/* -*- 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 #include #include #include #include #include #include #include #include #include #include using namespace ::com::sun::star; using namespace ::com::sun::star::uno; using namespace ::com::sun::star::drawing; using namespace ::com::sun::star::drawing::EnhancedCustomShapeSegmentCommand; void EnhancedCustomShape2d::SetEnhancedCustomShapeParameter( EnhancedCustomShapeParameter& rParameter, const sal_Int32 nValue ) { sal_uInt32 nDat = static_cast(nValue); sal_Int32 nNewValue = nValue; // check if this is a special point if ( ( nDat >> 16 ) == 0x8000 ) { nNewValue = static_cast(nDat); rParameter.Type = EnhancedCustomShapeParameterType::EQUATION; } else rParameter.Type = EnhancedCustomShapeParameterType::NORMAL; rParameter.Value <<= nNewValue; } OUString EnhancedCustomShape2d::GetEquation( const sal_uInt16 nFlags, sal_Int32 nP1, sal_Int32 nP2, sal_Int32 nP3 ) { OUString aEquation; bool b1Special = ( nFlags & 0x2000 ) != 0; bool b2Special = ( nFlags & 0x4000 ) != 0; bool b3Special = ( nFlags & 0x8000 ) != 0; switch( nFlags & 0xff ) { case 0 : case 14 : { sal_Int32 nOptimize = 0; if ( nP1 ) nOptimize |= 1; if ( nP2 ) nOptimize |= 2; if ( b1Special ) nOptimize |= 4; if ( b2Special ) nOptimize |= 8; switch( nOptimize ) { case 0 : break; case 1 : case 4 : case 5 : EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); break; case 2 : case 8 : case 10: EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); break; default : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "+"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); } break; } if ( b3Special || nP3 ) { aEquation += "-"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); } } break; case 1 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); if ( b2Special || ( nP2 != 1 ) ) { aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); } if ( b3Special || ( ( nP3 != 1 ) && ( nP3 != 0 ) ) ) { aEquation += "/"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); } } break; case 2 : { aEquation += "("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "+"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ")/2"; } break; case 3 : { aEquation += "abs("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ")"; } break; case 4 : { aEquation += "min("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ")"; } break; case 5 : { aEquation += "max("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ")"; } break; case 6 : { aEquation += "if("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += ")"; } break; case 7 : { aEquation += "sqrt("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "+"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "+"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += ")"; } break; case 8 : { aEquation += "atan2("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ")/(pi/180)"; } break; case 9 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*sin("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "*(pi/180))"; } break; case 10 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*cos("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "*(pi/180))"; } break; case 11 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*cos(atan2("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "))"; } break; case 12 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*sin(atan2("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += ","; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "))"; } break; case 13 : { aEquation += "sqrt("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ")"; } break; case 15 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*sqrt(1-("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "/"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ")" "*("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "/"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "))"; } break; case 16 : { EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*tan("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += ")"; } break; case 0x80 : { aEquation += "sqrt("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "-"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "*"; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += ")"; } break; case 0x81 : { aEquation += "(cos("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*(pi/180))*("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "-10800)+sin("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*(pi/180))*("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "-10800))+10800"; } break; case 0x82 : { aEquation += "-(sin("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*(pi/180))*("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP1, b1Special ); aEquation += "-10800)-cos("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP3, b3Special ); aEquation += "*(pi/180))*("; EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( aEquation, nP2, b2Special ); aEquation += "-10800))+10800"; } break; } return aEquation; } void EnhancedCustomShape2d::AppendEnhancedCustomShapeEquationParameter( OUString& rParameter, const sal_Int32 nPara, const bool bIsSpecialValue ) { if ( bIsSpecialValue ) { if ( nPara & 0x400 ) { rParameter += "?"; rParameter += OUString::number( ( nPara & 0xff ) ); rParameter += " "; } else { switch( nPara ) { case DFF_Prop_adjustValue : case DFF_Prop_adjust2Value : case DFF_Prop_adjust3Value : case DFF_Prop_adjust4Value : case DFF_Prop_adjust5Value : case DFF_Prop_adjust6Value : case DFF_Prop_adjust7Value : case DFF_Prop_adjust8Value : case DFF_Prop_adjust9Value : case DFF_Prop_adjust10Value : { rParameter += "$"; rParameter += OUString::number( ( nPara - DFF_Prop_adjustValue ) ); rParameter += " "; } break; case DFF_Prop_geoLeft : { rParameter += "left"; } break; case DFF_Prop_geoTop : { rParameter += "top"; } break; case DFF_Prop_geoRight : { rParameter += "right"; } break; case DFF_Prop_geoBottom : { rParameter += "bottom"; } break; } } } else { rParameter += OUString::number( nPara ); } } void EnhancedCustomShape2d::SetEnhancedCustomShapeHandleParameter( EnhancedCustomShapeParameter& rParameter, const sal_Int32 nPara, const bool bIsSpecialValue, bool bHorz ) { sal_Int32 nValue = 0; if ( bIsSpecialValue ) { if ( ( nPara >= 0x100 ) && ( nPara <= 0x107 ) ) { nValue = nPara & 0xff; rParameter.Type = EnhancedCustomShapeParameterType::ADJUSTMENT; } else if ( ( nPara >= 3 ) && ( nPara <= 0x82 ) ) { nValue = nPara - 3; rParameter.Type = EnhancedCustomShapeParameterType::EQUATION; } else if ( nPara == 0 ) { nValue = 0; if ( bHorz ) rParameter.Type = EnhancedCustomShapeParameterType::LEFT; else rParameter.Type = EnhancedCustomShapeParameterType::TOP; } else if ( nPara == 1 ) { nValue = 0; if ( bHorz ) rParameter.Type = EnhancedCustomShapeParameterType::RIGHT; else rParameter.Type = EnhancedCustomShapeParameterType::BOTTOM; } else if ( nPara == 2 ) // means to be centered, but should not be { // used in our implementation nValue = 5600; rParameter.Type = EnhancedCustomShapeParameterType::NORMAL; } else { nValue = nPara; rParameter.Type = EnhancedCustomShapeParameterType::NORMAL; } } else { nValue = nPara; rParameter.Type = EnhancedCustomShapeParameterType::NORMAL; } rParameter.Value <<= nValue; } bool EnhancedCustomShape2d::ConvertSequenceToEnhancedCustomShape2dHandle( const css::beans::PropertyValues& rHandleProperties, EnhancedCustomShape2d::Handle& rDestinationHandle ) { bool bRetValue = false; if ( rHandleProperties.hasElements() ) { rDestinationHandle.nFlags = HandleFlags::NONE; for ( const css::beans::PropertyValue& rPropVal : rHandleProperties ) { if ( rPropVal.Name == "Position" ) { if ( rPropVal.Value >>= rDestinationHandle.aPosition ) bRetValue = true; } else if ( rPropVal.Name == "MirroredX" ) { bool bMirroredX; if ( rPropVal.Value >>= bMirroredX ) { if ( bMirroredX ) rDestinationHandle.nFlags |= HandleFlags::MIRRORED_X; } } else if ( rPropVal.Name == "MirroredY" ) { bool bMirroredY; if ( rPropVal.Value >>= bMirroredY ) { if ( bMirroredY ) rDestinationHandle.nFlags |= HandleFlags::MIRRORED_Y; } } else if ( rPropVal.Name == "Switched" ) { bool bSwitched; if ( rPropVal.Value >>= bSwitched ) { if ( bSwitched ) rDestinationHandle.nFlags |= HandleFlags::SWITCHED; } } else if ( rPropVal.Name == "Polar" ) { if ( rPropVal.Value >>= rDestinationHandle.aPolar ) rDestinationHandle.nFlags |= HandleFlags::POLAR; } else if ( rPropVal.Name == "RefX" ) { if ( rPropVal.Value >>= rDestinationHandle.nRefX ) rDestinationHandle.nFlags |= HandleFlags::REFX; } else if ( rPropVal.Name == "RefY" ) { if ( rPropVal.Value >>= rDestinationHandle.nRefY ) rDestinationHandle.nFlags |= HandleFlags::REFY; } else if ( rPropVal.Name == "RefAngle" ) { if ( rPropVal.Value >>= rDestinationHandle.nRefAngle ) rDestinationHandle.nFlags |= HandleFlags::REFANGLE; } else if ( rPropVal.Name == "RefR" ) { if ( rPropVal.Value >>= rDestinationHandle.nRefR ) rDestinationHandle.nFlags |= HandleFlags::REFR; } else if ( rPropVal.Name == "RadiusRangeMinimum" ) { if ( rPropVal.Value >>= rDestinationHandle.aRadiusRangeMinimum ) rDestinationHandle.nFlags |= HandleFlags::RADIUS_RANGE_MINIMUM; } else if ( rPropVal.Name == "RadiusRangeMaximum" ) { if ( rPropVal.Value >>= rDestinationHandle.aRadiusRangeMaximum ) rDestinationHandle.nFlags |= HandleFlags::RADIUS_RANGE_MAXIMUM; } else if ( rPropVal.Name == "RangeXMinimum" ) { if ( rPropVal.Value >>= rDestinationHandle.aXRangeMinimum ) rDestinationHandle.nFlags |= HandleFlags::RANGE_X_MINIMUM; } else if ( rPropVal.Name == "RangeXMaximum" ) { if ( rPropVal.Value >>= rDestinationHandle.aXRangeMaximum ) rDestinationHandle.nFlags |= HandleFlags::RANGE_X_MAXIMUM; } else if ( rPropVal.Name == "RangeYMinimum" ) { if ( rPropVal.Value >>= rDestinationHandle.aYRangeMinimum ) rDestinationHandle.nFlags |= HandleFlags::RANGE_Y_MINIMUM; } else if ( rPropVal.Name == "RangeYMaximum" ) { if ( rPropVal.Value >>= rDestinationHandle.aYRangeMaximum ) rDestinationHandle.nFlags |= HandleFlags::RANGE_Y_MAXIMUM; } } } return bRetValue; } void EnhancedCustomShape2d::ApplyShapeAttributes( const SdrCustomShapeGeometryItem& rGeometryItem ) { // AdjustmentValues const Any* pAny = const_cast(rGeometryItem).GetPropertyValueByName( "AdjustmentValues" ); if ( pAny ) *pAny >>= seqAdjustmentValues; // Coordsize const Any* pViewBox = const_cast(rGeometryItem).GetPropertyValueByName( "ViewBox" ); css::awt::Rectangle aViewBox; if ( pViewBox && (*pViewBox >>= aViewBox ) ) { nCoordLeft = aViewBox.X; nCoordTop = aViewBox.Y; nCoordWidthG = labs( aViewBox.Width ); nCoordHeightG = labs( aViewBox.Height); } const OUString sPath( "Path" ); // Path/Coordinates pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "Coordinates" ); if ( pAny ) *pAny >>= seqCoordinates; // Path/GluePoints pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "GluePoints" ); if ( pAny ) *pAny >>= seqGluePoints; // Path/Segments pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "Segments" ); if ( pAny ) *pAny >>= seqSegments; // Path/SubViewSize pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "SubViewSize" ); if ( pAny ) *pAny >>= seqSubViewSize; // Path/StretchX pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "StretchX" ); if ( pAny ) { sal_Int32 nStretchX = 0; if ( *pAny >>= nStretchX ) nXRef = nStretchX; } // Path/StretchY pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "StretchY" ); if ( pAny ) { sal_Int32 nStretchY = 0; if ( *pAny >>= nStretchY ) nYRef = nStretchY; } // Path/TextFrames pAny = const_cast(rGeometryItem).GetPropertyValueByName( sPath, "TextFrames" ); if ( pAny ) *pAny >>= seqTextFrames; // Equations pAny = const_cast(rGeometryItem).GetPropertyValueByName( "Equations" ); if ( pAny ) *pAny >>= seqEquations; // Handles pAny = const_cast(rGeometryItem).GetPropertyValueByName( "Handles" ); if ( pAny ) *pAny >>= seqHandles; } EnhancedCustomShape2d::~EnhancedCustomShape2d() { } void EnhancedCustomShape2d::SetPathSize( sal_Int32 nIndex ) { sal_Int32 nWidth = 0; sal_Int32 nHeight = 0; if ( seqSubViewSize.hasElements() && nIndex < seqSubViewSize.getLength() ) { nWidth = seqSubViewSize[ nIndex ].Width; nHeight = seqSubViewSize[ nIndex ].Height; SAL_INFO( "svx", "set subpath " << nIndex << " size: " << nWidth << " x " << nHeight); } if ( nWidth && nHeight ) { nCoordWidth = nWidth; nCoordHeight = nHeight; } else { nCoordWidth = nCoordWidthG; nCoordHeight = nCoordHeightG; } fXScale = nCoordWidth == 0 ? 0.0 : static_cast(aLogicRect.GetWidth()) / static_cast(nCoordWidth); fYScale = nCoordHeight == 0 ? 0.0 : static_cast(aLogicRect.GetHeight()) / static_cast(nCoordHeight); if ( bOOXMLShape ) { SAL_INFO( "svx", "ooxml shape, path width: " << nCoordWidth << " height: " << nCoordHeight); // Try to set up scale separately, if given only width or height // This is possible case in OOXML when only width or height is non-zero if ( nCoordWidth == 0 ) { if ( nWidth ) fXScale = static_cast(aLogicRect.GetWidth()) / static_cast(nWidth); else fXScale = 1.0; } if ( nCoordHeight == 0 ) { if ( nHeight ) fYScale = static_cast(aLogicRect.GetHeight()) / static_cast(nHeight); else fYScale = 1.0; } } if ( static_cast(nXRef) != 0x80000000 && aLogicRect.GetHeight() ) { fXRatio = static_cast(aLogicRect.GetWidth()) / static_cast(aLogicRect.GetHeight()); if ( fXRatio > 1 ) fXScale /= fXRatio; else fXRatio = 1.0; } else fXRatio = 1.0; if ( static_cast(nYRef) != 0x80000000 && aLogicRect.GetWidth() ) { fYRatio = static_cast(aLogicRect.GetHeight()) / static_cast(aLogicRect.GetWidth()); if ( fYRatio > 1 ) fYScale /= fYRatio; else fYRatio = 1.0; } else fYRatio = 1.0; } EnhancedCustomShape2d::EnhancedCustomShape2d(SdrObjCustomShape& rSdrObjCustomShape) : SfxItemSet ( rSdrObjCustomShape.GetMergedItemSet() ), mrSdrObjCustomShape ( rSdrObjCustomShape ), eSpType ( mso_sptNil ), nCoordLeft ( 0 ), nCoordTop ( 0 ), nCoordWidthG ( 21600 ), nCoordHeightG ( 21600 ), bOOXMLShape ( false ), nXRef ( 0x80000000 ), nYRef ( 0x80000000 ), nColorData ( 0 ), bFilled ( rSdrObjCustomShape.GetMergedItem( XATTR_FILLSTYLE ).GetValue() != drawing::FillStyle_NONE ), bStroked ( rSdrObjCustomShape.GetMergedItem( XATTR_LINESTYLE ).GetValue() != drawing::LineStyle_NONE ), bFlipH ( false ), bFlipV ( false ) { // bTextFlow needs to be set before clearing the TextDirection Item ClearItem( SDRATTR_TEXTDIRECTION ); //SJ: vertical writing is not required, by removing this item no outliner is created // #i105323# For 2D AutoShapes, the shadow attribute does not need to be applied to any // of the constructed helper SdrObjects. This would lead to problems since the shadow // of one helper object would fall on one helper object behind it (e.g. with the // eyes of the smiley shape). This is not wanted; instead a single shadow 'behind' // the AutoShape visualisation is wanted. This is done with primitive functionality // now in SdrCustomShapePrimitive2D::create2DDecomposition, but only for 2D objects // (see there and in EnhancedCustomShape3d::Create3DObject to read more). // This exception may be removed later when AutoShapes will create primitives directly. // So, currently remove the ShadowAttribute from the ItemSet to not apply it to any // 2D helper shape. ClearItem(SDRATTR_SHADOW); Point aP( mrSdrObjCustomShape.GetSnapRect().Center() ); Size aS( mrSdrObjCustomShape.GetLogicRect().GetSize() ); aP.AdjustX( -(aS.Width() / 2) ); aP.AdjustY( -(aS.Height() / 2) ); aLogicRect = tools::Rectangle( aP, aS ); OUString sShapeType; const SdrCustomShapeGeometryItem& rGeometryItem(mrSdrObjCustomShape.GetMergedItem( SDRATTR_CUSTOMSHAPE_GEOMETRY )); const Any* pAny = rGeometryItem.GetPropertyValueByName( "Type" ); if ( pAny ) { *pAny >>= sShapeType; bOOXMLShape = sShapeType.startsWith("ooxml-"); SAL_INFO("svx", "shape type: " << sShapeType << " " << bOOXMLShape); } eSpType = EnhancedCustomShapeTypeNames::Get( sShapeType ); pAny = rGeometryItem.GetPropertyValueByName( "MirroredX" ); if ( pAny ) *pAny >>= bFlipH; pAny = rGeometryItem.GetPropertyValueByName( "MirroredY" ); if ( pAny ) *pAny >>= bFlipV; nRotateAngle = static_cast(mrSdrObjCustomShape.GetObjectRotation() * 100.0); /*const sal_Int32* pDefData =*/ ApplyShapeAttributes( rGeometryItem ); SetPathSize(); switch( eSpType ) { case mso_sptCan : nColorData = 0x20400000; break; case mso_sptCube : nColorData = 0x302e0000; break; case mso_sptActionButtonBlank : nColorData = 0x502ce400; break; case mso_sptActionButtonHome : nColorData = 0x702ce4ce; break; case mso_sptActionButtonHelp : nColorData = 0x602ce4c0; break; case mso_sptActionButtonInformation : nColorData = 0x702ce4c5; break; case mso_sptActionButtonBackPrevious : nColorData = 0x602ce4c0; break; case mso_sptActionButtonForwardNext : nColorData = 0x602ce4c0; break; case mso_sptActionButtonBeginning : nColorData = 0x602ce4c0; break; case mso_sptActionButtonEnd : nColorData = 0x602ce4c0; break; case mso_sptActionButtonReturn : nColorData = 0x602ce4c0; break; case mso_sptActionButtonDocument : nColorData = 0x702ce4ec; break; case mso_sptActionButtonSound : nColorData = 0x602ce4c0; break; case mso_sptActionButtonMovie : nColorData = 0x602ce4c0; break; case mso_sptBevel : nColorData = 0x502ce400; break; case mso_sptFoldedCorner : nColorData = 0x20e00000; break; case mso_sptSmileyFace : nColorData = 0x20e00000; break; case mso_sptNil : { if( sShapeType.getLength() > 4 && sShapeType.match( "col-" )) { nColorData = sShapeType.copy( 4 ).toUInt32( 16 ); } } break; case mso_sptCurvedLeftArrow : case mso_sptCurvedRightArrow : case mso_sptCurvedUpArrow : case mso_sptCurvedDownArrow : nColorData = 0x20d00000; break; case mso_sptRibbon2 : nColorData = 0x30ee0000; break; case mso_sptRibbon : nColorData = 0x30ee0000; break; case mso_sptEllipseRibbon2 : nColorData = 0x30ee0000; break; case mso_sptEllipseRibbon : nColorData = 0x30ee0000; break; case mso_sptVerticalScroll : nColorData = 0x30ee0000; break; case mso_sptHorizontalScroll : nColorData = 0x30ee0000; break; default: break; } sal_Int32 nLength = seqEquations.getLength(); if ( nLength ) { vNodesSharedPtr.resize( nLength ); vEquationResults.resize( nLength ); for ( sal_Int32 i = 0; i < nLength; i++ ) { vEquationResults[ i ].bReady = false; try { vNodesSharedPtr[ i ] = EnhancedCustomShape::FunctionParser::parseFunction( seqEquations[ i ], *this ); } catch ( EnhancedCustomShape::ParseError& ) { SAL_INFO( "svx", "error: equation number: " << i << ", parser failed (" << seqEquations[i] << ")"); } } } } using EnhancedCustomShape::ExpressionFunct; double EnhancedCustomShape2d::GetEnumFunc( const ExpressionFunct eFunc ) const { double fRet = 0.0; switch( eFunc ) { case ExpressionFunct::EnumPi : fRet = F_PI; break; case ExpressionFunct::EnumLeft : fRet = static_cast(nCoordLeft); break; case ExpressionFunct::EnumTop : fRet = static_cast(nCoordTop); break; case ExpressionFunct::EnumRight : fRet = static_cast(nCoordLeft + nCoordWidth) * fXRatio; break; case ExpressionFunct::EnumBottom : fRet = static_cast(nCoordTop + nCoordHeight) * fYRatio; break; case ExpressionFunct::EnumXStretch : fRet = nXRef; break; case ExpressionFunct::EnumYStretch : fRet = nYRef; break; case ExpressionFunct::EnumHasStroke : fRet = bStroked ? 1.0 : 0.0; break; case ExpressionFunct::EnumHasFill : fRet = bFilled ? 1.0 : 0.0; break; case ExpressionFunct::EnumWidth : fRet = nCoordWidth; break; case ExpressionFunct::EnumHeight : fRet = nCoordHeight; break; case ExpressionFunct::EnumLogWidth : fRet = aLogicRect.GetWidth(); break; case ExpressionFunct::EnumLogHeight : fRet = aLogicRect.GetHeight(); break; default: break; } return fRet; } double EnhancedCustomShape2d::GetAdjustValueAsDouble( const sal_Int32 nIndex ) const { double fNumber = 0.0; if ( nIndex < seqAdjustmentValues.getLength() ) { if ( seqAdjustmentValues[ nIndex ].Value.getValueTypeClass() == TypeClass_DOUBLE ) seqAdjustmentValues[ nIndex ].Value >>= fNumber; else { sal_Int32 nNumber = 0; seqAdjustmentValues[ nIndex ].Value >>= nNumber; fNumber = static_cast(nNumber); } } return fNumber; } double EnhancedCustomShape2d::GetEquationValueAsDouble( const sal_Int32 nIndex ) const { double fNumber = 0.0; static sal_uInt32 nLevel = 0; if ( nIndex < static_cast(vNodesSharedPtr.size()) ) { if ( vNodesSharedPtr[ nIndex ] ) { nLevel ++; try { if ( vEquationResults[ nIndex ].bReady ) fNumber = vEquationResults[ nIndex ].fValue; else { // cast to non const, so that we can optimize by caching // equation results, without changing all the const in the stack struct EquationResult &aResult = const_cast(this)->vEquationResults[ nIndex ]; fNumber = aResult.fValue = (*vNodesSharedPtr[ nIndex ])(); aResult.bReady = true; SAL_INFO("svx", "equation " << nLevel << " (level: " << seqEquations[nIndex] << "): " << fNumber << " --> " << 180.0*fNumber/10800000.0); } if ( !std::isfinite( fNumber ) ) fNumber = 0.0; } catch ( ... ) { SAL_WARN("svx", "EnhancedCustomShape2d::GetEquationValueAsDouble failed"); } nLevel --; } SAL_INFO( "svx", "?" << nIndex << " --> " << fNumber << " (angle: " << 180.0*fNumber/10800000.0 << ")"); } return fNumber; } bool EnhancedCustomShape2d::SetAdjustValueAsDouble( const double& rValue, const sal_Int32 nIndex ) { bool bRetValue = false; if ( nIndex < seqAdjustmentValues.getLength() ) { // updating our local adjustment sequence seqAdjustmentValues[ nIndex ].Value <<= rValue; seqAdjustmentValues[ nIndex ].State = css::beans::PropertyState_DIRECT_VALUE; bRetValue = true; } return bRetValue; } basegfx::B2DPoint EnhancedCustomShape2d::GetPointAsB2DPoint( const css::drawing::EnhancedCustomShapeParameterPair& rPair, const bool bScale, const bool bReplaceGeoSize ) const { double fValX, fValY; // width GetParameter(fValX, rPair.First, bReplaceGeoSize, false); fValX -= nCoordLeft; if (bScale) { fValX *= fXScale; } // height GetParameter(fValY, rPair.Second, false, bReplaceGeoSize); fValY -= nCoordTop; if (bScale) { fValY *= fYScale; } return basegfx::B2DPoint(fValX,fValY); } Point EnhancedCustomShape2d::GetPoint( const css::drawing::EnhancedCustomShapeParameterPair& rPair, const bool bScale, const bool bReplaceGeoSize ) const { basegfx::B2DPoint aPoint(GetPointAsB2DPoint(rPair, bScale, bReplaceGeoSize)); return Point(static_cast(aPoint.getX()), static_cast(aPoint.getY())); } void EnhancedCustomShape2d::GetParameter( double& rRetValue, const EnhancedCustomShapeParameter& rParameter, const bool bReplaceGeoWidth, const bool bReplaceGeoHeight ) const { rRetValue = 0.0; switch ( rParameter.Type ) { case EnhancedCustomShapeParameterType::ADJUSTMENT : { sal_Int32 nAdjustmentIndex = 0; if ( rParameter.Value >>= nAdjustmentIndex ) { rRetValue = GetAdjustValueAsDouble( nAdjustmentIndex ); } } break; case EnhancedCustomShapeParameterType::EQUATION : { sal_Int32 nEquationIndex = 0; if ( rParameter.Value >>= nEquationIndex ) { rRetValue = GetEquationValueAsDouble( nEquationIndex ); } } break; case EnhancedCustomShapeParameterType::NORMAL : { if ( rParameter.Value.getValueTypeClass() == TypeClass_DOUBLE ) { double fValue(0.0); if ( rParameter.Value >>= fValue ) { rRetValue = fValue; } } else { sal_Int32 nValue = 0; if ( rParameter.Value >>= nValue ) { rRetValue = nValue; if ( bReplaceGeoWidth && ( nValue == nCoordWidth ) ) rRetValue *= fXRatio; else if ( bReplaceGeoHeight && ( nValue == nCoordHeight ) ) rRetValue *= fYRatio; } } } break; case EnhancedCustomShapeParameterType::LEFT : { rRetValue = 0.0; } break; case EnhancedCustomShapeParameterType::TOP : { rRetValue = 0.0; } break; case EnhancedCustomShapeParameterType::RIGHT : { rRetValue = nCoordWidth; } break; case EnhancedCustomShapeParameterType::BOTTOM : { rRetValue = nCoordHeight; } break; } } // nLumDat 28-31 = number of luminance entries in nLumDat // nLumDat 27-24 = nLumDatEntry 0 // nLumDat 23-20 = nLumDatEntry 1 ... // each 4bit entry is to be interpreted as a 10 percent signed luminance changing sal_Int32 EnhancedCustomShape2d::GetLuminanceChange( sal_uInt32 nIndex ) const { const sal_uInt32 nCount = nColorData >> 28; if ( !nCount ) return 0; if ( nIndex >= nCount ) nIndex = nCount - 1; const sal_Int32 nLumDat = nColorData << ( ( 1 + nIndex ) << 2 ); return ( nLumDat >> 28 ) * 10; } Color EnhancedCustomShape2d::GetColorData( const Color& rFillColor, sal_uInt32 nIndex, double dBrightness ) const { if ( bOOXMLShape || ( mso_sptMin == eSpType /* ODF "non-primitive" */ ) ) { //do LibreOffice way, using dBrightness if ( dBrightness == 0.0) { return rFillColor; } else { if (dBrightness >=0.0) { //lighten, blending with white return Color( static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetRed() * (1.0-dBrightness) + dBrightness * 255.0, 0.0, 255.0) )), static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetGreen() * (1.0-dBrightness) + dBrightness * 255.0, 0.0, 255.0) )), static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetBlue() * (1.0-dBrightness) + dBrightness * 255.0, 0.0, 255.0) )) ); } else { //darken (indicated by negative sign), blending with black return Color( static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetRed() * (1.0+dBrightness), 0.0, 255.0) )), static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetGreen() * (1.0+dBrightness), 0.0, 255.0) )), static_cast(static_cast< sal_Int32 >( std::clamp(rFillColor.GetBlue() * (1.0+dBrightness), 0.0, 255.0) )) ); } } } else { //do OpenOffice way, using nColorData const sal_Int32 nLuminance = GetLuminanceChange(nIndex); if( !nLuminance ) return rFillColor; basegfx::BColor aHSVColor= basegfx::utils::rgb2hsv( basegfx::BColor(rFillColor.GetRed()/255.0, rFillColor.GetGreen()/255.0, rFillColor.GetBlue()/255.0)); if( nLuminance > 0 ) { aHSVColor.setGreen( aHSVColor.getGreen() * (1.0-nLuminance/100.0)); aHSVColor.setBlue( nLuminance/100.0 + (1.0-nLuminance/100.0)*aHSVColor.getBlue()); } else if( nLuminance < 0 ) { aHSVColor.setBlue( (1.0+nLuminance/100.0)*aHSVColor.getBlue()); } aHSVColor = basegfx::utils::hsv2rgb(aHSVColor); return Color( static_cast(static_cast< sal_Int32 >( std::clamp(aHSVColor.getRed(),0.0,1.0) * 255.0 + 0.5 )), static_cast(static_cast< sal_Int32 >( std::clamp(aHSVColor.getGreen(),0.0,1.0) * 255.0 + 0.5 )), static_cast(static_cast< sal_Int32 >( std::clamp(aHSVColor.getBlue(),0.0,1.0) * 255.0 + 0.5 )) ); } } tools::Rectangle EnhancedCustomShape2d::GetTextRect() const { if ( !seqTextFrames.hasElements() ) return aLogicRect; sal_Int32 nIndex = 0; Point aTopLeft( GetPoint( seqTextFrames[ nIndex ].TopLeft, !bOOXMLShape, true ) ); Point aBottomRight( GetPoint( seqTextFrames[ nIndex ].BottomRight, !bOOXMLShape, true ) ); tools::Rectangle aRect( aTopLeft, aBottomRight ); if ( bFlipH ) { aRect.SetLeft(aLogicRect.GetWidth() - 1 - aBottomRight.X()); aRect.SetRight( aLogicRect.GetWidth() - 1 - aTopLeft.X()); } if ( bFlipV ) { aRect.SetTop(aLogicRect.GetHeight() - 1 - aBottomRight.Y()); aRect.SetBottom(aLogicRect.GetHeight() - 1 - aTopLeft.Y()); } SAL_INFO("svx", aRect.GetWidth() << " x " << aRect.GetHeight()); if( aRect.GetWidth() <= 1 || aRect.GetHeight() <= 1 ) return aLogicRect; aRect.Move( aLogicRect.Left(), aLogicRect.Top() ); aRect.Justify(); return aRect; } sal_uInt32 EnhancedCustomShape2d::GetHdlCount() const { return seqHandles.getLength(); } bool EnhancedCustomShape2d::GetHandlePosition( const sal_uInt32 nIndex, Point& rReturnPosition ) const { bool bRetValue = false; if ( nIndex < GetHdlCount() ) { Handle aHandle; if ( ConvertSequenceToEnhancedCustomShape2dHandle( seqHandles[ nIndex ], aHandle ) ) { if ( aHandle.nFlags & HandleFlags::POLAR ) { Point aReferencePoint( GetPoint( aHandle.aPolar ) ); double fAngle; double fRadius; GetParameter( fRadius, aHandle.aPosition.First, false, false ); GetParameter( fAngle, aHandle.aPosition.Second, false, false ); double a = basegfx::deg2rad(360.0 - fAngle); double dx = fRadius * fXScale; double fX = dx * cos( a ); double fY =-dx * sin( a ); rReturnPosition = Point( FRound( fX + aReferencePoint.X() ), basegfx::fTools::equalZero(fXScale) ? aReferencePoint.Y() : FRound( ( fY * fYScale ) / fXScale + aReferencePoint.Y() ) ); } else { if ( aHandle.nFlags & HandleFlags::SWITCHED ) { if ( aLogicRect.GetHeight() > aLogicRect.GetWidth() ) { css::drawing::EnhancedCustomShapeParameter aFirst = aHandle.aPosition.First; css::drawing::EnhancedCustomShapeParameter aSecond = aHandle.aPosition.Second; aHandle.aPosition.First = aSecond; aHandle.aPosition.Second = aFirst; } } if (bOOXMLShape) rReturnPosition = GetPoint(aHandle.aPosition, false /*bScale*/); else rReturnPosition = GetPoint(aHandle.aPosition, true /*bScale*/); } const GeoStat aGeoStat(mrSdrObjCustomShape.GetGeoStat()); if ( aGeoStat.nShearAngle ) { double nTan = aGeoStat.nTan; if (bFlipV != bFlipH) nTan = -nTan; ShearPoint( rReturnPosition, Point( aLogicRect.GetWidth() / 2, aLogicRect.GetHeight() / 2 ), nTan ); } if ( nRotateAngle ) { double a = nRotateAngle * F_PI18000; RotatePoint( rReturnPosition, Point( aLogicRect.GetWidth() / 2, aLogicRect.GetHeight() / 2 ), sin( a ), cos( a ) ); } if ( bFlipH ) rReturnPosition.setX( aLogicRect.GetWidth() - rReturnPosition.X() ); if ( bFlipV ) rReturnPosition.setY( aLogicRect.GetHeight() - rReturnPosition.Y() ); rReturnPosition.Move( aLogicRect.Left(), aLogicRect.Top() ); bRetValue = true; } } return bRetValue; } static double lcl_getXAdjustmentValue(const OUString& rShapeType, const sal_uInt32 nHandleIndex, const double fX, const double fW, const double fH) { // degenerated shapes are not worth to calculate special case for each shape type if (fW <= 0.0 || fH <= 0.0) return 50000; // pattern (w - x) / ss * 100000 or (r - x) / ss * 100000 if ((rShapeType == "ooxml-bentArrow" && nHandleIndex == 2) || (rShapeType == "ooxml-chevron") || (rShapeType == "ooxml-curvedRightArrow") || (rShapeType == "ooxml-foldedCorner") || (rShapeType == "ooxml-homePlate") || (rShapeType == "ooxml-notchedRightArrow") || (rShapeType == "ooxml-nonIsoscelesTrapezoid" && nHandleIndex == 1) || (rShapeType == "ooxml-rightArrow") || (rShapeType == "ooxml-rightArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-round1Rect") || (rShapeType == "ooxml-round2DiagRect" && nHandleIndex == 1) || (rShapeType == "ooxml-round2SameRect" && nHandleIndex == 0) || (rShapeType == "ooxml-snip1Rect") || (rShapeType == "ooxml-snip2DiagRect" && nHandleIndex == 1) || (rShapeType == "ooxml-snip2SameRect" && nHandleIndex == 0) || (rShapeType == "ooxml-snipRoundRect" && nHandleIndex == 1) || (rShapeType == "ooxml-swooshArrow") || (rShapeType == "ooxml-stripedRightArrow")) return (fW - fX) / std::min(fW, fH) * 100000.0; // pattern x / ss * 100000 or (x - l) / ss * 100000 if ((rShapeType == "ooxml-bentArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-bentArrow" && nHandleIndex == 3) || (rShapeType == "ooxml-corner") || (rShapeType == "ooxml-curvedDownArrow") || (rShapeType == "ooxml-curvedLeftArrow") || (rShapeType == "ooxml-curvedUpArrow") || (rShapeType == "ooxml-leftArrow") || (rShapeType == "ooxml-leftArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-leftRightArrow") || (rShapeType == "ooxml-leftRightArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-leftRightRibbon") || (rShapeType == "ooxml-nonIsoscelesTrapezoid" && nHandleIndex == 0) || (rShapeType == "ooxml-parallelogram") || (rShapeType == "ooxml-round2DiagRect" && nHandleIndex == 0) || (rShapeType == "ooxml-round2SameRect" && nHandleIndex == 1) || (rShapeType == "ooxml-roundRect") || (rShapeType == "ooxml-snip2DiagRect" && nHandleIndex == 0) || (rShapeType == "ooxml-snip2SameRect" && nHandleIndex == 1) || (rShapeType == "ooxml-snipRoundRect" && nHandleIndex == 0) || (rShapeType == "ooxml-uturnArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-uturnArrow" && nHandleIndex == 3)) return fX / std::min(fW, fH) * 100000.0; // pattern (hc - x) / ss * 200000 if ((rShapeType == "ooxml-downArrowCallout" && nHandleIndex == 0) || (rShapeType == "ooxml-leftRightUpArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-quadArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-quadArrowCallout" && nHandleIndex == 0) || (rShapeType == "ooxml-upArrowCallout" && nHandleIndex == 0) || (rShapeType == "ooxml-upDownArrowCallout" && nHandleIndex == 0)) return (fW / 2.0 - fX) / std::min(fW, fH) * 200000.0; // pattern (hc - x) / ss * 100000 if ((rShapeType == "ooxml-downArrowCallout" && nHandleIndex == 1) || (rShapeType == "ooxml-leftRightUpArrow" && nHandleIndex == 1) || (rShapeType == "ooxml-quadArrow" && nHandleIndex == 1) || (rShapeType == "ooxml-quadArrowCallout" && nHandleIndex == 1) || (rShapeType == "ooxml-upArrowCallout" && nHandleIndex == 1) || (rShapeType == "ooxml-upDownArrowCallout" && nHandleIndex == 1)) return (fW / 2.0 - fX) / std::min(fW, fH) * 100000.0; // pattern (w - x) / ss * 50000 or (r - x) / ss * 50000 if ((rShapeType == "ooxml-bentUpArrow") || (rShapeType == "ooxml-leftUpArrow") || (rShapeType == "ooxml-uturnArrow" && nHandleIndex == 1)) return (fW - fX) / std::min(fW, fH) * 50000.0; // pattern x / ss * 200000 if (rShapeType == "ooxml-nonIsoscelesTrapezoid" && nHandleIndex == 0) return fX / std::min(fW, fH) * 200000.0; // pattern (hc - x) / w * 200000 if ((rShapeType == "ooxml-downArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-ellipseRibbon") || (rShapeType == "ooxml-ellipseRibbon2") || (rShapeType == "ooxml-leftRightArrowCallout" && nHandleIndex == 3) || (rShapeType == "ooxml-ribbon") || (rShapeType == "ooxml-ribbon2") || (rShapeType == "ooxml-upArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-upDownArrow" && nHandleIndex == 0)) return (fW / 2.0 - fX) / fW * 200000.0; // pattern (x - hc) / w * 100000 if ((rShapeType == "ooxml-cloudCallout") || (rShapeType == "ooxml-doubleWave") || (rShapeType == "ooxml-wave") || (rShapeType == "ooxml-wedgeEllipseCallout") || (rShapeType == "ooxml-wedgeRectCallout") || (rShapeType == "ooxml-wedgeRoundRectCallout")) return (fX - fW / 2.0) / fW * 100000.0; // pattern (x - hc) / w * 200000 if (rShapeType == "ooxml-teardrop") return (fX - fW / 2.0) / fW * 200000.0; // pattern (w - x) / w * 100000 or (r - x) / w * 100000 if (rShapeType == "ooxml-leftArrowCallout" && nHandleIndex == 3) return (fW - fX) / fW * 100000.0; // pattern (hc - x) / h * 100000 if (rShapeType == "ooxml-mathDivide") return (fW / 2.0 - fX) / fH * 100000.0; // pattern x / w * 100000, simple scaling if (rShapeType.startsWith("ooxml-")) return fX / fW * 100000.0; return fX; // method is unknown } static double lcl_getYAdjustmentValue(const OUString& rShapeType, const sal_uInt32 nHandleIndex, const double fY, const double fW, const double fH) { // degenerated shapes are not worth to calculate a special case for each shape type if (fW <= 0.0 || fH <= 0.0) return 50000; // pattern (vc - y) / ss * 100000 if ((rShapeType == "ooxml-leftArrowCallout" && nHandleIndex == 1) || (rShapeType == "ooxml-leftRightArrowCallout" && nHandleIndex == 1) || (rShapeType == "ooxml-rightArrowCallout" && nHandleIndex == 1)) return (fH / 2.0 - fY) / std::min(fW, fH) * 100000.0; // pattern (vc - y) / ss * 200000 if ((rShapeType == "ooxml-curvedLeftArrow") || (rShapeType == "ooxml-curvedRightArrow") || (rShapeType == "ooxml-leftArrowCallout" && nHandleIndex == 0) || (rShapeType == "ooxml-leftRightArrowCallout" && nHandleIndex == 0) || (rShapeType == "ooxml-mathPlus") || (rShapeType == "ooxml-rightArrowCallout" && nHandleIndex == 0)) return (fH / 2.0 - fY) / std::min(fW, fH) * 200000.0; // pattern (h - y) / ss * 100000 or (b - y) / ss * 100000 if ((rShapeType == "ooxml-bentUpArrow" && nHandleIndex == 0) || (rShapeType == "ooxml-corner") || (rShapeType == "ooxml-curvedDownArrow") || (rShapeType == "ooxml-downArrow") || (rShapeType == "ooxml-downArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-uturnArrow" && nHandleIndex == 2)) return (fH - fY) / std::min(fW, fH) * 100000.0; // pattern (h - y) / ss * 200000 or (b - y) / ss * 200000 if (rShapeType == "ooxml-leftUpArrow" && nHandleIndex == 0) // - adj2 * 2 outside return (fH - fY) / std::min(fW, fH) * 200000.0; // pattern y / ss * 100000 or (y - t) / ss * 100000 if ((rShapeType == "ooxml-bentUpArrow" && nHandleIndex == 2) || (rShapeType == "ooxml-bracePair") || (rShapeType == "ooxml-bracketPair") || (rShapeType == "ooxml-can") || (rShapeType == "ooxml-cube") || (rShapeType == "ooxml-curvedUpArrow") || (rShapeType == "ooxml-halfFrame") || (rShapeType == "ooxml-leftBrace" && nHandleIndex == 0) || (rShapeType == "ooxml-leftBracket") || (rShapeType == "ooxml-leftRightUpArrow") || (rShapeType == "ooxml-leftUpArrow" && nHandleIndex == 2) || (rShapeType == "ooxml-mathMultiply") || (rShapeType == "ooxml-quadArrow") || (rShapeType == "ooxml-quadArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-rightBrace" && nHandleIndex == 0) || (rShapeType == "ooxml-rightBracket") || (rShapeType == "ooxml-upArrow") || (rShapeType == "ooxml-upArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-upDownArrow") || (rShapeType == "ooxml-upDownArrowCallout" && nHandleIndex == 2) || (rShapeType == "ooxml-verticalScroll")) return fY / std::min(fW, fH) * 100000.0; // pattern y / ss * 50000 if (rShapeType == "ooxml-bentArrow") return fY / std::min(fW, fH) * 50000.0; // pattern (vc - y) / h * 100000 if ((rShapeType == "ooxml-mathDivide" && nHandleIndex == 1) // -adj1 / 2 - adj3 outside || (rShapeType == "ooxml-mathEqual" && nHandleIndex == 0) // -adj2 / 2 outside || (rShapeType == "ooxml-mathNotEqual" && nHandleIndex == 0) // -adj3 / 2 outside || (rShapeType == "ooxml-star4") || (rShapeType == "ooxml-star6") || (rShapeType == "ooxml-star8") || (rShapeType == "ooxml-star10") || (rShapeType == "ooxml-star12") || (rShapeType == "ooxml-star16") || (rShapeType == "ooxml-star24") || (rShapeType == "ooxml-star32")) return (fH / 2.0 - fY) / fH * 100000.0; // pattern (vc - y) / h * 200000 if ((rShapeType == "ooxml-leftArrow") || (rShapeType == "ooxml-leftRightArrow") || (rShapeType == "ooxml-mathDivide" && nHandleIndex == 0) || (rShapeType == "ooxml-mathEqual" && nHandleIndex == 1) || (rShapeType == "ooxml-mathMinus") || (rShapeType == "ooxml-notchedRightArrow") || (rShapeType == "ooxml-mathNotEqual" && nHandleIndex == 2) || (rShapeType == "ooxml-quadArrowCallout" && nHandleIndex == 3) || (rShapeType == "ooxml-rightArrow") || (rShapeType == "ooxml-stripedRightArrow") || (rShapeType == "ooxml-upDownArrowCallout" && nHandleIndex == 3)) return (fH / 2.0 - fY) / fH * 200000.0; // pattern (y - vc) / h * 100000 if ((rShapeType == "ooxml-cloudCallout") || (rShapeType == "ooxml-wedgeEllipseCallout") || (rShapeType == "ooxml-wedgeRectCallout") || (rShapeType == "ooxml-wedgeRoundRectCallout")) return (fY - fH / 2.0) / fH * 100000.0; // pattern (h - y) / h * 100000 or (b - y) / h * 100000 if ((rShapeType == "ooxml-ellipseRibbon" && nHandleIndex == 2) || (rShapeType == "ooxml-ellipseRibbon2" && nHandleIndex == 0) || (rShapeType == "ooxml-ribbon2") || (rShapeType == "ooxml-upArrowCallout" && nHandleIndex == 3)) return (fH - fY) / fH * 100000.0; // special pattern smiley if (rShapeType == "ooxml-smileyFace") return (fY - fH * 16515.0 / 21600.0) / fH * 100000.0; // special pattern for star with odd number of tips, because center of star not center of shape if (rShapeType == "ooxml-star5") return (fH / 2.0 - fY * 100000.0 / 110557.0) / fH * 100000.0; if (rShapeType == "ooxml-star7") return (fH / 2.0 - fY * 100000.0 / 105210.0) / fH * 100000.0; // special pattern swooshArrow if (rShapeType == "ooxml-swooshArrow") return (fY - std::min(fW, fH) / 8.0) / fH * 100000.0; // special pattern leftRightRibbon if (rShapeType == "ooxml-leftRightRibbon") return fY / fH * 200000 - 100000; // pattern y / h * 100000, simple scaling if (rShapeType.startsWith("ooxml-")) return fY / fH * 100000.0; return fY; // method is unknown } static double lcl_getAngleInOOXMLUnit(double fDY, double fDX) { if (fDX != 0.0 || fDY != 0.0) { double fAngleRad(atan2(fDY, fDX)); double fAngle = basegfx::rad2deg(fAngleRad); // atan2 returns angle in ]-pi; pi], OOXML preset shapes use [0;360[. if (fAngle < 0.0) fAngle += 360.0; // OOXML uses angle unit 1/60000 degree. fAngle *= 60000.0; return fAngle; } return 0.0; // no angle defined for origin in polar coordinate system } static double lcl_getRadiusDistance(double fWR, double fHR, double fX, double fY) { // Get D so, that point (fX|fY) is on the ellipse, that has width fWR-D and // height fHR-D and center in origin. // Get solution of ellipse equation (fX/(fWR-D))^2 + (fY/(fHR-D)^2 = 1 by solving // fX^2*(fHR-D)^2 + fY^2*(fWR-D)^2 - (fWR-D)^2 * (fHR-D)^2 = 0 with Newton-method. if (fX == 0.0) return std::min(fHR - fY, fWR); else if (fY == 0.0) return std::min(fWR - fX, fHR); double fD = std::min(fWR, fHR) - sqrt(fX * fX + fY * fY); // iteration start value sal_uInt8 nIter(0); bool bFound(false); do { ++nIter; const double fOldD(fD); const double fWRmD(fWR - fD); const double fHRmD(fHR - fD); double fNumerator = fX * fX * fHRmD * fHRmD + fY * fY * fWRmD * fWRmD - fWRmD * fWRmD * fHRmD * fHRmD; double fDenominator = 2.0 * (fHRmD * (fWRmD * fWRmD - fX * fX) + fWRmD * (fHRmD * fHRmD - fY * fY)); if (fDenominator != 0.0) { fD = fD - fNumerator / fDenominator; bFound = fabs(fOldD - fD) < 1.0E-12; } else fD = fD * 0.9; // new start value } while (nIter < 50 && !bFound); return fD; } bool EnhancedCustomShape2d::SetHandleControllerPosition( const sal_uInt32 nIndex, const css::awt::Point& rPosition ) { // The method name is misleading. Essentially it calculates the adjustment values from a given // handle position. // For ooxml-foo shapes, the way to calculate the adjustment value from the handle position depends on // the type of the shape, therefore need 'Type'. OUString sShapeType("non-primitive"); // default for ODF const SdrCustomShapeGeometryItem& rGeometryItem(mrSdrObjCustomShape.GetMergedItem( SDRATTR_CUSTOMSHAPE_GEOMETRY )); const Any* pAny = rGeometryItem.GetPropertyValueByName("Type"); if (pAny) *pAny >>= sShapeType; bool bRetValue = false; if ( nIndex < GetHdlCount() ) { Handle aHandle; if ( ConvertSequenceToEnhancedCustomShape2dHandle( seqHandles[ nIndex ], aHandle ) ) { Point aP( rPosition.X, rPosition.Y ); // apply the negative object rotation to the controller position aP.Move( -aLogicRect.Left(), -aLogicRect.Top() ); if ( bFlipH ) aP.setX( aLogicRect.GetWidth() - aP.X() ); if ( bFlipV ) aP.setY( aLogicRect.GetHeight() - aP.Y() ); if ( nRotateAngle ) { double a = -nRotateAngle * F_PI18000; RotatePoint( aP, Point( aLogicRect.GetWidth() / 2, aLogicRect.GetHeight() / 2 ), sin( a ), cos( a ) ); } const GeoStat aGeoStat(mrSdrObjCustomShape.GetGeoStat()); if ( aGeoStat.nShearAngle ) { double nTan = -aGeoStat.nTan; if (bFlipV != bFlipH) nTan = -nTan; ShearPoint( aP, Point( aLogicRect.GetWidth() / 2, aLogicRect.GetHeight() / 2 ), nTan ); } double fPos1 = aP.X(); //( bFlipH ) ? aLogicRect.GetWidth() - aP.X() : aP.X(); double fPos2 = aP.Y(); //( bFlipV ) ? aLogicRect.GetHeight() -aP.Y() : aP.Y(); fPos1 = !basegfx::fTools::equalZero(fXScale) ? (fPos1 / fXScale) : SAL_MAX_INT32; fPos2 = !basegfx::fTools::equalZero(fYScale) ? (fPos2 / fYScale) : SAL_MAX_INT32; // revert -nCoordLeft and -nCoordTop aus GetPoint() fPos1 += nCoordLeft; fPos2 += nCoordTop; // Used for scaling the adjustment values based on handle positions double fWidth; double fHeight; if ( nCoordWidth || nCoordHeight ) { fWidth = nCoordWidth; fHeight = nCoordHeight; } else { fWidth = aLogicRect.GetWidth(); fHeight = aLogicRect.GetHeight(); } if ( aHandle.nFlags & HandleFlags::SWITCHED ) { if ( aLogicRect.GetHeight() > aLogicRect.GetWidth() ) { double fX = fPos1; double fY = fPos2; double fTmp = fWidth; fPos1 = fY; fPos2 = fX; fHeight = fWidth; fWidth = fTmp; } } sal_Int32 nFirstAdjustmentValue = -1, nSecondAdjustmentValue = -1; // ODF shapes are expected to use a direct binding between position and adjustment // values. OOXML preset shapes use known formulas. These are calculated backward to // get the adjustment values. So far we do not have a general method to calculate // the adjustment values for any shape from the handle position. if ( aHandle.aPosition.First.Type == EnhancedCustomShapeParameterType::ADJUSTMENT ) aHandle.aPosition.First.Value >>= nFirstAdjustmentValue; if ( aHandle.aPosition.Second.Type == EnhancedCustomShapeParameterType::ADJUSTMENT ) aHandle.aPosition.Second.Value>>= nSecondAdjustmentValue; if ( aHandle.nFlags & ( HandleFlags::POLAR | HandleFlags::REFR | HandleFlags::REFANGLE)) { // Polar-Handle if (aHandle.nFlags & HandleFlags::REFR) nFirstAdjustmentValue = aHandle.nRefR; if (aHandle.nFlags & HandleFlags::REFANGLE) nSecondAdjustmentValue = aHandle.nRefAngle; double fAngle(0.0); double fRadius(0.0); // 'then' treats only shapes of type "ooxml-foo", fontwork shapes have been mapped // to MS binary import and will be treated in 'else'. if (bOOXMLShape) { // DrawingML polar handles set REFR or REFANGLE instead of POLAR // use the shape center instead. double fDX = fPos1 - fWidth / 2.0; double fDY = fPos2 - fHeight / 2.0; // There exists no common pattern. 'radius' or 'angle' might have special meaning. if (sShapeType == "ooxml-blockArc" && nIndex == 1) { // usual angle, special radius fAngle = lcl_getAngleInOOXMLUnit(fDY, fDX); // The value connected to REFR is the _difference_ between the outer // ellipse given by shape width and height and the inner ellipse through // the handle position. double fRadiusDifference = lcl_getRadiusDistance(fWidth / 2.0, fHeight / 2.0, fDX, fDY); double fss(std::min(fWidth, fHeight)); if (fss != 0) fRadius = fRadiusDifference * 100000.0 / fss; } else if (sShapeType == "ooxml-donut" || sShapeType == "ooxml-noSmoking") { // no angle adjustment, radius bound to x-coordinate of handle double fss(std::min(fWidth, fHeight)); if (fss != 0.0) fRadius = fPos1 * 100000.0 / fss; } else if ((sShapeType == "ooxml-circularArrow" || sShapeType == "ooxml-leftRightCircularArrow" || sShapeType == "ooxml-leftCircularArrow") && nIndex == 0) { // The value adj2 is the increase compared to the angle in adj3 double fHandleAngle = lcl_getAngleInOOXMLUnit(fDY, fDX); if (sShapeType == "ooxml-leftCircularArrow") fAngle = GetAdjustValueAsDouble(2) - fHandleAngle; else fAngle = fHandleAngle - GetAdjustValueAsDouble(2); if (fAngle < 0.0) // 0deg to 360deg cut fAngle += 21600000.0; // no REFR } else if ((sShapeType == "ooxml-circularArrow" || sShapeType == "ooxml-leftCircularArrow" || sShapeType == "ooxml-leftRightCircularArrow") && nIndex == 2) { // The value adj1 connected to REFR is the thickness of the arc. The adjustvalue adj5 // has the _difference_ between the outer ellipse given by shape width and height // and the middle ellipse of the arc. The handle is on the outer side of the // arc. So we calculate the difference between the ellipse through the handle // and the outer ellipse and subtract then. double fRadiusDifferenceHandle = lcl_getRadiusDistance(fWidth / 2.0, fHeight / 2.0, fDX, fDY); double fadj5(GetAdjustValueAsDouble(4)); double fss(std::min(fWidth, fHeight)); if (fss != 0.0) { fadj5 = fadj5 * fss / 100000.0; fRadius = 2.0 * (fadj5 - fRadiusDifferenceHandle); fRadius = fRadius * 100000.0 / fss; } // ToDo: Get angle adj3 exact. Use approximation for now fAngle = lcl_getAngleInOOXMLUnit(fDY, fDX); } else if ((sShapeType == "ooxml-circularArrow" || sShapeType == "ooxml-leftCircularArrow" || sShapeType == "ooxml-leftRightCircularArrow") && nIndex == 3) { // ToDo: Getting handle position from adjustment value adj5 is complex. // Analytical or numerical solution for backward calculation is missing. // Approximation for now, using a line from center through handle position. double fAngleRad(0.0); if (fDX != 0.0 || fDY != 0.0) fAngleRad = atan2(fDY, fDX); double fHelpX = cos(fAngleRad) * fHeight / 2.0; double fHelpY = sin(fAngleRad) * fWidth / 2.0; if (fHelpX != 0.0 || fHelpY != 0.0) { double fHelpAngle = atan2(fHelpY, fHelpX); double fOuterX = fWidth / 2.0 * cos(fHelpAngle); double fOuterY = fHeight / 2.0 * sin(fHelpAngle); double fOuterRadius = sqrt(fOuterX * fOuterX + fOuterY * fOuterY); double fHandleRadius = sqrt(fDX * fDX + fDY * fDY); fRadius = (fOuterRadius - fHandleRadius) / 2.0; double fss(std::min(fWidth, fHeight)); if (fss != 0.0) fRadius = fRadius * 100000.0 / fss; } // no REFANGLE } else if (sShapeType == "ooxml-mathNotEqual" && nIndex == 1) { double fadj1(GetAdjustValueAsDouble(0)); double fadj3(GetAdjustValueAsDouble(2)); fadj1 = fadj1 * fHeight / 100000.0; fadj3 = fadj3 * fHeight / 100000.0; double fDYRefHorizBar = fDY + fadj1 + fadj3; if (fDX != 0.0 || fDYRefHorizBar != 0.0) { double fRawAngleDeg = basegfx::rad2deg(atan2(fDYRefHorizBar, fDX)); fAngle = (fRawAngleDeg + 180.0) * 60000.0; } // no REFR } else { // no special meaning of radius or angle, suitable for "ooxml-arc", // "ooxml-chord", "ooxml-pie" and circular arrows value adj4. fAngle = lcl_getAngleInOOXMLUnit(fDY, fDX); fRadius = sqrt(fDX * fDX + fDY * fDY); double fss(std::min(fWidth, fHeight)); if (fss != 0.0) fRadius = fRadius * 100000.0 / fss; } } else // e.g. shapes from ODF, MS binary import or shape type "fontwork-foo" { double fXRef, fYRef; if (aHandle.nFlags & HandleFlags::POLAR) { GetParameter(fXRef, aHandle.aPolar.First, false, false); GetParameter(fYRef, aHandle.aPolar.Second, false, false); } else { fXRef = fWidth / 2.0; fYRef = fHeight / 2.0; } const double fDX = fPos1 - fXRef; const double fDY = fPos2 - fYRef; // ToDo: MS binary uses fixed-point number for the angle. Make sure conversion // to double is done in import and export. // ToDo: Angle unit is degree, but range ]-180;180] or [0;360[? Assume ]-180;180]. if (fDX != 0.0 || fDY != 0.0) { fRadius = sqrt(fDX * fDX + fDY * fDY); fAngle = basegfx::rad2deg(atan2(fDY, fDX)); } } // All formats can restrict the radius to a range if ( aHandle.nFlags & HandleFlags::RADIUS_RANGE_MINIMUM ) { double fMin; GetParameter( fMin, aHandle.aRadiusRangeMinimum, false, false ); if ( fRadius < fMin ) fRadius = fMin; } if ( aHandle.nFlags & HandleFlags::RADIUS_RANGE_MAXIMUM ) { double fMax; GetParameter( fMax, aHandle.aRadiusRangeMaximum, false, false ); if ( fRadius > fMax ) fRadius = fMax; } if ( nFirstAdjustmentValue >= 0 ) SetAdjustValueAsDouble( fRadius, nFirstAdjustmentValue ); if ( nSecondAdjustmentValue >= 0 ) SetAdjustValueAsDouble( fAngle, nSecondAdjustmentValue ); } else // XY-Handle { // Calculating the adjustment values follows in most cases some patterns, which only // need width and height of the shape and handle position. These patterns are calculated // in the static, local methods. More complex calculations or additional steps are // done here. // Values for corner cases like 'root(negative)' or 'div zero' are meaningless dummies. // Identifiers often refer to guide names in OOXML shape definitions. double fAdjustX = fPos1; double fAdjustY = fPos2; if (aHandle.nFlags & HandleFlags::REFX) { nFirstAdjustmentValue = aHandle.nRefX; if ((sShapeType == "ooxml-gear6") || (sShapeType == "ooxml-gear9")) { // special, needs angle calculations double fss(std::min(fWidth, fHeight)); double fadj1(GetAdjustValueAsDouble(0)); // from point D6 or D9 double fth(fadj1 * fss / 100000.0); // radius difference double frw(fWidth / 2.0 - fth); // inner ellipse double frh(fHeight / 2.0 - fth); double fDX(fPos1 - fWidth / 2.0); double fDY(fPos2 - fHeight / 2.0); double fbA(-1.7); // effective angle for point A6 or A9, dummy value if (fDX != 0.0 || fDY != 0.0) fbA = atan2(fDY, fDX); double faA(fbA); // corresponding circle angle, dummy value double ftmpX(frh * cos(fbA)); double ftmpY(frw * sin(fbA)); if (ftmpX != 0.0 || ftmpY != 0.0) faA = atan2(ftmpY, ftmpX); // range ]-pi..pi], here -pi < faA < -pi/2 // screen 270 deg = mathematic coordinate system -pi/2 double fha(-F_PI2 - faA); // positive circle angle difference to 270 deg if (abs(fha) == F_PI2) // should not happen, but ensure no tan(90deg) fha = 0.12; // dummy value double flFD(2 * std::min(frw, frh) * tan(fha) - fth); if (fss != 0.0) fAdjustX = flFD / fss * 100000.0; } else { fAdjustX = lcl_getXAdjustmentValue(sShapeType, nIndex, fPos1, fWidth, fHeight); if ((sShapeType == "ooxml-curvedDownArrow") || (sShapeType == "ooxml-curvedUpArrow")) { double fss(std::min(fWidth, fHeight)); if (fss != 0.0) { double fadj3(GetAdjustValueAsDouble(2)); double fHScaled(100000.0 * fHeight / fss); double fRadicand(fHScaled * fHScaled - fadj3 * fadj3); double fSqrt = fRadicand >= 0.0 ? sqrt(fRadicand) : 0.0; double fPart(200000.0 * fWidth / fss * (fSqrt + fHScaled)); fAdjustX = fPart - 4.0 * fHScaled * fAdjustX; if (nIndex == 0) { // calculate adj1 double fadj2(GetAdjustValueAsDouble(1)); fAdjustX = fAdjustX - fadj2 * (fSqrt + fHScaled); double fDenominator(fSqrt - 3.0 * fHScaled); fAdjustX /= fDenominator != 0.0 ? fDenominator : 1.0; } else { // nIndex == 1, calculate adj2 double fadj1(GetAdjustValueAsDouble(0)); fAdjustX = fAdjustX - fadj1 * (fSqrt - fHScaled); double fDenominator(fSqrt + 3.0 * fHScaled); fAdjustX /= fDenominator != 0.0 ? fDenominator : 1.0; } } } } } if (aHandle.nFlags & HandleFlags::REFY) { nSecondAdjustmentValue = aHandle.nRefY; if ((sShapeType == "ooxml-gear6") || (sShapeType == "ooxml-gear9")) { // special, acts more like a polar handle radius double fDX = fPos1 - fWidth / 2.0; double fDY = fPos2 - fHeight / 2.0; double fRadiusDifference = lcl_getRadiusDistance(fWidth / 2.0, fHeight / 2.0, fDX, fDY); double fss(std::min(fWidth, fHeight)); if (fss != 0) fAdjustY = fRadiusDifference / fss * 100000.0; } else { fAdjustY = lcl_getYAdjustmentValue(sShapeType, nIndex, fPos2, fWidth, fHeight); if (sShapeType == "ooxml-mathDivide" && nIndex == 1) fAdjustY = fAdjustY - GetAdjustValueAsDouble(0) / 2.0 - GetAdjustValueAsDouble(2); else if (sShapeType == "ooxml-mathEqual" && nIndex == 0) fAdjustY -= GetAdjustValueAsDouble(1) / 2.0; else if (sShapeType == "ooxml-mathNotEqual" && nIndex == 0) fAdjustY -= GetAdjustValueAsDouble(2) / 2.0; else if (sShapeType == "ooxml-leftUpArrow" && nIndex == 0) fAdjustY -= GetAdjustValueAsDouble(1) * 2.0; else if ((sShapeType == "ooxml-curvedRightArrow") || (sShapeType == "ooxml-curvedLeftArrow")) { double fss(std::min(fWidth, fHeight)); if (fss != 0.0) { double fadj3(GetAdjustValueAsDouble(2)); double fWScaled(100000.0 * fWidth / fss); double fRadicand(fWScaled * fWScaled - fadj3 * fadj3); double fSqrt = fRadicand >= 0.0 ? sqrt(fRadicand) : 0.0; if (nIndex == 0) { // calculate adj1 double fadj2(GetAdjustValueAsDouble(1)); fAdjustY = fWScaled * (2.0 * fAdjustY - fadj2); fAdjustY += (200000.0 / fss * fHeight - fadj2) * fSqrt; double fDenominator(fSqrt + fWScaled); fAdjustY /= fDenominator != 0.0 ? fDenominator : 1.0; } else { // nIndex == 1, calculate adj2 double fadj1(GetAdjustValueAsDouble(0)); fAdjustY = fWScaled * (2.0 * fAdjustY + fadj1); fAdjustY += (200000.0 / fss * fHeight - fadj1) * fSqrt; double fDenominator(fSqrt + 3.0 * fWScaled); fAdjustY /= fDenominator != 0.0 ? fDenominator : 1.0; } } } else if (sShapeType == "ooxml-uturnArrow" && nIndex == 2) { double fss(std::min(fWidth, fHeight)); if (fss != 0.0) { double fadj5(GetAdjustValueAsDouble(4)); fAdjustY += fHeight / fss * (fadj5 - 100000.0); } } else if (sShapeType == "ooxml-leftRightRibbon") { if (nIndex == 0) fAdjustY = GetAdjustValueAsDouble(2) - fAdjustY; else // nIndex == 2 fAdjustY = GetAdjustValueAsDouble(0) + fAdjustY; } } } if ( nFirstAdjustmentValue >= 0 ) { if ( aHandle.nFlags & HandleFlags::RANGE_X_MINIMUM ) // check if horizontal handle needs to be within a range { double fXMin; GetParameter( fXMin, aHandle.aXRangeMinimum, false, false ); if (fAdjustX < fXMin) fAdjustX = fXMin; } if ( aHandle.nFlags & HandleFlags::RANGE_X_MAXIMUM ) // check if horizontal handle needs to be within a range { double fXMax; GetParameter( fXMax, aHandle.aXRangeMaximum, false, false ); if (fAdjustX > fXMax) fAdjustX = fXMax; } SetAdjustValueAsDouble(fAdjustX, nFirstAdjustmentValue); } if ( nSecondAdjustmentValue >= 0 ) { if ( aHandle.nFlags & HandleFlags::RANGE_Y_MINIMUM ) // check if vertical handle needs to be within a range { double fYMin; GetParameter( fYMin, aHandle.aYRangeMinimum, false, false ); if (fAdjustY < fYMin) fAdjustY = fYMin; } if ( aHandle.nFlags & HandleFlags::RANGE_Y_MAXIMUM ) // check if vertical handle needs to be within a range { double fYMax; GetParameter( fYMax, aHandle.aYRangeMaximum, false, false ); if (fAdjustY > fYMax) fAdjustY = fYMax; } SetAdjustValueAsDouble(fAdjustY, nSecondAdjustmentValue); } } // and writing them back into the GeometryItem SdrCustomShapeGeometryItem aGeometryItem(mrSdrObjCustomShape.GetMergedItem( SDRATTR_CUSTOMSHAPE_GEOMETRY )); css::beans::PropertyValue aPropVal; aPropVal.Name = "AdjustmentValues"; aPropVal.Value <<= seqAdjustmentValues; aGeometryItem.SetPropertyValue( aPropVal ); mrSdrObjCustomShape.SetMergedItem( aGeometryItem ); bRetValue = true; } } return bRetValue; } void EnhancedCustomShape2d::SwapStartAndEndArrow( SdrObject* pObj ) //#108274 { XLineStartItem aLineStart; aLineStart.SetLineStartValue(pObj->GetMergedItem( XATTR_LINEEND ).GetLineEndValue()); XLineStartWidthItem aLineStartWidth(pObj->GetMergedItem( XATTR_LINEENDWIDTH ).GetValue()); XLineStartCenterItem aLineStartCenter(pObj->GetMergedItem( XATTR_LINEENDCENTER ).GetValue()); XLineEndItem aLineEnd; aLineEnd.SetLineEndValue(pObj->GetMergedItem( XATTR_LINESTART ).GetLineStartValue()); XLineEndWidthItem aLineEndWidth(pObj->GetMergedItem( XATTR_LINESTARTWIDTH ).GetValue()); XLineEndCenterItem aLineEndCenter(pObj->GetMergedItem( XATTR_LINESTARTCENTER ).GetValue()); pObj->SetMergedItem( aLineStart ); pObj->SetMergedItem( aLineStartWidth ); pObj->SetMergedItem( aLineStartCenter ); pObj->SetMergedItem( aLineEnd ); pObj->SetMergedItem( aLineEndWidth ); pObj->SetMergedItem( aLineEndCenter ); } static basegfx::B2DPolygon CreateArc( const tools::Rectangle& rRect, const Point& rStart, const Point& rEnd, const bool bClockwise ) { tools::Rectangle aRect( rRect ); Point aStart( rStart ); Point aEnd( rEnd ); sal_Int32 bSwapStartEndAngle = 0; if ( aRect.Left() > aRect.Right() ) bSwapStartEndAngle ^= 0x01; if ( aRect.Top() > aRect.Bottom() ) bSwapStartEndAngle ^= 0x11; if ( bSwapStartEndAngle ) { aRect.Justify(); if ( bSwapStartEndAngle & 1 ) { Point aTmp( aStart ); aStart = aEnd; aEnd = aTmp; } } tools::Polygon aTempPoly( aRect, aStart, aEnd, PolyStyle::Arc ); basegfx::B2DPolygon aRetval; if ( bClockwise ) { for ( sal_uInt16 j = aTempPoly.GetSize(); j--; ) { aRetval.append(basegfx::B2DPoint(aTempPoly[ j ].X(), aTempPoly[ j ].Y())); } } else { for ( sal_uInt16 j = 0; j < aTempPoly.GetSize(); j++ ) { aRetval.append(basegfx::B2DPoint(aTempPoly[ j ].X(), aTempPoly[ j ].Y())); } } return aRetval; } static double lcl_getNormalizedCircleAngleRad(const double fWR, const double fHR, const double fEllipseAngleDeg) { double fRet(0.0); double fEAngleDeg(fmod(fEllipseAngleDeg, 360.0)); if (fEAngleDeg < 0.0) fEAngleDeg += 360.0; if (fEAngleDeg == 0.0 || fEAngleDeg == 90.0 || fEAngleDeg == 180.0 || fEAngleDeg == 270.0) return basegfx::deg2rad(fEAngleDeg); const double fX(fHR * cos(basegfx::deg2rad(fEAngleDeg))); const double fY(fWR * sin(basegfx::deg2rad(fEAngleDeg))); if (fX != 0.0 || fY != 0.0) { fRet = atan2(fY, fX); if (fRet < 0.0) fRet += F_2PI; } return fRet; } static double lcl_getNormalizedAngleRad(const double fCircleAngleDeg) { double fRet(fmod(fCircleAngleDeg, 360.0)); if (fRet < 0.0) fRet += 360.0; return basegfx::deg2rad(fRet); } void EnhancedCustomShape2d::CreateSubPath( sal_Int32& rSrcPt, sal_Int32& rSegmentInd, std::vector< std::pair< SdrPathObj*, double> >& rObjectList, const bool bLineGeometryNeededOnly, const bool bSortFilledObjectsToBack, sal_Int32 nIndex) { bool bNoFill = false; bool bNoStroke = false; double dBrightness = 0.0; //no blending basegfx::B2DPolyPolygon aNewB2DPolyPolygon; basegfx::B2DPolygon aNewB2DPolygon; SetPathSize( nIndex ); sal_Int32 nSegInfoSize = seqSegments.getLength(); if ( !nSegInfoSize ) { for ( const EnhancedCustomShapeParameterPair& rCoordinate : std::as_const(seqCoordinates) ) { const Point aTempPoint(GetPoint( rCoordinate, true, true )); aNewB2DPolygon.append(basegfx::B2DPoint(aTempPoint.X(), aTempPoint.Y())); } aNewB2DPolygon.setClosed(true); } else { sal_Int32 nCoordSize = seqCoordinates.getLength(); for ( ;rSegmentInd < nSegInfoSize; ) { sal_Int16 nCommand = seqSegments[ rSegmentInd ].Command; sal_Int16 nPntCount= seqSegments[ rSegmentInd++ ].Count; switch ( nCommand ) { case NOFILL : bNoFill = true; break; case NOSTROKE : bNoStroke = true; break; case DARKEN : dBrightness = -0.4; //use sign to distinguish DARKEN from LIGHTEN break; case DARKENLESS : dBrightness = -0.2; break; case LIGHTEN : dBrightness = 0.4; break; case LIGHTENLESS : dBrightness = 0.2; break; case MOVETO : { if(aNewB2DPolygon.count() > 1) { // #i76201# Add conversion to closed polygon when first and last points are equal basegfx::utils::checkClosed(aNewB2DPolygon); aNewB2DPolyPolygon.append(aNewB2DPolygon); } aNewB2DPolygon.clear(); if ( rSrcPt < nCoordSize ) { const Point aTempPoint(GetPoint( seqCoordinates[ rSrcPt++ ], true, true )); SAL_INFO( "svx", "moveTo: " << aTempPoint.X() << "," << aTempPoint.Y()); aNewB2DPolygon.append(basegfx::B2DPoint(aTempPoint.X(), aTempPoint.Y())); } } break; case ENDSUBPATH : break; case CLOSESUBPATH : { if(aNewB2DPolygon.count()) { if(aNewB2DPolygon.count() > 1) { aNewB2DPolygon.setClosed(true); aNewB2DPolyPolygon.append(aNewB2DPolygon); } aNewB2DPolygon.clear(); } } break; case CURVETO : { for ( sal_uInt16 i = 0; ( i < nPntCount ) && ( ( rSrcPt + 2 ) < nCoordSize ); i++ ) { const Point aControlA(GetPoint( seqCoordinates[ rSrcPt++ ], true, true )); const Point aControlB(GetPoint( seqCoordinates[ rSrcPt++ ], true, true )); const Point aEnd(GetPoint( seqCoordinates[ rSrcPt++ ], true, true )); DBG_ASSERT(aNewB2DPolygon.count(), "EnhancedCustomShape2d::CreateSubPath: Error in adding control point (!)"); aNewB2DPolygon.appendBezierSegment( basegfx::B2DPoint(aControlA.X(), aControlA.Y()), basegfx::B2DPoint(aControlB.X(), aControlB.Y()), basegfx::B2DPoint(aEnd.X(), aEnd.Y())); } } break; case ANGLEELLIPSE: // command U case ANGLEELLIPSETO: // command T { // Some shapes will need special handling, decide on property 'Type'. OUString sShpType; SdrCustomShapeGeometryItem& rGeometryItem = const_cast(mrSdrObjCustomShape.GetMergedItem(SDRATTR_CUSTOMSHAPE_GEOMETRY)); Any* pAny = rGeometryItem.GetPropertyValueByName("Type"); if (pAny) *pAny >>= sShpType; // User defined shapes in MS binary format, which contain command U or T after import // in LibreOffice, starts with "mso". const bool bIsFromBinaryImport(sShpType.startsWith("mso")); // The only own or imported preset shapes with U command are those listed below. // Command T is not used in preset shapes. const std::unordered_set aPresetShapesWithU = { "ellipse", "ring", "smiley", "sun", "forbidden", "flowchart-connector", "flowchart-summing-junction", "flowchart-or", "cloud-callout"}; std::unordered_set::const_iterator aIter = aPresetShapesWithU.find(sShpType); const bool bIsPresetShapeWithU(aIter != aPresetShapesWithU.end()); for (sal_uInt16 i = 0; (i < nPntCount) && ((rSrcPt + 2) < nCoordSize); i++) { // ANGLEELLIPSE is the same as ANGLEELLIPSETO, only that it // makes an implicit MOVETO. That ends the previous subpath. if (ANGLEELLIPSE == nCommand) { if (aNewB2DPolygon.count() > 1) { // #i76201# Add conversion to closed polygon when first and last points are equal basegfx::utils::checkClosed(aNewB2DPolygon); aNewB2DPolyPolygon.append(aNewB2DPolygon); } aNewB2DPolygon.clear(); } // Read all parameters, but do not finally handle them. basegfx::B2DPoint aCenter(GetPointAsB2DPoint(seqCoordinates[ rSrcPt ], true, true)); double fWR; // horizontal ellipse radius double fHR; // vertical ellipse radius GetParameter(fWR, seqCoordinates[rSrcPt + 1].First, true, false); GetParameter(fHR, seqCoordinates[rSrcPt + 1].Second, false, true); double fStartAngle; GetParameter(fStartAngle, seqCoordinates[rSrcPt + 2].First, false, false); double fEndAngle; GetParameter(fEndAngle, seqCoordinates[rSrcPt + 2].Second, false, false); // Increasing here allows flat case differentiation tree by using 'continue'. rSrcPt += 3; double fScaledWR(fWR * fXScale); double fScaledHR(fHR * fYScale); if (fScaledWR == 0.0 && fScaledHR == 0.0) { // degenerated ellipse, add center point aNewB2DPolygon.append(aCenter); continue; } if (bIsFromBinaryImport) { // If a shape comes from MS binary ('escher') import, the angles are in degrees*2^16 // and the second angle is not an end angle, but a swing angle. // MS Word shows this behavior: 0deg right, 90deg top, 180deg left and 270deg // bottom. Third and forth parameter are horizontal and vertical radius, not width // and height as noted in VML spec. A positive swing angle goes counter-clock // wise (in user view). The swing angle might go several times around in case // abs(swing angle) >= 360deg. Stroke accumulates, so that e.g. dash-dot might fill the // gaps of previous turn. Fill does not accumulate but uses even-odd rule, semi-transparent // fill does not become darker. The start and end points of the arc are calculated by // using the angles on a circle and then scaling the circle to the ellipse. Caution, that // is different from angle handling in ARCANGLETO and ODF. // The following implementation generates such rendering. It is only for rendering legacy // MS shapes and independent of the meaning of commands U and T in ODF specification. // The WordArt shape 'RingOutside' has already angles in degree, all other need // conversion from fixed-point number. double fSwingAngle = fEndAngle; if (sShpType != "mso-spt143") { fStartAngle /= 65536.0; fSwingAngle = fEndAngle / 65536.0; } // Convert orientation fStartAngle = -fStartAngle; fSwingAngle = -fSwingAngle; fEndAngle = fStartAngle + fSwingAngle; if (fSwingAngle < 0.0) std::swap(fStartAngle, fEndAngle); double fFrom(fStartAngle); double fTo(fFrom + 180.0); basegfx::B2DPolygon aTempB2DPolygon; double fS; // fFrom in radians in [0..2Pi[ double fE; // fTo or fEndAngle in radians in [0..2PI[ while (fTo < fEndAngle) { fS = lcl_getNormalizedAngleRad(fFrom); fE = lcl_getNormalizedAngleRad(fTo); aTempB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fScaledWR, fScaledHR, fS,fE)); fFrom = fTo; fTo += 180.0; } fS = lcl_getNormalizedAngleRad(fFrom); fE = lcl_getNormalizedAngleRad(fEndAngle); aTempB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fScaledWR, fScaledHR,fS, fE)); if (fSwingAngle < 0) aTempB2DPolygon.flip(); aNewB2DPolygon.append(aTempB2DPolygon); continue; } // The not yet handled shapes are own preset shapes, or preset shapes from MS binary import, or user // defined shapes, or foreign shapes. Shapes from OOXML import do not use ANGLEELLIPSE or // ANGLEELLIPSETO, but use ARCANGLETO. if (bIsPresetShapeWithU) { // Besides "cloud-callout" all preset shapes have angle values '0 360'. // The imported "cloud-callout" has angle values '0 360' too, only our own "cloud-callout" // has values '0 23592960'. But that is fixedfloat and means 360*2^16. Thus all these shapes // have a full ellipse with start at 0deg. aNewB2DPolygon.append(basegfx::utils::createPolygonFromEllipse(aCenter, fScaledWR, fScaledHR)); continue; } // In all other cases, full ODF conform handling is necessary. ODF rules: // Third and forth parameter are horizontal and vertical radius. // An angle determines the start or end point of the segment by intersection of the second angle // leg with the ellipse. The first angle leg is always the positive x-axis. For the position // of the intersection points the angle is used modulo 360deg in range [0deg..360deg[. // The position of range [0deg..360deg[ is the same as in command ARCANGLETO, with 0deg right, // 90deg bottom, 180deg left and 270deg top. Only if abs(end angle - start angle) == 360 deg, // a full ellipse is drawn. The segment is always drawn clock wise (in user view) from start // point to end point. The end point of the segment becomes the new "current" point. if (fabs(fabs(fEndAngle - fStartAngle) - 360.0) < 1.0E-15) { // draw full ellipse // Because createPolygonFromEllipseSegment cannot create full ellipse and // createPolygonFromEllipse has no varying starts, we use two half ellipses. const double fS(lcl_getNormalizedCircleAngleRad(fWR, fHR, fStartAngle)); const double fH(lcl_getNormalizedCircleAngleRad(fWR, fHR, fStartAngle + 180.0)); const double fE(lcl_getNormalizedCircleAngleRad(fWR, fHR, fEndAngle)); aNewB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fScaledWR, fScaledHR, fS, fH)); aNewB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fScaledWR, fScaledHR, fH, fE)); continue; } // remaining cases with central segment angle < 360 double fS(lcl_getNormalizedCircleAngleRad(fWR, fHR, fStartAngle)); double fE(lcl_getNormalizedCircleAngleRad(fWR, fHR, fEndAngle)); aNewB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fScaledWR, fScaledHR, fS, fE)); } // end for } // end case break; case QUADRATICCURVETO : { for ( sal_Int32 i(0); ( i < nPntCount ) && ( rSrcPt + 1 < nCoordSize ); i++ ) { DBG_ASSERT(aNewB2DPolygon.count(), "EnhancedCustomShape2d::CreateSubPath: Error no previous point for Q (!)"); if (aNewB2DPolygon.count() > 0) { const basegfx::B2DPoint aPreviousEndPoint(aNewB2DPolygon.getB2DPoint(aNewB2DPolygon.count()-1)); const basegfx::B2DPoint aControlQ(GetPointAsB2DPoint( seqCoordinates[ rSrcPt++ ], true, true )); const basegfx::B2DPoint aEnd(GetPointAsB2DPoint( seqCoordinates[ rSrcPt++ ], true, true )); const basegfx::B2DPoint aControlA((aPreviousEndPoint + (aControlQ * 2)) / 3); const basegfx::B2DPoint aControlB(((aControlQ * 2) + aEnd) / 3); aNewB2DPolygon.appendBezierSegment(aControlA, aControlB, aEnd); } else // no previous point; ill structured path, but try to draw as much as possible { rSrcPt++; // skip control point const basegfx::B2DPoint aEnd(GetPointAsB2DPoint( seqCoordinates[ rSrcPt++ ], true, true )); aNewB2DPolygon.append(aEnd); } } } break; case LINETO : { for ( sal_Int32 i(0); ( i < nPntCount ) && ( rSrcPt < nCoordSize ); i++ ) { const Point aTempPoint(GetPoint( seqCoordinates[ rSrcPt++ ], true, true )); SAL_INFO( "svx", "lineTo: " << aTempPoint.X() << "," << aTempPoint.Y()); aNewB2DPolygon.append(basegfx::B2DPoint(aTempPoint.X(), aTempPoint.Y())); } } break; case ARC : case CLOCKWISEARC : { if(aNewB2DPolygon.count() > 1) { // #i76201# Add conversion to closed polygon when first and last points are equal basegfx::utils::checkClosed(aNewB2DPolygon); aNewB2DPolyPolygon.append(aNewB2DPolygon); } aNewB2DPolygon.clear(); [[fallthrough]]; } case ARCTO : case CLOCKWISEARCTO : { bool bClockwise = ( nCommand == CLOCKWISEARC ) || ( nCommand == CLOCKWISEARCTO ); sal_uInt32 nXor = bClockwise ? 3 : 2; for ( sal_uInt16 i = 0; ( i < nPntCount ) && ( ( rSrcPt + 3 ) < nCoordSize ); i++ ) { tools::Rectangle aRect = tools::Rectangle::Justify( GetPoint( seqCoordinates[ rSrcPt ], true, true ), GetPoint( seqCoordinates[ rSrcPt + 1 ], true, true ) ); if ( aRect.GetWidth() && aRect.GetHeight() ) { Point aStart( GetPoint( seqCoordinates[ static_cast( rSrcPt + nXor ) ], true, true ) ); Point aEnd( GetPoint( seqCoordinates[ static_cast( rSrcPt + ( nXor ^ 1 ) ) ], true, true ) ); aNewB2DPolygon.append(CreateArc( aRect, aStart, aEnd, bClockwise)); } rSrcPt += 4; } } break; case ARCANGLETO : { double fWR, fHR; // in Shape coordinate system double fStartAngle, fSwingAngle; // in deg for ( sal_uInt16 i = 0; ( i < nPntCount ) && ( rSrcPt + 1 < nCoordSize ); i++ ) { basegfx::B2DPoint aTempPair; aTempPair = GetPointAsB2DPoint(seqCoordinates[static_cast(rSrcPt)], false /*bScale*/, false /*bReplaceGeoSize*/); fWR = aTempPair.getX(); fHR = aTempPair.getY(); aTempPair = GetPointAsB2DPoint(seqCoordinates[static_cast(rSrcPt + 1)], false /*bScale*/, false /*bReplaceGeoSize*/); fStartAngle = aTempPair.getX(); fSwingAngle = aTempPair.getY(); // tdf#122323 MS Office clamps the swing angle to [-360,360]. Such restriction // is neither in OOXML nor in ODF. Nevertheless, to be compatible we do it for // "ooxml-foo" shapes. Those shapes have their origin in MS Office. if (bOOXMLShape) { fSwingAngle = std::clamp(fSwingAngle, -360.0, 360.0); } SAL_INFO("svx", "ARCANGLETO scale: " << fWR << "x" << fHR << " angles: " << fStartAngle << "," << fSwingAngle); if (aNewB2DPolygon.count() > 0) // otherwise no "current point" { // use similar methods as in command U basegfx::B2DPolygon aTempB2DPolygon; if (fWR == 0.0 && fHR == 0.0) { // degenerated ellipse, add this one point aTempB2DPolygon.append(basegfx::B2DPoint(0.0, 0.0)); } else { double fEndAngle = fStartAngle + fSwingAngle; // Generate arc with ellipse left|top = 0|0. basegfx::B2DPoint aCenter(fWR, fHR); if (fSwingAngle < 0.0) std::swap(fStartAngle, fEndAngle); double fS; // fFrom in radians in [0..2Pi[ double fE; // fTo or fEndAngle in radians in [0..2PI[ double fFrom(fStartAngle); // createPolygonFromEllipseSegment expects angles in [0..2PI[. if (fSwingAngle >= 360.0 || fSwingAngle <= -360.0) { double fTo(fFrom + 180.0); while (fTo < fEndAngle) { fS = lcl_getNormalizedCircleAngleRad(fWR, fHR, fFrom); fE = lcl_getNormalizedCircleAngleRad(fWR, fHR, fTo); aTempB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fWR, fHR, fS,fE)); fFrom = fTo; fTo += 180.0; } } fS = lcl_getNormalizedCircleAngleRad(fWR, fHR, fFrom); fE = lcl_getNormalizedCircleAngleRad(fWR, fHR, fEndAngle); aTempB2DPolygon.append(basegfx::utils::createPolygonFromEllipseSegment(aCenter, fWR, fHR,fS, fE)); if (fSwingAngle < 0) aTempB2DPolygon.flip(); aTempB2DPolygon.removeDoublePoints(); } // Scale arc to 1/100mm basegfx::B2DHomMatrix aMatrix = basegfx::utils::createScaleB2DHomMatrix(fXScale, fYScale); aTempB2DPolygon.transform(aMatrix); // Now that we have the arc, move it to the "current point". basegfx::B2DPoint aCurrentPointB2D( aNewB2DPolygon.getB2DPoint(aNewB2DPolygon.count() - 1 ) ); const double fDx(aCurrentPointB2D.getX() - aTempB2DPolygon.getB2DPoint(0).getX()); const double fDy(aCurrentPointB2D.getY() - aTempB2DPolygon.getB2DPoint(0).getY()); aMatrix = basegfx::utils::createTranslateB2DHomMatrix(fDx, fDy); aTempB2DPolygon.transform(aMatrix); aNewB2DPolygon.append(aTempB2DPolygon); } rSrcPt += 2; } } break; case ELLIPTICALQUADRANTX : case ELLIPTICALQUADRANTY : { if (nPntCount && (rSrcPt < nCoordSize)) { // The arc starts at the previous point and ends at the point given in the parameter. basegfx::B2DPoint aStart; basegfx::B2DPoint aEnd; sal_uInt16 i = 0; if (rSrcPt) { aStart = GetPointAsB2DPoint(seqCoordinates[rSrcPt - 1], true, true); } else { // no previous point, path is ill-structured. But we want to show as much as possible. // Thus make a moveTo to the point given as parameter and continue from there. aStart = GetPointAsB2DPoint(seqCoordinates[static_cast(rSrcPt)], true, true); aNewB2DPolygon.append(aStart); rSrcPt++; i++; } // If there are several points, then the direction changes with every point. bool bIsXDirection(nCommand == ELLIPTICALQUADRANTX); basegfx::B2DPolygon aArc; for ( ; ( i < nPntCount ) && ( rSrcPt < nCoordSize ); i++ ) { aEnd = GetPointAsB2DPoint(seqCoordinates[rSrcPt], true, true); basegfx::B2DPoint aCenter; double fRadiusX = fabs(aEnd.getX() - aStart.getX()); double fRadiusY = fabs(aEnd.getY() - aStart.getY()); if (bIsXDirection) { aCenter = basegfx::B2DPoint(aStart.getX(),aEnd.getY()); if (aEnd.getX()=aStart.getX() { if (aEnd.getY()=aStart.getX() { if (aEnd.getY() 1) { // #i76201# Add conversion to closed polygon when first and last points are equal basegfx::utils::checkClosed(aNewB2DPolygon); aNewB2DPolyPolygon.append(aNewB2DPolygon); } if(aNewB2DPolyPolygon.count()) { // #i37011# bool bForceCreateTwoObjects(false); if(!bSortFilledObjectsToBack && !aNewB2DPolyPolygon.isClosed() && !bNoStroke) { bForceCreateTwoObjects = true; } if(bLineGeometryNeededOnly) { bForceCreateTwoObjects = true; bNoFill = true; bNoStroke = false; } if(bForceCreateTwoObjects || bSortFilledObjectsToBack) { if(bFilled && !bNoFill) { basegfx::B2DPolyPolygon aClosedPolyPolygon(aNewB2DPolyPolygon); aClosedPolyPolygon.setClosed(true); SdrPathObj* pFill = new SdrPathObj( mrSdrObjCustomShape.getSdrModelFromSdrObject(), OBJ_POLY, aClosedPolyPolygon); SfxItemSet aTempSet(*this); aTempSet.Put(makeSdrShadowItem(false)); aTempSet.Put(XLineStyleItem(drawing::LineStyle_NONE)); pFill->SetMergedItemSet(aTempSet); rObjectList.push_back(std::pair< SdrPathObj*, double >(pFill, dBrightness)); } if(!bNoStroke) { // there is no reason to use OBJ_PLIN here when the polygon is actually closed, // the non-fill is defined by XFILL_NONE. Since SdrPathObj::ImpForceKind() needs // to correct the polygon (here: open it) using the type, the last edge may get lost. // Thus, use a type that fits the polygon SdrPathObj* pStroke = new SdrPathObj( mrSdrObjCustomShape.getSdrModelFromSdrObject(), aNewB2DPolyPolygon.isClosed() ? OBJ_POLY : OBJ_PLIN, aNewB2DPolyPolygon); SfxItemSet aTempSet(*this); aTempSet.Put(makeSdrShadowItem(false)); aTempSet.Put(XFillStyleItem(drawing::FillStyle_NONE)); pStroke->SetMergedItemSet(aTempSet); rObjectList.push_back(std::pair< SdrPathObj*, double >(pStroke, dBrightness)); } } else { SdrPathObj* pObj = nullptr; SfxItemSet aTempSet(*this); aTempSet.Put(makeSdrShadowItem(false)); if(bNoFill) { // see comment above about OBJ_PLIN pObj = new SdrPathObj( mrSdrObjCustomShape.getSdrModelFromSdrObject(), aNewB2DPolyPolygon.isClosed() ? OBJ_POLY : OBJ_PLIN, aNewB2DPolyPolygon); aTempSet.Put(XFillStyleItem(drawing::FillStyle_NONE)); } else { aNewB2DPolyPolygon.setClosed(true); pObj = new SdrPathObj( mrSdrObjCustomShape.getSdrModelFromSdrObject(), OBJ_POLY, aNewB2DPolyPolygon); } if(bNoStroke) { aTempSet.Put(XLineStyleItem(drawing::LineStyle_NONE)); } pObj->SetMergedItemSet(aTempSet); rObjectList.push_back(std::pair< SdrPathObj*, double >(pObj, dBrightness)); } } } static void CorrectCalloutArrows( MSO_SPT eSpType, sal_uInt32 nLineObjectCount, std::vector< std::pair< SdrPathObj*, double> >& vObjectList ) { bool bAccent = false; switch( eSpType ) { case mso_sptCallout1 : case mso_sptBorderCallout1 : case mso_sptCallout90 : case mso_sptBorderCallout90 : default: break; case mso_sptAccentCallout1 : case mso_sptAccentBorderCallout1 : case mso_sptAccentCallout90 : case mso_sptAccentBorderCallout90 : { sal_uInt32 nLine = 0; for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if(pObj->IsLine()) { nLine++; if ( nLine == nLineObjectCount ) { pObj->ClearMergedItem( XATTR_LINESTART ); pObj->ClearMergedItem( XATTR_LINEEND ); } } } } break; // switch start & end case mso_sptAccentCallout2 : case mso_sptAccentBorderCallout2 : bAccent = true; [[fallthrough]]; case mso_sptCallout2 : case mso_sptBorderCallout2 : { sal_uInt32 nLine = 0; for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if(pObj->IsLine()) { nLine++; if ( nLine == 1 ) pObj->ClearMergedItem( XATTR_LINEEND ); else if ( ( bAccent && ( nLine == nLineObjectCount - 1 ) ) || ( !bAccent && ( nLine == nLineObjectCount ) ) ) pObj->ClearMergedItem( XATTR_LINESTART ); else { pObj->ClearMergedItem( XATTR_LINESTART ); pObj->ClearMergedItem( XATTR_LINEEND ); } } } } break; case mso_sptAccentCallout3 : case mso_sptAccentBorderCallout3 : case mso_sptCallout3 : case mso_sptBorderCallout3 : { sal_uInt32 nLine = 0; for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if(pObj->IsLine()) { if ( nLine ) { pObj->ClearMergedItem( XATTR_LINESTART ); pObj->ClearMergedItem( XATTR_LINEEND ); } else EnhancedCustomShape2d::SwapStartAndEndArrow( pObj ); nLine++; } } } break; } } void EnhancedCustomShape2d::AdaptObjColor( SdrPathObj& rObj, double dBrightness, const SfxItemSet& rCustomShapeSet, sal_uInt32& nColorIndex, sal_uInt32 nColorCount) { if ( !rObj.IsLine() ) { const drawing::FillStyle eFillStyle = rObj.GetMergedItem(XATTR_FILLSTYLE).GetValue(); switch( eFillStyle ) { default: case drawing::FillStyle_SOLID: { Color aFillColor; if ( nColorCount || 0.0 != dBrightness ) { aFillColor = GetColorData( rCustomShapeSet.Get( XATTR_FILLCOLOR ).GetColorValue(), std::min(nColorIndex, nColorCount-1), dBrightness ); rObj.SetMergedItem( XFillColorItem( "", aFillColor ) ); } break; } case drawing::FillStyle_GRADIENT: { XGradient aXGradient(rObj.GetMergedItem(XATTR_FILLGRADIENT).GetGradientValue()); if ( nColorCount || 0.0 != dBrightness ) { aXGradient.SetStartColor( GetColorData( aXGradient.GetStartColor(), std::min(nColorIndex, nColorCount-1), dBrightness )); aXGradient.SetEndColor( GetColorData( aXGradient.GetEndColor(), std::min(nColorIndex, nColorCount-1), dBrightness )); } rObj.SetMergedItem( XFillGradientItem( "", aXGradient ) ); break; } case drawing::FillStyle_HATCH: { XHatch aXHatch(rObj.GetMergedItem(XATTR_FILLHATCH).GetHatchValue()); if ( nColorCount || 0.0 != dBrightness ) { aXHatch.SetColor( GetColorData( aXHatch.GetColor(), std::min(nColorIndex, nColorCount-1), dBrightness )); } rObj.SetMergedItem( XFillHatchItem( "", aXHatch ) ); break; } case drawing::FillStyle_BITMAP: { if ( nColorCount || 0.0 != dBrightness ) { BitmapEx aBitmap(rObj.GetMergedItem(XATTR_FILLBITMAP).GetGraphicObject().GetGraphic().GetBitmapEx()); short nLuminancePercent = static_cast< short > ( GetLuminanceChange( std::min(nColorIndex, nColorCount-1))); aBitmap.Adjust( nLuminancePercent, 0, 0, 0, 0 ); rObj.SetMergedItem(XFillBitmapItem(OUString(), Graphic(aBitmap))); } break; } } if ( nColorIndex < nColorCount ) nColorIndex++; } } SdrObject* EnhancedCustomShape2d::CreatePathObj( bool bLineGeometryNeededOnly ) { if ( !seqCoordinates.hasElements() ) { return nullptr; } std::vector< std::pair< SdrPathObj*, double > > vObjectList; const bool bSortFilledObjectsToBack(SortFilledObjectsToBackByDefault(eSpType)); sal_Int32 nSubPathIndex(0); sal_Int32 nSrcPt(0); sal_Int32 nSegmentInd(0); SdrObject* pRet(nullptr); while( nSegmentInd <= seqSegments.getLength() ) { CreateSubPath( nSrcPt, nSegmentInd, vObjectList, bLineGeometryNeededOnly, bSortFilledObjectsToBack, nSubPathIndex); nSubPathIndex++; } if ( !vObjectList.empty() ) { const SfxItemSet& rCustomShapeSet(mrSdrObjCustomShape.GetMergedItemSet()); const sal_uInt32 nColorCount(nColorData >> 28); sal_uInt32 nColorIndex(0); // #i37011# remove invisible objects std::vector< std::pair< SdrPathObj*, double> > vNewList; for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); const drawing::LineStyle eLineStyle(pObj->GetMergedItem(XATTR_LINESTYLE).GetValue()); const drawing::FillStyle eFillStyle(pObj->GetMergedItem(XATTR_FILLSTYLE).GetValue()); // #i40600# if bLineGeometryNeededOnly is set, linestyle does not matter if(!bLineGeometryNeededOnly && (drawing::LineStyle_NONE == eLineStyle) && (drawing::FillStyle_NONE == eFillStyle)) { // always use SdrObject::Free(...) for SdrObjects (!) SdrObject* pTemp(pObj); SdrObject::Free(pTemp); } else { vNewList.push_back(rCandidate); } } vObjectList = vNewList; if(1 == vObjectList.size()) { // a single object, correct some values AdaptObjColor( *vObjectList.begin()->first, vObjectList.begin()->second, rCustomShapeSet, nColorIndex, nColorCount); } else { sal_Int32 nLineObjectCount(0); // correct some values and collect content data for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if(pObj->IsLine()) { nLineObjectCount++; } else { AdaptObjColor( *pObj, rCandidate.second, rCustomShapeSet, nColorIndex, nColorCount); // OperationSmiley: when we have access to the SdrObjCustomShape and the // CustomShape is built with more than a single filled Geometry, use it // to define that all helper geometries defined here (SdrObjects currently) // will use the same FillGeometryDefinition (from the referenced SdrObjCustomShape). // This will all same-filled objects look like filled smoothly with the same style. pObj->setFillGeometryDefiningShape(&mrSdrObjCustomShape); } } // #i88870# correct line arrows for callouts if ( nLineObjectCount ) { CorrectCalloutArrows( eSpType, nLineObjectCount, vObjectList); } // sort objects so that filled ones are in front. Necessary // for some strange objects if(bSortFilledObjectsToBack) { std::vector< std::pair< SdrPathObj*, double> > vTempList; vTempList.reserve(vObjectList.size()); for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if ( !pObj->IsLine() ) { vTempList.push_back(rCandidate); } } for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); if ( pObj->IsLine() ) { vTempList.push_back(rCandidate); } } vObjectList = vTempList; } } } // #i37011# if(!vObjectList.empty()) { // copy remaining objects to pRet if(vObjectList.size() > 1) { pRet = new SdrObjGroup(mrSdrObjCustomShape.getSdrModelFromSdrObject()); for ( const std::pair< SdrPathObj*, double >& rCandidate : vObjectList ) { SdrPathObj* pObj(rCandidate.first); pRet->GetSubList()->NbcInsertObject(pObj); } } else if(1 == vObjectList.size()) { pRet = vObjectList.begin()->first; } if(pRet) { // move to target position tools::Rectangle aCurRect(pRet->GetSnapRect()); aCurRect.Move(aLogicRect.Left(), aLogicRect.Top()); pRet->NbcSetSnapRect(aCurRect); } } return pRet; } SdrObject* EnhancedCustomShape2d::CreateObject( bool bLineGeometryNeededOnly ) { SdrObject* pRet = nullptr; if ( eSpType == mso_sptRectangle ) { pRet = new SdrRectObj(mrSdrObjCustomShape.getSdrModelFromSdrObject(), aLogicRect); pRet->SetMergedItemSet( *this ); } if ( !pRet ) pRet = CreatePathObj( bLineGeometryNeededOnly ); return pRet; } void EnhancedCustomShape2d::ApplyGluePoints( SdrObject* pObj ) { if ( pObj ) { for ( const auto& rGluePoint : std::as_const(seqGluePoints) ) { SdrGluePoint aGluePoint; aGluePoint.SetPos( GetPoint( rGluePoint, true, true ) ); aGluePoint.SetPercent( false ); aGluePoint.SetAlign( SdrAlign::VERT_TOP | SdrAlign::HORZ_LEFT ); aGluePoint.SetEscDir( SdrEscapeDirection::SMART ); SdrGluePointList* pList = pObj->ForceGluePointList(); if( pList ) /* sal_uInt16 nId = */ pList->Insert( aGluePoint ); } } } SdrObject* EnhancedCustomShape2d::CreateLineGeometry() { return CreateObject( true ); } /* vim:set shiftwidth=4 softtabstop=4 expandtab: */