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1130
1131 | /* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/*
* This file is part of the LibreOffice project.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
*/
#include <vcl/BitmapTools.hxx>
#include <sal/log.hxx>
#include <comphelper/processfactory.hxx>
#include <comphelper/seqstream.hxx>
#include <vcl/canvastools.hxx>
#include <basegfx/matrix/b2dhommatrix.hxx>
#include <com/sun/star/graphic/SvgTools.hpp>
#include <com/sun/star/graphic/Primitive2DTools.hpp>
#include <drawinglayer/primitive2d/baseprimitive2d.hxx>
#include <com/sun/star/rendering/XIntegerReadOnlyBitmap.hpp>
#include <vcl/dibtools.hxx>
#include <vcl/settings.hxx>
#include <vcl/svapp.hxx>
#include <vcl/bitmapaccess.hxx>
#include <vcl/virdev.hxx>
#if ENABLE_CAIRO_CANVAS
#include <cairo.h>
#endif
#include <tools/diagnose_ex.h>
#include <tools/fract.hxx>
#include <tools/stream.hxx>
#include <bitmapwriteaccess.hxx>
using namespace css;
using drawinglayer::primitive2d::Primitive2DSequence;
using drawinglayer::primitive2d::Primitive2DReference;
namespace vcl::bitmap
{
BitmapEx loadFromName(const OUString& rFileName, const ImageLoadFlags eFlags)
{
bool bSuccess = true;
OUString aIconTheme;
BitmapEx aBitmapEx;
try
{
aIconTheme = Application::GetSettings().GetStyleSettings().DetermineIconTheme();
ImageTree::get().loadImage(rFileName, aIconTheme, aBitmapEx, true, eFlags);
}
catch (...)
{
bSuccess = false;
}
SAL_WARN_IF(!bSuccess, "vcl", "vcl::bitmap::loadFromName : could not load image " << rFileName << " via icon theme " << aIconTheme);
return aBitmapEx;
}
void loadFromSvg(SvStream& rStream, const OUString& sPath, BitmapEx& rBitmapEx, double fScalingFactor)
{
uno::Reference<uno::XComponentContext> xContext(comphelper::getProcessComponentContext());
const uno::Reference<graphic::XSvgParser> xSvgParser = graphic::SvgTools::create(xContext);
std::size_t nSize = rStream.remainingSize();
std::vector<sal_Int8> aBuffer(nSize + 1);
rStream.ReadBytes(aBuffer.data(), nSize);
aBuffer[nSize] = 0;
uno::Sequence<sal_Int8> aData(aBuffer.data(), nSize + 1);
uno::Reference<io::XInputStream> aInputStream(new comphelper::SequenceInputStream(aData));
const Primitive2DSequence aPrimitiveSequence = xSvgParser->getDecomposition(aInputStream, sPath);
if (!aPrimitiveSequence.hasElements())
return;
uno::Sequence<beans::PropertyValue> aViewParameters;
geometry::RealRectangle2D aRealRect;
basegfx::B2DRange aRange;
for (Primitive2DReference const & xReference : aPrimitiveSequence)
{
if (xReference.is())
{
aRealRect = xReference->getRange(aViewParameters);
aRange.expand(basegfx::B2DRange(aRealRect.X1, aRealRect.Y1, aRealRect.X2, aRealRect.Y2));
}
}
aRealRect.X1 = aRange.getMinX();
aRealRect.Y1 = aRange.getMinY();
aRealRect.X2 = aRange.getMaxX();
aRealRect.Y2 = aRange.getMaxY();
double nDPI = 96 * fScalingFactor;
const css::uno::Reference<css::graphic::XPrimitive2DRenderer> xPrimitive2DRenderer = css::graphic::Primitive2DTools::create(xContext);
const css::uno::Reference<css::rendering::XBitmap> xBitmap(
xPrimitive2DRenderer->rasterize(aPrimitiveSequence, aViewParameters, nDPI, nDPI, aRealRect, 256*256));
if (xBitmap.is())
{
const css::uno::Reference<css::rendering::XIntegerReadOnlyBitmap> xIntBmp(xBitmap, uno::UNO_QUERY_THROW);
rBitmapEx = vcl::unotools::bitmapExFromXBitmap(xIntBmp);
}
}
/** Copy block of image data into the bitmap.
Assumes that the Bitmap has been constructed with the desired size.
@param pData
The block of data to copy
@param nStride
The number of bytes in a scanline, must >= (width * nBitCount / 8)
*/
BitmapEx CreateFromData( sal_uInt8 const *pData, sal_Int32 nWidth, sal_Int32 nHeight, sal_Int32 nStride, sal_uInt16 nBitCount )
{
assert(nStride >= (nWidth * nBitCount / 8));
assert( nBitCount == 1 || nBitCount == 24 || nBitCount == 32);
Bitmap aBmp( Size( nWidth, nHeight ), nBitCount );
BitmapScopedWriteAccess pWrite(aBmp);
assert(pWrite.get());
if( !pWrite )
return BitmapEx();
std::unique_ptr<AlphaMask> pAlphaMask;
AlphaScopedWriteAccess xMaskAcc;
if (nBitCount == 32)
{
pAlphaMask.reset( new AlphaMask( Size(nWidth, nHeight) ) );
xMaskAcc = AlphaScopedWriteAccess(*pAlphaMask);
}
if (nBitCount == 1)
{
for( long y = 0; y < nHeight; ++y )
{
Scanline pScanline = pWrite->GetScanline(y);
for (long x = 0; x < nWidth; ++x)
{
sal_uInt8 const *p = pData + y * nStride / 8;
int bitIndex = (y * nStride) % 8;
pWrite->SetPixelOnData(pScanline, x, BitmapColor((*p >> bitIndex) & 1));
}
}
}
else
{
for( long y = 0; y < nHeight; ++y )
{
sal_uInt8 const *p = pData + (y * nStride);
Scanline pScanline = pWrite->GetScanline(y);
for (long x = 0; x < nWidth; ++x)
{
BitmapColor col(p[0], p[1], p[2]);
pWrite->SetPixelOnData(pScanline, x, col);
p += nBitCount/8;
}
if (nBitCount == 32)
{
p = pData + (y * nStride) + 3;
Scanline pMaskScanLine = xMaskAcc->GetScanline(y);
for (long x = 0; x < nWidth; ++x)
{
xMaskAcc->SetPixelOnData(pMaskScanLine, x, BitmapColor(*p));
p += 4;
}
}
}
}
if (nBitCount == 32)
return BitmapEx(aBmp, *pAlphaMask);
else
return BitmapEx(aBmp);
}
/** Copy block of image data into the bitmap.
Assumes that the Bitmap has been constructed with the desired size.
*/
BitmapEx CreateFromData( RawBitmap&& rawBitmap )
{
auto nBitCount = rawBitmap.GetBitCount();
assert( nBitCount == 24 || nBitCount == 32);
Bitmap aBmp( rawBitmap.maSize, nBitCount );
BitmapScopedWriteAccess pWrite(aBmp);
assert(pWrite.get());
if( !pWrite )
return BitmapEx();
std::unique_ptr<AlphaMask> pAlphaMask;
AlphaScopedWriteAccess xMaskAcc;
if (nBitCount == 32)
{
pAlphaMask.reset( new AlphaMask( rawBitmap.maSize ) );
xMaskAcc = AlphaScopedWriteAccess(*pAlphaMask);
}
auto nHeight = rawBitmap.maSize.getHeight();
auto nWidth = rawBitmap.maSize.getWidth();
auto nStride = nWidth * nBitCount / 8;
for( long y = 0; y < nHeight; ++y )
{
sal_uInt8 const *p = rawBitmap.mpData.get() + (y * nStride);
Scanline pScanline = pWrite->GetScanline(y);
for (long x = 0; x < nWidth; ++x)
{
BitmapColor col(p[0], p[1], p[2]);
pWrite->SetPixelOnData(pScanline, x, col);
p += nBitCount/8;
}
if (nBitCount == 32)
{
p = rawBitmap.mpData.get() + (y * nStride) + 3;
Scanline pMaskScanLine = xMaskAcc->GetScanline(y);
for (long x = 0; x < nWidth; ++x)
{
xMaskAcc->SetPixelOnData(pMaskScanLine, x, BitmapColor(*p));
p += 4;
}
}
}
if (nBitCount == 32)
return BitmapEx(aBmp, *pAlphaMask);
else
return BitmapEx(aBmp);
}
#if ENABLE_CAIRO_CANVAS
BitmapEx* CreateFromCairoSurface(Size aSize, cairo_surface_t * pSurface)<--- The function 'CreateFromCairoSurface' is never used.
{
// FIXME: if we could teach VCL/ about cairo handles, life could
// be significantly better here perhaps.
#if CAIRO_VERSION >= CAIRO_VERSION_ENCODE(1, 12, 0)
cairo_surface_t *pPixels = cairo_surface_create_similar_image(pSurface,
#else
cairo_surface_t *pPixels = cairo_image_surface_create(
#endif
CAIRO_FORMAT_ARGB32, aSize.Width(), aSize.Height());
cairo_t *pCairo = cairo_create( pPixels );
if( !pPixels || !pCairo || cairo_status(pCairo) != CAIRO_STATUS_SUCCESS )
return nullptr;
// suck ourselves from the X server to this buffer so then we can fiddle with
// Alpha to turn it into the ultra-lame vcl required format and then push it
// all back again later at vast expense [ urgh ]
cairo_set_source_surface( pCairo, pSurface, 0, 0 );
cairo_set_operator( pCairo, CAIRO_OPERATOR_SOURCE );
cairo_paint( pCairo );
::Bitmap aRGB( aSize, 24 );
::AlphaMask aMask( aSize );
BitmapScopedWriteAccess pRGBWrite(aRGB);
assert(pRGBWrite);
if (!pRGBWrite)
return nullptr;
AlphaScopedWriteAccess pMaskWrite(aMask);
assert(pMaskWrite);
if (!pMaskWrite)
return nullptr;
cairo_surface_flush(pPixels);
unsigned char *pSrc = cairo_image_surface_get_data( pPixels );
unsigned int nStride = cairo_image_surface_get_stride( pPixels );
vcl::bitmap::lookup_table unpremultiply_table = vcl::bitmap::get_unpremultiply_table();
for( long y = 0; y < aSize.Height(); y++ )
{
sal_uInt32 *pPix = reinterpret_cast<sal_uInt32 *>(pSrc + nStride * y);
for( long x = 0; x < aSize.Width(); x++ )
{
#if defined OSL_BIGENDIAN
sal_uInt8 nB = (*pPix >> 24);
sal_uInt8 nG = (*pPix >> 16) & 0xff;
sal_uInt8 nR = (*pPix >> 8) & 0xff;
sal_uInt8 nAlpha = *pPix & 0xff;
#else
sal_uInt8 nAlpha = (*pPix >> 24);
sal_uInt8 nR = (*pPix >> 16) & 0xff;
sal_uInt8 nG = (*pPix >> 8) & 0xff;
sal_uInt8 nB = *pPix & 0xff;
#endif
if( nAlpha != 0 && nAlpha != 255 )
{
// Cairo uses pre-multiplied alpha - we do not => re-multiply
nR = unpremultiply_table[nAlpha][nR];
nG = unpremultiply_table[nAlpha][nG];
nB = unpremultiply_table[nAlpha][nB];
}
pRGBWrite->SetPixel( y, x, BitmapColor( nR, nG, nB ) );
pMaskWrite->SetPixelIndex( y, x, 255 - nAlpha );
pPix++;
}
}
// ignore potential errors above. will get caller a
// uniformly white bitmap, but not that there would
// be error handling in calling code ...
::BitmapEx *pBitmapEx = new ::BitmapEx( aRGB, aMask );
cairo_destroy( pCairo );
cairo_surface_destroy( pPixels );
return pBitmapEx;
}
#endif
BitmapEx CanvasTransformBitmap( const BitmapEx& rBitmap,<--- The function 'CanvasTransformBitmap' is never used.
const ::basegfx::B2DHomMatrix& rTransform,
::basegfx::B2DRectangle const & rDestRect,
::basegfx::B2DHomMatrix const & rLocalTransform )
{
const Size aBmpSize( rBitmap.GetSizePixel() );
Bitmap aSrcBitmap( rBitmap.GetBitmap() );
Bitmap aSrcAlpha;
// differentiate mask and alpha channel (on-off
// vs. multi-level transparency)
if( rBitmap.IsTransparent() )
{
if( rBitmap.IsAlpha() )
aSrcAlpha = rBitmap.GetAlpha().GetBitmap();
else
aSrcAlpha = rBitmap.GetMask();
}
Bitmap::ScopedReadAccess pReadAccess( aSrcBitmap );
Bitmap::ScopedReadAccess pAlphaReadAccess( rBitmap.IsTransparent() ?
aSrcAlpha.AcquireReadAccess() :
nullptr,
aSrcAlpha );
if( pReadAccess.get() == nullptr ||
(pAlphaReadAccess.get() == nullptr && rBitmap.IsTransparent()) )
{
// TODO(E2): Error handling!
ENSURE_OR_THROW( false,
"transformBitmap(): could not access source bitmap" );
}
// mapping table, to translate pAlphaReadAccess' pixel
// values into destination alpha values (needed e.g. for
// paletted 1-bit masks).
sal_uInt8 aAlphaMap[256];
if( rBitmap.IsTransparent() )
{
if( rBitmap.IsAlpha() )
{
// source already has alpha channel - 1:1 mapping,
// i.e. aAlphaMap[0]=0,...,aAlphaMap[255]=255.
sal_uInt8 val=0;
sal_uInt8* pCur=aAlphaMap;
sal_uInt8* const pEnd=&aAlphaMap[256];
while(pCur != pEnd)
*pCur++ = val++;
}
else
{
// mask transparency - determine used palette colors
const BitmapColor& rCol0( pAlphaReadAccess->GetPaletteColor( 0 ) );
const BitmapColor& rCol1( pAlphaReadAccess->GetPaletteColor( 1 ) );
// shortcut for true luminance calculation
// (assumes that palette is grey-level)
aAlphaMap[0] = rCol0.GetRed();
aAlphaMap[1] = rCol1.GetRed();
}
}
// else: mapping table is not used
const Size aDestBmpSize( ::basegfx::fround( rDestRect.getWidth() ),
::basegfx::fround( rDestRect.getHeight() ) );
if( aDestBmpSize.IsEmpty() )
return BitmapEx();
Bitmap aDstBitmap( aDestBmpSize, aSrcBitmap.GetBitCount(), &pReadAccess->GetPalette() );
Bitmap aDstAlpha( AlphaMask( aDestBmpSize ).GetBitmap() );
{
// just to be on the safe side: let the
// ScopedAccessors get destructed before
// copy-constructing the resulting bitmap. This will
// rule out the possibility that cached accessor data
// is not yet written back.
BitmapScopedWriteAccess pWriteAccess( aDstBitmap );
BitmapScopedWriteAccess pAlphaWriteAccess( aDstAlpha );
if( pWriteAccess.get() != nullptr &&
pAlphaWriteAccess.get() != nullptr &&
rTransform.isInvertible() )
{
// we're doing inverse mapping here, i.e. mapping
// points from the destination bitmap back to the
// source
::basegfx::B2DHomMatrix aTransform( rLocalTransform );
aTransform.invert();
// for the time being, always read as ARGB
for( long y=0; y<aDestBmpSize.Height(); ++y )
{
// differentiate mask and alpha channel (on-off
// vs. multi-level transparency)
if( rBitmap.IsTransparent() )
{
Scanline pScan = pWriteAccess->GetScanline( y );
Scanline pScanAlpha = pAlphaWriteAccess->GetScanline( y );
// Handling alpha and mask just the same...
for( long x=0; x<aDestBmpSize.Width(); ++x )
{
::basegfx::B2DPoint aPoint(x,y);
aPoint *= aTransform;
const int nSrcX( ::basegfx::fround( aPoint.getX() ) );
const int nSrcY( ::basegfx::fround( aPoint.getY() ) );
if( nSrcX < 0 || nSrcX >= aBmpSize.Width() ||
nSrcY < 0 || nSrcY >= aBmpSize.Height() )
{
pAlphaWriteAccess->SetPixelOnData( pScanAlpha, x, BitmapColor(255) );
}
else
{
const sal_uInt8 cAlphaIdx = pAlphaReadAccess->GetPixelIndex( nSrcY, nSrcX );
pAlphaWriteAccess->SetPixelOnData( pScanAlpha, x, BitmapColor(aAlphaMap[ cAlphaIdx ]) );
pWriteAccess->SetPixelOnData( pScan, x, pReadAccess->GetPixel( nSrcY, nSrcX ) );
}
}
}
else
{
Scanline pScan = pWriteAccess->GetScanline( y );
Scanline pScanAlpha = pAlphaWriteAccess->GetScanline( y );
for( long x=0; x<aDestBmpSize.Width(); ++x )
{
::basegfx::B2DPoint aPoint(x,y);
aPoint *= aTransform;
const int nSrcX( ::basegfx::fround( aPoint.getX() ) );
const int nSrcY( ::basegfx::fround( aPoint.getY() ) );
if( nSrcX < 0 || nSrcX >= aBmpSize.Width() ||
nSrcY < 0 || nSrcY >= aBmpSize.Height() )
{
pAlphaWriteAccess->SetPixelOnData( pScanAlpha, x, BitmapColor(255) );
}
else
{
pAlphaWriteAccess->SetPixelOnData( pScanAlpha, x, BitmapColor(0) );
pWriteAccess->SetPixelOnData( pScan, x, pReadAccess->GetPixel( nSrcY,
nSrcX ) );
}
}
}
}
}
else
{
// TODO(E2): Error handling!
ENSURE_OR_THROW( false,
"transformBitmap(): could not access bitmap" );
}
}
return BitmapEx(aDstBitmap, AlphaMask(aDstAlpha));
}
void DrawAlphaBitmapAndAlphaGradient(BitmapEx & rBitmapEx, bool bFixedTransparence, float fTransparence, AlphaMask & rNewMask)
{
// mix existing and new alpha mask
AlphaMask aOldMask;
if(rBitmapEx.IsAlpha())
{
aOldMask = rBitmapEx.GetAlpha();
}
else if(TransparentType::Bitmap == rBitmapEx.GetTransparentType())
{
aOldMask = rBitmapEx.GetMask();
}
else if(TransparentType::Color == rBitmapEx.GetTransparentType())
{
aOldMask = rBitmapEx.GetBitmap().CreateMask(rBitmapEx.GetTransparentColor());
}
{
AlphaScopedWriteAccess pOld(aOldMask);
assert(pOld && "Got no access to old alpha mask (!)");
const double fFactor(1.0 / 255.0);
if(bFixedTransparence)
{
const double fOpNew(1.0 - fTransparence);
for(long y(0); y < pOld->Height(); y++)
{
Scanline pScanline = pOld->GetScanline( y );
for(long x(0); x < pOld->Width(); x++)
{
const double fOpOld(1.0 - (pOld->GetIndexFromData(pScanline, x) * fFactor));
const sal_uInt8 aCol(basegfx::fround((1.0 - (fOpOld * fOpNew)) * 255.0));
pOld->SetPixelOnData(pScanline, x, BitmapColor(aCol));
}
}
}
else
{
AlphaMask::ScopedReadAccess pNew(rNewMask);
assert(pNew && "Got no access to new alpha mask (!)");
assert(pOld->Width() == pNew->Width() && pOld->Height() == pNew->Height() &&
"Alpha masks have different sizes (!)");
for(long y(0); y < pOld->Height(); y++)
{
Scanline pScanline = pOld->GetScanline( y );
for(long x(0); x < pOld->Width(); x++)
{
const double fOpOld(1.0 - (pOld->GetIndexFromData(pScanline, x) * fFactor));
const double fOpNew(1.0 - (pNew->GetIndexFromData(pScanline, x) * fFactor));
const sal_uInt8 aCol(basegfx::fround((1.0 - (fOpOld * fOpNew)) * 255.0));
pOld->SetPixelOnData(pScanline, x, BitmapColor(aCol));
}
}
}
}
// apply combined bitmap as mask
rBitmapEx = BitmapEx(rBitmapEx.GetBitmap(), aOldMask);
}
void DrawAndClipBitmap(const Point& rPos, const Size& rSize, const BitmapEx& rBitmap, BitmapEx & aBmpEx, basegfx::B2DPolyPolygon const & rClipPath)
{
ScopedVclPtrInstance< VirtualDevice > pVDev;
MapMode aMapMode( MapUnit::Map100thMM );
aMapMode.SetOrigin( Point( -rPos.X(), -rPos.Y() ) );
const Size aOutputSizePixel( pVDev->LogicToPixel( rSize, aMapMode ) );
const Size aSizePixel( rBitmap.GetSizePixel() );
if ( aOutputSizePixel.Width() && aOutputSizePixel.Height() )
{
aMapMode.SetScaleX( Fraction( aSizePixel.Width(), aOutputSizePixel.Width() ) );
aMapMode.SetScaleY( Fraction( aSizePixel.Height(), aOutputSizePixel.Height() ) );
}
pVDev->SetMapMode( aMapMode );
pVDev->SetOutputSizePixel( aSizePixel );
pVDev->SetFillColor( COL_BLACK );
const tools::PolyPolygon aClip( rClipPath );
pVDev->DrawPolyPolygon( aClip );
// #i50672# Extract whole VDev content (to match size of rBitmap)
pVDev->EnableMapMode( false );
const Bitmap aVDevMask(pVDev->GetBitmap(Point(), aSizePixel));
if(aBmpEx.IsTransparent())
{
// bitmap already uses a Mask or Alpha, we need to blend that with
// the new masking in pVDev
if(aBmpEx.IsAlpha())
{
// need to blend in AlphaMask quality (8Bit)
AlphaMask fromVDev(aVDevMask);
AlphaMask fromBmpEx(aBmpEx.GetAlpha());
AlphaMask::ScopedReadAccess pR(fromVDev);
AlphaScopedWriteAccess pW(fromBmpEx);
if(pR && pW)
{
const long nWidth(std::min(pR->Width(), pW->Width()));
const long nHeight(std::min(pR->Height(), pW->Height()));
for(long nY(0); nY < nHeight; nY++)
{
Scanline pScanlineR = pR->GetScanline( nY );
Scanline pScanlineW = pW->GetScanline( nY );
for(long nX(0); nX < nWidth; nX++)
{
const sal_uInt8 nIndR(pR->GetIndexFromData(pScanlineR, nX));
const sal_uInt8 nIndW(pW->GetIndexFromData(pScanlineW, nX));
// these values represent transparency (0 == no, 255 == fully transparent),
// so to blend these we have to multiply the inverse (opacity)
// and re-invert the result to transparence
const sal_uInt8 nCombined(0x00ff - (((0x00ff - nIndR) * (0x00ff - nIndW)) >> 8));
pW->SetPixelOnData(pScanlineW, nX, BitmapColor(nCombined));
}
}
}
pR.reset();
pW.reset();
aBmpEx = BitmapEx(aBmpEx.GetBitmap(), fromBmpEx);
}
else
{
// need to blend in Mask quality (1Bit)
Bitmap aMask(aVDevMask.CreateMask(COL_WHITE));
if ( rBitmap.GetTransparentColor() == COL_WHITE )
{
aMask.CombineSimple( rBitmap.GetMask(), BmpCombine::Or );
}
else
{
aMask.CombineSimple( rBitmap.GetMask(), BmpCombine::And );
}
aBmpEx = BitmapEx( rBitmap.GetBitmap(), aMask );
}
}
else
{
// no mask yet, create and add new mask. For better quality, use Alpha,
// this allows the drawn mask being processed with AntiAliasing (AAed)
aBmpEx = BitmapEx(rBitmap.GetBitmap(), aVDevMask);
}
}
css::uno::Sequence< sal_Int8 > GetMaskDIB(BitmapEx const & aBmpEx)
{
if ( aBmpEx.IsAlpha() )
{
SvMemoryStream aMem;
WriteDIB(aBmpEx.GetAlpha().GetBitmap(), aMem, false, true);
return css::uno::Sequence< sal_Int8 >( static_cast<sal_Int8 const *>(aMem.GetData()), aMem.Tell() );
}
else if ( aBmpEx.IsTransparent() )
{
SvMemoryStream aMem;
WriteDIB(aBmpEx.GetMask(), aMem, false, true);
return css::uno::Sequence< sal_Int8 >( static_cast<sal_Int8 const *>(aMem.GetData()), aMem.Tell() );
}
return css::uno::Sequence< sal_Int8 >();
}
static bool readAlpha( BitmapReadAccess const * pAlphaReadAcc, long nY, const long nWidth, unsigned char* data, long nOff )
{
bool bIsAlpha = false;
long nX;
int nAlpha;
Scanline pReadScan;
nOff += 3;
switch( pAlphaReadAcc->GetScanlineFormat() )
{
case ScanlineFormat::N8BitTcMask:
pReadScan = pAlphaReadAcc->GetScanline( nY );
for( nX = 0; nX < nWidth; nX++ )
{
nAlpha = data[ nOff ] = 255 - ( *pReadScan++ );
if( nAlpha != 255 )
bIsAlpha = true;
nOff += 4;
}
break;
case ScanlineFormat::N8BitPal:
pReadScan = pAlphaReadAcc->GetScanline( nY );
for( nX = 0; nX < nWidth; nX++ )
{
BitmapColor const& rColor(
pAlphaReadAcc->GetPaletteColor(*pReadScan));
pReadScan++;
nAlpha = data[ nOff ] = 255 - rColor.GetIndex();
if( nAlpha != 255 )
bIsAlpha = true;
nOff += 4;
}
break;
default:
SAL_INFO( "canvas.cairo", "fallback to GetColor for alpha - slow, format: " << static_cast<int>(pAlphaReadAcc->GetScanlineFormat()) );
for( nX = 0; nX < nWidth; nX++ )
{
nAlpha = data[ nOff ] = 255 - pAlphaReadAcc->GetColor( nY, nX ).GetIndex();
if( nAlpha != 255 )
bIsAlpha = true;
nOff += 4;
}
}
return bIsAlpha;
}
/**
* @param data will be filled with alpha data, if xBitmap is alpha/transparent image
* @param bHasAlpha will be set to true if resulting surface has alpha
**/
void CanvasCairoExtractBitmapData( BitmapEx const & aBmpEx, Bitmap & aBitmap, unsigned char*& data, bool& bHasAlpha, long& rnWidth, long& rnHeight )<--- The function 'CanvasCairoExtractBitmapData' is never used.
{
AlphaMask aAlpha = aBmpEx.GetAlpha();
::BitmapReadAccess* pBitmapReadAcc = aBitmap.AcquireReadAccess();
::BitmapReadAccess* pAlphaReadAcc = nullptr;
const long nWidth = rnWidth = pBitmapReadAcc->Width();
const long nHeight = rnHeight = pBitmapReadAcc->Height();
long nX, nY;
bool bIsAlpha = false;
if( aBmpEx.IsTransparent() || aBmpEx.IsAlpha() )
pAlphaReadAcc = aAlpha.AcquireReadAccess();
data = static_cast<unsigned char*>(malloc( nWidth*nHeight*4 ));
long nOff = 0;
::Color aColor;
unsigned int nAlpha = 255;
vcl::bitmap::lookup_table premultiply_table = vcl::bitmap::get_premultiply_table();
for( nY = 0; nY < nHeight; nY++ )
{
::Scanline pReadScan;
switch( pBitmapReadAcc->GetScanlineFormat() )
{
case ScanlineFormat::N8BitPal:
pReadScan = pBitmapReadAcc->GetScanline( nY );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff++ ];
else
nAlpha = data[ nOff++ ] = 255;
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
#endif
aColor = pBitmapReadAcc->GetPaletteColor(*pReadScan++);
#ifdef OSL_BIGENDIAN
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetRed()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetGreen()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetBlue()];
#else
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetBlue()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetGreen()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetRed()];
nOff++;
#endif
}
break;
case ScanlineFormat::N24BitTcBgr:
pReadScan = pBitmapReadAcc->GetScanline( nY );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff ];
else
nAlpha = data[ nOff ] = 255;
data[ nOff + 3 ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff + 2 ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff + 1 ] = premultiply_table[nAlpha][*pReadScan++];
nOff += 4;
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
nOff++;
#endif
}
break;
case ScanlineFormat::N24BitTcRgb:
pReadScan = pBitmapReadAcc->GetScanline( nY );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff++ ];
else
nAlpha = data[ nOff++ ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 2 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 1 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 0 ]];
pReadScan += 3;
nOff++;
#endif
}
break;
case ScanlineFormat::N32BitTcBgra:
pReadScan = pBitmapReadAcc->GetScanline( nY );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff++ ];
else
nAlpha = data[ nOff++ ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 2 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 1 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 0 ]];
pReadScan += 4;
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
pReadScan++;
nOff++;
#endif
}
break;
case ScanlineFormat::N32BitTcRgba:
pReadScan = pBitmapReadAcc->GetScanline( nY );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff ++ ];
else
nAlpha = data[ nOff ++ ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
data[ nOff++ ] = premultiply_table[nAlpha][*pReadScan++];
pReadScan++;
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 2 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 1 ]];
data[ nOff++ ] = premultiply_table[nAlpha][pReadScan[ 0 ]];
pReadScan += 4;
nOff++;
#endif
}
break;
default:
SAL_INFO( "canvas.cairo", "fallback to GetColor - slow, format: " << static_cast<int>(pBitmapReadAcc->GetScanlineFormat()) );
if( pAlphaReadAcc )
if( readAlpha( pAlphaReadAcc, nY, nWidth, data, nOff ) )
bIsAlpha = true;
for( nX = 0; nX < nWidth; nX++ )
{
aColor = pBitmapReadAcc->GetColor( nY, nX );
// cairo need premultiplied color values
// TODO(rodo) handle endianness
#ifdef OSL_BIGENDIAN
if( pAlphaReadAcc )
nAlpha = data[ nOff++ ];
else
nAlpha = data[ nOff++ ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetRed()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetGreen()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetBlue()];
#else
if( pAlphaReadAcc )
nAlpha = data[ nOff + 3 ];
else
nAlpha = data[ nOff + 3 ] = 255;
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetBlue()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetGreen()];
data[ nOff++ ] = premultiply_table[nAlpha][aColor.GetRed()];
nOff ++;
#endif
}
}
}
::Bitmap::ReleaseAccess( pBitmapReadAcc );
if( pAlphaReadAcc )
aAlpha.ReleaseAccess( pAlphaReadAcc );
bHasAlpha = bIsAlpha;
}
uno::Sequence< sal_Int8 > CanvasExtractBitmapData(BitmapEx const & rBitmapEx, const geometry::IntegerRectangle2D& rect)
{
Bitmap aBitmap( rBitmapEx.GetBitmap() );
Bitmap aAlpha( rBitmapEx.GetAlpha().GetBitmap() );
Bitmap::ScopedReadAccess pReadAccess( aBitmap );
Bitmap::ScopedReadAccess pAlphaReadAccess( aAlpha.IsEmpty() ?
nullptr : aAlpha.AcquireReadAccess(),
aAlpha );
assert( pReadAccess );
// TODO(F1): Support more formats.
const Size aBmpSize( aBitmap.GetSizePixel() );
// for the time being, always return as BGRA
uno::Sequence< sal_Int8 > aRes( 4*aBmpSize.Width()*aBmpSize.Height() );
sal_Int8* pRes = aRes.getArray();
int nCurrPos(0);
for( long y=rect.Y1;
y<aBmpSize.Height() && y<rect.Y2;
++y )
{
if( pAlphaReadAccess.get() != nullptr )
{
Scanline pScanlineReadAlpha = pAlphaReadAccess->GetScanline( y );
for( long x=rect.X1;
x<aBmpSize.Width() && x<rect.X2;
++x )
{
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetRed();
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetGreen();
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetBlue();
pRes[ nCurrPos++ ] = pAlphaReadAccess->GetIndexFromData( pScanlineReadAlpha, x );
}
}
else
{
for( long x=rect.X1;
x<aBmpSize.Width() && x<rect.X2;
++x )
{
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetRed();
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetGreen();
pRes[ nCurrPos++ ] = pReadAccess->GetColor( y, x ).GetBlue();
pRes[ nCurrPos++ ] = sal_uInt8(255);
}
}
}
return aRes;
}
BitmapEx createHistorical8x8FromArray(std::array<sal_uInt8,64> const & pArray, Color aColorPix, Color aColorBack)
{
BitmapPalette aPalette(2);
aPalette[0] = BitmapColor(aColorBack);
aPalette[1] = BitmapColor(aColorPix);
Bitmap aBitmap(Size(8, 8), 1, &aPalette);
BitmapWriteAccess* pContent(aBitmap.AcquireWriteAccess());
for(sal_uInt16 a(0); a < 8; a++)
{
for(sal_uInt16 b(0); b < 8; b++)
{
if(pArray[(a * 8) + b])
{
pContent->SetPixelIndex(a, b, 1);
}
else
{
pContent->SetPixelIndex(a, b, 0);
}
}
}
return BitmapEx(aBitmap);
}
bool isHistorical8x8(const BitmapEx& rBitmapEx, Color& o_rBack, Color& o_rFront)
{
bool bRet(false);
if(!rBitmapEx.IsTransparent())
{
Bitmap aBitmap(rBitmapEx.GetBitmap());
if(8 == aBitmap.GetSizePixel().Width() && 8 == aBitmap.GetSizePixel().Height())
{
if(2 == aBitmap.GetColorCount())
{
BitmapReadAccess* pRead = aBitmap.AcquireReadAccess();
if(pRead)
{
if(pRead->HasPalette() && 2 == pRead->GetPaletteEntryCount())
{
const BitmapPalette& rPalette = pRead->GetPalette();
// #i123564# background and foreground were exchanged; of course
// rPalette[0] is the background color
o_rFront = rPalette[1];
o_rBack = rPalette[0];
bRet = true;
}
Bitmap::ReleaseAccess(pRead);
}
}
}
}
return bRet;
}
sal_uInt8 unpremultiply(sal_uInt8 c, sal_uInt8 a)
{
return (a == 0) ? 0 : (c * 255 + a / 2) / a;
}
sal_uInt8 premultiply(sal_uInt8 c, sal_uInt8 a)
{
return (c * a + 127) / 255;
}
lookup_table get_unpremultiply_table()
{
static bool inited;
static sal_uInt8 unpremultiply_table[256][256];
if (!inited)
{
for (int a = 0; a < 256; ++a)
for (int c = 0; c < 256; ++c)
unpremultiply_table[a][c] = unpremultiply(c, a);
inited = true;
}
return unpremultiply_table;
}
lookup_table get_premultiply_table()
{
static bool inited;
static sal_uInt8 premultiply_table[256][256];
if (!inited)
{
for (int a = 0; a < 256; ++a)
for (int c = 0; c < 256; ++c)
premultiply_table[a][c] = premultiply(c, a);
inited = true;
}
return premultiply_table;
}
bool convertBitmap32To24Plus8(BitmapEx const & rInput, BitmapEx & rResult)
{
Bitmap aBitmap(rInput.GetBitmap());
if (aBitmap.GetBitCount() != 32)
return false;
Size aSize = aBitmap.GetSizePixel();
Bitmap aResultBitmap(aSize, 24);
AlphaMask aResultAlpha(aSize);
{
BitmapScopedWriteAccess pResultBitmapAccess(aResultBitmap);
AlphaScopedWriteAccess pResultAlphaAccess(aResultAlpha);
Bitmap::ScopedReadAccess pReadAccess(aBitmap);
for (long nY = 0; nY < aSize.Height(); ++nY)
{
Scanline aResultScan = pResultBitmapAccess->GetScanline(nY);
Scanline aResultScanAlpha = pResultAlphaAccess->GetScanline(nY);
Scanline aReadScan = pReadAccess->GetScanline(nY);
for (long nX = 0; nX < aSize.Width(); ++nX)
{
const BitmapColor aColor = pReadAccess->GetPixelFromData(aReadScan, nX);
BitmapColor aResultColor(aColor.GetRed(), aColor.GetGreen(), aColor.GetBlue());
BitmapColor aResultColorAlpha(aColor.GetAlpha(), aColor.GetAlpha(), aColor.GetAlpha());
pResultBitmapAccess->SetPixelOnData(aResultScan, nX, aResultColor);
pResultAlphaAccess->SetPixelOnData(aResultScanAlpha, nX, aResultColorAlpha);
}
}
}
if (rInput.IsTransparent())
rResult = BitmapEx(aResultBitmap, rInput.GetAlpha());
else
rResult = BitmapEx(aResultBitmap, aResultAlpha);
return true;
}
} // end vcl::bitmap
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