/* -*- 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 namespace { void putCommandChar(OUStringBuffer& rBuffer,sal_Unicode& rLastSVGCommand, sal_Unicode aChar, bool bToLower,bool bVerbose) { const sal_Unicode aCommand = bToLower ? rtl::toAsciiLowerCase(aChar) : aChar; if (bVerbose && rBuffer.getLength()) rBuffer.append(' '); if (bVerbose || rLastSVGCommand != aCommand) { rBuffer.append(aCommand); rLastSVGCommand = aCommand; } } void putNumberChar(OUStringBuffer& rStr,double fValue, double fOldValue, bool bUseRelativeCoordinates,bool bVerbose) { if (bUseRelativeCoordinates) fValue -= fOldValue; const sal_Int32 aLen(rStr.getLength()); if (bVerbose || (aLen && basegfx::internal::isOnNumberChar(rStr[aLen - 1], false) && fValue >= 0.0)) rStr.append(' '); rStr.append(fValue); } } namespace basegfx::utils { bool PointIndex::operator<(const PointIndex& rComp) const { if(rComp.getPolygonIndex() == getPolygonIndex()) { return rComp.getPointIndex() < getPointIndex(); } return rComp.getPolygonIndex() < getPolygonIndex(); } bool importFromSvgD( B2DPolyPolygon& o_rPolyPolygon, std::u16string_view rSvgDStatement, bool bHandleRelativeNextPointCompatible, PointIndexSet* pHelpPointIndexSet) { o_rPolyPolygon.clear(); const sal_Int32 nLen(rSvgDStatement.size()); sal_Int32 nPos(0); double nLastX( 0.0 ); double nLastY( 0.0 ); B2DPolygon aCurrPoly; // skip initial whitespace basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen) { bool bRelative(false); const sal_Unicode aCurrChar(rSvgDStatement[nPos]); if(o_rPolyPolygon.count() && !aCurrPoly.count() && aCurrChar != 'm' && aCurrChar != 'M') { // we have a new sub-polygon starting, but without a 'moveto' command. // this requires to add the current point as start point to the polygon // (see SVG1.1 8.3.3 The "closepath" command) aCurrPoly.append(B2DPoint(nLastX, nLastY)); } switch(aCurrChar) { case 'z' : case 'Z' : { // consume CurrChar and whitespace nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); // create closed polygon and reset import values if(aCurrPoly.count()) { if(!bHandleRelativeNextPointCompatible) { // SVG defines that "the next subpath starts at the // same initial point as the current subpath", so set the // current point if we do not need to be compatible nLastX = aCurrPoly.getB2DPoint(0).getX(); nLastY = aCurrPoly.getB2DPoint(0).getY(); } aCurrPoly.setClosed(true); o_rPolyPolygon.append(aCurrPoly); aCurrPoly.clear(); } break; } case 'm' : case 'M' : { // create non-closed polygon and reset import values if(aCurrPoly.count()) { o_rPolyPolygon.append(aCurrPoly); aCurrPoly.clear(); } [[fallthrough]]; // to add coordinate data as 1st point of new polygon } case 'l' : case 'L' : { if(aCurrChar == 'm' || aCurrChar == 'l') { bRelative = true; } // consume CurrChar and whitespace nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX += nLastX; nY += nLastY; } // set last position nLastX = nX; nLastY = nY; // add point aCurrPoly.append(B2DPoint(nX, nY)); } break; } case 'h' : { bRelative = true; [[fallthrough]]; } case 'H' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY(nLastY); if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX += nLastX; } // set last position nLastX = nX; // add point aCurrPoly.append(B2DPoint(nX, nY)); } break; } case 'v' : { bRelative = true; [[fallthrough]]; } case 'V' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX(nLastX), nY; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nY += nLastY; } // set last position nLastY = nY; // add point aCurrPoly.append(B2DPoint(nX, nY)); } break; } case 's' : { bRelative = true; [[fallthrough]]; } case 'S' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; double nX2, nY2; if(!basegfx::internal::importDoubleAndSpaces(nX2, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY2, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX2 += nLastX; nY2 += nLastY; nX += nLastX; nY += nLastY; } // ensure existence of start point sal_uInt32 nCurrPolyCount = aCurrPoly.count(); if (nCurrPolyCount == 0) { aCurrPoly.append(B2DPoint(nLastX, nLastY)); nCurrPolyCount = 1; } assert(nCurrPolyCount > 0 && "coverity 2023.12.2"); // get first control point. It's the reflection of the PrevControlPoint // of the last point. If not existent, use current point (see SVG) B2DPoint aPrevControl(nLastX, nLastY); const sal_uInt32 nIndex(nCurrPolyCount - 1); if(aCurrPoly.areControlPointsUsed() && aCurrPoly.isPrevControlPointUsed(nIndex)) { const B2DPoint aPrevPoint(aCurrPoly.getB2DPoint(nIndex)); const B2DPoint aPrevControlPoint(aCurrPoly.getPrevControlPoint(nIndex)); // use mirrored previous control point aPrevControl.setX((2.0 * aPrevPoint.getX()) - aPrevControlPoint.getX()); aPrevControl.setY((2.0 * aPrevPoint.getY()) - aPrevControlPoint.getY()); } // append curved edge aCurrPoly.appendBezierSegment(aPrevControl, B2DPoint(nX2, nY2), B2DPoint(nX, nY)); // set last position nLastX = nX; nLastY = nY; } break; } case 'c' : { bRelative = true; [[fallthrough]]; } case 'C' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; double nX1, nY1; double nX2, nY2; if(!basegfx::internal::importDoubleAndSpaces(nX1, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY1, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nX2, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY2, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX1 += nLastX; nY1 += nLastY; nX2 += nLastX; nY2 += nLastY; nX += nLastX; nY += nLastY; } // ensure existence of start point if(!aCurrPoly.count()) { aCurrPoly.append(B2DPoint(nLastX, nLastY)); } // append curved edge aCurrPoly.appendBezierSegment(B2DPoint(nX1, nY1), B2DPoint(nX2, nY2), B2DPoint(nX, nY)); // set last position nLastX = nX; nLastY = nY; } break; } // #100617# quadratic beziers are imported as cubic ones case 'q' : { bRelative = true; [[fallthrough]]; } case 'Q' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; double nX1, nY1; if(!basegfx::internal::importDoubleAndSpaces(nX1, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY1, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX1 += nLastX; nY1 += nLastY; nX += nLastX; nY += nLastY; } // ensure existence of start point if(!aCurrPoly.count()) { aCurrPoly.append(B2DPoint(nLastX, nLastY)); } // append curved edge aCurrPoly.appendQuadraticBezierSegment(B2DPoint(nX1, nY1), B2DPoint(nX, nY)); // set last position nLastX = nX; nLastY = nY; } break; } // #100617# relative quadratic beziers are imported as cubic case 't' : { bRelative = true; [[fallthrough]]; } case 'T' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX += nLastX; nY += nLastY; } // ensure existence of start point sal_uInt32 nCurrPolyCount = aCurrPoly.count(); if (nCurrPolyCount == 0) { aCurrPoly.append(B2DPoint(nLastX, nLastY)); nCurrPolyCount = 1; } assert(nCurrPolyCount > 0 && "coverity 2023.12.2"); // get first control point. It's the reflection of the PrevControlPoint // of the last point. If not existent, use current point (see SVG) B2DPoint aPrevControl(nLastX, nLastY); const sal_uInt32 nIndex(nCurrPolyCount - 1); const B2DPoint aPrevPoint(aCurrPoly.getB2DPoint(nIndex)); if(aCurrPoly.areControlPointsUsed() && aCurrPoly.isPrevControlPointUsed(nIndex)) { const B2DPoint aPrevControlPoint(aCurrPoly.getPrevControlPoint(nIndex)); // use mirrored previous control point aPrevControl.setX((2.0 * aPrevPoint.getX()) - aPrevControlPoint.getX()); aPrevControl.setY((2.0 * aPrevPoint.getY()) - aPrevControlPoint.getY()); } if(!aPrevControl.equal(aPrevPoint)) { // there is a prev control point, and we have the already mirrored one // in aPrevControl. We also need the quadratic control point for this // new quadratic segment to calculate the 2nd cubic control point const B2DPoint aQuadControlPoint( ((3.0 * aPrevControl.getX()) - aPrevPoint.getX()) / 2.0, ((3.0 * aPrevControl.getY()) - aPrevPoint.getY()) / 2.0); // calculate the cubic bezier coefficients from the quadratic ones. const double nX2Prime((aQuadControlPoint.getX() * 2.0 + nX) / 3.0); const double nY2Prime((aQuadControlPoint.getY() * 2.0 + nY) / 3.0); // append curved edge, use mirrored cubic control point directly aCurrPoly.appendBezierSegment(aPrevControl, B2DPoint(nX2Prime, nY2Prime), B2DPoint(nX, nY)); } else { // when no previous control, SVG says to use current point -> straight line. // Just add end point aCurrPoly.append(B2DPoint(nX, nY)); } // set last position nLastX = nX; nLastY = nY; } break; } case 'a' : { bRelative = true; [[fallthrough]]; } case 'A' : { nPos++; basegfx::internal::skipSpaces(nPos, rSvgDStatement, nLen); while(nPos < nLen && basegfx::internal::isOnNumberChar(rSvgDStatement, nPos)) { double nX, nY; double fRX, fRY, fPhi; sal_Int32 bLargeArcFlag, bSweepFlag; if(!basegfx::internal::importDoubleAndSpaces(fRX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(fRY, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(fPhi, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importFlagAndSpaces(bLargeArcFlag, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importFlagAndSpaces(bSweepFlag, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgDStatement, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgDStatement, nLen)) return false; if(bRelative) { nX += nLastX; nY += nLastY; } if( rtl::math::approxEqual(nX, nLastX) && rtl::math::approxEqual(nY, nLastY) ) continue; // start==end -> skip according to SVG spec if( fRX == 0.0 || fRY == 0.0 ) { // straight line segment according to SVG spec aCurrPoly.append(B2DPoint(nX, nY)); } else { // normalize according to SVG spec fRX=fabs(fRX); fRY=fabs(fRY); // from the SVG spec, appendix F.6.4 // |x1'| |cos phi sin phi| |(x1 - x2)/2| // |y1'| = |-sin phi cos phi| |(y1 - y2)/2| const B2DPoint p1(nLastX, nLastY); const B2DPoint p2(nX, nY); B2DHomMatrix aTransform(basegfx::utils::createRotateB2DHomMatrix( -deg2rad(fPhi))); const B2DPoint p1_prime( aTransform * B2DPoint(((p1-p2)/2.0)) ); // ______________________________________ rx y1' // |cx'| + / rx^2 ry^2 - rx^2 y1'^2 - ry^2 x1^2 ry // |cy'| =-/ rx^2y1'^2 + ry^2 x1'^2 - ry x1' // rx // chose + if f_A != f_S // chose - if f_A = f_S B2DPoint aCenter_prime; const double fRadicant( (fRX*fRX*fRY*fRY - fRX*fRX*p1_prime.getY()*p1_prime.getY() - fRY*fRY*p1_prime.getX()*p1_prime.getX())/ (fRX*fRX*p1_prime.getY()*p1_prime.getY() + fRY*fRY*p1_prime.getX()*p1_prime.getX())); if( fRadicant < 0.0 ) { // no solution - according to SVG // spec, scale up ellipse // uniformly such that it passes // through end points (denominator // of radicant solved for fRY, // with s=fRX/fRY) const double fRatio(fRX/fRY); fRY=std::hypot(p1_prime.getY(), p1_prime.getX()/fRatio); fRX=fRatio*fRY; // keep center_prime forced to (0,0) } else { const double fFactor( (bLargeArcFlag==bSweepFlag ? -1.0 : 1.0) * sqrt(fRadicant)); // actually calculate center_prime aCenter_prime = B2DPoint( fFactor*fRX*p1_prime.getY()/fRY, -fFactor*fRY*p1_prime.getX()/fRX); } // + u - v // angle(u,v) = arccos( ------------ ) (take the sign of (ux vy - uy vx)) // - ||u|| ||v|| // 1 | (x1' - cx')/rx | // theta1 = angle(( ), | | ) // 0 | (y1' - cy')/ry | const B2DPoint aRadii(fRX,fRY); double fTheta1( B2DVector(1.0,0.0).angle( (p1_prime-aCenter_prime)/aRadii)); // |1| | (-x1' - cx')/rx | // theta2 = angle( | | , | | ) // |0| | (-y1' - cy')/ry | double fTheta2( B2DVector(1.0,0.0).angle( (-p1_prime-aCenter_prime)/aRadii)); // map both angles to [0,2pi) fTheta1 = fmod(2*M_PI+fTheta1,2*M_PI); fTheta2 = fmod(2*M_PI+fTheta2,2*M_PI); // make sure the large arc is taken // (since // createPolygonFromEllipseSegment() // normalizes to e.g. cw arc) if( !bSweepFlag ) std::swap(fTheta1,fTheta2); // finally, create bezier polygon from this B2DPolygon aSegment( utils::createPolygonFromUnitEllipseSegment( fTheta1, fTheta2 )); // transform ellipse by rotation & move to final center aTransform = basegfx::utils::createScaleB2DHomMatrix(fRX, fRY); aTransform.translate(aCenter_prime.getX(), aCenter_prime.getY()); aTransform.rotate(deg2rad(fPhi)); const B2DPoint aOffset((p1+p2)/2.0); aTransform.translate(aOffset.getX(), aOffset.getY()); aSegment.transform(aTransform); // createPolygonFromEllipseSegment() // always creates arcs that are // positively oriented - flip polygon // if we swapped angles above if( !bSweepFlag ) aSegment.flip(); // remember PointIndex of evtl. added pure helper points sal_uInt32 nPointIndex(aCurrPoly.count() + 1); aCurrPoly.append(aSegment); // if asked for, mark pure helper points by adding them to the index list of // helper points if(pHelpPointIndexSet && aCurrPoly.count() > 1) { const sal_uInt32 nPolyIndex(o_rPolyPolygon.count()); for(;nPointIndex + 1 < aCurrPoly.count(); nPointIndex++) { pHelpPointIndexSet->insert(PointIndex(nPolyIndex, nPointIndex)); } } } // set last position nLastX = nX; nLastY = nY; } break; } default: { SAL_WARN("basegfx", "importFromSvgD(): skipping tags in svg:d element (unknown: \"" << OUString(aCurrChar) << "\")!"); ++nPos; break; } } } // if there is polygon data, create non-closed polygon if(aCurrPoly.count()) { o_rPolyPolygon.append(aCurrPoly); } return true; } bool importFromSvgPoints( B2DPolygon& o_rPoly, std::u16string_view rSvgPointsAttribute ) { o_rPoly.clear(); const sal_Int32 nLen(rSvgPointsAttribute.size()); sal_Int32 nPos(0); double nX, nY; // skip initial whitespace basegfx::internal::skipSpaces(nPos, rSvgPointsAttribute, nLen); while(nPos < nLen) { if(!basegfx::internal::importDoubleAndSpaces(nX, nPos, rSvgPointsAttribute, nLen)) return false; if(!basegfx::internal::importDoubleAndSpaces(nY, nPos, rSvgPointsAttribute, nLen)) return false; // add point o_rPoly.append(B2DPoint(nX, nY)); // skip to next number, or finish basegfx::internal::skipSpaces(nPos, rSvgPointsAttribute, nLen); } return true; } OUString exportToSvgPoints( const B2DPolygon& rPoly ) { SAL_WARN_IF(rPoly.areControlPointsUsed(), "basegfx", "exportToSvgPoints: Only non-bezier polygons allowed (!)"); const sal_uInt32 nPointCount(rPoly.count()); OUStringBuffer aResult; for(sal_uInt32 a(0); a < nPointCount; a++) { const basegfx::B2DPoint aPoint(rPoly.getB2DPoint(a)); if(a) { aResult.append(' '); } aResult.append(OUString::number(aPoint.getX()) + "," + OUString::number(aPoint.getY())); } return aResult.makeStringAndClear(); } OUString exportToSvgD( const B2DPolyPolygon& rPolyPolygon, bool bUseRelativeCoordinates, bool bDetectQuadraticBeziers, bool bHandleRelativeNextPointCompatible, bool bOOXMLMotionPath) { const sal_uInt32 nCount(rPolyPolygon.count()); sal_uInt32 nCombinedPointCount = 0; for(sal_uInt32 i(0); i < nCount; i++) { const B2DPolygon& aPolygon(rPolyPolygon.getB2DPolygon(i)); nCombinedPointCount += aPolygon.count(); } OUStringBuffer aResult(std::max(nCombinedPointCount * 32,512)); B2DPoint aCurrentSVGPosition(0.0, 0.0); // SVG assumes (0,0) as the initial current point for(sal_uInt32 i(0); i < nCount; i++) { const B2DPolygon& aPolygon(rPolyPolygon.getB2DPolygon(i)); const sal_uInt32 nPointCount(aPolygon.count()); if(nPointCount) { const bool bPolyUsesControlPoints(aPolygon.areControlPointsUsed()); const sal_uInt32 nEdgeCount(aPolygon.isClosed() ? nPointCount : nPointCount - 1); sal_Unicode aLastSVGCommand(' '); // last SVG command char B2DPoint aLeft, aRight; // for quadratic bezier test // handle polygon start point B2DPoint aEdgeStart(aPolygon.getB2DPoint(0)); bool bUseRelativeCoordinatesForFirstPoint(bUseRelativeCoordinates); if(bHandleRelativeNextPointCompatible) { // To get around the error that the start point for the next polygon is the // start point of the current one (and not the last as it was handled up to now) // do force to write an absolute 'M' command as start for the next polygon bUseRelativeCoordinatesForFirstPoint = false; } // Write 'moveto' and the 1st coordinates, set aLastSVGCommand to 'lineto' putCommandChar(aResult, aLastSVGCommand, 'M', bUseRelativeCoordinatesForFirstPoint, bOOXMLMotionPath); putNumberChar(aResult, aEdgeStart.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinatesForFirstPoint, bOOXMLMotionPath); putNumberChar(aResult, aEdgeStart.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinatesForFirstPoint, bOOXMLMotionPath); aLastSVGCommand = bUseRelativeCoordinatesForFirstPoint ? 'l' : 'L'; aCurrentSVGPosition = aEdgeStart; for(sal_uInt32 nIndex(0); nIndex < nEdgeCount; nIndex++) { // prepare access to next point const sal_uInt32 nNextIndex((nIndex + 1) % nPointCount); const B2DPoint aEdgeEnd(aPolygon.getB2DPoint(nNextIndex)); // handle edge from (aEdgeStart, aEdgeEnd) using indices (nIndex, nNextIndex) const bool bEdgeIsBezier(bPolyUsesControlPoints && (aPolygon.isNextControlPointUsed(nIndex) || aPolygon.isPrevControlPointUsed(nNextIndex))); if(bEdgeIsBezier) { // handle bezier edge const B2DPoint aControlEdgeStart(aPolygon.getNextControlPoint(nIndex)); const B2DPoint aControlEdgeEnd(aPolygon.getPrevControlPoint(nNextIndex)); bool bIsQuadraticBezier(false); // check continuity at current edge's start point. For SVG, do NOT use an // existing continuity since no 'S' or 's' statement should be written. At // import, that 'previous' control vector is not available. SVG documentation // says for interpretation: // "(If there is no previous command or if the previous command was // not a C, c, S or s, assume the first control point is coincident // with the current point.)" // That's what is done from our import, so avoid exporting it as first statement // is necessary. const bool bSymmetricAtEdgeStart( !bOOXMLMotionPath && nIndex != 0 && aPolygon.getContinuityInPoint(nIndex) == B2VectorContinuity::C2); if(bDetectQuadraticBeziers) { // check for quadratic beziers - that's // the case if both control points are in // the same place when they are prolonged // to the common quadratic control point // Left: P = (3P1 - P0) / 2 // Right: P = (3P2 - P3) / 2 aLeft = B2DPoint((3.0 * aControlEdgeStart - aEdgeStart) / 2.0); aRight= B2DPoint((3.0 * aControlEdgeEnd - aEdgeEnd) / 2.0); bIsQuadraticBezier = aLeft.equal(aRight); } if(bIsQuadraticBezier) { // approximately equal, export as quadratic bezier if(bSymmetricAtEdgeStart) { putCommandChar(aResult, aLastSVGCommand, 'T', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } else { putCommandChar(aResult, aLastSVGCommand, 'Q', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aLeft.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aLeft.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } } else { // export as cubic bezier if(bSymmetricAtEdgeStart) { putCommandChar(aResult, aLastSVGCommand, 'S', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } else { putCommandChar(aResult, aLastSVGCommand, 'C', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeStart.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeStart.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aControlEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } } } else { // straight edge if(nNextIndex == 0) { // it's a closed polygon's last edge and it's not a bezier edge, so there is // no need to write it } else { const bool bXEqual(rtl::math::approxEqual(aEdgeStart.getX(), aEdgeEnd.getX())); const bool bYEqual(rtl::math::approxEqual(aEdgeStart.getY(), aEdgeEnd.getY())); if(bXEqual && bYEqual) { // point is a double point; do not export at all } else if(bXEqual && !bOOXMLMotionPath) { // export as vertical line putCommandChar(aResult, aLastSVGCommand, 'V', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } else if(bYEqual && !bOOXMLMotionPath) { // export as horizontal line putCommandChar(aResult, aLastSVGCommand, 'H', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } else { // export as line putCommandChar(aResult, aLastSVGCommand, 'L', bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getX(), aCurrentSVGPosition.getX(), bUseRelativeCoordinates, bOOXMLMotionPath); putNumberChar(aResult, aEdgeEnd.getY(), aCurrentSVGPosition.getY(), bUseRelativeCoordinates, bOOXMLMotionPath); aCurrentSVGPosition = aEdgeEnd; } } } // prepare edge start for next loop step aEdgeStart = aEdgeEnd; } // close path if closed poly (Z and z are equivalent here, but looks nicer when case is matched) if(aPolygon.isClosed()) { putCommandChar(aResult, aLastSVGCommand, 'Z', bUseRelativeCoordinates, bOOXMLMotionPath); } else if (bOOXMLMotionPath) { putCommandChar(aResult, aLastSVGCommand, 'E', bUseRelativeCoordinates, bOOXMLMotionPath); } if(!bHandleRelativeNextPointCompatible) { // SVG defines that "the next subpath starts at the same initial point as the current subpath", // so set aCurrentSVGPosition to the 1st point of the current, now ended and written path aCurrentSVGPosition = aPolygon.getB2DPoint(0); } } } return aResult.makeStringAndClear(); } } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */