/* -*- 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/. * * This file incorporates work covered by the following license notice: * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed * with this work for additional information regarding copyright * ownership. The ASF licenses this file to you under the Apache * License, Version 2.0 (the "License"); you may not use this file * except in compliance with the License. You may obtain a copy of * the License at http://www.apache.org/licenses/LICENSE-2.0 . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if ENABLE_CAIRO_CANVAS # if defined CAIRO_VERSION && CAIRO_VERSION < CAIRO_VERSION_ENCODE(1, 10, 0) # define CAIRO_OPERATOR_DIFFERENCE (static_cast(23)) # endif #endif namespace { basegfx::B2DRange getClipBox(cairo_t* cr) { double x1, y1, x2, y2; cairo_clip_extents(cr, &x1, &y1, &x2, &y2); // support B2DRange::isEmpty() if(0.0 != x1 || 0.0 != y1 || 0.0 != x2 || 0.0 != y2) { return basegfx::B2DRange(x1, y1, x2, y2); } return basegfx::B2DRange(); } basegfx::B2DRange getFillDamage(cairo_t* cr) { double x1, y1, x2, y2; // this is faster than cairo_fill_extents, at the cost of some overdraw cairo_path_extents(cr, &x1, &y1, &x2, &y2); // support B2DRange::isEmpty() if(0.0 != x1 || 0.0 != y1 || 0.0 != x2 || 0.0 != y2) { return basegfx::B2DRange(x1, y1, x2, y2); } return basegfx::B2DRange(); } basegfx::B2DRange getClippedFillDamage(cairo_t* cr) { basegfx::B2DRange aDamageRect(getFillDamage(cr)); aDamageRect.intersect(getClipBox(cr)); return aDamageRect; } basegfx::B2DRange getStrokeDamage(cairo_t* cr) { double x1, y1, x2, y2; // less accurate, but much faster cairo_path_extents(cr, &x1, &y1, &x2, &y2); // support B2DRange::isEmpty() if(0.0 != x1 || 0.0 != y1 || 0.0 != x2 || 0.0 != y2) { return basegfx::B2DRange(x1, y1, x2, y2); } return basegfx::B2DRange(); } basegfx::B2DRange getClippedStrokeDamage(cairo_t* cr) { basegfx::B2DRange aDamageRect(getStrokeDamage(cr)); aDamageRect.intersect(getClipBox(cr)); return aDamageRect; } } bool SvpSalGraphics::blendBitmap( const SalTwoRect&, const SalBitmap& /*rBitmap*/ ) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::blendBitmap case"); return false; } bool SvpSalGraphics::blendAlphaBitmap( const SalTwoRect&, const SalBitmap&, const SalBitmap&, const SalBitmap& ) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::blendAlphaBitmap case"); return false; } namespace { cairo_format_t getCairoFormat(const BitmapBuffer& rBuffer) { cairo_format_t nFormat; #ifdef HAVE_CAIRO_FORMAT_RGB24_888 assert(rBuffer.mnBitCount == 32 || rBuffer.mnBitCount == 24 || rBuffer.mnBitCount == 1); #else assert(rBuffer.mnBitCount == 32 || rBuffer.mnBitCount == 1); #endif if (rBuffer.mnBitCount == 32) nFormat = CAIRO_FORMAT_ARGB32; #ifdef HAVE_CAIRO_FORMAT_RGB24_888 else if (rBuffer.mnBitCount == 24) nFormat = CAIRO_FORMAT_RGB24_888; #endif else nFormat = CAIRO_FORMAT_A1; return nFormat; } void Toggle1BitTransparency(const BitmapBuffer& rBuf) { assert(rBuf.maPalette.GetBestIndex(BitmapColor(COL_BLACK)) == 0); // TODO: make upper layers use standard alpha if (getCairoFormat(rBuf) == CAIRO_FORMAT_A1) { const int nImageSize = rBuf.mnHeight * rBuf.mnScanlineSize; unsigned char* pDst = rBuf.mpBits; for (int i = nImageSize; --i >= 0; ++pDst) *pDst = ~*pDst; } } std::unique_ptr FastConvert24BitRgbTo32BitCairo(const BitmapBuffer* pSrc) { if (pSrc == nullptr) return nullptr; assert(pSrc->mnFormat == SVP_24BIT_FORMAT); const long nWidth = pSrc->mnWidth; const long nHeight = pSrc->mnHeight; std::unique_ptr pDst(new BitmapBuffer); pDst->mnFormat = (ScanlineFormat::N32BitTcArgb | ScanlineFormat::TopDown); pDst->mnWidth = nWidth; pDst->mnHeight = nHeight; pDst->mnBitCount = 32; pDst->maColorMask = pSrc->maColorMask; pDst->maPalette = pSrc->maPalette; long nScanlineBase; const bool bFail = o3tl::checked_multiply(pDst->mnBitCount, nWidth, nScanlineBase); if (bFail) { SAL_WARN("vcl.gdi", "checked multiply failed"); pDst->mpBits = nullptr; return nullptr; } pDst->mnScanlineSize = AlignedWidth4Bytes(nScanlineBase); if (pDst->mnScanlineSize < nScanlineBase/8) { SAL_WARN("vcl.gdi", "scanline calculation wraparound"); pDst->mpBits = nullptr; return nullptr; } try { pDst->mpBits = new sal_uInt8[ pDst->mnScanlineSize * nHeight ]; } catch (const std::bad_alloc&) { // memory exception, clean up pDst->mpBits = nullptr; return nullptr; } for (long y = 0; y < nHeight; ++y) { sal_uInt8* pS = pSrc->mpBits + y * pSrc->mnScanlineSize; sal_uInt8* pD = pDst->mpBits + y * pDst->mnScanlineSize; for (long x = 0; x < nWidth; ++x) { #if defined(ANDROID) && !HAVE_FEATURE_ANDROID_LOK static_assert((SVP_CAIRO_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N32BitTcRgba, "Expected SVP_CAIRO_FORMAT set to N32BitTcBgra"); static_assert((SVP_24BIT_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N24BitTcRgb, "Expected SVP_24BIT_FORMAT set to N24BitTcRgb"); pD[0] = pS[0]; pD[1] = pS[1]; pD[2] = pS[2]; pD[3] = 0xff; // Alpha #elif defined OSL_BIGENDIAN static_assert((SVP_CAIRO_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N32BitTcArgb, "Expected SVP_CAIRO_FORMAT set to N32BitTcBgra"); static_assert((SVP_24BIT_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N24BitTcRgb, "Expected SVP_24BIT_FORMAT set to N24BitTcRgb"); pD[0] = 0xff; // Alpha pD[1] = pS[0]; pD[2] = pS[1]; pD[3] = pS[2]; #else static_assert((SVP_CAIRO_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N32BitTcBgra, "Expected SVP_CAIRO_FORMAT set to N32BitTcBgra"); static_assert((SVP_24BIT_FORMAT & ~ScanlineFormat::TopDown) == ScanlineFormat::N24BitTcBgr, "Expected SVP_24BIT_FORMAT set to N24BitTcBgr"); pD[0] = pS[0]; pD[1] = pS[1]; pD[2] = pS[2]; pD[3] = 0xff; // Alpha #endif pS += 3; pD += 4; } } return pDst; } // check for env var that decides for using downscale pattern static const char* pDisableDownScale(getenv("SAL_DISABLE_CAIRO_DOWNSCALE")); static bool bDisableDownScale(nullptr != pDisableDownScale); class SurfaceHelper { private: cairo_surface_t* pSurface; std::unordered_map maDownscaled; SurfaceHelper(const SurfaceHelper&) = delete; SurfaceHelper& operator=(const SurfaceHelper&) = delete; cairo_surface_t* implCreateOrReuseDownscale( unsigned long nTargetWidth, unsigned long nTargetHeight) { const unsigned long nSourceWidth(cairo_image_surface_get_width(pSurface)); const unsigned long nSourceHeight(cairo_image_surface_get_height(pSurface)); // zoomed in, need to stretch at paint, no pre-scale useful if(nTargetWidth >= nSourceWidth || nTargetHeight >= nSourceHeight) { return pSurface; } // calculate downscale factor unsigned long nWFactor(1); unsigned long nW((nSourceWidth + 1) / 2); unsigned long nHFactor(1); unsigned long nH((nSourceHeight + 1) / 2); while(nW > nTargetWidth && nW > 1) { nW = (nW + 1) / 2; nWFactor *= 2; } while(nH > nTargetHeight && nH > 1) { nH = (nH + 1) / 2; nHFactor *= 2; } if(1 == nWFactor && 1 == nHFactor) { // original size *is* best binary size, use it return pSurface; } // go up one scale again - look for no change nW = (1 == nWFactor) ? nTargetWidth : nW * 2; nH = (1 == nHFactor) ? nTargetHeight : nH * 2; // check if we have a downscaled version of required size const unsigned long long key((nW * LONG_MAX) + nH); auto isHit(maDownscaled.find(key)); if(isHit != maDownscaled.end()) { return isHit->second; } // create new surface in the targeted size cairo_surface_t* pSurfaceTarget = cairo_surface_create_similar( pSurface, cairo_surface_get_content(pSurface), nW, nH); // did a version to scale self first that worked well, but wouuld've // been hard to support CAIRO_FORMAT_A1 including bit shifting, so // I decided to go with cairo itself - use CAIRO_FILTER_FAST or // CAIRO_FILTER_GOOD though. Please modify as needed for // performance/quality cairo_t* cr = cairo_create(pSurfaceTarget); const double fScaleX(static_cast(nW)/static_cast(nSourceWidth)); const double fScaleY(static_cast(nH)/static_cast(nSourceHeight)); cairo_scale(cr, fScaleX, fScaleY); cairo_set_source_surface(cr, pSurface, 0.0, 0.0); cairo_pattern_set_filter(cairo_get_source(cr), CAIRO_FILTER_GOOD); cairo_paint(cr); cairo_destroy(cr); // need to set device_scale for downscale surfaces to get // them handled correctly cairo_surface_set_device_scale(pSurfaceTarget, fScaleX, fScaleY); // add entry to cached entries maDownscaled[key] = pSurfaceTarget; return pSurfaceTarget; } protected: cairo_surface_t* implGetSurface() const { return pSurface; } void implSetSurface(cairo_surface_t* pNew) { pSurface = pNew; } bool isTrivial() const { constexpr unsigned long nMinimalSquareSizeToBuffer(64*64); const unsigned long nSourceWidth(cairo_image_surface_get_width(pSurface)); const unsigned long nSourceHeight(cairo_image_surface_get_height(pSurface)); return nSourceWidth * nSourceHeight < nMinimalSquareSizeToBuffer; } public: explicit SurfaceHelper() : pSurface(nullptr), maDownscaled() { } ~SurfaceHelper() { cairo_surface_destroy(pSurface); for(auto& candidate : maDownscaled) { cairo_surface_destroy(candidate.second); } } cairo_surface_t* getSurface( unsigned long nTargetWidth = 0, unsigned long nTargetHeight = 0) const { if (bDisableDownScale || 0 == nTargetWidth || 0 == nTargetHeight || !pSurface || isTrivial()) { // caller asks for original or disabled or trivial (smaller then a minimal square size) // also excludes zero cases for width/height after this point if need to prescale return pSurface; } return const_cast(this)->implCreateOrReuseDownscale( nTargetWidth, nTargetHeight); } }; class BitmapHelper : public SurfaceHelper { private: #ifdef HAVE_CAIRO_FORMAT_RGB24_888 const bool m_bForceARGB32; #endif SvpSalBitmap aTmpBmp; public: explicit BitmapHelper( const SalBitmap& rSourceBitmap, const bool bForceARGB32 = false) : SurfaceHelper(), #ifdef HAVE_CAIRO_FORMAT_RGB24_888 m_bForceARGB32(bForceARGB32), #endif aTmpBmp() { const SvpSalBitmap& rSrcBmp = static_cast(rSourceBitmap); #ifdef HAVE_CAIRO_FORMAT_RGB24_888 if ((rSrcBmp.GetBitCount() != 32 && rSrcBmp.GetBitCount() != 24) || bForceARGB32) #else (void)bForceARGB32; if (rSrcBmp.GetBitCount() != 32) #endif { //big stupid copy here const BitmapBuffer* pSrc = rSrcBmp.GetBuffer(); const SalTwoRect aTwoRect = { 0, 0, pSrc->mnWidth, pSrc->mnHeight, 0, 0, pSrc->mnWidth, pSrc->mnHeight }; std::unique_ptr pTmp = (pSrc->mnFormat == SVP_24BIT_FORMAT ? FastConvert24BitRgbTo32BitCairo(pSrc) : StretchAndConvert(*pSrc, aTwoRect, SVP_CAIRO_FORMAT)); aTmpBmp.Create(std::move(pTmp)); assert(aTmpBmp.GetBitCount() == 32); implSetSurface(SvpSalGraphics::createCairoSurface(aTmpBmp.GetBuffer())); } else { implSetSurface(SvpSalGraphics::createCairoSurface(rSrcBmp.GetBuffer())); } } void mark_dirty() { cairo_surface_mark_dirty(implGetSurface()); } unsigned char* getBits(sal_Int32 &rStride) { cairo_surface_flush(implGetSurface()); unsigned char *mask_data = cairo_image_surface_get_data(implGetSurface()); const cairo_format_t nFormat = cairo_image_surface_get_format(implGetSurface()); #ifdef HAVE_CAIRO_FORMAT_RGB24_888 if (!m_bForceARGB32) assert(nFormat == CAIRO_FORMAT_RGB24_888 && "Expected RGB24_888 image"); else #endif assert(nFormat == CAIRO_FORMAT_ARGB32 && "need to implement CAIRO_FORMAT_A1 after all here"); rStride = cairo_format_stride_for_width(nFormat, cairo_image_surface_get_width(implGetSurface())); return mask_data; } }; sal_Int64 estimateUsageInBytesForSurfaceHelper(const SurfaceHelper* pHelper) { sal_Int64 nRetval(0); if(nullptr != pHelper) { cairo_surface_t* pSurface(pHelper->getSurface()); if(pSurface) { const long nStride(cairo_image_surface_get_stride(pSurface)); const long nHeight(cairo_image_surface_get_height(pSurface)); nRetval = nStride * nHeight; // if we do downscale, size will grow by 1/4 + 1/16 + 1/32 + ..., // rough estimation just multiplies by 1.25, should be good enough // for estimation of buffer survival time if(!bDisableDownScale) { nRetval = (nRetval * 5) / 4; } } } return nRetval; } class SystemDependentData_BitmapHelper : public basegfx::SystemDependentData { private: std::shared_ptr maBitmapHelper; public: SystemDependentData_BitmapHelper( basegfx::SystemDependentDataManager& rSystemDependentDataManager, const std::shared_ptr& rBitmapHelper) : basegfx::SystemDependentData(rSystemDependentDataManager), maBitmapHelper(rBitmapHelper) { } const std::shared_ptr& getBitmapHelper() const { return maBitmapHelper; }; virtual sal_Int64 estimateUsageInBytes() const override; }; sal_Int64 SystemDependentData_BitmapHelper::estimateUsageInBytes() const { return estimateUsageInBytesForSurfaceHelper(maBitmapHelper.get()); } class MaskHelper : public SurfaceHelper { private: std::unique_ptr pAlphaBits; public: explicit MaskHelper(const SalBitmap& rAlphaBitmap) : SurfaceHelper(), pAlphaBits() { const SvpSalBitmap& rMask = static_cast(rAlphaBitmap); const BitmapBuffer* pMaskBuf = rMask.GetBuffer(); if (rAlphaBitmap.GetBitCount() == 8) { // the alpha values need to be inverted for Cairo // so big stupid copy and invert here const int nImageSize = pMaskBuf->mnHeight * pMaskBuf->mnScanlineSize; pAlphaBits.reset( new unsigned char[nImageSize] ); memcpy(pAlphaBits.get(), pMaskBuf->mpBits, nImageSize); // TODO: make upper layers use standard alpha sal_uInt32* pLDst = reinterpret_cast(pAlphaBits.get()); for( int i = nImageSize/sizeof(sal_uInt32); --i >= 0; ++pLDst ) *pLDst = ~*pLDst; assert(reinterpret_cast(pLDst) == pAlphaBits.get()+nImageSize); implSetSurface( cairo_image_surface_create_for_data( pAlphaBits.get(), CAIRO_FORMAT_A8, pMaskBuf->mnWidth, pMaskBuf->mnHeight, pMaskBuf->mnScanlineSize)); } else { // the alpha values need to be inverted for Cairo // so big stupid copy and invert here const int nImageSize = pMaskBuf->mnHeight * pMaskBuf->mnScanlineSize; pAlphaBits.reset( new unsigned char[nImageSize] ); memcpy(pAlphaBits.get(), pMaskBuf->mpBits, nImageSize); const sal_Int32 nBlackIndex = pMaskBuf->maPalette.GetBestIndex(BitmapColor(COL_BLACK)); if (nBlackIndex == 0) { // TODO: make upper layers use standard alpha unsigned char* pDst = pAlphaBits.get(); for (int i = nImageSize; --i >= 0; ++pDst) *pDst = ~*pDst; } implSetSurface( cairo_image_surface_create_for_data( pAlphaBits.get(), CAIRO_FORMAT_A1, pMaskBuf->mnWidth, pMaskBuf->mnHeight, pMaskBuf->mnScanlineSize)); } } }; class SystemDependentData_MaskHelper : public basegfx::SystemDependentData { private: std::shared_ptr maMaskHelper; public: SystemDependentData_MaskHelper( basegfx::SystemDependentDataManager& rSystemDependentDataManager, const std::shared_ptr& rMaskHelper) : basegfx::SystemDependentData(rSystemDependentDataManager), maMaskHelper(rMaskHelper) { } const std::shared_ptr& getMaskHelper() const { return maMaskHelper; }; virtual sal_Int64 estimateUsageInBytes() const override; }; sal_Int64 SystemDependentData_MaskHelper::estimateUsageInBytes() const { return estimateUsageInBytesForSurfaceHelper(maMaskHelper.get()); } // MM02 decide to use buffers or not static const char* pDisableMM02Goodies(getenv("SAL_DISABLE_MM02_GOODIES")); static bool bUseBuffer(nullptr == pDisableMM02Goodies); static long nMinimalSquareSizeToBuffer(64*64); void tryToUseSourceBuffer( const SalBitmap& rSourceBitmap, std::shared_ptr& rSurface) { // MM02 try to access buffered BitmapHelper std::shared_ptr pSystemDependentData_BitmapHelper; const bool bBufferSource(bUseBuffer && rSourceBitmap.GetSize().Width() * rSourceBitmap.GetSize().Height() > nMinimalSquareSizeToBuffer); if(bBufferSource) { const SvpSalBitmap& rSrcBmp(static_cast(rSourceBitmap)); pSystemDependentData_BitmapHelper = rSrcBmp.getSystemDependentData(); if(pSystemDependentData_BitmapHelper) { // reuse buffered data rSurface = pSystemDependentData_BitmapHelper->getBitmapHelper(); } } if(!rSurface) { // create data on-demand rSurface = std::make_shared(rSourceBitmap); if(bBufferSource) { // add to buffering mechanism to potentially reuse next time const SvpSalBitmap& rSrcBmp(static_cast(rSourceBitmap)); rSrcBmp.addOrReplaceSystemDependentData( ImplGetSystemDependentDataManager(), rSurface); } } } void tryToUseMaskBuffer( const SalBitmap& rMaskBitmap, std::shared_ptr& rMask) { // MM02 try to access buffered MaskHelper std::shared_ptr pSystemDependentData_MaskHelper; const bool bBufferMask(bUseBuffer && rMaskBitmap.GetSize().Width() * rMaskBitmap.GetSize().Height() > nMinimalSquareSizeToBuffer); if(bBufferMask) { const SvpSalBitmap& rSrcBmp(static_cast(rMaskBitmap)); pSystemDependentData_MaskHelper = rSrcBmp.getSystemDependentData(); if(pSystemDependentData_MaskHelper) { // reuse buffered data rMask = pSystemDependentData_MaskHelper->getMaskHelper(); } } if(!rMask) { // create data on-demand rMask = std::make_shared(rMaskBitmap); if(bBufferMask) { // add to buffering mechanism to potentially reuse next time const SvpSalBitmap& rSrcBmp(static_cast(rMaskBitmap)); rSrcBmp.addOrReplaceSystemDependentData( ImplGetSystemDependentDataManager(), rMask); } } } } bool SvpSalGraphics::drawAlphaBitmap( const SalTwoRect& rTR, const SalBitmap& rSourceBitmap, const SalBitmap& rAlphaBitmap ) { if (rAlphaBitmap.GetBitCount() != 8 && rAlphaBitmap.GetBitCount() != 1) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawAlphaBitmap alpha depth case: " << rAlphaBitmap.GetBitCount()); return false; } // MM02 try to access buffered BitmapHelper std::shared_ptr aSurface; tryToUseSourceBuffer(rSourceBitmap, aSurface); cairo_surface_t* source = aSurface->getSurface( rTR.mnDestWidth, rTR.mnDestHeight); if (!source) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawAlphaBitmap case"); return false; } // MM02 try to access buffered MaskHelper std::shared_ptr aMask; tryToUseMaskBuffer(rAlphaBitmap, aMask); cairo_surface_t *mask = aMask->getSurface( rTR.mnDestWidth, rTR.mnDestHeight); if (!mask) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawAlphaBitmap case"); return false; } cairo_t* cr = getCairoContext(false); clipRegion(cr); cairo_rectangle(cr, rTR.mnDestX, rTR.mnDestY, rTR.mnDestWidth, rTR.mnDestHeight); basegfx::B2DRange extents = getClippedFillDamage(cr); cairo_clip(cr); cairo_pattern_t* maskpattern = cairo_pattern_create_for_surface(mask); cairo_translate(cr, rTR.mnDestX, rTR.mnDestY); double fXScale = static_cast(rTR.mnDestWidth)/rTR.mnSrcWidth; double fYScale = static_cast(rTR.mnDestHeight)/rTR.mnSrcHeight; cairo_scale(cr, fXScale, fYScale); cairo_set_source_surface(cr, source, -rTR.mnSrcX, -rTR.mnSrcY); //tdf#114117 when stretching a single pixel width/height source to fit an area //set extend and filter to stretch it with simplest expected interpolation if ((fXScale != 1.0 && rTR.mnSrcWidth == 1) || (fYScale != 1.0 && rTR.mnSrcHeight == 1)) { cairo_pattern_t* sourcepattern = cairo_get_source(cr); cairo_pattern_set_extend(sourcepattern, CAIRO_EXTEND_REPEAT); cairo_pattern_set_filter(sourcepattern, CAIRO_FILTER_NEAREST); cairo_pattern_set_extend(maskpattern, CAIRO_EXTEND_REPEAT); cairo_pattern_set_filter(maskpattern, CAIRO_FILTER_NEAREST); } //this block is just "cairo_mask_surface", but we have to make it explicit //because of the cairo_pattern_set_filter etc we may want applied cairo_matrix_t matrix; cairo_matrix_init_translate(&matrix, rTR.mnSrcX, rTR.mnSrcY); cairo_pattern_set_matrix(maskpattern, &matrix); cairo_mask(cr, maskpattern); cairo_pattern_destroy(maskpattern); releaseCairoContext(cr, false, extents); return true; } bool SvpSalGraphics::drawTransformedBitmap( const basegfx::B2DPoint& rNull, const basegfx::B2DPoint& rX, const basegfx::B2DPoint& rY, const SalBitmap& rSourceBitmap, const SalBitmap* pAlphaBitmap) { if (pAlphaBitmap && pAlphaBitmap->GetBitCount() != 8 && pAlphaBitmap->GetBitCount() != 1) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawTransformedBitmap alpha depth case: " << pAlphaBitmap->GetBitCount()); return false; } // MM02 try to access buffered BitmapHelper std::shared_ptr aSurface; tryToUseSourceBuffer(rSourceBitmap, aSurface); const long nDestWidth(basegfx::fround(basegfx::B2DVector(rX - rNull).getLength())); const long nDestHeight(basegfx::fround(basegfx::B2DVector(rY - rNull).getLength())); cairo_surface_t* source( aSurface->getSurface( nDestWidth, nDestHeight)); if(!source) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawTransformedBitmap case"); return false; } // MM02 try to access buffered MaskHelper std::shared_ptr aMask; if(nullptr != pAlphaBitmap) { tryToUseMaskBuffer(*pAlphaBitmap, aMask); } // access cairo_surface_t from MaskHelper cairo_surface_t* mask(nullptr); if(aMask) { mask = aMask->getSurface( nDestWidth, nDestHeight); } if(nullptr != pAlphaBitmap && nullptr == mask) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawTransformedBitmap case"); return false; } const Size aSize = rSourceBitmap.GetSize(); cairo_t* cr = getCairoContext(false); clipRegion(cr); // setup the image transformation // using the rNull,rX,rY points as destinations for the (0,0),(0,Width),(Height,0) source points const basegfx::B2DVector aXRel = rX - rNull; const basegfx::B2DVector aYRel = rY - rNull; cairo_matrix_t matrix; cairo_matrix_init(&matrix, aXRel.getX()/aSize.Width(), aXRel.getY()/aSize.Width(), aYRel.getX()/aSize.Height(), aYRel.getY()/aSize.Height(), rNull.getX(), rNull.getY()); cairo_transform(cr, &matrix); cairo_rectangle(cr, 0, 0, aSize.Width(), aSize.Height()); basegfx::B2DRange extents = getClippedFillDamage(cr); cairo_clip(cr); cairo_set_source_surface(cr, source, 0, 0); if (mask) cairo_mask_surface(cr, mask, 0, 0); else cairo_paint(cr); releaseCairoContext(cr, false, extents); return true; } void SvpSalGraphics::clipRegion(cairo_t* cr, const vcl::Region& rClipRegion) { RectangleVector aRectangles; if (!rClipRegion.IsEmpty()) { rClipRegion.GetRegionRectangles(aRectangles); } if (!aRectangles.empty()) { for (auto const& rectangle : aRectangles) { cairo_rectangle(cr, rectangle.Left(), rectangle.Top(), rectangle.GetWidth(), rectangle.GetHeight()); } cairo_clip(cr); } } void SvpSalGraphics::clipRegion(cairo_t* cr) { SvpSalGraphics::clipRegion(cr, m_aClipRegion); } bool SvpSalGraphics::drawAlphaRect(long nX, long nY, long nWidth, long nHeight, sal_uInt8 nTransparency) { const bool bHasFill(m_aFillColor != SALCOLOR_NONE); const bool bHasLine(m_aLineColor != SALCOLOR_NONE); if(!(bHasFill || bHasLine)) { return true; } cairo_t* cr = getCairoContext(false); clipRegion(cr); const double fTransparency = nTransparency * (1.0/100); // To make releaseCairoContext work, use empty extents basegfx::B2DRange extents; if (bHasFill) { cairo_rectangle(cr, nX, nY, nWidth, nHeight); applyColor(cr, m_aFillColor, fTransparency); // set FillDamage extents = getClippedFillDamage(cr); cairo_fill(cr); } if (bHasLine) { // PixelOffset used: Set PixelOffset as linear transformation // Note: Was missing here - probably not by purpose (?) cairo_matrix_t aMatrix; cairo_matrix_init_translate(&aMatrix, 0.5, 0.5); cairo_set_matrix(cr, &aMatrix); cairo_rectangle(cr, nX, nY, nWidth, nHeight); applyColor(cr, m_aLineColor, fTransparency); // expand with possible StrokeDamage basegfx::B2DRange stroke_extents = getClippedStrokeDamage(cr); stroke_extents.transform(basegfx::utils::createTranslateB2DHomMatrix(0.5, 0.5)); extents.expand(stroke_extents); cairo_stroke(cr); } releaseCairoContext(cr, false, extents); return true; } SvpSalGraphics::SvpSalGraphics() : m_pSurface(nullptr) , m_fScale(1.0) , m_aLineColor(Color(0x00, 0x00, 0x00)) , m_aFillColor(Color(0xFF, 0xFF, 0XFF)) , m_ePaintMode(PaintMode::Over) , m_aTextRenderImpl(*this) { bool bLOKActive = comphelper::LibreOfficeKit::isActive(); if (!initWidgetDrawBackends(bLOKActive)) { if (bLOKActive) m_pWidgetDraw.reset(new vcl::CustomWidgetDraw(*this)); } } SvpSalGraphics::~SvpSalGraphics() { ReleaseFonts(); } void SvpSalGraphics::setSurface(cairo_surface_t* pSurface, const basegfx::B2IVector& rSize) { m_pSurface = pSurface; m_aFrameSize = rSize; dl_cairo_surface_get_device_scale(pSurface, &m_fScale, nullptr); ResetClipRegion(); } void SvpSalGraphics::GetResolution( sal_Int32& rDPIX, sal_Int32& rDPIY ) { rDPIX = rDPIY = 96; } sal_uInt16 SvpSalGraphics::GetBitCount() const { if (cairo_surface_get_content(m_pSurface) != CAIRO_CONTENT_COLOR_ALPHA) return 1; return 32; } long SvpSalGraphics::GetGraphicsWidth() const { return m_pSurface ? m_aFrameSize.getX() : 0; } void SvpSalGraphics::ResetClipRegion() { m_aClipRegion.SetNull(); } bool SvpSalGraphics::setClipRegion( const vcl::Region& i_rClip ) { m_aClipRegion = i_rClip; return true; } void SvpSalGraphics::SetLineColor() { m_aLineColor = SALCOLOR_NONE; } void SvpSalGraphics::SetLineColor( Color nColor ) { m_aLineColor = nColor; } void SvpSalGraphics::SetFillColor() { m_aFillColor = SALCOLOR_NONE; } void SvpSalGraphics::SetFillColor( Color nColor ) { m_aFillColor = nColor; } void SvpSalGraphics::SetXORMode(bool bSet, bool ) { m_ePaintMode = bSet ? PaintMode::Xor : PaintMode::Over; } void SvpSalGraphics::SetROPLineColor( SalROPColor nROPColor ) { switch( nROPColor ) { case SalROPColor::N0: m_aLineColor = Color(0, 0, 0); break; case SalROPColor::N1: m_aLineColor = Color(0xff, 0xff, 0xff); break; case SalROPColor::Invert: m_aLineColor = Color(0xff, 0xff, 0xff); break; } } void SvpSalGraphics::SetROPFillColor( SalROPColor nROPColor ) { switch( nROPColor ) { case SalROPColor::N0: m_aFillColor = Color(0, 0, 0); break; case SalROPColor::N1: m_aFillColor = Color(0xff, 0xff, 0xff); break; case SalROPColor::Invert: m_aFillColor = Color(0xff, 0xff, 0xff); break; } } void SvpSalGraphics::drawPixel( long nX, long nY ) { if (m_aLineColor != SALCOLOR_NONE) { drawPixel(nX, nY, m_aLineColor); } } void SvpSalGraphics::drawPixel( long nX, long nY, Color aColor ) { cairo_t* cr = getCairoContext(true); clipRegion(cr); cairo_rectangle(cr, nX, nY, 1, 1); applyColor(cr, aColor, 0.0); cairo_fill(cr); basegfx::B2DRange extents = getClippedFillDamage(cr); releaseCairoContext(cr, true, extents); } void SvpSalGraphics::drawRect( long nX, long nY, long nWidth, long nHeight ) { // because of the -1 hack we have to do fill and draw separately Color aOrigFillColor = m_aFillColor; Color aOrigLineColor = m_aLineColor; m_aFillColor = SALCOLOR_NONE; m_aLineColor = SALCOLOR_NONE; if (aOrigFillColor != SALCOLOR_NONE) { basegfx::B2DPolygon aRect = basegfx::utils::createPolygonFromRect(basegfx::B2DRectangle(nX, nY, nX+nWidth, nY+nHeight)); m_aFillColor = aOrigFillColor; drawPolyPolygon( basegfx::B2DHomMatrix(), basegfx::B2DPolyPolygon(aRect), 0.0); m_aFillColor = SALCOLOR_NONE; } if (aOrigLineColor != SALCOLOR_NONE) { // need same -1 hack as X11SalGraphicsImpl::drawRect basegfx::B2DPolygon aRect = basegfx::utils::createPolygonFromRect(basegfx::B2DRectangle( nX, nY, nX+nWidth-1, nY+nHeight-1)); m_aLineColor = aOrigLineColor; drawPolyPolygon( basegfx::B2DHomMatrix(), basegfx::B2DPolyPolygon(aRect), 0.0); m_aLineColor = SALCOLOR_NONE; } m_aFillColor = aOrigFillColor; m_aLineColor = aOrigLineColor; } void SvpSalGraphics::drawPolyLine(sal_uInt32 nPoints, const SalPoint* pPtAry) { basegfx::B2DPolygon aPoly; aPoly.append(basegfx::B2DPoint(pPtAry->mnX, pPtAry->mnY), nPoints); for (sal_uInt32 i = 1; i < nPoints; ++i) aPoly.setB2DPoint(i, basegfx::B2DPoint(pPtAry[i].mnX, pPtAry[i].mnY)); aPoly.setClosed(false); drawPolyLine( basegfx::B2DHomMatrix(), aPoly, 0.0, 1.0, nullptr, // MM01 basegfx::B2DLineJoin::Miter, css::drawing::LineCap_BUTT, basegfx::deg2rad(15.0) /*default*/, false); } void SvpSalGraphics::drawPolygon(sal_uInt32 nPoints, const SalPoint* pPtAry) { basegfx::B2DPolygon aPoly; aPoly.append(basegfx::B2DPoint(pPtAry->mnX, pPtAry->mnY), nPoints); for (sal_uInt32 i = 1; i < nPoints; ++i) aPoly.setB2DPoint(i, basegfx::B2DPoint(pPtAry[i].mnX, pPtAry[i].mnY)); drawPolyPolygon( basegfx::B2DHomMatrix(), basegfx::B2DPolyPolygon(aPoly), 0.0); } void SvpSalGraphics::drawPolyPolygon(sal_uInt32 nPoly, const sal_uInt32* pPointCounts, PCONSTSALPOINT* pPtAry) { basegfx::B2DPolyPolygon aPolyPoly; for(sal_uInt32 nPolygon = 0; nPolygon < nPoly; ++nPolygon) { sal_uInt32 nPoints = pPointCounts[nPolygon]; if (nPoints) { PCONSTSALPOINT pPoints = pPtAry[nPolygon]; basegfx::B2DPolygon aPoly; aPoly.append( basegfx::B2DPoint(pPoints->mnX, pPoints->mnY), nPoints); for (sal_uInt32 i = 1; i < nPoints; ++i) aPoly.setB2DPoint(i, basegfx::B2DPoint( pPoints[i].mnX, pPoints[i].mnY)); aPolyPoly.append(aPoly); } } drawPolyPolygon( basegfx::B2DHomMatrix(), aPolyPoly, 0.0); } static basegfx::B2DPoint impPixelSnap( const basegfx::B2DPolygon& rPolygon, const basegfx::B2DHomMatrix& rObjectToDevice, basegfx::B2DHomMatrix& rObjectToDeviceInv, sal_uInt32 nIndex) { const sal_uInt32 nCount(rPolygon.count()); // get the data const basegfx::B2ITuple aPrevTuple(basegfx::fround(rObjectToDevice * rPolygon.getB2DPoint((nIndex + nCount - 1) % nCount))); const basegfx::B2DPoint aCurrPoint(rObjectToDevice * rPolygon.getB2DPoint(nIndex)); const basegfx::B2ITuple aCurrTuple(basegfx::fround(aCurrPoint)); const basegfx::B2ITuple aNextTuple(basegfx::fround(rObjectToDevice * rPolygon.getB2DPoint((nIndex + 1) % nCount))); // get the states const bool bPrevVertical(aPrevTuple.getX() == aCurrTuple.getX()); const bool bNextVertical(aNextTuple.getX() == aCurrTuple.getX()); const bool bPrevHorizontal(aPrevTuple.getY() == aCurrTuple.getY()); const bool bNextHorizontal(aNextTuple.getY() == aCurrTuple.getY()); const bool bSnapX(bPrevVertical || bNextVertical); const bool bSnapY(bPrevHorizontal || bNextHorizontal); if(bSnapX || bSnapY) { basegfx::B2DPoint aSnappedPoint( bSnapX ? aCurrTuple.getX() : aCurrPoint.getX(), bSnapY ? aCurrTuple.getY() : aCurrPoint.getY()); if(rObjectToDeviceInv.isIdentity()) { rObjectToDeviceInv = rObjectToDevice; rObjectToDeviceInv.invert(); } aSnappedPoint *= rObjectToDeviceInv; return aSnappedPoint; } return rPolygon.getB2DPoint(nIndex); } // Remove bClosePath: Checked that the already used mechanism for Win using // Gdiplus already relies on rPolygon.isClosed(), so should be safe to replace // this. // For PixelSnap we need the ObjectToDevice transformation here now. This is a // special case relative to the also executed LineDraw-Offset of (0.5, 0.5) in // DeviceCoordinates: The LineDraw-Offset is applied *after* the snap, so we // need the ObjectToDevice transformation *without* that offset here to do the // same. The LineDraw-Offset will be applied by the callers using a linear // transformation for Cairo now // For support of PixelSnapHairline we also need the ObjectToDevice transformation // and a method (same as in gdiimpl.cxx for Win and Gdiplus). This is needed e.g. // for Chart-content visualization. CAUTION: It's not the same as PixelSnap (!) // tdf#129845 add reply value to allow counting a point/byte/size measurement to // be included static size_t AddPolygonToPath( cairo_t* cr, const basegfx::B2DPolygon& rPolygon, const basegfx::B2DHomMatrix& rObjectToDevice, bool bPixelSnap, bool bPixelSnapHairline) { // short circuit if there is nothing to do const sal_uInt32 nPointCount(rPolygon.count()); size_t nSizeMeasure(0); if(0 == nPointCount) { return nSizeMeasure; } const bool bHasCurves(rPolygon.areControlPointsUsed()); const bool bClosePath(rPolygon.isClosed()); const bool bObjectToDeviceUsed(!rObjectToDevice.isIdentity()); basegfx::B2DHomMatrix aObjectToDeviceInv; basegfx::B2DPoint aLast; for( sal_uInt32 nPointIdx = 0, nPrevIdx = 0;; nPrevIdx = nPointIdx++ ) { int nClosedIdx = nPointIdx; if( nPointIdx >= nPointCount ) { // prepare to close last curve segment if needed if( bClosePath && (nPointIdx == nPointCount) ) { nClosedIdx = 0; } else { break; } } basegfx::B2DPoint aPoint(rPolygon.getB2DPoint(nClosedIdx)); if(bPixelSnap) { // snap device coordinates to full pixels if(bObjectToDeviceUsed) { // go to DeviceCoordinates aPoint *= rObjectToDevice; } // snap by rounding aPoint.setX( basegfx::fround( aPoint.getX() ) ); aPoint.setY( basegfx::fround( aPoint.getY() ) ); if(bObjectToDeviceUsed) { if(aObjectToDeviceInv.isIdentity()) { aObjectToDeviceInv = rObjectToDevice; aObjectToDeviceInv.invert(); } // go back to ObjectCoordinates aPoint *= aObjectToDeviceInv; } } if(bPixelSnapHairline) { // snap horizontal and vertical lines (mainly used in Chart for // 'nicer' AAing) aPoint = impPixelSnap(rPolygon, rObjectToDevice, aObjectToDeviceInv, nClosedIdx); } if( !nPointIdx ) { // first point => just move there cairo_move_to(cr, aPoint.getX(), aPoint.getY()); aLast = aPoint; continue; } bool bPendingCurve(false); if( bHasCurves ) { bPendingCurve = rPolygon.isNextControlPointUsed( nPrevIdx ); bPendingCurve |= rPolygon.isPrevControlPointUsed( nClosedIdx ); } if( !bPendingCurve ) // line segment { cairo_line_to(cr, aPoint.getX(), aPoint.getY()); nSizeMeasure++; } else // cubic bezier segment { basegfx::B2DPoint aCP1 = rPolygon.getNextControlPoint( nPrevIdx ); basegfx::B2DPoint aCP2 = rPolygon.getPrevControlPoint( nClosedIdx ); // tdf#99165 if the control points are 'empty', create the mathematical // correct replacement ones to avoid problems with the graphical sub-system // tdf#101026 The 1st attempt to create a mathematically correct replacement control // vector was wrong. Best alternative is one as close as possible which means short. if (aCP1.equal(aLast)) { aCP1 = aLast + ((aCP2 - aLast) * 0.0005); } if(aCP2.equal(aPoint)) { aCP2 = aPoint + ((aCP1 - aPoint) * 0.0005); } cairo_curve_to(cr, aCP1.getX(), aCP1.getY(), aCP2.getX(), aCP2.getY(), aPoint.getX(), aPoint.getY()); // take some bigger measure for curve segments - too expensive to subdivide // here and that precision not needed, but four (2 points, 2 control-points) // would be a too low weight nSizeMeasure += 10; } aLast = aPoint; } if( bClosePath ) { cairo_close_path(cr); } return nSizeMeasure; } void SvpSalGraphics::drawLine( long nX1, long nY1, long nX2, long nY2 ) { basegfx::B2DPolygon aPoly; // PixelOffset used: To not mix with possible PixelSnap, cannot do // directly on coordinates as tried before - despite being already 'snapped' // due to being integer. If it would be directly added here, it would be // 'snapped' again when !getAntiAliasB2DDraw(), losing the (0.5, 0.5) offset aPoly.append(basegfx::B2DPoint(nX1, nY1)); aPoly.append(basegfx::B2DPoint(nX2, nY2)); cairo_t* cr = getCairoContext(false); clipRegion(cr); // PixelOffset used: Set PixelOffset as linear transformation cairo_matrix_t aMatrix; cairo_matrix_init_translate(&aMatrix, 0.5, 0.5); cairo_set_matrix(cr, &aMatrix); AddPolygonToPath( cr, aPoly, basegfx::B2DHomMatrix(), !getAntiAliasB2DDraw(), false); applyColor(cr, m_aLineColor); basegfx::B2DRange extents = getClippedStrokeDamage(cr); extents.transform(basegfx::utils::createTranslateB2DHomMatrix(0.5, 0.5)); cairo_stroke(cr); releaseCairoContext(cr, false, extents); } namespace { class SystemDependentData_CairoPath : public basegfx::SystemDependentData { private: // the path data itself cairo_path_t* mpCairoPath; // all other values the path data is based on and // need to be compared with to check for data validity bool mbNoJoin; bool mbAntiAliasB2DDraw; std::vector< double > maStroke; public: SystemDependentData_CairoPath( basegfx::SystemDependentDataManager& rSystemDependentDataManager, size_t nSizeMeasure, cairo_t* cr, bool bNoJoin, bool bAntiAliasB2DDraw, const std::vector< double >* pStroke); // MM01 virtual ~SystemDependentData_CairoPath() override; // read access cairo_path_t* getCairoPath() { return mpCairoPath; } bool getNoJoin() const { return mbNoJoin; } bool getAntiAliasB2DDraw() const { return mbAntiAliasB2DDraw; } const std::vector< double >& getStroke() const { return maStroke; } virtual sal_Int64 estimateUsageInBytes() const override; }; } SystemDependentData_CairoPath::SystemDependentData_CairoPath( basegfx::SystemDependentDataManager& rSystemDependentDataManager, size_t nSizeMeasure, cairo_t* cr, bool bNoJoin, bool bAntiAliasB2DDraw, const std::vector< double >* pStroke) : basegfx::SystemDependentData(rSystemDependentDataManager), mpCairoPath(nullptr), mbNoJoin(bNoJoin), mbAntiAliasB2DDraw(bAntiAliasB2DDraw), maStroke() { // tdf#129845 only create a copy of the path when nSizeMeasure is // bigger than some decent threshold if(nSizeMeasure > 50) { mpCairoPath = cairo_copy_path(cr); if(nullptr != pStroke) { maStroke = *pStroke; } } } SystemDependentData_CairoPath::~SystemDependentData_CairoPath() { if(nullptr != mpCairoPath) { cairo_path_destroy(mpCairoPath); mpCairoPath = nullptr; } } sal_Int64 SystemDependentData_CairoPath::estimateUsageInBytes() const { // tdf#129845 by using the default return value of zero when no path // was created, SystemDependentData::calculateCombinedHoldCyclesInSeconds // will do the right thing and not buffer this entry at all sal_Int64 nRetval(0); if(nullptr != mpCairoPath) { // per node // - num_data incarnations of // - sizeof(cairo_path_data_t) which is a union of defines and point data // thus may 2 x sizeof(double) nRetval = mpCairoPath->num_data * sizeof(cairo_path_data_t); } return nRetval; } bool SvpSalGraphics::drawPolyLine( const basegfx::B2DHomMatrix& rObjectToDevice, const basegfx::B2DPolygon& rPolyLine, double fTransparency, double fLineWidth, const std::vector< double >* pStroke, // MM01 basegfx::B2DLineJoin eLineJoin, css::drawing::LineCap eLineCap, double fMiterMinimumAngle, bool bPixelSnapHairline) { // short circuit if there is nothing to do if(0 == rPolyLine.count() || fTransparency < 0.0 || fTransparency >= 1.0) { return true; } // Wrap call to static version of ::drawPolyLine by // preparing/getting some local data and parameters // due to usage in vcl/unx/generic/gdi/salgdi.cxx. // This is mainly about extended handling of extents // and the way destruction of CairoContext is handled // due to current XOR stuff cairo_t* cr = getCairoContext(false); basegfx::B2DRange aExtents; clipRegion(cr); bool bRetval( drawPolyLine( cr, &aExtents, m_aLineColor, getAntiAliasB2DDraw(), rObjectToDevice, rPolyLine, fTransparency, fLineWidth, pStroke, // MM01 eLineJoin, eLineCap, fMiterMinimumAngle, bPixelSnapHairline)); releaseCairoContext(cr, false, aExtents); return bRetval; } bool SvpSalGraphics::drawPolyLine( cairo_t* cr, basegfx::B2DRange* pExtents, const Color& rLineColor, bool bAntiAliasB2DDraw, const basegfx::B2DHomMatrix& rObjectToDevice, const basegfx::B2DPolygon& rPolyLine, double fTransparency, double fLineWidth, const std::vector< double >* pStroke, // MM01 basegfx::B2DLineJoin eLineJoin, css::drawing::LineCap eLineCap, double fMiterMinimumAngle, bool bPixelSnapHairline) { // short circuit if there is nothing to do if(0 == rPolyLine.count() || fTransparency < 0.0 || fTransparency >= 1.0) { return true; } // need to check/handle LineWidth when ObjectToDevice transformation is used const bool bObjectToDeviceIsIdentity(rObjectToDevice.isIdentity()); // tdf#124848 calculate-back logical LineWidth for a hairline // since this implementation hands over the transformation to // the graphic sub-system if(fLineWidth == 0) { fLineWidth = 1.0; if(!bObjectToDeviceIsIdentity) { basegfx::B2DHomMatrix aObjectToDeviceInv(rObjectToDevice); aObjectToDeviceInv.invert(); fLineWidth = (aObjectToDeviceInv * basegfx::B2DVector(fLineWidth, 0)).getLength(); } } // PixelOffset used: Need to reflect in linear transformation cairo_matrix_t aMatrix; basegfx::B2DHomMatrix aDamageMatrix(basegfx::utils::createTranslateB2DHomMatrix(0.5, 0.5)); if (bObjectToDeviceIsIdentity) { // Set PixelOffset as requested cairo_matrix_init_translate(&aMatrix, 0.5, 0.5); } else { // Prepare ObjectToDevice transformation. Take PixelOffset for Lines into // account: Multiply from left to act in DeviceCoordinates aDamageMatrix = aDamageMatrix * rObjectToDevice; cairo_matrix_init( &aMatrix, aDamageMatrix.get( 0, 0 ), aDamageMatrix.get( 1, 0 ), aDamageMatrix.get( 0, 1 ), aDamageMatrix.get( 1, 1 ), aDamageMatrix.get( 0, 2 ), aDamageMatrix.get( 1, 2 )); } // set linear transformation cairo_set_matrix(cr, &aMatrix); // setup line attributes cairo_line_join_t eCairoLineJoin = CAIRO_LINE_JOIN_MITER; switch (eLineJoin) { case basegfx::B2DLineJoin::Bevel: eCairoLineJoin = CAIRO_LINE_JOIN_BEVEL; break; case basegfx::B2DLineJoin::Round: eCairoLineJoin = CAIRO_LINE_JOIN_ROUND; break; case basegfx::B2DLineJoin::NONE: case basegfx::B2DLineJoin::Miter: eCairoLineJoin = CAIRO_LINE_JOIN_MITER; break; } // convert miter minimum angle to miter limit double fMiterLimit = 1.0 / sin( fMiterMinimumAngle / 2.0); // setup cap attribute cairo_line_cap_t eCairoLineCap(CAIRO_LINE_CAP_BUTT); switch (eLineCap) { default: // css::drawing::LineCap_BUTT: { eCairoLineCap = CAIRO_LINE_CAP_BUTT; break; } case css::drawing::LineCap_ROUND: { eCairoLineCap = CAIRO_LINE_CAP_ROUND; break; } case css::drawing::LineCap_SQUARE: { eCairoLineCap = CAIRO_LINE_CAP_SQUARE; break; } } cairo_set_source_rgba( cr, rLineColor.GetRed()/255.0, rLineColor.GetGreen()/255.0, rLineColor.GetBlue()/255.0, 1.0-fTransparency); cairo_set_line_join(cr, eCairoLineJoin); cairo_set_line_cap(cr, eCairoLineCap); cairo_set_line_width(cr, fLineWidth); cairo_set_miter_limit(cr, fMiterLimit); // try to access buffered data std::shared_ptr pSystemDependentData_CairoPath( rPolyLine.getSystemDependentData()); // MM01 need to do line dashing as fallback stuff here now const double fDotDashLength(nullptr != pStroke ? std::accumulate(pStroke->begin(), pStroke->end(), 0.0) : 0.0); const bool bStrokeUsed(0.0 != fDotDashLength); assert(!bStrokeUsed || (bStrokeUsed && pStroke)); // MM01 decide if to stroke directly static bool bDoDirectCairoStroke(true); // MM01 activate to stroke directly if(bDoDirectCairoStroke && bStrokeUsed) { cairo_set_dash(cr, pStroke->data(), pStroke->size(), 0.0); } if(!bDoDirectCairoStroke && pSystemDependentData_CairoPath) { // MM01 - check on stroke change. Used against not used, or if both used, // equal or different? const bool bStrokeWasUsed(!pSystemDependentData_CairoPath->getStroke().empty()); if(bStrokeWasUsed != bStrokeUsed || (bStrokeUsed && *pStroke != pSystemDependentData_CairoPath->getStroke())) { // data invalid, forget pSystemDependentData_CairoPath.reset(); } } // check for basegfx::B2DLineJoin::NONE to react accordingly const bool bNoJoin((basegfx::B2DLineJoin::NONE == eLineJoin && basegfx::fTools::more(fLineWidth, 0.0))); if(pSystemDependentData_CairoPath) { // check data validity if(nullptr == pSystemDependentData_CairoPath->getCairoPath() || pSystemDependentData_CairoPath->getNoJoin() != bNoJoin || pSystemDependentData_CairoPath->getAntiAliasB2DDraw() != bAntiAliasB2DDraw || bPixelSnapHairline /*tdf#124700*/ ) { // data invalid, forget pSystemDependentData_CairoPath.reset(); } } if(pSystemDependentData_CairoPath) { // re-use data cairo_append_path(cr, pSystemDependentData_CairoPath->getCairoPath()); } else { // create data size_t nSizeMeasure(0); // MM01 need to do line dashing as fallback stuff here now basegfx::B2DPolyPolygon aPolyPolygonLine; if(!bDoDirectCairoStroke && bStrokeUsed) { // apply LineStyle basegfx::utils::applyLineDashing( rPolyLine, // source *pStroke, // pattern &aPolyPolygonLine, // target for lines nullptr, // target for gaps fDotDashLength); // full length if available } else { // no line dashing or direct stroke, just copy aPolyPolygonLine.append(rPolyLine); } // MM01 checked/verified for Cairo for(sal_uInt32 a(0); a < aPolyPolygonLine.count(); a++) { const basegfx::B2DPolygon aPolyLine(aPolyPolygonLine.getB2DPolygon(a)); if (!bNoJoin) { // PixelOffset now reflected in linear transformation used nSizeMeasure += AddPolygonToPath( cr, aPolyLine, rObjectToDevice, // ObjectToDevice *without* LineDraw-Offset !bAntiAliasB2DDraw, bPixelSnapHairline); } else { const sal_uInt32 nPointCount(aPolyLine.count()); const sal_uInt32 nEdgeCount(aPolyLine.isClosed() ? nPointCount : nPointCount - 1); basegfx::B2DPolygon aEdge; aEdge.append(aPolyLine.getB2DPoint(0)); aEdge.append(basegfx::B2DPoint(0.0, 0.0)); for (sal_uInt32 i(0); i < nEdgeCount; i++) { const sal_uInt32 nNextIndex((i + 1) % nPointCount); aEdge.setB2DPoint(1, aPolyLine.getB2DPoint(nNextIndex)); aEdge.setNextControlPoint(0, aPolyLine.getNextControlPoint(i)); aEdge.setPrevControlPoint(1, aPolyLine.getPrevControlPoint(nNextIndex)); // PixelOffset now reflected in linear transformation used nSizeMeasure += AddPolygonToPath( cr, aEdge, rObjectToDevice, // ObjectToDevice *without* LineDraw-Offset !bAntiAliasB2DDraw, bPixelSnapHairline); // prepare next step aEdge.setB2DPoint(0, aEdge.getB2DPoint(1)); } } } // copy and add to buffering mechanism if (!bPixelSnapHairline /*tdf#124700*/) { pSystemDependentData_CairoPath = rPolyLine.addOrReplaceSystemDependentData( ImplGetSystemDependentDataManager(), nSizeMeasure, cr, bNoJoin, bAntiAliasB2DDraw, pStroke); } } // extract extents if (pExtents) { *pExtents = getClippedStrokeDamage(cr); // transform also extents (ranges) of damage so they can be correctly redrawn pExtents->transform(aDamageMatrix); } // draw and consume cairo_stroke(cr); return true; } bool SvpSalGraphics::drawPolyLineBezier( sal_uInt32, const SalPoint*, const PolyFlags* ) { SAL_INFO("vcl.gdi", "unsupported SvpSalGraphics::drawPolyLineBezier case"); return false; } bool SvpSalGraphics::drawPolygonBezier( sal_uInt32, const SalPoint*, const PolyFlags* ) { SAL_INFO("vcl.gdi", "unsupported SvpSalGraphics::drawPolygonBezier case"); return false; } bool SvpSalGraphics::drawPolyPolygonBezier( sal_uInt32, const sal_uInt32*, const SalPoint* const*, const PolyFlags* const* ) { SAL_INFO("vcl.gdi", "unsupported SvpSalGraphics::drawPolyPolygonBezier case"); return false; } namespace { void add_polygon_path(cairo_t* cr, const basegfx::B2DPolyPolygon& rPolyPolygon, const basegfx::B2DHomMatrix& rObjectToDevice, bool bPixelSnap) { // try to access buffered data std::shared_ptr pSystemDependentData_CairoPath( rPolyPolygon.getSystemDependentData()); if(pSystemDependentData_CairoPath) { // re-use data cairo_append_path(cr, pSystemDependentData_CairoPath->getCairoPath()); } else { // create data size_t nSizeMeasure(0); for (const auto & rPoly : rPolyPolygon) { // PixelOffset used: Was dependent of 'm_aLineColor != SALCOLOR_NONE' // Adapt setupPolyPolygon-users to set a linear transformation to achieve PixelOffset nSizeMeasure += AddPolygonToPath( cr, rPoly, rObjectToDevice, bPixelSnap, false); } // copy and add to buffering mechanism // for decisions how/what to buffer, see Note in WinSalGraphicsImpl::drawPolyPolygon pSystemDependentData_CairoPath = rPolyPolygon.addOrReplaceSystemDependentData( ImplGetSystemDependentDataManager(), nSizeMeasure, cr, false, false, nullptr); } } } bool SvpSalGraphics::drawPolyPolygon( const basegfx::B2DHomMatrix& rObjectToDevice, const basegfx::B2DPolyPolygon& rPolyPolygon, double fTransparency) { const bool bHasFill(m_aFillColor != SALCOLOR_NONE); const bool bHasLine(m_aLineColor != SALCOLOR_NONE); if(0 == rPolyPolygon.count() || !(bHasFill || bHasLine) || fTransparency < 0.0 || fTransparency >= 1.0) { return true; } cairo_t* cr = getCairoContext(true); clipRegion(cr); // Set full (Object-to-Device) transformation - if used if(!rObjectToDevice.isIdentity()) { cairo_matrix_t aMatrix; cairo_matrix_init( &aMatrix, rObjectToDevice.get( 0, 0 ), rObjectToDevice.get( 1, 0 ), rObjectToDevice.get( 0, 1 ), rObjectToDevice.get( 1, 1 ), rObjectToDevice.get( 0, 2 ), rObjectToDevice.get( 1, 2 )); cairo_set_matrix(cr, &aMatrix); } // To make releaseCairoContext work, use empty extents basegfx::B2DRange extents; if (bHasFill) { add_polygon_path(cr, rPolyPolygon, rObjectToDevice, !getAntiAliasB2DDraw()); applyColor(cr, m_aFillColor, fTransparency); // Get FillDamage (will be extended for LineDamage below) extents = getClippedFillDamage(cr); cairo_fill(cr); } if (bHasLine) { // PixelOffset used: Set PixelOffset as linear transformation cairo_matrix_t aMatrix; cairo_matrix_init_translate(&aMatrix, 0.5, 0.5); cairo_set_matrix(cr, &aMatrix); add_polygon_path(cr, rPolyPolygon, rObjectToDevice, !getAntiAliasB2DDraw()); applyColor(cr, m_aLineColor, fTransparency); // expand with possible StrokeDamage basegfx::B2DRange stroke_extents = getClippedStrokeDamage(cr); stroke_extents.transform(basegfx::utils::createTranslateB2DHomMatrix(0.5, 0.5)); extents.expand(stroke_extents); cairo_stroke(cr); } // if transformation has been applied, transform also extents (ranges) // of damage so they can be correctly redrawn extents.transform(rObjectToDevice); releaseCairoContext(cr, true, extents); return true; } bool SvpSalGraphics::implDrawGradient(basegfx::B2DPolyPolygon const & rPolyPolygon, SalGradient const & rGradient) { cairo_t* cr = getCairoContext(true); clipRegion(cr); basegfx::B2DHomMatrix rObjectToDevice; for (auto const & rPolygon : rPolyPolygon) AddPolygonToPath(cr, rPolygon, rObjectToDevice, !getAntiAliasB2DDraw(), false); cairo_pattern_t* pattern; pattern = cairo_pattern_create_linear(rGradient.maPoint1.getX(), rGradient.maPoint1.getY(), rGradient.maPoint2.getX(), rGradient.maPoint2.getY()); for (SalGradientStop const & rStop : rGradient.maStops) { double r = rStop.maColor.GetRed() / 255.0; double g = rStop.maColor.GetGreen() / 255.0; double b = rStop.maColor.GetBlue() / 255.0; double a = (0xFF - rStop.maColor.GetTransparency()) / 255.0; double offset = rStop.mfOffset; cairo_pattern_add_color_stop_rgba(pattern, offset, r, g, b, a); } cairo_set_source(cr, pattern); basegfx::B2DRange extents = getClippedFillDamage(cr); cairo_fill_preserve(cr); releaseCairoContext(cr, true, extents); return true; } void SvpSalGraphics::applyColor(cairo_t *cr, Color aColor, double fTransparency) { if (cairo_surface_get_content(m_pSurface) == CAIRO_CONTENT_COLOR_ALPHA) { cairo_set_source_rgba(cr, aColor.GetRed()/255.0, aColor.GetGreen()/255.0, aColor.GetBlue()/255.0, 1.0 - fTransparency); } else { double fSet = aColor == COL_BLACK ? 1.0 : 0.0; cairo_set_source_rgba(cr, 1, 1, 1, fSet); cairo_set_operator(cr, CAIRO_OPERATOR_SOURCE); } } void SvpSalGraphics::copyArea( long nDestX, long nDestY, long nSrcX, long nSrcY, long nSrcWidth, long nSrcHeight, bool /*bWindowInvalidate*/ ) { SalTwoRect aTR(nSrcX, nSrcY, nSrcWidth, nSrcHeight, nDestX, nDestY, nSrcWidth, nSrcHeight); copyBits(aTR, this); } static basegfx::B2DRange renderWithOperator(cairo_t* cr, const SalTwoRect& rTR, cairo_surface_t* source, cairo_operator_t eOperator = CAIRO_OPERATOR_SOURCE) { cairo_rectangle(cr, rTR.mnDestX, rTR.mnDestY, rTR.mnDestWidth, rTR.mnDestHeight); basegfx::B2DRange extents = getClippedFillDamage(cr); cairo_clip(cr); cairo_translate(cr, rTR.mnDestX, rTR.mnDestY); double fXScale = 1.0f; double fYScale = 1.0f; if (rTR.mnSrcWidth != 0 && rTR.mnSrcHeight != 0) { fXScale = static_cast(rTR.mnDestWidth)/rTR.mnSrcWidth; fYScale = static_cast(rTR.mnDestHeight)/rTR.mnSrcHeight; cairo_scale(cr, fXScale, fYScale); } cairo_save(cr); cairo_set_source_surface(cr, source, -rTR.mnSrcX, -rTR.mnSrcY); if ((fXScale != 1.0 && rTR.mnSrcWidth == 1) || (fYScale != 1.0 && rTR.mnSrcHeight == 1)) { cairo_pattern_t* sourcepattern = cairo_get_source(cr); cairo_pattern_set_extend(sourcepattern, CAIRO_EXTEND_REPEAT); cairo_pattern_set_filter(sourcepattern, CAIRO_FILTER_NEAREST); } cairo_set_operator(cr, eOperator); cairo_paint(cr); cairo_restore(cr); return extents; } static basegfx::B2DRange renderSource(cairo_t* cr, const SalTwoRect& rTR, cairo_surface_t* source) { return renderWithOperator(cr, rTR, source, CAIRO_OPERATOR_SOURCE); } void SvpSalGraphics::copyWithOperator( const SalTwoRect& rTR, cairo_surface_t* source, cairo_operator_t eOp ) { cairo_t* cr = getCairoContext(false); clipRegion(cr); basegfx::B2DRange extents = renderWithOperator(cr, rTR, source, eOp); releaseCairoContext(cr, false, extents); } void SvpSalGraphics::copySource( const SalTwoRect& rTR, cairo_surface_t* source ) { copyWithOperator(rTR, source, CAIRO_OPERATOR_SOURCE); } void SvpSalGraphics::copyBits( const SalTwoRect& rTR, SalGraphics* pSrcGraphics ) { SalTwoRect aTR(rTR); SvpSalGraphics* pSrc = pSrcGraphics ? static_cast(pSrcGraphics) : this; cairo_surface_t* source = pSrc->m_pSurface; cairo_surface_t *pCopy = nullptr; if (pSrc == this) { //self copy is a problem, so dup source in that case pCopy = cairo_surface_create_similar(source, cairo_surface_get_content(m_pSurface), aTR.mnSrcWidth * m_fScale, aTR.mnSrcHeight * m_fScale); dl_cairo_surface_set_device_scale(pCopy, m_fScale, m_fScale); cairo_t* cr = cairo_create(pCopy); cairo_set_source_surface(cr, source, -aTR.mnSrcX, -aTR.mnSrcY); cairo_rectangle(cr, 0, 0, aTR.mnSrcWidth, aTR.mnSrcHeight); cairo_fill(cr); cairo_destroy(cr); source = pCopy; aTR.mnSrcX = 0; aTR.mnSrcY = 0; } copySource(aTR, source); if (pCopy) cairo_surface_destroy(pCopy); } void SvpSalGraphics::drawBitmap(const SalTwoRect& rTR, const SalBitmap& rSourceBitmap) { // MM02 try to access buffered BitmapHelper std::shared_ptr aSurface; tryToUseSourceBuffer(rSourceBitmap, aSurface); cairo_surface_t* source = aSurface->getSurface( rTR.mnDestWidth, rTR.mnDestHeight); if (!source) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawAlphaBitmap case"); return; } copyWithOperator(rTR, source, CAIRO_OPERATOR_OVER); } void SvpSalGraphics::drawBitmap(const SalTwoRect& rTR, const BitmapBuffer* pBuffer, cairo_operator_t eOp) { cairo_surface_t* source = createCairoSurface( pBuffer ); copyWithOperator(rTR, source, eOp); cairo_surface_destroy(source); } void SvpSalGraphics::drawBitmap( const SalTwoRect& rTR, const SalBitmap& rSourceBitmap, const SalBitmap& rTransparentBitmap ) { drawAlphaBitmap(rTR, rSourceBitmap, rTransparentBitmap); } void SvpSalGraphics::drawMask( const SalTwoRect& rTR, const SalBitmap& rSalBitmap, Color nMaskColor ) { /** creates an image from the given rectangle, replacing all black pixels * with nMaskColor and make all other full transparent */ // MM02 here decided *against* using buffered BitmapHelper // because the data gets somehow 'unmuliplied'. This may also be // done just once, but I am not sure if this is safe to do. // So for now dispense re-using data here. BitmapHelper aSurface(rSalBitmap, true); // The mask is argb32 if (!aSurface.getSurface()) { SAL_WARN("vcl.gdi", "unsupported SvpSalGraphics::drawMask case"); return; } sal_Int32 nStride; unsigned char *mask_data = aSurface.getBits(nStride); vcl::bitmap::lookup_table unpremultiply_table = vcl::bitmap::get_unpremultiply_table(); for (long y = rTR.mnSrcY ; y < rTR.mnSrcY + rTR.mnSrcHeight; ++y) { unsigned char *row = mask_data + (nStride*y); unsigned char *data = row + (rTR.mnSrcX * 4); for (long x = rTR.mnSrcX; x < rTR.mnSrcX + rTR.mnSrcWidth; ++x) { sal_uInt8 a = data[SVP_CAIRO_ALPHA]; sal_uInt8 b = unpremultiply_table[a][data[SVP_CAIRO_BLUE]]; sal_uInt8 g = unpremultiply_table[a][data[SVP_CAIRO_GREEN]]; sal_uInt8 r = unpremultiply_table[a][data[SVP_CAIRO_RED]]; if (r == 0 && g == 0 && b == 0) { data[0] = nMaskColor.GetBlue(); data[1] = nMaskColor.GetGreen(); data[2] = nMaskColor.GetRed(); data[3] = 0xff; } else { data[0] = 0; data[1] = 0; data[2] = 0; data[3] = 0; } data+=4; } } aSurface.mark_dirty(); cairo_t* cr = getCairoContext(false); clipRegion(cr); cairo_rectangle(cr, rTR.mnDestX, rTR.mnDestY, rTR.mnDestWidth, rTR.mnDestHeight); basegfx::B2DRange extents = getClippedFillDamage(cr); cairo_clip(cr); cairo_translate(cr, rTR.mnDestX, rTR.mnDestY); double fXScale = static_cast(rTR.mnDestWidth)/rTR.mnSrcWidth; double fYScale = static_cast(rTR.mnDestHeight)/rTR.mnSrcHeight; cairo_scale(cr, fXScale, fYScale); cairo_set_source_surface(cr, aSurface.getSurface(), -rTR.mnSrcX, -rTR.mnSrcY); if ((fXScale != 1.0 && rTR.mnSrcWidth == 1) || (fYScale != 1.0 && rTR.mnSrcHeight == 1)) { cairo_pattern_t* sourcepattern = cairo_get_source(cr); cairo_pattern_set_extend(sourcepattern, CAIRO_EXTEND_REPEAT); cairo_pattern_set_filter(sourcepattern, CAIRO_FILTER_NEAREST); } cairo_paint(cr); releaseCairoContext(cr, false, extents); } std::shared_ptr SvpSalGraphics::getBitmap( long nX, long nY, long nWidth, long nHeight ) { std::shared_ptr pBitmap = std::make_shared(); BitmapPalette aPal; if (GetBitCount() == 1) { aPal.SetEntryCount(2); aPal[0] = COL_BLACK; aPal[1] = COL_WHITE; } if (!pBitmap->Create(Size(nWidth, nHeight), GetBitCount(), aPal)) { SAL_WARN("vcl.gdi", "SvpSalGraphics::getBitmap, cannot create bitmap"); return nullptr; } cairo_surface_t* target = SvpSalGraphics::createCairoSurface(pBitmap->GetBuffer()); if (!target) { SAL_WARN("vcl.gdi", "SvpSalGraphics::getBitmap, cannot create cairo surface"); return nullptr; } cairo_t* cr = cairo_create(target); SalTwoRect aTR(nX, nY, nWidth, nHeight, 0, 0, nWidth, nHeight); renderSource(cr, aTR, m_pSurface); cairo_destroy(cr); cairo_surface_destroy(target); Toggle1BitTransparency(*pBitmap->GetBuffer()); return pBitmap; } Color SvpSalGraphics::getPixel( long nX, long nY ) { #if CAIRO_VERSION >= CAIRO_VERSION_ENCODE(1, 12, 0) cairo_surface_t *target = cairo_surface_create_similar_image(m_pSurface, CAIRO_FORMAT_ARGB32, 1, 1); #else cairo_surface_t *target = cairo_image_surface_create(CAIRO_FORMAT_ARGB32, 1, 1); #endif cairo_t* cr = cairo_create(target); cairo_rectangle(cr, 0, 0, 1, 1); cairo_set_source_surface(cr, m_pSurface, -nX, -nY); cairo_paint(cr); cairo_destroy(cr); cairo_surface_flush(target); vcl::bitmap::lookup_table unpremultiply_table = vcl::bitmap::get_unpremultiply_table(); unsigned char *data = cairo_image_surface_get_data(target); sal_uInt8 a = data[SVP_CAIRO_ALPHA]; sal_uInt8 b = unpremultiply_table[a][data[SVP_CAIRO_BLUE]]; sal_uInt8 g = unpremultiply_table[a][data[SVP_CAIRO_GREEN]]; sal_uInt8 r = unpremultiply_table[a][data[SVP_CAIRO_RED]]; Color aColor(0xFF - a, r, g, b); cairo_surface_destroy(target); return aColor; } namespace { cairo_pattern_t * create_stipple() { static unsigned char data[16] = { 0xFF, 0xFF, 0x00, 0x00, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00, 0xFF, 0xFF, 0x00, 0x00, 0xFF, 0xFF }; cairo_surface_t* surface = cairo_image_surface_create_for_data(data, CAIRO_FORMAT_A8, 4, 4, 4); cairo_pattern_t* pattern = cairo_pattern_create_for_surface(surface); cairo_surface_destroy(surface); cairo_pattern_set_extend(pattern, CAIRO_EXTEND_REPEAT); cairo_pattern_set_filter(pattern, CAIRO_FILTER_NEAREST); return pattern; } } void SvpSalGraphics::invert(const basegfx::B2DPolygon &rPoly, SalInvert nFlags) { cairo_t* cr = getCairoContext(false); clipRegion(cr); // To make releaseCairoContext work, use empty extents basegfx::B2DRange extents; AddPolygonToPath( cr, rPoly, basegfx::B2DHomMatrix(), !getAntiAliasB2DDraw(), false); cairo_set_source_rgb(cr, 1.0, 1.0, 1.0); if (cairo_version() >= CAIRO_VERSION_ENCODE(1, 10, 0)) { cairo_set_operator(cr, CAIRO_OPERATOR_DIFFERENCE); } else { SAL_WARN("vcl.gdi", "SvpSalGraphics::invert, archaic cairo"); } if (nFlags & SalInvert::TrackFrame) { cairo_set_line_width(cr, 2.0); const double dashLengths[2] = { 4.0, 4.0 }; cairo_set_dash(cr, dashLengths, 2, 0); extents = getClippedStrokeDamage(cr); //see tdf#106577 under wayland, some pixel droppings seen, maybe we're //out by one somewhere, or cairo_stroke_extents is confused by //dashes/line width if(!extents.isEmpty()) { extents.grow(1); } cairo_stroke(cr); } else { extents = getClippedFillDamage(cr); cairo_clip(cr); if (nFlags & SalInvert::N50) { cairo_pattern_t *pattern = create_stipple(); cairo_surface_t* surface = cairo_surface_create_similar(m_pSurface, cairo_surface_get_content(m_pSurface), extents.getWidth() * m_fScale, extents.getHeight() * m_fScale); dl_cairo_surface_set_device_scale(surface, m_fScale, m_fScale); cairo_t* stipple_cr = cairo_create(surface); cairo_set_source_rgb(stipple_cr, 1.0, 1.0, 1.0); cairo_mask(stipple_cr, pattern); cairo_pattern_destroy(pattern); cairo_destroy(stipple_cr); cairo_mask_surface(cr, surface, extents.getMinX(), extents.getMinY()); cairo_surface_destroy(surface); } else { cairo_paint(cr); } } releaseCairoContext(cr, false, extents); } void SvpSalGraphics::invert( long nX, long nY, long nWidth, long nHeight, SalInvert nFlags ) { basegfx::B2DPolygon aRect = basegfx::utils::createPolygonFromRect(basegfx::B2DRectangle(nX, nY, nX+nWidth, nY+nHeight)); invert(aRect, nFlags); } void SvpSalGraphics::invert(sal_uInt32 nPoints, const SalPoint* pPtAry, SalInvert nFlags) { basegfx::B2DPolygon aPoly; aPoly.append(basegfx::B2DPoint(pPtAry->mnX, pPtAry->mnY), nPoints); for (sal_uInt32 i = 1; i < nPoints; ++i) aPoly.setB2DPoint(i, basegfx::B2DPoint(pPtAry[i].mnX, pPtAry[i].mnY)); aPoly.setClosed(true); invert(aPoly, nFlags); } bool SvpSalGraphics::drawEPS( long, long, long, long, void*, sal_uInt32 ) { return false; } namespace { bool isCairoCompatible(const BitmapBuffer* pBuffer) { if (!pBuffer) return false; // We use Cairo that supports 24-bit RGB. #ifdef HAVE_CAIRO_FORMAT_RGB24_888 if (pBuffer->mnBitCount != 32 && pBuffer->mnBitCount != 24 && pBuffer->mnBitCount != 1) #else if (pBuffer->mnBitCount != 32 && pBuffer->mnBitCount != 1) #endif return false; cairo_format_t nFormat = getCairoFormat(*pBuffer); return (cairo_format_stride_for_width(nFormat, pBuffer->mnWidth) == pBuffer->mnScanlineSize); } } cairo_surface_t* SvpSalGraphics::createCairoSurface(const BitmapBuffer *pBuffer) { if (!isCairoCompatible(pBuffer)) return nullptr; cairo_format_t nFormat = getCairoFormat(*pBuffer); cairo_surface_t *target = cairo_image_surface_create_for_data(pBuffer->mpBits, nFormat, pBuffer->mnWidth, pBuffer->mnHeight, pBuffer->mnScanlineSize); if (cairo_surface_status(target) != CAIRO_STATUS_SUCCESS) { cairo_surface_destroy(target); return nullptr; } return target; } cairo_t* SvpSalGraphics::createTmpCompatibleCairoContext() const { #if CAIRO_VERSION >= CAIRO_VERSION_ENCODE(1, 12, 0) cairo_surface_t *target = cairo_surface_create_similar_image(m_pSurface, #else cairo_surface_t *target = cairo_image_surface_create( #endif CAIRO_FORMAT_ARGB32, m_aFrameSize.getX() * m_fScale, m_aFrameSize.getY() * m_fScale); dl_cairo_surface_set_device_scale(target, m_fScale, m_fScale); return cairo_create(target); } cairo_t* SvpSalGraphics::getCairoContext(bool bXorModeAllowed) const { cairo_t* cr; if (m_ePaintMode == PaintMode::Xor && bXorModeAllowed) cr = createTmpCompatibleCairoContext(); else cr = cairo_create(m_pSurface); cairo_set_line_width(cr, 1); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_EVEN_ODD); cairo_set_antialias(cr, getAntiAliasB2DDraw() ? CAIRO_ANTIALIAS_DEFAULT : CAIRO_ANTIALIAS_NONE); cairo_set_operator(cr, CAIRO_OPERATOR_OVER); // ensure no linear transformation and no PathInfo in local cairo_path_t cairo_identity_matrix(cr); cairo_new_path(cr); return cr; } cairo_user_data_key_t* SvpSalGraphics::getDamageKey() { static cairo_user_data_key_t aDamageKey; return &aDamageKey; } void SvpSalGraphics::releaseCairoContext(cairo_t* cr, bool bXorModeAllowed, const basegfx::B2DRange& rExtents) const { const bool bXoring = (m_ePaintMode == PaintMode::Xor && bXorModeAllowed); if (rExtents.isEmpty()) { //nothing changed, return early if (bXoring) { cairo_surface_t* surface = cairo_get_target(cr); cairo_surface_destroy(surface); } cairo_destroy(cr); return; } basegfx::B2IRange aIntExtents(basegfx::unotools::b2ISurroundingRangeFromB2DRange(rExtents)); sal_Int32 nExtentsLeft(aIntExtents.getMinX()), nExtentsTop(aIntExtents.getMinY()); sal_Int32 nExtentsRight(aIntExtents.getMaxX()), nExtentsBottom(aIntExtents.getMaxY()); sal_Int32 nWidth = m_aFrameSize.getX(); sal_Int32 nHeight = m_aFrameSize.getY(); nExtentsLeft = std::max(nExtentsLeft, 0); nExtentsTop = std::max(nExtentsTop, 0); nExtentsRight = std::min(nExtentsRight, nWidth); nExtentsBottom = std::min(nExtentsBottom, nHeight); cairo_surface_t* surface = cairo_get_target(cr); cairo_surface_flush(surface); //For the most part we avoid the use of XOR these days, but there //are some edge cases where legacy stuff still supports it, so //emulate it (slowly) here. if (bXoring) { cairo_surface_t* target_surface = m_pSurface; if (cairo_surface_get_type(target_surface) != CAIRO_SURFACE_TYPE_IMAGE) { //in the unlikely case we can't use m_pSurface directly, copy contents //to another temp image surface cairo_t* copycr = createTmpCompatibleCairoContext(); cairo_rectangle(copycr, nExtentsLeft, nExtentsTop, nExtentsRight - nExtentsLeft, nExtentsBottom - nExtentsTop); cairo_set_source_surface(copycr, m_pSurface, 0, 0); cairo_paint(copycr); target_surface = cairo_get_target(copycr); cairo_destroy(copycr); } cairo_surface_flush(target_surface); unsigned char *target_surface_data = cairo_image_surface_get_data(target_surface); unsigned char *xor_surface_data = cairo_image_surface_get_data(surface); cairo_format_t nFormat = cairo_image_surface_get_format(target_surface); assert(nFormat == CAIRO_FORMAT_ARGB32 && "need to implement CAIRO_FORMAT_A1 after all here"); sal_Int32 nStride = cairo_format_stride_for_width(nFormat, nWidth * m_fScale); sal_Int32 nUnscaledExtentsLeft = nExtentsLeft * m_fScale; sal_Int32 nUnscaledExtentsRight = nExtentsRight * m_fScale; sal_Int32 nUnscaledExtentsTop = nExtentsTop * m_fScale; sal_Int32 nUnscaledExtentsBottom = nExtentsBottom * m_fScale; vcl::bitmap::lookup_table unpremultiply_table = vcl::bitmap::get_unpremultiply_table(); vcl::bitmap::lookup_table premultiply_table = vcl::bitmap::get_premultiply_table(); for (sal_Int32 y = nUnscaledExtentsTop; y < nUnscaledExtentsBottom; ++y) { unsigned char *true_row = target_surface_data + (nStride*y); unsigned char *xor_row = xor_surface_data + (nStride*y); unsigned char *true_data = true_row + (nUnscaledExtentsLeft * 4); unsigned char *xor_data = xor_row + (nUnscaledExtentsLeft * 4); for (sal_Int32 x = nUnscaledExtentsLeft; x < nUnscaledExtentsRight; ++x) { sal_uInt8 a = true_data[SVP_CAIRO_ALPHA]; sal_uInt8 xor_a = xor_data[SVP_CAIRO_ALPHA]; sal_uInt8 b = unpremultiply_table[a][true_data[SVP_CAIRO_BLUE]] ^ unpremultiply_table[xor_a][xor_data[SVP_CAIRO_BLUE]]; sal_uInt8 g = unpremultiply_table[a][true_data[SVP_CAIRO_GREEN]] ^ unpremultiply_table[xor_a][xor_data[SVP_CAIRO_GREEN]]; sal_uInt8 r = unpremultiply_table[a][true_data[SVP_CAIRO_RED]] ^ unpremultiply_table[xor_a][xor_data[SVP_CAIRO_RED]]; true_data[SVP_CAIRO_BLUE] = premultiply_table[a][b]; true_data[SVP_CAIRO_GREEN] = premultiply_table[a][g]; true_data[SVP_CAIRO_RED] = premultiply_table[a][r]; true_data+=4; xor_data+=4; } } cairo_surface_mark_dirty(target_surface); if (target_surface != m_pSurface) { cairo_t* copycr = cairo_create(m_pSurface); //unlikely case we couldn't use m_pSurface directly, copy contents //back from image surface cairo_rectangle(copycr, nExtentsLeft, nExtentsTop, nExtentsRight - nExtentsLeft, nExtentsBottom - nExtentsTop); cairo_set_source_surface(copycr, target_surface, 0, 0); cairo_paint(copycr); cairo_destroy(copycr); cairo_surface_destroy(target_surface); } cairo_surface_destroy(surface); } cairo_destroy(cr); // unref DamageHandler* pDamage = static_cast(cairo_surface_get_user_data(m_pSurface, getDamageKey())); if (pDamage) { pDamage->damaged(pDamage->handle, nExtentsLeft, nExtentsTop, nExtentsRight - nExtentsLeft, nExtentsBottom - nExtentsTop); } } #if ENABLE_CAIRO_CANVAS bool SvpSalGraphics::SupportsCairo() const { return false; } cairo::SurfaceSharedPtr SvpSalGraphics::CreateSurface(const cairo::CairoSurfaceSharedPtr& /*rSurface*/) const { return cairo::SurfaceSharedPtr(); } cairo::SurfaceSharedPtr SvpSalGraphics::CreateSurface(const OutputDevice& /*rRefDevice*/, int /*x*/, int /*y*/, int /*width*/, int /*height*/) const { return cairo::SurfaceSharedPtr(); } cairo::SurfaceSharedPtr SvpSalGraphics::CreateBitmapSurface(const OutputDevice& /*rRefDevice*/, const BitmapSystemData& /*rData*/, const Size& /*rSize*/) const { return cairo::SurfaceSharedPtr(); } css::uno::Any SvpSalGraphics::GetNativeSurfaceHandle(cairo::SurfaceSharedPtr& /*rSurface*/, const basegfx::B2ISize& /*rSize*/) const { return css::uno::Any(); } #endif // ENABLE_CAIRO_CANVAS SystemGraphicsData SvpSalGraphics::GetGraphicsData() const { return SystemGraphicsData(); } bool SvpSalGraphics::supportsOperation(OutDevSupportType eType) const { switch (eType) { case OutDevSupportType::TransparentRect: case OutDevSupportType::B2DDraw: return true; } return false; } void dl_cairo_surface_set_device_scale(cairo_surface_t *surface, double x_scale, double y_scale) { #ifdef ANDROID cairo_surface_set_device_scale(surface, x_scale, y_scale); #else static auto func = reinterpret_cast( dlsym(nullptr, "cairo_surface_set_device_scale")); if (func) func(surface, x_scale, y_scale); #endif } void dl_cairo_surface_get_device_scale(cairo_surface_t *surface, double* x_scale, double* y_scale) { #ifdef ANDROID cairo_surface_get_device_scale(surface, x_scale, y_scale); #else static auto func = reinterpret_cast( dlsym(nullptr, "cairo_surface_get_device_scale")); if (func) func(surface, x_scale, y_scale); else { if (x_scale) *x_scale = 1.0; if (y_scale) *y_scale = 1.0; } #endif } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */