/* -*- 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 namespace chart { using namespace ::com::sun::star; using namespace ::com::sun::star::chart2; using ::com::sun::star::uno::Reference; using ::rtl::math::cos; using ::rtl::math::sin; using ::rtl::math::tan; namespace { bool lcl_isRightAngledAxesSetAndSupported( const rtl::Reference< Diagram >& xDiagram ) { if( xDiagram.is() ) { bool bRightAngledAxes = false; xDiagram->getPropertyValue( u"RightAngledAxes"_ustr) >>= bRightAngledAxes; if(bRightAngledAxes) { if( ChartTypeHelper::isSupportingRightAngledAxes( xDiagram->getChartTypeByIndex( 0 ) ) ) { return true; } } } return false; } } //end anonymous namespace drawing::CameraGeometry ThreeDHelper::getDefaultCameraGeometry( bool bPie ) { // ViewReferencePoint (Point on the View plane) drawing::Position3D vrp(17634.6218373783, 10271.4823817647, 24594.8639082739); // ViewPlaneNormal (Normal to the View Plane) drawing::Direction3D vpn(0.416199821709347, 0.173649045905254, 0.892537795986984); // ViewUpVector (determines the v-axis direction on the view plane as // projection of VUP parallel to VPN onto th view pane) drawing::Direction3D vup(-0.0733876362771618, 0.984807599917971, -0.157379306090273); if( bPie ) { vrp = drawing::Position3D( 0.0, 0.0, 87591.2408759124 );//--> 5 percent perspective vpn = drawing::Direction3D( 0.0, 0.0, 1.0 ); vup = drawing::Direction3D( 0.0, 1.0, 0.0 ); } return drawing::CameraGeometry( vrp, vpn, vup ); } namespace { void lcl_ensureIntervalMinus1To1( double& rSinOrCos ) { if (rSinOrCos < -1.0) rSinOrCos = -1.0; else if (rSinOrCos > 1.0) rSinOrCos = 1.0; } bool lcl_isSinZero( double fAngleRad ) { return ::basegfx::fTools::equalZero( sin(fAngleRad), 0.0000001 ); } bool lcl_isCosZero( double fAngleRad ) { return ::basegfx::fTools::equalZero( cos(fAngleRad), 0.0000001 ); } } void ThreeDHelper::convertElevationRotationDegToXYZAngleRad( sal_Int32 nElevationDeg, sal_Int32 nRotationDeg, double& rfXAngleRad, double& rfYAngleRad, double& rfZAngleRad) { // for a description of the algorithm see issue 72994 //https://bz.apache.org/ooo/show_bug.cgi?id=72994 //https://bz.apache.org/ooo/attachment.cgi?id=50608 nElevationDeg = NormAngle360(nElevationDeg); nRotationDeg = NormAngle360(nRotationDeg); double& x = rfXAngleRad; double& y = rfYAngleRad; double& z = rfZAngleRad; double E = basegfx::deg2rad(nElevationDeg); //elevation in Rad double R = basegfx::deg2rad(nRotationDeg); //rotation in Rad if( (nRotationDeg == 0 || nRotationDeg == 180 ) && ( nElevationDeg == 90 || nElevationDeg == 270 ) ) { //sR==0 && cE==0 z = 0.0; //element 23 double f23 = cos(R)*sin(E); if(f23>0) x = M_PI_2; else x = -M_PI_2; y = R; } else if( ( nRotationDeg == 90 || nRotationDeg == 270 ) && ( nElevationDeg == 90 || nElevationDeg == 270 ) ) { //cR==0 && cE==0 z = M_PI_2; if( sin(R)>0 ) x = M_PI_2; else x = -M_PI_2; if( (sin(R)*sin(E))>0 ) y = 0.0; else y = M_PI; } else if( (nRotationDeg == 0 || nRotationDeg == 180 ) && ( nElevationDeg == 0 || nElevationDeg == 180 ) ) { //sR==0 && sE==0 z = 0.0; y = R; x = E; } else if( ( nRotationDeg == 90 || nRotationDeg == 270 ) && ( nElevationDeg == 0 || nElevationDeg == 180 ) ) { //cR==0 && sE==0 z = 0.0; if( (sin(R)/cos(E))>0 ) y = M_PI_2; else y = -M_PI_2; if( (cos(E))>0 ) x = 0; else x = M_PI; } else if ( nElevationDeg == 0 || nElevationDeg == 180 ) { //sR!=0 cR!=0 sE==0 z = 0.0; x = E; y = R; //use element 13 for sign if((cos(x)*sin(y)*sin(R))<0.0) y *= -1.0; } else if ( nElevationDeg == 90 || nElevationDeg == 270 ) { //sR!=0 cR!=0 cE==0 //element 12 + 22 --> y=0 or M_PI and x=+-M_PI/2 //-->element 13/23: z = atan(sin(R)/(cos(R)*sin(E))); //use element 13 for sign for x if( (sin(R)*sin(z))>0.0 ) x = M_PI_2; else x = -M_PI_2; //use element 21 for y if( (sin(R)*sin(E)*sin(z))>0.0) y = 0.0; else y = M_PI; } else if ( nRotationDeg == 0 || nRotationDeg == 180 ) { //sE!=0 cE!=0 sR==0 z = 0.0; x = E; y = R; double f23 = cos(R)*sin(E); if( (f23 * sin(x)) < 0.0 ) x *= -1.0; //todo ?? } else if (nRotationDeg == 90 || nRotationDeg == 270) { //sE!=0 cE!=0 cR==0 //z = +- M_PI/2; //x = +- M_PI/2; z = M_PI_2; x = M_PI_2; double sR = sin(R); if( sR<0.0 ) x *= -1.0; //different signs for x and z //use element 21: double cy = sR*sin(E)/sin(z); lcl_ensureIntervalMinus1To1(cy); y = acos(cy); //use element 22 for sign: if( (sin(x)*sin(y)*sin(z)*cos(E))<0.0) y *= -1.0; } else { z = atan(tan(R) * sin(E)); if(cos(z)==0.0) { OSL_FAIL("calculation error in ThreeDHelper::convertElevationRotationDegToXYZAngleRad"); return; } double cy = cos(R)/cos(z); lcl_ensureIntervalMinus1To1(cy); y = acos(cy); //element 12 in 23 double fDenominator = cos(z)*(1.0-pow(sin(y),2)); if(fDenominator==0.0) { OSL_FAIL("calculation error in ThreeDHelper::convertElevationRotationDegToXYZAngleRad"); return; } double sx = cos(R)*sin(E)/fDenominator; lcl_ensureIntervalMinus1To1(sx); x = asin( sx ); //use element 13 for sign: double f13a = cos(x)*cos(z)*sin(y); double f13b = sin(R)-sx*sin(z); if( (f13b*f13a)<0.0 ) { //change x or y //use element 22 for further investigations: //try y *= -1; double f22a = cos(x)*cos(z); double f22b = cos(E)-(sx*sin(y)*sin(z)); if( (f22a*f22b)<0.0 ) { y *= -1; x=(M_PI-x); } } else { //change nothing or both //use element 22 for further investigations: double f22a = cos(x)*cos(z); double f22b = cos(E)-(sx*sin(y)*sin(z)); if( (f22a*f22b)<0.0 ) { y *= -1; x=(M_PI-x); } } } } void ThreeDHelper::convertXYZAngleRadToElevationRotationDeg( sal_Int32& rnElevationDeg, sal_Int32& rnRotationDeg, double fXRad, double fYRad, double fZRad) { // for a description of the algorithm see issue 72994 //https://bz.apache.org/ooo/show_bug.cgi?id=72994 //https://bz.apache.org/ooo/attachment.cgi?id=50608 double R = 0.0; //Rotation in Rad double E = 0.0; //Elevation in Rad double& x = fXRad; double& y = fYRad; double& z = fZRad; double f11 = cos(y)*cos(z); if( lcl_isSinZero(y) ) { //siny == 0 if( lcl_isCosZero(x) ) { //siny == 0 && cosx == 0 if( lcl_isSinZero(z) ) { //siny == 0 && cosx == 0 && sinz == 0 //example: x=+-90 y=0oder180 z=0(oder180) //element 13+11 if( f11 > 0 ) R = 0.0; else R = M_PI; //element 23 double f23 = cos(z)*sin(x) / cos(R); if( f23 > 0 ) E = M_PI_2; else E = -M_PI_2; } else if( lcl_isCosZero(z) ) { //siny == 0 && cosx == 0 && cosz == 0 //example: x=+-90 y=0oder180 z=+-90 double f13 = sin(x)*sin(z); //element 13+11 if( f13 > 0 ) R = M_PI_2; else R = -M_PI_2; //element 21 double f21 = cos(y)*sin(z) / sin(R); if( f21 > 0 ) E = M_PI_2; else E = -M_PI_2; } else { //siny == 0 && cosx == 0 && cosz != 0 && sinz != 0 //element 11 && 13 double f13 = sin(x)*sin(z); R = atan( f13/f11 ); if(f11<0) R+=M_PI; //element 23 double f23 = cos(z)*sin(x); if( f23/cos(R) > 0 ) E = M_PI_2; else E = -M_PI_2; } } else if( lcl_isSinZero(x) ) { //sinY==0 sinX==0 //element 13+11 if( f11 > 0 ) R = 0.0; else R = M_PI; double f22 = cos(x)*cos(z); if( f22 > 0 ) E = 0.0; else E = M_PI; } else if( lcl_isSinZero(z) ) { //sinY==0 sinZ==0 sinx!=0 cosx!=0 //element 13+11 if( f11 > 0 ) R = 0.0; else R = M_PI; //element 22 && 23 double f22 = cos(x)*cos(z); double f23 = cos(z)*sin(x); E = atan( f23/(f22*cos(R)) ); if( (f22*cos(E))<0 ) E+=M_PI; } else if( lcl_isCosZero(z) ) { //sinY == 0 && cosZ == 0 && cosx != 0 && sinx != 0 double f13 = sin(x)*sin(z); //element 13+11 if( f13 > 0 ) R = M_PI_2; else R = -M_PI_2; //element 21+22 double f21 = cos(y)*sin(z); if( f21/sin(R) > 0 ) E = M_PI_2; else E = -M_PI_2; } else { //sinY == 0 && all other !=0 double f13 = sin(x)*sin(z); R = atan( f13/f11 ); if( (f11*cos(R))<0.0 ) R+=M_PI; double f22 = cos(x)*cos(z); if( !lcl_isCosZero(R) ) E = atan( cos(z)*sin(x) /( f22*cos(R) ) ); else E = atan( cos(y)*sin(z) /( f22*sin(R) ) ); if( (f22*cos(E))<0 ) E+=M_PI; } } else if( lcl_isCosZero(y) ) { //cosY==0 double f13 = sin(x)*sin(z)+cos(x)*cos(z)*sin(y); if( f13 >= 0 ) R = M_PI_2; else R = -M_PI_2; double f22 = cos(x)*cos(z)+sin(x)*sin(y)*sin(z); if( f22 >= 0 ) E = 0.0; else E = M_PI; } else if( lcl_isSinZero(x) ) { //cosY!=0 sinY!=0 sinX=0 if( lcl_isSinZero(z) ) { //cosY!=0 sinY!=0 sinX=0 sinZ=0 double f13 = cos(x)*cos(z)*sin(y); R = atan( f13/f11 ); //R = asin(f13); if( f11<0 ) R+=M_PI; double f22 = cos(x)*cos(z); if( f22>0 ) E = 0.0; else E = M_PI; } else if( lcl_isCosZero(z) ) { //cosY!=0 sinY!=0 sinX=0 cosZ=0 R = x; E = y;//or -y //use 23 for 'signs' double f23 = -1.0*cos(x)*sin(y)*sin(z); if( (f23*cos(R)*sin(E))<0.0 ) { //change R or E E = -y; } } else { //cosY!=0 sinY!=0 sinX=0 sinZ!=0 cosZ!=0 double f13 = cos(x)*cos(z)*sin(y); R = atan( f13/f11 ); if( f11<0 ) R+=M_PI; double f21 = cos(y)*sin(z); double f22 = cos(x)*cos(z); E = atan(f21/(f22*sin(R)) ); if( (f22*cos(E))<0.0 ) E+=M_PI; } } else if( lcl_isCosZero(x) ) { //cosY!=0 sinY!=0 cosX=0 if( lcl_isSinZero(z) ) { //cosY!=0 sinY!=0 cosX=0 sinZ=0 R=0;//13 -> R=0 or M_PI if( f11<0.0 ) R=M_PI; E=M_PI_2;//22 -> E=+-M_PI/2 //use element 11 and 23 for sign double f23 = cos(z)*sin(x); if( (f11*f23*sin(E))<0.0 ) E=-M_PI_2; } else if( lcl_isCosZero(z) ) { //cosY!=0 sinY!=0 cosX=0 cosZ=0 //element 11 & 13: if( (sin(x)*sin(z))>0.0 ) R=M_PI_2; else R=-M_PI_2; //element 22: E=acos( sin(x)*sin(y)*sin(z)); //use element 21 for sign: if( (cos(y)*sin(z)*sin(R)*sin(E))<0.0 ) E*=-1.0; } else { //cosY!=0 sinY!=0 cosX=0 sinZ!=0 cosZ!=0 //element 13/11 R = atan( sin(x)*sin(z)/(cos(y)*cos(z)) ); //use 13 for 'sign' if( (sin(x)*sin(z))<0.0 ) R += M_PI; //element 22 E = acos(sin(x)*sin(y)*sin(z) ); //use 21 for sign if( (cos(y)*sin(z)*sin(R)*sin(E))<0.0 ) E*=-1.0; } } else if( lcl_isSinZero(z) ) { //cosY!=0 sinY!=0 sinX!=0 cosX!=0 sinZ=0 //element 11 R=y; //use element 13 for sign if( (cos(x)*cos(z)*sin(y)*sin(R))<0.0 ) R*=-1.0; //element 22 E = acos( cos(x)*cos(z) ); //use element 23 for sign if( (cos(z)*sin(x)*cos(R)*sin(E))<0.0 ) E*=-1.0; } else if( lcl_isCosZero(z) ) { //cosY!=0 sinY!=0 sinX!=0 cosX!=0 cosZ=0 //element 21/23 R=atan(-cos(y)/(cos(x)*sin(y))); //use element 13 for 'sign' if( (sin(x)*sin(z)*sin(R))<0.0 ) R+=M_PI; //element 21/22 E=atan( cos(y)*sin(z)/(sin(R)*sin(x)*sin(y)*sin(z)) ); //use element 23 for 'sign' if( (-cos(x)*sin(y)*sin(z)*cos(R)*sin(E))<0.0 ) E+=M_PI; } else { //cosY!=0 sinY!=0 sinX!=0 cosX!=0 sinZ!=0 cosZ!=0 //13/11: double f13 = sin(x)*sin(z)+cos(x)*cos(z)*sin(y); R = atan( f13/ f11 ); if(f11<0.0) R+=M_PI; double f22 = cos(x)*cos(z)+sin(x)*sin(y)*sin(z); double f23 = cos(x)*sin(y)*sin(z)-cos(z)*sin(x); //23/22: E = atan( -1.0*f23/(f22*cos(R)) ); if(f22<0.0) E+=M_PI; } rnElevationDeg = basegfx::fround(basegfx::rad2deg(E)); rnRotationDeg = basegfx::fround(basegfx::rad2deg(R)); } double ThreeDHelper::getValueClippedToRange( double fAngle, const double& fPositivLimit ) { if( fAngle<-1*fPositivLimit ) fAngle=-1*fPositivLimit; else if( fAngle>fPositivLimit ) fAngle=fPositivLimit; return fAngle; } void ThreeDHelper::adaptRadAnglesForRightAngledAxes( double& rfXAngleRad, double& rfYAngleRad ) { rfXAngleRad = ThreeDHelper::getValueClippedToRange(rfXAngleRad, basegfx::deg2rad(ThreeDHelper::getXDegreeAngleLimitForRightAngledAxes()) ); rfYAngleRad = ThreeDHelper::getValueClippedToRange(rfYAngleRad, basegfx::deg2rad(ThreeDHelper::getYDegreeAngleLimitForRightAngledAxes()) ); } void ThreeDHelper::getCameraDistanceRange( double& rfMinimumDistance, double& rfMaximumDistance ) { rfMinimumDistance = 3.0/4.0*FIXED_SIZE_FOR_3D_CHART_VOLUME;//empiric value rfMaximumDistance = 20.0*FIXED_SIZE_FOR_3D_CHART_VOLUME;//empiric value } void ThreeDHelper::ensureCameraDistanceRange( double& rfCameraDistance ) { double fMin, fMax; getCameraDistanceRange( fMin, fMax ); if( rfCameraDistance < fMin ) rfCameraDistance = fMin; if( rfCameraDistance > fMax ) rfCameraDistance = fMax; } double ThreeDHelper::CameraDistanceToPerspective( double fCameraDistance ) { double fMin, fMax; ThreeDHelper::getCameraDistanceRange( fMin, fMax ); //fMax <-> 0; fMin <->100 //a/x + b = y double a = 100.0*fMax*fMin/(fMax-fMin); double b = -a/fMax; double fRet = a/fCameraDistance + b; return fRet; } double ThreeDHelper::PerspectiveToCameraDistance( double fPerspective ) { double fMin, fMax; ThreeDHelper::getCameraDistanceRange( fMin, fMax ); //fMax <-> 0; fMin <->100 //a/x + b = y double a = 100.0*fMax*fMin/(fMax-fMin); double b = -a/fMax; double fRet = a/(fPerspective - b); return fRet; } void ThreeDHelper::getRoundedEdgesAndObjectLines( const rtl::Reference< Diagram > & xDiagram , sal_Int32& rnRoundedEdges, sal_Int32& rnObjectLines ) { rnRoundedEdges = -1; rnObjectLines = -1; try { bool bDifferentRoundedEdges = false; bool bDifferentObjectLines = false; drawing::LineStyle aLineStyle( drawing::LineStyle_SOLID ); std::vector< rtl::Reference< DataSeries > > aSeriesList = xDiagram->getDataSeries(); sal_Int32 nSeriesCount = static_cast( aSeriesList.size() ); OUString aPercentDiagonalPropertyName( u"PercentDiagonal"_ustr ); OUString aBorderStylePropertyName( u"BorderStyle"_ustr ); for( sal_Int32 nS = 0; nS < nSeriesCount; ++nS ) { const rtl::Reference< DataSeries >& xSeries( aSeriesList[nS] ); if(!nS) { rnRoundedEdges = 0; try { sal_Int16 nPercentDiagonal = 0; xSeries->getPropertyValue( aPercentDiagonalPropertyName ) >>= nPercentDiagonal; rnRoundedEdges = static_cast< sal_Int32 >( nPercentDiagonal ); if( DataSeriesHelper::hasAttributedDataPointDifferentValue( xSeries , aPercentDiagonalPropertyName, uno::Any(nPercentDiagonal) ) ) bDifferentRoundedEdges = true; } catch( const uno::Exception& ) { TOOLS_WARN_EXCEPTION("chart2", "" ); bDifferentRoundedEdges = true; } try { xSeries->getPropertyValue( aBorderStylePropertyName ) >>= aLineStyle; if( DataSeriesHelper::hasAttributedDataPointDifferentValue( xSeries , aBorderStylePropertyName, uno::Any(aLineStyle) ) ) bDifferentObjectLines = true; } catch( const uno::Exception& ) { TOOLS_WARN_EXCEPTION("chart2", "" ); bDifferentObjectLines = true; } } else { if( !bDifferentRoundedEdges ) { sal_Int16 nPercentDiagonal = 0; xSeries->getPropertyValue( aPercentDiagonalPropertyName ) >>= nPercentDiagonal; sal_Int32 nCurrentRoundedEdges = static_cast< sal_Int32 >( nPercentDiagonal ); if(nCurrentRoundedEdges!=rnRoundedEdges || DataSeriesHelper::hasAttributedDataPointDifferentValue( xSeries , aPercentDiagonalPropertyName, uno::Any( static_cast< sal_Int16 >(rnRoundedEdges) ) ) ) { bDifferentRoundedEdges = true; } } if( !bDifferentObjectLines ) { drawing::LineStyle aCurrentLineStyle; xSeries->getPropertyValue( aBorderStylePropertyName ) >>= aCurrentLineStyle; if(aCurrentLineStyle!=aLineStyle || DataSeriesHelper::hasAttributedDataPointDifferentValue( xSeries , aBorderStylePropertyName, uno::Any(aLineStyle) ) ) bDifferentObjectLines = true; } } if( bDifferentRoundedEdges && bDifferentObjectLines ) break; } //set rnObjectLines rnObjectLines = 0; if( bDifferentObjectLines ) rnObjectLines = -1; else if( aLineStyle == drawing::LineStyle_SOLID ) rnObjectLines = 1; } catch( const uno::Exception& ) { TOOLS_WARN_EXCEPTION("chart2", "" ); } } void ThreeDHelper::setRoundedEdgesAndObjectLines( const rtl::Reference< Diagram > & xDiagram , sal_Int32 nRoundedEdges, sal_Int32 nObjectLines ) { if( (nRoundedEdges<0||nRoundedEdges>100) && nObjectLines!=0 && nObjectLines!=1 ) return; drawing::LineStyle aLineStyle( drawing::LineStyle_NONE ); if(nObjectLines==1) aLineStyle = drawing::LineStyle_SOLID; uno::Any aALineStyle( aLineStyle); uno::Any aARoundedEdges( static_cast< sal_Int16 >( nRoundedEdges )); std::vector< rtl::Reference< DataSeries > > aSeriesList = xDiagram->getDataSeries(); for( auto const& xSeries : aSeriesList) { if( nRoundedEdges>=0 && nRoundedEdges<=100 ) DataSeriesHelper::setPropertyAlsoToAllAttributedDataPoints( xSeries, u"PercentDiagonal"_ustr, aARoundedEdges ); if( nObjectLines==0 || nObjectLines==1 ) DataSeriesHelper::setPropertyAlsoToAllAttributedDataPoints( xSeries, u"BorderStyle"_ustr, aALineStyle ); } } CuboidPlanePosition ThreeDHelper::getAutomaticCuboidPlanePositionForStandardLeftWall( const rtl::Reference< ::chart::Diagram >& xDiagram ) { CuboidPlanePosition eRet(CuboidPlanePosition_Left); double fXAngleRad=0.0; double fYAngleRad=0.0; double fZAngleRad=0.0; xDiagram->getRotationAngle( fXAngleRad, fYAngleRad, fZAngleRad ); if( lcl_isRightAngledAxesSetAndSupported( xDiagram ) ) { ThreeDHelper::adaptRadAnglesForRightAngledAxes( fXAngleRad, fYAngleRad ); } if( sin(fYAngleRad)>0.0 ) eRet = CuboidPlanePosition_Right; return eRet; } CuboidPlanePosition ThreeDHelper::getAutomaticCuboidPlanePositionForStandardBackWall( const rtl::Reference< Diagram >& xDiagram ) { CuboidPlanePosition eRet(CuboidPlanePosition_Back); double fXAngleRad=0.0; double fYAngleRad=0.0; double fZAngleRad=0.0; xDiagram->getRotationAngle( fXAngleRad, fYAngleRad, fZAngleRad ); if( lcl_isRightAngledAxesSetAndSupported( xDiagram ) ) { ThreeDHelper::adaptRadAnglesForRightAngledAxes( fXAngleRad, fYAngleRad ); } if( cos(fXAngleRad)*cos(fYAngleRad)<0.0 ) eRet = CuboidPlanePosition_Front; return eRet; } CuboidPlanePosition ThreeDHelper::getAutomaticCuboidPlanePositionForStandardBottom( const rtl::Reference< Diagram >& xDiagram ) { CuboidPlanePosition eRet(CuboidPlanePosition_Bottom); double fXAngleRad=0.0; double fYAngleRad=0.0; double fZAngleRad=0.0; xDiagram->getRotationAngle( fXAngleRad, fYAngleRad, fZAngleRad ); if( lcl_isRightAngledAxesSetAndSupported( xDiagram ) ) { ThreeDHelper::adaptRadAnglesForRightAngledAxes( fXAngleRad, fYAngleRad ); } if( sin(fXAngleRad)*cos(fYAngleRad)<0.0 ) eRet = CuboidPlanePosition_Top; return eRet; } } //namespace chart /* vim:set shiftwidth=4 softtabstop=4 expandtab: */