/************************************************************** * * 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 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. * *************************************************************/ #include "oox/drawingml/customshapeproperties.hxx" #include "oox/helper/helper.hxx" #include "oox/helper/propertymap.hxx" #include "oox/helper/propertyset.hxx" #include #include #include #include #include #include using rtl::OUString; using namespace ::oox::core; using namespace ::com::sun::star; using namespace ::com::sun::star::uno; using namespace ::com::sun::star::beans; using namespace ::com::sun::star::graphic; using namespace ::com::sun::star::drawing; namespace oox { namespace drawingml { CustomShapeProperties::CustomShapeProperties() : mbMirroredX ( sal_False ) , mbMirroredY ( sal_False ) { } CustomShapeProperties::~CustomShapeProperties() { } sal_Int32 CustomShapeProperties::SetCustomShapeGuideValue( std::vector< CustomShapeGuide >& rGuideList, const CustomShapeGuide& rGuide ) { sal_uInt32 nIndex = 0; for( ; nIndex < rGuideList.size(); nIndex++ ) { if ( rGuideList[ nIndex ].maName == rGuide.maName ) break; } if ( nIndex == rGuideList.size() ) rGuideList.push_back( rGuide ); return static_cast< sal_Int32 >( nIndex ); } // returns the index into the guidelist for a given formula name, // if the return value is < 0 then the guide value could not be found sal_Int32 CustomShapeProperties::GetCustomShapeGuideValue( const std::vector< CustomShapeGuide >& rGuideList, const rtl::OUString& rFormulaName ) { sal_Int32 nIndex = 0; for( ; nIndex < static_cast< sal_Int32 >( rGuideList.size() ); nIndex++ ) { if ( rGuideList[ nIndex ].maName == rFormulaName ) break; } if ( nIndex == static_cast< sal_Int32 >( rGuideList.size() ) ) nIndex = -1; return nIndex; } void CustomShapeProperties::apply( const CustomShapePropertiesPtr& /* rSourceCustomShapeProperties */ ) { // not sure if this needs to be implemented } void CustomShapeProperties::pushToPropSet( const ::oox::core::FilterBase& /* rFilterBase */, const Reference < XPropertySet >& xPropSet, const Reference < XShape > & xShape ) const { if ( maShapePresetType.getLength() ) { //const uno::Reference < drawing::XShape > xShape( xPropSet, UNO_QUERY ); Reference< drawing::XEnhancedCustomShapeDefaulter > xDefaulter( xShape, UNO_QUERY ); if( xDefaulter.is() ) xDefaulter->createCustomShapeDefaults( maShapePresetType ); if ( maAdjustmentGuideList.size() ) { const OUString sType = CREATE_OUSTRING( "Type" ); const OUString sCustomShapeGeometry( RTL_CONSTASCII_USTRINGPARAM( "CustomShapeGeometry" ) ); uno::Any aGeoPropSet = xPropSet->getPropertyValue( sCustomShapeGeometry ); uno::Sequence< beans::PropertyValue > aGeoPropSeq; if ( aGeoPropSet >>= aGeoPropSeq ) { sal_Int32 i, nCount = aGeoPropSeq.getLength(); for ( i = 0; i < nCount; i++ ) { const rtl::OUString sAdjustmentValues( RTL_CONSTASCII_USTRINGPARAM( "AdjustmentValues" ) ); if ( aGeoPropSeq[ i ].Name.equals( sAdjustmentValues ) ) { uno::Sequence< com::sun::star::drawing::EnhancedCustomShapeAdjustmentValue > aAdjustmentSeq; if ( aGeoPropSeq[ i ].Value >>= aAdjustmentSeq ) { std::vector< CustomShapeGuide >::const_iterator aIter( maAdjustmentGuideList.begin() ); while( aIter != maAdjustmentGuideList.end() ) { if ( (*aIter).maName.getLength() > 3 ) { sal_Int32 nAdjustmentIndex = (*aIter).maName.copy( 3 ).toInt32() - 1; if ( ( nAdjustmentIndex >= 0 ) && ( nAdjustmentIndex < aAdjustmentSeq.getLength() ) ) { EnhancedCustomShapeAdjustmentValue aAdjustmentVal; aAdjustmentVal.Value <<= (*aIter).maFormula.toInt32(); aAdjustmentVal.State = PropertyState_DIRECT_VALUE; aAdjustmentSeq[ nAdjustmentIndex ] = aAdjustmentVal; } } aIter++; } aGeoPropSeq[ i ].Value <<= aAdjustmentSeq; xPropSet->setPropertyValue( sCustomShapeGeometry, Any( aGeoPropSeq ) ); } } else if ( aGeoPropSeq[ i ].Name.equals( sType ) ) { aGeoPropSeq[ i ].Value <<= maShapePresetType; } } } } } else { sal_uInt32 i; PropertyMap aPropertyMap; aPropertyMap[ PROP_Type ] <<= CREATE_OUSTRING( "non-primitive" ); aPropertyMap[ PROP_MirroredX ] <<= Any( mbMirroredX ); aPropertyMap[ PROP_MirroredY ] <<= Any( mbMirroredY ); awt::Size aSize( xShape->getSize() ); awt::Rectangle aViewBox( 0, 0, aSize.Width * 360, aSize.Height * 360 ); if ( maPath2DList.size() ) { // TODO: each polygon may have its own size, but I think it is rather been used // so we are only taking care of the first if ( maPath2DList[ 0 ].w ) aViewBox.Width = static_cast< sal_Int32 >( maPath2DList[ 0 ].w ); if ( maPath2DList[ 0 ].h ) aViewBox.Height = static_cast< sal_Int32 >( maPath2DList[ 0 ].h ); } aPropertyMap[ PROP_ViewBox ] <<= aViewBox; Sequence< EnhancedCustomShapeAdjustmentValue > aAdjustmentValues( maAdjustmentGuideList.size() ); for ( i = 0; i < maAdjustmentGuideList.size(); i++ ) { EnhancedCustomShapeAdjustmentValue aAdjustmentVal; aAdjustmentVal.Value <<= maAdjustmentGuideList[ i ].maFormula.toInt32(); aAdjustmentVal.State = PropertyState_DIRECT_VALUE; aAdjustmentValues[ i ] = aAdjustmentVal; } aPropertyMap[ PROP_AdjustmentValues ] <<= aAdjustmentValues; Sequence< rtl::OUString > aEquations( maGuideList.size() ); for ( i = 0; i < maGuideList.size(); i++ ) aEquations[ i ] = maGuideList[ i ].maFormula; aPropertyMap[ PROP_Equations ] <<= aEquations; PropertyMap aPath; Sequence< EnhancedCustomShapeSegment > aSegments( maSegments.size() ); for ( i = 0; i < maSegments.size(); i++ ) aSegments[ i ] = maSegments[ i ]; aPath[ PROP_Segments ] <<= aSegments; sal_uInt32 j, k, nParameterPairs = 0; for ( i = 0; i < maPath2DList.size(); i++ ) nParameterPairs += maPath2DList[ i ].parameter.size(); Sequence< EnhancedCustomShapeParameterPair > aParameterPairs( nParameterPairs ); for ( i = 0, k = 0; i < maPath2DList.size(); i++ ) for ( j = 0; j < maPath2DList[ i ].parameter.size(); j++ ) aParameterPairs[ k++ ] = maPath2DList[ i ].parameter[ j ]; aPath[ PROP_Coordinates ] <<= aParameterPairs; Sequence< PropertyValue > aPathSequence = aPath.makePropertyValueSequence(); aPropertyMap[ PROP_Path ] <<= aPathSequence; Sequence< PropertyValues > aHandles( maAdjustHandleList.size() ); for ( i = 0; i < maAdjustHandleList.size(); i++ ) { PropertyMap aHandle; // maAdjustmentHandle[ i ].gdRef1 ... maAdjustmentHandle[ i ].gdRef2 ... :( // gdRef1 && gdRef2 -> we do not offer such reference, so it is difficult // to determine the correct adjustment handle that should be updated with the adjustment // position. here is the solution: the adjustment value that is used within the position // has to be updated, in case the position is a formula the first usage of a // adjument value is decisive if ( maAdjustHandleList[ i ].polar ) { aHandle[ PROP_Position ] <<= maAdjustHandleList[ i ].pos; if ( maAdjustHandleList[ i ].min1.has() ) aHandle[ PROP_RadiusRangeMinimum ] <<= maAdjustHandleList[ i ].min1.get(); if ( maAdjustHandleList[ i ].max1.has() ) aHandle[ PROP_RadiusRangeMaximum ] <<= maAdjustHandleList[ i ].max1.get(); /* TODO: AngleMin & AngleMax if ( maAdjustHandleList[ i ].min2.has() ) aHandle[ PROP_ ] = maAdjustHandleList[ i ].min2.get(); if ( maAdjustHandleList[ i ].max2.has() ) aHandle[ PROP_ ] = maAdjustHandleList[ i ].max2.get(); */ } else { aHandle[ PROP_Position ] <<= maAdjustHandleList[ i ].pos; if ( maAdjustHandleList[ i ].gdRef1.has() ) { // TODO: PROP_RefX and PROP_RefY are not yet part of our file format, // so the handles will not work after save/reload sal_Int32 nIndex = GetCustomShapeGuideValue( maAdjustmentGuideList, maAdjustHandleList[ i ].gdRef1.get() ); if ( nIndex >= 0 ) aHandle[ PROP_RefX ] <<= nIndex; } if ( maAdjustHandleList[ i ].gdRef2.has() ) { sal_Int32 nIndex = GetCustomShapeGuideValue( maAdjustmentGuideList, maAdjustHandleList[ i ].gdRef2.get() ); if ( nIndex >= 0 ) aHandle[ PROP_RefY ] <<= nIndex; } if ( maAdjustHandleList[ i ].min1.has() ) aHandle[ PROP_RangeXMinimum ] <<= maAdjustHandleList[ i ].min1.get(); if ( maAdjustHandleList[ i ].max1.has() ) aHandle[ PROP_RangeXMaximum ] <<= maAdjustHandleList[ i ].max1.get(); if ( maAdjustHandleList[ i ].min2.has() ) aHandle[ PROP_RangeYMinimum ] <<= maAdjustHandleList[ i ].min2.get(); if ( maAdjustHandleList[ i ].max2.has() ) aHandle[ PROP_RangeYMaximum ] <<= maAdjustHandleList[ i ].max2.get(); } aHandles[ i ] = aHandle.makePropertyValueSequence(); } aPropertyMap[ PROP_Handles ] <<= aHandles; // converting the vector to a sequence Sequence< PropertyValue > aSeq = aPropertyMap.makePropertyValueSequence(); PropertySet aPropSet( xPropSet ); aPropSet.setProperty( PROP_CustomShapeGeometry, aSeq ); } } double CustomShapeProperties::getValue( const std::vector< CustomShapeGuide >& rGuideList, sal_uInt32 nIndex ) const { double fRet = 0.0; if ( nIndex < rGuideList.size() ) { } return fRet; } } }