY) % 3) == 2)
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iPenColor,iDrawMode);
return;
case EVerticalHatchBrush:
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
while (Abs((xcoord - origin.iX) % 3) != 2)
xcoord++;
for (; xcoord < aLeft.iX + length; xcoord += 3)
drawDevice->WriteRgb(xcoord,aLeft.iY,iPenColor,iDrawMode);
return;
case ESquareCrossHatchBrush:
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
if (Abs((aLeft.iY - origin.iY) % 3) == 2)
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iPenColor,iDrawMode);
else
{
while (Abs((xcoord - origin.iX) % 3) != 2)
xcoord++;
for (; xcoord < aLeft.iX + length; xcoord += 3)
drawDevice->WriteRgb(xcoord,aLeft.iY,iPenColor,iDrawMode);
}
return;
case EForwardDiagonalHatchBrush:
{
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
TInt diff = (origin.iX + origin.iY - aLeft.iX - aLeft.iY) % 3;
if (diff < 0)
diff += 3;
xcoord += diff;
for (; xcoord < aLeft.iX + length; xcoord += 3)
drawDevice->WriteRgb(xcoord,aLeft.iY,iPenColor,iDrawMode);
}
return;
case ERearwardDiagonalHatchBrush:
{
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
TInt diff = (origin.iX - origin.iY - aLeft.iX + aLeft.iY) % 3;
if (diff < 0)
diff += 3;
xcoord += diff;
for (; xcoord < aLeft.iX + length; xcoord += 3)
drawDevice->WriteRgb(xcoord,aLeft.iY,iPenColor,iDrawMode);
}
return;
case EDiamondCrossHatchBrush:
{
drawDevice->WriteRgbMulti(aLeft.iX,aLeft.iY,length,1,iBrushColor,iDrawMode);
TInt sum = aLeft.iX + aLeft.iY - origin.iX - origin.iY;
for (; xcoord < aLeft.iX + length; xcoord++,sum++)
if ((sum & 1) == 0 && ((sum & 3) != 0 || ((xcoord-origin.iX) & 1) == 1))
drawDevice->WriteRgb(xcoord,aLeft.iY,iPenColor,iDrawMode);
}
return;
default:
return;
}
}
void CFbsBitGc::PenAllocate()
{
iFbsBitGcExtraData->ResetPenArray();
if (iPenSize.iWidth == 1 && iPenSize.iHeight == 1)
return;
const TInt doublepenheight = iPenSize.iHeight << 1;
TInt* penArray = new TInt[doublepenheight];
if (!penArray)
return;
iFbsBitGcExtraData->SetPenArray(penArray);
if (iPenSize.iWidth == 1 || iPenSize.iWidth == 2 || iPenSize.iHeight == 1 || iPenSize.iHeight == 2)
{
TInt* bitGcPenArray = iFbsBitGcExtraData->PenArray();
for (TInt count = 0; count < iPenSize.iHeight; count += 2)
{
bitGcPenArray[doublepenheight - count - 2] = 0;
bitGcPenArray[doublepenheight - count - 1] = iPenSize.iWidth - 1;
bitGcPenArray[count] = 0;
bitGcPenArray[count + 1] = iPenSize.iWidth - 1;
}
}
else
{
TPoint tl,tr,bl,br;
TEllipse ellipse;
ellipse.Construct(TRect(iPenSize));
TInt* bitGcPenArray = iFbsBitGcExtraData->PenArray();
for (TInt count = 0; count < iPenSize.iHeight; count += 2)
{
//coverity[check_return]
//coverity[unchecked_value]
ellipse.NextStep(tl,tr,bl,br);
bitGcPenArray[doublepenheight - count - 2] = bl.iX;
bitGcPenArray[doublepenheight - count - 1] = br.iX;
bitGcPenArray[count] = tl.iX;
bitGcPenArray[count + 1] = tr.iX;
}
}
}
void CFbsBitGc::PenDrawClipped(TPoint aPoint)
{
BG_ASSERT_DEBUG(iPenSize.iWidth > 0,EBitgdiPanicZeroLength);
BG_ASSERT_DEBUG(iPenSize.iHeight > 0,EBitgdiPanicZeroLength);
aPoint.iX -= ((iPenSize.iWidth - 1) >> 1);
aPoint.iY -= ((iPenSize.iHeight - 1) >> 1);
BG_ASSERT_DEBUG(iClipRect.iTl.iX >= iUserClipRect.iTl.iX,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iTl.iY >= iUserClipRect.iTl.iY,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iBr.iX <= iUserClipRect.iBr.iX,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iBr.iY <= iUserClipRect.iBr.iY,EBitgdiPanicOutOfBounds);
CFbsDrawDevice* drawDevice = iDevice->iDrawDevice;
if (iPenSize.iWidth == 1 && iPenSize.iHeight == 1)
{
if (iPenStyle == CGraphicsContext::ESolidPen || (iDotMask & (1 << (iDotParam % iDotLength))))
if (iClipRect.Contains(aPoint))
drawDevice->WriteRgb(aPoint.iX,aPoint.iY,iPenColor,iDrawMode);
}
else if (iFbsBitGcExtraData->PenArray())
{
TInt ycoord = aPoint.iY;
const TInt maxdim = Max(iPenSize.iWidth,iPenSize.iHeight);
const TInt doublepenheight = iPenSize.iHeight << 1;
if (iPenStyle == CGraphicsContext::ESolidPen || (iDotMask & (1 << ((iDotParam / maxdim) % iDotLength))))
{
for (TInt ix = 0; ix < doublepenheight; ycoord++,ix += 2)
{
if (ycoord >= iClipRect.iTl.iY && ycoord < iClipRect.iBr.iY)
{
TInt left = aPoint.iX + iFbsBitGcExtraData->PenArray()[ix];
TInt right = aPoint.iX + iFbsBitGcExtraData->PenArray()[ix+1];
if (left < iClipRect.iTl.iX)
left = iClipRect.iTl.iX;
if (right >= iClipRect.iBr.iX)
right = iClipRect.iBr.iX - 1;
if (left <= right)
drawDevice->WriteRgbMulti(left,ycoord,right - left + 1,1,iPenColor,CGraphicsContext::EDrawModePEN);
}
}
}
}
else
{
TPoint tl,tr,bl,br;
TEllipse ellipse;
ellipse.Construct(TRect(aPoint,iPenSize));
while (!ellipse.NextStep(tl,tr,bl,br))
{
if (tl.iY >= iClipRect.iTl.iY && tl.iY < iClipRect.iBr.iY)
{
if (tl.iX < iClipRect.iTl.iX)
tl.iX = iClipRect.iTl.iX;
if (tr.iX >= iClipRect.iBr.iX)
tr.iX = iClipRect.iBr.iX-1;
if (tl.iX <= tr.iX)
drawDevice->WriteRgbMulti(tl.iX,tl.iY,tr.iX - tl.iX + 1,1,iPenColor,CGraphicsContext::EDrawModePEN);
}
if (bl.iY >= iClipRect.iTl.iY && bl.iY < iClipRect.iBr.iY)
{
if (bl.iX < iClipRect.iTl.iX)
bl.iX = iClipRect.iTl.iX;
if (br.iX >= iClipRect.iBr.iX)
br.iX = iClipRect.iBr.iX - 1;
if (bl.iX <= br.iX)
drawDevice->WriteRgbMulti(bl.iX,bl.iY,br.iX - bl.iX + 1,1,iPenColor,CGraphicsContext::EDrawModePEN);
}
}
if (tl.iY == bl.iY && tl.iY >= iClipRect.iTl.iY && tl.iY < iClipRect.iBr.iY)
{
if (tl.iX < iClipRect.iTl.iX)
tl.iX = iClipRect.iTl.iX;
if (tr.iX >= iClipRect.iBr.iX)
tr.iX = iClipRect.iBr.iX - 1;
if (tl.iX <= tr.iX)
drawDevice->WriteRgbMulti(tl.iX,tl.iY,tr.iX - tl.iX + 1,1,iPenColor,CGraphicsContext::EDrawModePEN);
}
}
}
void CFbsBitGc::PenDrawDeferred(TPoint aPoint,TInt* aArray,TInt aFirstElement)
{
BG_ASSERT_DEBUG(iFbsBitGcExtraData->PenArray(),EBitgdiPanicZeroLength);
BG_ASSERT_DEBUG(iPenSize.iWidth > 0,EBitgdiPanicZeroLength);
BG_ASSERT_DEBUG(iPenSize.iHeight > 0,EBitgdiPanicZeroLength);
BG_ASSERT_DEBUG(iClipRect.iTl.iX >= iUserClipRect.iTl.iX,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iTl.iY >= iUserClipRect.iTl.iY,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iBr.iX <= iUserClipRect.iBr.iX,EBitgdiPanicOutOfBounds);
BG_ASSERT_DEBUG(iClipRect.iBr.iY <= iUserClipRect.iBr.iY,EBitgdiPanicOutOfBounds);
aPoint.iX -= ((iPenSize.iWidth - 1) >> 1);
const TInt doublepenheight = iPenSize.iHeight << 1;
for (TInt ix = 0; ix < doublepenheight; ix++,aFirstElement++)
{
if (aFirstElement == doublepenheight)
aFirstElement = 0;
TInt newval = aPoint.iX + iFbsBitGcExtraData->PenArray()[ix];
if (newval < aArray[aFirstElement])
aArray[aFirstElement] = newval;
ix++;
aFirstElement++;
newval = aPoint.iX + iFbsBitGcExtraData->PenArray()[ix];
if (newval > aArray[aFirstElement])
aArray[aFirstElement] = newval;
}
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CGraphicsContext_2()
{
CBitmapContext::Reserved_CGraphicsContext_2();
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CBitmapContext_1()
{
CBitmapContext::Reserved_CBitmapContext_1();
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CBitmapContext_2()
{
CBitmapContext::Reserved_CBitmapContext_2();
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CBitmapContext_3()
{
CBitmapContext::Reserved_CBitmapContext_3();
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CFbsBitGc_1()
{
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CFbsBitGc_2()
{
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CFbsBitGc_3()
{
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CFbsBitGc_4()
{
}
//Default implementation of reserved virtual
EXPORT_C void CFbsBitGc::Reserved_CFbsBitGc_5()
{
}