/* -*- 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 using namespace com::sun::star; namespace drawinglayer::primitive3d { Primitive3DContainer SdrExtrudePrimitive3D::create3DDecomposition(const geometry::ViewInformation3D& rViewInformation) const { Primitive3DContainer aRetval; // get slices const Slice3DVector& rSliceVector = getSlices(); if(!rSliceVector.empty()) { sal_uInt32 a; // decide what to create const css::drawing::NormalsKind eNormalsKind(getSdr3DObjectAttribute().getNormalsKind()); const bool bCreateNormals(css::drawing::NormalsKind_SPECIFIC == eNormalsKind); const bool bCreateTextureCoordinatesX(css::drawing::TextureProjectionMode_OBJECTSPECIFIC == getSdr3DObjectAttribute().getTextureProjectionX()); const bool bCreateTextureCoordinatesY(css::drawing::TextureProjectionMode_OBJECTSPECIFIC == getSdr3DObjectAttribute().getTextureProjectionY()); basegfx::B2DHomMatrix aTexTransform; if(!getSdrLFSAttribute().getFill().isDefault() && (bCreateTextureCoordinatesX || bCreateTextureCoordinatesY)) { const basegfx::B2DPolygon aFirstPolygon(maCorrectedPolyPolygon.getB2DPolygon(0)); const double fFrontLength(basegfx::utils::getLength(aFirstPolygon)); const double fFrontArea(basegfx::utils::getArea(aFirstPolygon)); const double fSqrtFrontArea(sqrt(fFrontArea)); double fRelativeTextureWidth = basegfx::fTools::equalZero(fSqrtFrontArea) ? 1.0 : fFrontLength / fSqrtFrontArea; fRelativeTextureWidth = std::trunc(fRelativeTextureWidth - 0.5); if(fRelativeTextureWidth < 1.0) { fRelativeTextureWidth = 1.0; } aTexTransform.translate(-0.5, -0.5); aTexTransform.scale(-1.0, -1.0); aTexTransform.translate(0.5, 0.5); aTexTransform.scale(fRelativeTextureWidth, 1.0); } // create geometry std::vector< basegfx::B3DPolyPolygon > aFill; extractPlanesFromSlice(aFill, rSliceVector, bCreateNormals, getSmoothNormals(), getSmoothLids(), false, 0.5, 0.6, bCreateTextureCoordinatesX || bCreateTextureCoordinatesY, aTexTransform); // get full range const basegfx::B3DRange aRange(getRangeFrom3DGeometry(aFill)); // normal creation if(!getSdrLFSAttribute().getFill().isDefault()) { if(css::drawing::NormalsKind_SPHERE == eNormalsKind) { applyNormalsKindSphereTo3DGeometry(aFill, aRange); } else if(css::drawing::NormalsKind_FLAT == eNormalsKind) { applyNormalsKindFlatTo3DGeometry(aFill); } if(getSdr3DObjectAttribute().getNormalsInvert()) { applyNormalsInvertTo3DGeometry(aFill); } } // texture coordinates if(!getSdrLFSAttribute().getFill().isDefault()) { applyTextureTo3DGeometry( getSdr3DObjectAttribute().getTextureProjectionX(), getSdr3DObjectAttribute().getTextureProjectionY(), aFill, aRange, getTextureSize()); } if(!getSdrLFSAttribute().getFill().isDefault()) { // add fill aRetval = create3DPolyPolygonFillPrimitives( aFill, getTransform(), getTextureSize(), getSdr3DObjectAttribute(), getSdrLFSAttribute().getFill(), getSdrLFSAttribute().getFillFloatTransGradient()); } else { // create simplified 3d hit test geometry aRetval = createHiddenGeometryPrimitives3D( aFill, getTransform(), getTextureSize(), getSdr3DObjectAttribute()); } // add line if(!getSdrLFSAttribute().getLine().isDefault()) { if(getSdr3DObjectAttribute().getReducedLineGeometry()) { // create geometric outlines with reduced line geometry for chart. const basegfx::B3DPolyPolygon aVerLine(extractVerticalLinesFromSlice(rSliceVector)); const sal_uInt32 nCount(aVerLine.count()); basegfx::B3DPolyPolygon aReducedLoops; basegfx::B3DPolyPolygon aNewLineGeometry; // sort out doubles (front and back planes when no edge rounding is done). Since // this is a line geometry merged from PolyPolygons, loop over all Polygons for(a = 0; a < nCount; a++) { const sal_uInt32 nReducedCount(aReducedLoops.count()); const basegfx::B3DPolygon& aCandidate(aVerLine.getB3DPolygon(a)); bool bAdd(true); if(nReducedCount) { for(sal_uInt32 b(0); bAdd && b < nReducedCount; b++) { if(aCandidate == aReducedLoops.getB3DPolygon(b)) { bAdd = false; } } } if(bAdd) { aReducedLoops.append(aCandidate); } } // from here work with reduced loops and reduced count without changing them const sal_uInt32 nReducedCount(aReducedLoops.count()); if(nReducedCount > 1) { for(sal_uInt32 b(1); b < nReducedCount; b++) { // get loop pair const basegfx::B3DPolygon& aCandA(aReducedLoops.getB3DPolygon(b - 1)); const basegfx::B3DPolygon& aCandB(aReducedLoops.getB3DPolygon(b)); // for each loop pair create the connection edges createReducedOutlines( rViewInformation, getTransform(), aCandA, aCandB, aNewLineGeometry); } } // add reduced loops themselves aNewLineGeometry.append(aReducedLoops); // to create vertical edges at non-C1/C2 steady loops, use maCorrectedPolyPolygon // directly since the 3D Polygons do not support this. // // Unfortunately there is no bezier polygon provided by the chart module; one reason is // that the API for extrude wants a 3D polygon geometry (for historical reasons, i guess) // and those have no beziers. Another reason is that he chart module uses self-created // stuff to create the 2D geometry (in ShapeFactory::createPieSegment), but this geometry // does not contain bezier infos, either. The only way which is possible for now is to 'detect' // candidates for vertical edges of pie segments by looking for the angles in the polygon. // // This is all not very well designed ATM. Ideally, the ReducedLineGeometry is responsible // for creating the outer geometry edges (createReducedOutlines), but for special edges // like the vertical ones for pie center and both start/end, the incarnation with the // knowledge about that it needs to create those and IS a pie segment -> in this case, // the chart itself. const sal_uInt32 nPolyCount(maCorrectedPolyPolygon.count()); for(sal_uInt32 c(0); c < nPolyCount; c++) { const basegfx::B2DPolygon aCandidate(maCorrectedPolyPolygon.getB2DPolygon(c)); const sal_uInt32 nPointCount(aCandidate.count()); if(nPointCount > 2) { sal_uInt32 nIndexA(nPointCount); sal_uInt32 nIndexB(nPointCount); sal_uInt32 nIndexC(nPointCount); for(sal_uInt32 d(0); d < nPointCount; d++) { const sal_uInt32 nPrevInd((d + nPointCount - 1) % nPointCount); const sal_uInt32 nNextInd((d + 1) % nPointCount); const basegfx::B2DPoint aPoint(aCandidate.getB2DPoint(d)); const basegfx::B2DVector aPrev(aCandidate.getB2DPoint(nPrevInd) - aPoint); const basegfx::B2DVector aNext(aCandidate.getB2DPoint(nNextInd) - aPoint); const double fAngle(aPrev.angle(aNext)); // take each angle which deviates more than 10% from going straight as // special edge. This will detect the two outer edges of pie segments, // but not always the center one (think about a near 180 degree pie) if(F_PI - fabs(fAngle) > F_PI * 0.1) { if(nPointCount == nIndexA) { nIndexA = d; } else if(nPointCount == nIndexB) { nIndexB = d; } else if(nPointCount == nIndexC) { nIndexC = d; d = nPointCount; } } } const bool bIndexAUsed(nIndexA != nPointCount); const bool bIndexBUsed(nIndexB != nPointCount); bool bIndexCUsed(nIndexC != nPointCount); if(bIndexCUsed) { // already three special edges found, so the center one was already detected // and does not need to be searched } else if(bIndexAUsed && bIndexBUsed) { // outer edges detected (they are approx. 90 degrees), but center one not. // Look with the knowledge that it's in-between the two found ones if(((nIndexA + 2) % nPointCount) == nIndexB) { nIndexC = (nIndexA + 1) % nPointCount; } else if(((nIndexA + nPointCount - 2) % nPointCount) == nIndexB) { nIndexC = (nIndexA + nPointCount - 1) % nPointCount; } bIndexCUsed = (nIndexC != nPointCount); } if(bIndexAUsed) { const basegfx::B2DPoint aPoint(aCandidate.getB2DPoint(nIndexA)); const basegfx::B3DPoint aStart(aPoint.getX(), aPoint.getY(), 0.0); const basegfx::B3DPoint aEnd(aPoint.getX(), aPoint.getY(), getDepth()); basegfx::B3DPolygon aToBeAdded; aToBeAdded.append(aStart); aToBeAdded.append(aEnd); aNewLineGeometry.append(aToBeAdded); } if(bIndexBUsed) { const basegfx::B2DPoint aPoint(aCandidate.getB2DPoint(nIndexB)); const basegfx::B3DPoint aStart(aPoint.getX(), aPoint.getY(), 0.0); const basegfx::B3DPoint aEnd(aPoint.getX(), aPoint.getY(), getDepth()); basegfx::B3DPolygon aToBeAdded; aToBeAdded.append(aStart); aToBeAdded.append(aEnd); aNewLineGeometry.append(aToBeAdded); } if(bIndexCUsed) { const basegfx::B2DPoint aPoint(aCandidate.getB2DPoint(nIndexC)); const basegfx::B3DPoint aStart(aPoint.getX(), aPoint.getY(), 0.0); const basegfx::B3DPoint aEnd(aPoint.getX(), aPoint.getY(), getDepth()); basegfx::B3DPolygon aToBeAdded; aToBeAdded.append(aStart); aToBeAdded.append(aEnd); aNewLineGeometry.append(aToBeAdded); } } } // append loops themselves aNewLineGeometry.append(aReducedLoops); if(aNewLineGeometry.count()) { const Primitive3DContainer aLines(create3DPolyPolygonLinePrimitives( aNewLineGeometry, getTransform(), getSdrLFSAttribute().getLine())); aRetval.append(aLines); } } else { // extract line geometry from slices const basegfx::B3DPolyPolygon aHorLine(extractHorizontalLinesFromSlice(rSliceVector, false)); const basegfx::B3DPolyPolygon aVerLine(extractVerticalLinesFromSlice(rSliceVector)); // add horizontal lines const Primitive3DContainer aHorLines(create3DPolyPolygonLinePrimitives( aHorLine, getTransform(), getSdrLFSAttribute().getLine())); aRetval.append(aHorLines); // add vertical lines const Primitive3DContainer aVerLines(create3DPolyPolygonLinePrimitives( aVerLine, getTransform(), getSdrLFSAttribute().getLine())); aRetval.append(aVerLines); } } // add shadow if(!getSdrLFSAttribute().getShadow().isDefault() && !aRetval.empty()) { const Primitive3DContainer aShadow(createShadowPrimitive3D( aRetval, getSdrLFSAttribute().getShadow(), getSdr3DObjectAttribute().getShadow3D())); aRetval.append(aShadow); } } return aRetval; } void SdrExtrudePrimitive3D::impCreateSlices() { // prepare the polygon. No double points, correct orientations and a correct // outmost polygon are needed // Also important: subdivide here to ensure equal point count for all slices (!) maCorrectedPolyPolygon = basegfx::utils::adaptiveSubdivideByAngle(getPolyPolygon()); maCorrectedPolyPolygon.removeDoublePoints(); maCorrectedPolyPolygon = basegfx::utils::correctOrientations(maCorrectedPolyPolygon); maCorrectedPolyPolygon = basegfx::utils::correctOutmostPolygon(maCorrectedPolyPolygon); // prepare slices as geometry createExtrudeSlices(maSlices, maCorrectedPolyPolygon, getBackScale(), getDiagonal(), getDepth(), getCharacterMode(), getCloseFront(), getCloseBack()); } const Slice3DVector& SdrExtrudePrimitive3D::getSlices() const { // This can be made dependent of getSdrLFSAttribute().getFill() and getSdrLFSAttribute().getLine() // again when no longer geometry is needed for non-visible 3D objects as it is now for chart if(getPolyPolygon().count() && maSlices.empty()) { ::osl::MutexGuard aGuard( m_aMutex ); const_cast< SdrExtrudePrimitive3D& >(*this).impCreateSlices(); } return maSlices; } SdrExtrudePrimitive3D::SdrExtrudePrimitive3D( const basegfx::B3DHomMatrix& rTransform, const basegfx::B2DVector& rTextureSize, const attribute::SdrLineFillShadowAttribute3D& rSdrLFSAttribute, const attribute::Sdr3DObjectAttribute& rSdr3DObjectAttribute, const basegfx::B2DPolyPolygon& rPolyPolygon, double fDepth, double fDiagonal, double fBackScale, bool bSmoothNormals, bool bSmoothLids, bool bCharacterMode, bool bCloseFront, bool bCloseBack) : SdrPrimitive3D(rTransform, rTextureSize, rSdrLFSAttribute, rSdr3DObjectAttribute), maPolyPolygon(rPolyPolygon), mfDepth(fDepth), mfDiagonal(fDiagonal), mfBackScale(fBackScale), mbSmoothNormals(bSmoothNormals), mbSmoothLids(bSmoothLids), mbCharacterMode(bCharacterMode), mbCloseFront(bCloseFront), mbCloseBack(bCloseBack) { // make sure depth is positive if(basegfx::fTools::lessOrEqual(getDepth(), 0.0)) { mfDepth = 0.0; } // make sure the percentage value getDiagonal() is between 0.0 and 1.0 if(basegfx::fTools::lessOrEqual(getDiagonal(), 0.0)) { mfDiagonal = 0.0; } else if(basegfx::fTools::moreOrEqual(getDiagonal(), 1.0)) { mfDiagonal = 1.0; } // no close front/back when polygon is not closed if(getPolyPolygon().count() && !getPolyPolygon().getB2DPolygon(0).isClosed()) { mbCloseFront = mbCloseBack = false; } // no edge rounding when not closing if(!getCloseFront() && !getCloseBack()) { mfDiagonal = 0.0; } } SdrExtrudePrimitive3D::~SdrExtrudePrimitive3D() { } bool SdrExtrudePrimitive3D::operator==(const BasePrimitive3D& rPrimitive) const { if(SdrPrimitive3D::operator==(rPrimitive)) { const SdrExtrudePrimitive3D& rCompare = static_cast< const SdrExtrudePrimitive3D& >(rPrimitive); return (getPolyPolygon() == rCompare.getPolyPolygon() && getDepth() == rCompare.getDepth() && getDiagonal() == rCompare.getDiagonal() && getBackScale() == rCompare.getBackScale() && getSmoothNormals() == rCompare.getSmoothNormals() && getSmoothLids() == rCompare.getSmoothLids() && getCharacterMode() == rCompare.getCharacterMode() && getCloseFront() == rCompare.getCloseFront() && getCloseBack() == rCompare.getCloseBack()); } return false; } basegfx::B3DRange SdrExtrudePrimitive3D::getB3DRange(const geometry::ViewInformation3D& /*rViewInformation*/) const { // use default from sdrPrimitive3D which uses transformation expanded by line width/2 // The parent implementation which uses the ranges of the decomposition would be more // correct, but for historical reasons it is necessary to do the old method: To get // the range of the non-transformed geometry and transform it then. This leads to different // ranges where the new method is more correct, but the need to keep the old behaviour // has priority here. return get3DRangeFromSlices(getSlices()); } Primitive3DContainer SdrExtrudePrimitive3D::get3DDecomposition(const geometry::ViewInformation3D& rViewInformation) const { if(getSdr3DObjectAttribute().getReducedLineGeometry()) { if(!mpLastRLGViewInformation || (!getBuffered3DDecomposition().empty() && *mpLastRLGViewInformation != rViewInformation)) { ::osl::MutexGuard aGuard( m_aMutex ); // conditions of last local decomposition with reduced lines have changed. Remember // new one and clear current decompositiopn SdrExtrudePrimitive3D* pThat = const_cast< SdrExtrudePrimitive3D* >(this); pThat->setBuffered3DDecomposition(Primitive3DContainer()); pThat->mpLastRLGViewInformation = rViewInformation; } } // no test for buffering needed, call parent return SdrPrimitive3D::get3DDecomposition(rViewInformation); } // provide unique ID ImplPrimitive3DIDBlock(SdrExtrudePrimitive3D, PRIMITIVE3D_ID_SDREXTRUDEPRIMITIVE3D) } // end of namespace /* vim:set shiftwidth=4 softtabstop=4 expandtab: */