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If not, see * * for a copy of the LGPLv3 License. * ************************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_drawinglayer.hxx" #include #include #include #include #include #include #include #include #include #include ////////////////////////////////////////////////////////////////////////////// // helper class for animated graphics #include #include #include #include ////////////////////////////////////////////////////////////////////////////// // includes for testing MetafilePrimitive2D::create2DDecomposition // this switch defines if the test code is included or not #undef USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE #ifdef USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE #include #include #include #endif // USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE ////////////////////////////////////////////////////////////////////////////// namespace { struct animationStep { BitmapEx maBitmapEx; sal_uInt32 mnTime; }; class animatedBitmapExPreparator { ::Animation maAnimation; ::std::vector< animationStep > maSteps; sal_uInt32 generateStepTime(sal_uInt32 nIndex) const; public: animatedBitmapExPreparator(const Graphic& rGraphic); sal_uInt32 count() const { return maSteps.size(); } sal_uInt32 loopCount() const { return (sal_uInt32)maAnimation.GetLoopCount(); } sal_uInt32 stepTime(sal_uInt32 a) const { return maSteps[a].mnTime; } const BitmapEx& stepBitmapEx(sal_uInt32 a) const { return maSteps[a].maBitmapEx; } }; sal_uInt32 animatedBitmapExPreparator::generateStepTime(sal_uInt32 nIndex) const { const AnimationBitmap& rAnimBitmap = maAnimation.Get(sal_uInt16(nIndex)); sal_uInt32 nWaitTime(rAnimBitmap.nWait * 10); // #115934# // Take care of special value for MultiPage TIFFs. ATM these shall just // show their first page. Later we will offer some switching when object // is selected. if(ANIMATION_TIMEOUT_ON_CLICK == rAnimBitmap.nWait) { // ATM the huge value would block the timer, so // use a long time to show first page (whole day) nWaitTime = 100 * 60 * 60 * 24; } // Bad trap: There are animated gifs with no set WaitTime (!). // In that case use a default value. if(0L == nWaitTime) { nWaitTime = 100L; } return nWaitTime; } animatedBitmapExPreparator::animatedBitmapExPreparator(const Graphic& rGraphic) : maAnimation(rGraphic.GetAnimation()) { OSL_ENSURE(GRAPHIC_BITMAP == rGraphic.GetType() && rGraphic.IsAnimated(), "animatedBitmapExPreparator: graphic is not animated (!)"); // #128539# secure access to Animation, looks like there exist animated GIFs out there // with a step count of zero if(maAnimation.Count()) { VirtualDevice aVirtualDevice(*Application::GetDefaultDevice()); VirtualDevice aVirtualDeviceMask(*Application::GetDefaultDevice(), 1L); // Prepare VirtualDevices and their states aVirtualDevice.EnableMapMode(sal_False); aVirtualDeviceMask.EnableMapMode(sal_False); aVirtualDevice.SetOutputSizePixel(maAnimation.GetDisplaySizePixel()); aVirtualDeviceMask.SetOutputSizePixel(maAnimation.GetDisplaySizePixel()); aVirtualDevice.Erase(); aVirtualDeviceMask.Erase(); for(sal_uInt16 a(0L); a < maAnimation.Count(); a++) { animationStep aNextStep; aNextStep.mnTime = generateStepTime(a); // prepare step const AnimationBitmap& rAnimBitmap = maAnimation.Get(sal_uInt16(a)); switch(rAnimBitmap.eDisposal) { case DISPOSE_NOT: { aVirtualDevice.DrawBitmapEx(rAnimBitmap.aPosPix, rAnimBitmap.aBmpEx); Bitmap aMask = rAnimBitmap.aBmpEx.GetMask(); if(aMask.IsEmpty()) { const Point aEmpty; const Rectangle aRect(aEmpty, aVirtualDeviceMask.GetOutputSizePixel()); const Wallpaper aWallpaper(COL_BLACK); aVirtualDeviceMask.DrawWallpaper(aRect, aWallpaper); } else { BitmapEx aExpandVisibilityMask = BitmapEx(aMask, aMask); aVirtualDeviceMask.DrawBitmapEx(rAnimBitmap.aPosPix, aExpandVisibilityMask); } break; } case DISPOSE_BACK: { // #i70772# react on no mask, for primitives, too. const Bitmap aMask(rAnimBitmap.aBmpEx.GetMask()); const Bitmap aContent(rAnimBitmap.aBmpEx.GetBitmap()); aVirtualDeviceMask.Erase(); aVirtualDevice.DrawBitmap(rAnimBitmap.aPosPix, aContent); if(aMask.IsEmpty()) { const Rectangle aRect(rAnimBitmap.aPosPix, aContent.GetSizePixel()); aVirtualDeviceMask.SetFillColor(COL_BLACK); aVirtualDeviceMask.SetLineColor(); aVirtualDeviceMask.DrawRect(aRect); } else { aVirtualDeviceMask.DrawBitmap(rAnimBitmap.aPosPix, aMask); } break; } case DISPOSE_FULL: { aVirtualDevice.DrawBitmapEx(rAnimBitmap.aPosPix, rAnimBitmap.aBmpEx); break; } case DISPOSE_PREVIOUS : { aVirtualDevice.DrawBitmapEx(rAnimBitmap.aPosPix, rAnimBitmap.aBmpEx); aVirtualDeviceMask.DrawBitmap(rAnimBitmap.aPosPix, rAnimBitmap.aBmpEx.GetMask()); break; } } // create BitmapEx Bitmap aMainBitmap = aVirtualDevice.GetBitmap(Point(), aVirtualDevice.GetOutputSizePixel()); Bitmap aMaskBitmap = aVirtualDeviceMask.GetBitmap(Point(), aVirtualDeviceMask.GetOutputSizePixel()); aNextStep.maBitmapEx = BitmapEx(aMainBitmap, aMaskBitmap); // add to vector maSteps.push_back(aNextStep); } } } } // end of anonymous namespace ////////////////////////////////////////////////////////////////////////////// namespace drawinglayer { namespace primitive2d { Primitive2DSequence GraphicPrimitive2D::create2DDecomposition(const geometry::ViewInformation2D& #ifdef USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE rViewInformation #else /*rViewInformation*/ #endif // USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE ) const { Primitive2DSequence aRetval; if(255L != getGraphicAttr().GetTransparency()) { Primitive2DReference xPrimitive; // do not apply mirroring from GraphicAttr to the Metafile by calling // GetTransformedGraphic, this will try to mirror the Metafile using Scale() // at the Metafile. This again calls Scale at the single MetaFile actions, // but this implementation never worked. I reworked that implementations, // but for security reasons i will try not to use it. basegfx::B2DHomMatrix aTransform(getTransform()); if(getGraphicAttr().IsMirrored()) { // content needs mirroring const bool bHMirr(getGraphicAttr().GetMirrorFlags() & BMP_MIRROR_HORZ); const bool bVMirr(getGraphicAttr().GetMirrorFlags() & BMP_MIRROR_VERT); // mirror by applying negative scale to the unit primitive and // applying the object transformation on it. aTransform = basegfx::tools::createScaleB2DHomMatrix( bHMirr ? -1.0 : 1.0, bVMirr ? -1.0 : 1.0); aTransform.translate( bHMirr ? 1.0 : 0.0, bVMirr ? 1.0 : 0.0); aTransform = getTransform() * aTransform; } // Get transformed graphic. Suppress rotation and cropping, only filtering is needed // here (and may be replaced later on). Cropping is handled below as mask primitive (if set). // Also need to suppress mirroring, it is part of the transformation now (see above). GraphicAttr aSuppressGraphicAttr(getGraphicAttr()); aSuppressGraphicAttr.SetCrop(0, 0, 0, 0); aSuppressGraphicAttr.SetRotation(0); aSuppressGraphicAttr.SetMirrorFlags(0); const Graphic aTransformedGraphic(getGraphicObject().GetTransformedGraphic(&aSuppressGraphicAttr)); switch(aTransformedGraphic.GetType()) { case GRAPHIC_BITMAP : { if(aTransformedGraphic.IsAnimated()) { // prepare animation data animatedBitmapExPreparator aData(aTransformedGraphic); if(aData.count()) { // create sub-primitives for animated bitmap and the needed animation loop animation::AnimationEntryLoop aAnimationLoop(aData.loopCount() ? aData.loopCount() : 0xffff); Primitive2DSequence aBitmapPrimitives(aData.count()); for(sal_uInt32 a(0L); a < aData.count(); a++) { animation::AnimationEntryFixed aTime((double)aData.stepTime(a), (double)a / (double)aData.count()); aAnimationLoop.append(aTime); const Primitive2DReference xRef(new BitmapPrimitive2D(aData.stepBitmapEx(a), aTransform)); aBitmapPrimitives[a] = xRef; } // prepare animation list animation::AnimationEntryList aAnimationList; aAnimationList.append(aAnimationLoop); // create and add animated switch primitive xPrimitive = Primitive2DReference(new AnimatedSwitchPrimitive2D(aAnimationList, aBitmapPrimitives, false)); } } else { xPrimitive = Primitive2DReference(new BitmapPrimitive2D(aTransformedGraphic.GetBitmapEx(), aTransform)); } break; } case GRAPHIC_GDIMETAFILE : { #ifdef USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE static bool bDoTest(false); if(bDoTest) { // All this is/was test code for testing MetafilePrimitive2D::create2DDecomposition // extensively. It may be needed again when diverse actions need debugging, so i leave // it in here, but take it out using USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE. // Use it by compiling with the code, insert any DrawObject, convert to Metafile. The // debugger will then stop here (when breakpoint set, of course). You may enter single // parts of actions and/or change to true what You want to check. GDIMetaFile aMtf; VirtualDevice aOut; const basegfx::B2DRange aRange(getB2DRange(rViewInformation)); const Rectangle aRectangle( basegfx::fround(aRange.getMinX()), basegfx::fround(aRange.getMinY()), basegfx::fround(aRange.getMaxX()), basegfx::fround(aRange.getMaxY())); const Point aOrigin(aRectangle.TopLeft()); const Fraction aScaleX(aRectangle.getWidth()); const Fraction aScaleY(aRectangle.getHeight()); MapMode aMapMode(MAP_100TH_MM, aOrigin, aScaleX, aScaleY); Size aDummySize(2, 2); aOut.SetOutputSizePixel(aDummySize); aOut.EnableOutput(FALSE); aOut.SetMapMode(aMapMode); aMtf.Clear(); aMtf.Record(&aOut); const Fraction aNeutralFraction(1, 1); const MapMode aRelativeMapMode( MAP_RELATIVE, Point(-aRectangle.Left(), -aRectangle.Top()), aNeutralFraction, aNeutralFraction); aOut.SetMapMode(aRelativeMapMode); if(false) { const sal_Int32 nHor(aRectangle.getWidth() / 4); const sal_Int32 nVer(aRectangle.getHeight() / 4); const Rectangle aCenteredRectangle( aRectangle.Left() + nHor, aRectangle.Top() + nVer, aRectangle.Right() - nHor, aRectangle.Bottom() - nVer); aOut.SetClipRegion(aCenteredRectangle); } if(false) { const Rectangle aRightRectangle(aRectangle.TopCenter(), aRectangle.BottomRight()); aOut.IntersectClipRegion(aRightRectangle); } if(false) { const Rectangle aRightRectangle(aRectangle.TopCenter(), aRectangle.BottomRight()); const Rectangle aBottomRectangle(aRectangle.LeftCenter(), aRectangle.BottomRight()); Region aRegion(aRightRectangle); aRegion.Intersect(aBottomRectangle); aOut.IntersectClipRegion(aRegion); } if(false) { const sal_Int32 nHor(aRectangle.getWidth() / 10); const sal_Int32 nVer(aRectangle.getHeight() / 10); aOut.MoveClipRegion(nHor, nVer); } if(false) { Wallpaper aWallpaper(Color(COL_BLACK)); aOut.DrawWallpaper(aRectangle, aWallpaper); } if(false) { Wallpaper aWallpaper(Gradient(GRADIENT_LINEAR, Color(COL_RED), Color(COL_GREEN))); aOut.DrawWallpaper(aRectangle, aWallpaper); } if(false) { SvFileStream aRead((const String&)String(ByteString( "c:\\test.png" ), RTL_TEXTENCODING_UTF8), STREAM_READ); vcl::PNGReader aPNGReader(aRead); BitmapEx aBitmapEx(aPNGReader.Read()); Wallpaper aWallpaper(aBitmapEx); aOut.DrawWallpaper(aRectangle, aWallpaper); } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); Color aColor(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0)); for(sal_uInt32 a(0); a < 5000; a++) { const Point aPoint( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); if(!(a % 3)) { aColor = Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0)); } aOut.DrawPixel(aPoint, aColor); } } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(); for(sal_uInt32 a(0); a < 5000; a++) { const Point aPoint( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); aOut.DrawPixel(aPoint); } } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(); Point aStart( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); Point aStop( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); LineInfo aLineInfo(LINE_SOLID, basegfx::fround(fHor / 50.0)); bool bUseLineInfo(false); for(sal_uInt32 a(0); a < 20; a++) { if(!(a%6)) { bUseLineInfo = !bUseLineInfo; } if(!(a%4)) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); } if(a%3) { aStart = aStop; aStop = Point( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); } else { aStart = Point( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); aStop = Point( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); } if(bUseLineInfo) { aOut.DrawLine(aStart, aStop, aLineInfo); } else { aOut.DrawLine(aStart, aStop); } } } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawRect(aRectangle); } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); const sal_uInt32 nHor(aRectangle.getWidth() / 10); const sal_uInt32 nVer(aRectangle.getHeight() / 10); aOut.DrawRect(aRectangle, nHor, nVer); } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawEllipse(aRectangle); } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawArc(aRectangle, aRectangle.TopLeft(), aRectangle.BottomCenter()); } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawPie(aRectangle, aRectangle.TopLeft(), aRectangle.BottomCenter()); } if(false) { aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawChord(aRectangle, aRectangle.TopLeft(), aRectangle.BottomCenter()); } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); for(sal_uInt32 b(0); b < 5; b++) { const sal_uInt32 nCount(basegfx::fround(rand() * (20 / 32767.0))); const bool bClose(basegfx::fround(rand() / 32767.0)); Polygon aPolygon(nCount + (bClose ? 1 : 0)); for(sal_uInt32 a(0); a < nCount; a++) { const Point aPoint( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); aPolygon[a] = aPoint; } if(bClose) { aPolygon[aPolygon.GetSize() - 1] = aPolygon[0]; } aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); if(!(b%2)) { const LineInfo aLineInfo(LINE_SOLID, basegfx::fround(fHor / 50.0)); aOut.DrawPolyLine(aPolygon, aLineInfo); } else { aOut.DrawPolyLine(aPolygon); } } } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); for(sal_uInt32 b(0); b < 5; b++) { const sal_uInt32 nCount(basegfx::fround(rand() * (20 / 32767.0))); const bool bClose(basegfx::fround(rand() / 32767.0)); Polygon aPolygon(nCount + (bClose ? 1 : 0)); for(sal_uInt32 a(0); a < nCount; a++) { const Point aPoint( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); aPolygon[a] = aPoint; } if(bClose) { aPolygon[aPolygon.GetSize() - 1] = aPolygon[0]; } aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawPolygon(aPolygon); } } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); PolyPolygon aPolyPolygon; for(sal_uInt32 b(0); b < 3; b++) { const sal_uInt32 nCount(basegfx::fround(rand() * (6 / 32767.0))); const bool bClose(basegfx::fround(rand() / 32767.0)); Polygon aPolygon(nCount + (bClose ? 1 : 0)); for(sal_uInt32 a(0); a < nCount; a++) { const Point aPoint( aRectangle.Left() + basegfx::fround(rand() * (fHor / 32767.0)), aRectangle.Top() + basegfx::fround(rand() * (fVer / 32767.0))); aPolygon[a] = aPoint; } if(bClose) { aPolygon[aPolygon.GetSize() - 1] = aPolygon[0]; } aPolyPolygon.Insert(aPolygon); } aOut.SetLineColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.SetFillColor(Color(basegfx::BColor(rand() / 32767.0, rand() / 32767.0, rand() / 32767.0))); aOut.DrawPolyPolygon(aPolyPolygon); } if(false) { SvFileStream aRead((const String&)String(ByteString( "c:\\test.png" ), RTL_TEXTENCODING_UTF8), STREAM_READ); vcl::PNGReader aPNGReader(aRead); BitmapEx aBitmapEx(aPNGReader.Read()); aOut.DrawBitmapEx(aRectangle.TopLeft(), aBitmapEx); } if(false) { SvFileStream aRead((const String&)String(ByteString( "c:\\test.png" ), RTL_TEXTENCODING_UTF8), STREAM_READ); vcl::PNGReader aPNGReader(aRead); BitmapEx aBitmapEx(aPNGReader.Read()); aOut.DrawBitmapEx(aRectangle.TopLeft(), aRectangle.GetSize(), aBitmapEx); } if(false) { SvFileStream aRead((const String&)String(ByteString( "c:\\test.png" ), RTL_TEXTENCODING_UTF8), STREAM_READ); vcl::PNGReader aPNGReader(aRead); BitmapEx aBitmapEx(aPNGReader.Read()); const Size aSizePixel(aBitmapEx.GetSizePixel()); aOut.DrawBitmapEx( aRectangle.TopLeft(), aRectangle.GetSize(), Point(0, 0), Size(aSizePixel.Width() /2, aSizePixel.Height() / 2), aBitmapEx); } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); const Point aPointA( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.3)); const Point aPointB( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.5)); const Point aPointC( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.7)); const String aText(ByteString("Hello, World!"), RTL_TEXTENCODING_UTF8); const String aFontName(ByteString("Comic Sans MS"), RTL_TEXTENCODING_UTF8); Font aFont(aFontName, Size(0, 1000)); aFont.SetAlign(ALIGN_BASELINE); aFont.SetColor(COL_RED); //sal_Int32* pDXArray = new sal_Int32[aText.Len()]; aFont.SetOutline(true); aOut.SetFont(aFont); aOut.DrawText(aPointA, aText, 0, aText.Len()); aFont.SetShadow(true); aOut.SetFont(aFont); aOut.DrawText(aPointB, aText, 0, aText.Len()); aFont.SetRelief(RELIEF_EMBOSSED); aOut.SetFont(aFont); aOut.DrawText(aPointC, aText, 0, aText.Len()); //delete pDXArray; } if(false) { const double fHor(aRectangle.getWidth()); const double fVer(aRectangle.getHeight()); const Point aPointA( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.3)); const Point aPointB( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.5)); const Point aPointC( aRectangle.Left() + basegfx::fround(fHor * 0.2), aRectangle.Top() + basegfx::fround(fVer * 0.7)); const String aText(ByteString("Hello, World!"), RTL_TEXTENCODING_UTF8); const String aFontName(ByteString("Comic Sans MS"), RTL_TEXTENCODING_UTF8); Font aFont(aFontName, Size(0, 1000)); aFont.SetAlign(ALIGN_BASELINE); aFont.SetColor(COL_RED); aOut.SetFont(aFont); const sal_Int32 nWidth(aOut.GetTextWidth(aText, 0, aText.Len())); aOut.DrawText(aPointA, aText, 0, aText.Len()); aOut.DrawTextLine(aPointA, nWidth, STRIKEOUT_SINGLE, UNDERLINE_SINGLE, UNDERLINE_SMALLWAVE); aOut.DrawTextLine(aPointB, nWidth, STRIKEOUT_SINGLE, UNDERLINE_SINGLE, UNDERLINE_SMALLWAVE); aOut.DrawTextLine(aPointC, nWidth, STRIKEOUT_SINGLE, UNDERLINE_SINGLE, UNDERLINE_SMALLWAVE); } aMtf.Stop(); aMtf.WindStart(); aMtf.SetPrefMapMode(MapMode(MAP_100TH_MM)); aMtf.SetPrefSize(Size(aRectangle.getWidth(), aRectangle.getHeight())); xPrimitive = Primitive2DReference( new MetafilePrimitive2D( aTransform, aMtf)); } else { #endif // USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE // create MetafilePrimitive2D const Graphic aGraphic(getGraphicObject().GetGraphic()); const GDIMetaFile& rMetafile = aTransformedGraphic.GetGDIMetaFile(); xPrimitive = Primitive2DReference( new MetafilePrimitive2D( aTransform, rMetafile)); // #i100357# find out if clipping is needed for this primitive. Unfortunately, // there exist Metafiles who's content is bigger than the proposed PrefSize set // at them. This is an error, but we need to work around this const Size aMetaFilePrefSize(rMetafile.GetPrefSize()); const Size aMetaFileRealSize( const_cast< GDIMetaFile& >(rMetafile).GetBoundRect( *Application::GetDefaultDevice()).GetSize()); if(aMetaFileRealSize.getWidth() > aMetaFilePrefSize.getWidth() || aMetaFileRealSize.getHeight() > aMetaFilePrefSize.getHeight()) { // clipping needed. Embed to MaskPrimitive2D. Create childs and mask polygon const primitive2d::Primitive2DSequence aChildContent(&xPrimitive, 1); basegfx::B2DPolygon aMaskPolygon(basegfx::tools::createUnitPolygon()); aMaskPolygon.transform(aTransform); xPrimitive = Primitive2DReference( new MaskPrimitive2D( basegfx::B2DPolyPolygon(aMaskPolygon), aChildContent)); } #ifdef USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE } #endif // USE_DEBUG_CODE_TO_TEST_METAFILE_DECOMPOSE break; } default: { // nothing to create break; } } if(xPrimitive.is()) { // check for cropping if(getGraphicAttr().IsCropped()) { // decompose to get current pos and size basegfx::B2DVector aScale, aTranslate; double fRotate, fShearX; getTransform().decompose(aScale, aTranslate, fRotate, fShearX); // create ranges. The current object range is just scale and translate const basegfx::B2DRange aCurrent( aTranslate.getX(), aTranslate.getY(), aTranslate.getX() + aScale.getX(), aTranslate.getY() + aScale.getY()); // calculate scalings between real image size and logic object size. This // is necessary since the crop values are relative to original bitmap size double fFactorX(1.0); double fFactorY(1.0); { const MapMode aMapMode100thmm(MAP_100TH_MM); Size aBitmapSize(getGraphicObject().GetPrefSize()); // #i95968# better support PrefMapMode; special for MAP_PIXEL was missing if(MAP_PIXEL == getGraphicObject().GetPrefMapMode().GetMapUnit()) { aBitmapSize = Application::GetDefaultDevice()->PixelToLogic(aBitmapSize, aMapMode100thmm); } else { aBitmapSize = Application::GetDefaultDevice()->LogicToLogic(aBitmapSize, getGraphicObject().GetPrefMapMode(), aMapMode100thmm); } const double fDivX(aBitmapSize.Width() - getGraphicAttr().GetLeftCrop() - getGraphicAttr().GetRightCrop()); const double fDivY(aBitmapSize.Height() - getGraphicAttr().GetTopCrop() - getGraphicAttr().GetBottomCrop()); if(!basegfx::fTools::equalZero(fDivX)) { fFactorX = aScale.getX() / fDivX; } if(!basegfx::fTools::equalZero(fDivY)) { fFactorY = aScale.getY() / fDivY; } } // Create cropped range, describes the bounds of the original graphic basegfx::B2DRange aCropped; aCropped.expand(aCurrent.getMinimum() - basegfx::B2DPoint(getGraphicAttr().GetLeftCrop() * fFactorX, getGraphicAttr().GetTopCrop() * fFactorY)); aCropped.expand(aCurrent.getMaximum() + basegfx::B2DPoint(getGraphicAttr().GetRightCrop() * fFactorX, getGraphicAttr().GetBottomCrop() * fFactorY)); if(aCropped.isEmpty()) { // nothing to add since cropped bitmap is completely empty // xPrimitive will not be used } else { // build new object transformation for transform primitive which contains xPrimitive basegfx::B2DHomMatrix aNewObjectTransform(getTransform()); aNewObjectTransform.invert(); aNewObjectTransform = basegfx::tools::createScaleTranslateB2DHomMatrix( aCropped.getWidth(), aCropped.getHeight(), aCropped.getMinX() - aCurrent.getMinX(), aCropped.getMinY() - aCurrent.getMinY()) * aNewObjectTransform; // add shear, rotate and translate using combined matrix to speedup const basegfx::B2DHomMatrix aCombinedMatrix(basegfx::tools::createShearXRotateTranslateB2DHomMatrix( fShearX, fRotate, aTranslate.getX(), aTranslate.getY())); aNewObjectTransform = aCombinedMatrix * aNewObjectTransform; // prepare TransformPrimitive2D with xPrimitive const Primitive2DReference xTransformPrimitive(new TransformPrimitive2D(aNewObjectTransform, Primitive2DSequence(&xPrimitive, 1L))); if(aCurrent.isInside(aCropped)) { // cropped just got smaller, no need to really use a mask. Add to destination directly appendPrimitive2DReferenceToPrimitive2DSequence(aRetval, xTransformPrimitive); } else { // cropped got bigger, mask it with original object's bounds basegfx::B2DPolyPolygon aMaskPolyPolygon(basegfx::tools::createUnitPolygon()); aMaskPolyPolygon.transform(getTransform()); // create maskPrimitive with aMaskPolyPolygon and aMaskContentVector const Primitive2DReference xRefB(new MaskPrimitive2D(aMaskPolyPolygon, Primitive2DSequence(&xTransformPrimitive, 1L))); appendPrimitive2DReferenceToPrimitive2DSequence(aRetval, xRefB); } } } else { // add to decomposition appendPrimitive2DReferenceToPrimitive2DSequence(aRetval, xPrimitive); } } } return aRetval; } GraphicPrimitive2D::GraphicPrimitive2D( const basegfx::B2DHomMatrix& rTransform, const GraphicObject& rGraphicObject, const GraphicAttr& rGraphicAttr) : BufferedDecompositionPrimitive2D(), maTransform(rTransform), maGraphicObject(rGraphicObject), maGraphicAttr(rGraphicAttr) { } GraphicPrimitive2D::GraphicPrimitive2D( const basegfx::B2DHomMatrix& rTransform, const GraphicObject& rGraphicObject) : BufferedDecompositionPrimitive2D(), maTransform(rTransform), maGraphicObject(rGraphicObject), maGraphicAttr() { } bool GraphicPrimitive2D::operator==(const BasePrimitive2D& rPrimitive) const { if(BufferedDecompositionPrimitive2D::operator==(rPrimitive)) { const GraphicPrimitive2D& rCompare = (GraphicPrimitive2D&)rPrimitive; return (getTransform() == rCompare.getTransform() && getGraphicObject() == rCompare.getGraphicObject() && getGraphicAttr() == rCompare.getGraphicAttr()); } return false; } basegfx::B2DRange GraphicPrimitive2D::getB2DRange(const geometry::ViewInformation2D& /*rViewInformation*/) const { basegfx::B2DRange aRetval(0.0, 0.0, 1.0, 1.0); aRetval.transform(getTransform()); return aRetval; } // provide unique ID ImplPrimitrive2DIDBlock(GraphicPrimitive2D, PRIMITIVE2D_ID_GRAPHICPRIMITIVE2D) } // end of namespace primitive2d } // end of namespace drawinglayer ////////////////////////////////////////////////////////////////////////////// // eof