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If not, see * * for a copy of the LGPLv3 License. * ************************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_chart2.hxx" #include "AxisHelper.hxx" #include "DiagramHelper.hxx" #include "ChartTypeHelper.hxx" #include "macros.hxx" #include "AxisIndexDefines.hxx" #include "LineProperties.hxx" #include "ContainerHelper.hxx" #include "servicenames_coosystems.hxx" #include "DataSeriesHelper.hxx" #include "Scaling.hxx" #include "ChartModelHelper.hxx" #include "DataSourceHelper.hxx" #include #include #include #include #include #include #include // header for class OUStringBuffer #include #include #include #include #include //............................................................................. namespace chart { //............................................................................. using namespace ::com::sun::star; using namespace ::com::sun::star::chart2; using ::com::sun::star::uno::Reference; using ::com::sun::star::uno::Sequence; Reference< chart2::XScaling > AxisHelper::createLinearScaling() { return new LinearScaling( 1.0, 0.0 ); } Reference< chart2::XScaling > AxisHelper::createLogarithmicScaling( double fBase ) { return new LogarithmicScaling( fBase ); } ScaleData AxisHelper::createDefaultScale() { ScaleData aScaleData; aScaleData.AxisType = chart2::AxisType::REALNUMBER; aScaleData.AutoDateAxis = true; aScaleData.ShiftedCategoryPosition = false;//this is adapted in the view code currently Sequence< SubIncrement > aSubIncrements(1); aSubIncrements[0] = SubIncrement(); aScaleData.IncrementData.SubIncrements = aSubIncrements; return aScaleData; } void AxisHelper::removeExplicitScaling( ScaleData& rScaleData ) { uno::Any aEmpty; rScaleData.Minimum = rScaleData.Maximum = rScaleData.Origin = aEmpty; rScaleData.Scaling = 0; ScaleData aDefaultScale( createDefaultScale() ); rScaleData.IncrementData = aDefaultScale.IncrementData; rScaleData.TimeIncrement = aDefaultScale.TimeIncrement; } bool AxisHelper::isLogarithmic( const Reference< XScaling >& xScaling ) { bool bReturn = false; Reference< lang::XServiceName > xServiceName( xScaling, uno::UNO_QUERY ); bReturn =( xServiceName.is() && (xServiceName->getServiceName()).equals( C2U( "com.sun.star.chart2.LogarithmicScaling" ))); return bReturn; } chart2::ScaleData AxisHelper::getDateCheckedScale( const Reference< chart2::XAxis >& xAxis, const Reference< frame::XModel >& xChartModel ) { DBG_ASSERT(xChartModel.is(),"missing chart model"); ScaleData aScale = xAxis->getScaleData(); Reference< chart2::XCoordinateSystem > xCooSys( ChartModelHelper::getFirstCoordinateSystem( xChartModel ) ); if( aScale.AutoDateAxis && aScale.AxisType == AxisType::CATEGORY ) { sal_Int32 nDimensionIndex=0; sal_Int32 nAxisIndex=0; AxisHelper::getIndicesForAxis(xAxis, xCooSys, nDimensionIndex, nAxisIndex ); bool bChartTypeAllowsDateAxis = ChartTypeHelper::isSupportingDateAxis( AxisHelper::getChartTypeByIndex( xCooSys, 0 ), 2, nDimensionIndex ); if( bChartTypeAllowsDateAxis ) aScale.AxisType = AxisType::DATE; } if( aScale.AxisType == AxisType::DATE ) { ExplicitCategoriesProvider aExplicitCategoriesProvider( xCooSys,xChartModel ); if( !aExplicitCategoriesProvider.isDateAxis() ) aScale.AxisType = AxisType::CATEGORY; } return aScale; } void AxisHelper::checkDateAxis( chart2::ScaleData& rScale, ExplicitCategoriesProvider* pExplicitCategoriesProvider, bool bChartTypeAllowsDateAxis ) { if( rScale.AutoDateAxis && rScale.AxisType == AxisType::CATEGORY && bChartTypeAllowsDateAxis ) { rScale.AxisType = AxisType::DATE; removeExplicitScaling( rScale ); } if( rScale.AxisType == AxisType::DATE && (!pExplicitCategoriesProvider || !pExplicitCategoriesProvider->isDateAxis()) ) { rScale.AxisType = AxisType::CATEGORY; removeExplicitScaling( rScale ); } } sal_Int32 AxisHelper::getExplicitNumberFormatKeyForAxis( const Reference< chart2::XAxis >& xAxis , const Reference< chart2::XCoordinateSystem > & xCorrespondingCoordinateSystem , const Reference< util::XNumberFormatsSupplier >& xNumberFormatsSupplier , bool bSearchForParallelAxisIfNothingIsFound ) { sal_Int32 nNumberFormatKey(0); bool bNumberFormatKeyFoundViaAttachedData = false; sal_Int32 nAxisIndex = 0; sal_Int32 nDimensionIndex = 1; AxisHelper::getIndicesForAxis( xAxis, xCorrespondingCoordinateSystem, nDimensionIndex, nAxisIndex ); Reference< chart2::XChartDocument > xChartDoc( xNumberFormatsSupplier, uno::UNO_QUERY ); Reference< beans::XPropertySet > xProp( xAxis, uno::UNO_QUERY ); if( xProp.is() && !( xProp->getPropertyValue( C2U( "NumberFormat" ) ) >>= nNumberFormatKey ) ) { bool bFormatSet = false; //check wether we have a percent scale -> use percent format if( xNumberFormatsSupplier.is() ) { ScaleData aData = AxisHelper::getDateCheckedScale( xAxis, Reference< frame::XModel >( xNumberFormatsSupplier, uno::UNO_QUERY ) ); if( aData.AxisType==AxisType::PERCENT ) { sal_Int32 nPercentFormat = DiagramHelper::getPercentNumberFormat( xNumberFormatsSupplier ); if( nPercentFormat != -1 ) { nNumberFormatKey = nPercentFormat; bFormatSet = true; } } else if( aData.AxisType==AxisType::DATE ) { if( aData.Categories.is() ) { Reference< data::XDataSequence > xSeq( aData.Categories->getValues()); if( xSeq.is() && !( xChartDoc.is() && xChartDoc->hasInternalDataProvider()) ) nNumberFormatKey = xSeq->getNumberFormatKeyByIndex( -1 ); else nNumberFormatKey = DiagramHelper::getDateNumberFormat( xNumberFormatsSupplier ); bFormatSet = true; } } else if( xChartDoc.is() && xChartDoc->hasInternalDataProvider() && nDimensionIndex == 0 ) //maybe date axis { Reference< chart2::XDiagram > xDiagram( xChartDoc->getFirstDiagram() ); if( DiagramHelper::isSupportingDateAxis( xDiagram ) ) { nNumberFormatKey = DiagramHelper::getDateNumberFormat( xNumberFormatsSupplier ); } else { Reference< data::XDataSource > xSource( DataSourceHelper::getUsedData( xChartDoc ) ); if( xSource.is() ) { ::std::vector< Reference< chart2::data::XLabeledDataSequence > > aXValues( DataSeriesHelper::getAllDataSequencesByRole( xSource->getDataSequences(), C2U("values-x"), true ) ); if( aXValues.empty() ) { Reference< data::XLabeledDataSequence > xCategories( DiagramHelper::getCategoriesFromDiagram( xDiagram ) ); if( xCategories.is() ) { Reference< data::XDataSequence > xSeq( xCategories->getValues()); if( xSeq.is() ) { bool bHasValidDoubles = false; double fTest=0.0; Sequence< uno::Any > aCats( xSeq->getData() ); sal_Int32 nCount = aCats.getLength(); for( sal_Int32 i = 0; i < nCount; ++i ) { if( (aCats[i]>>=fTest) && !::rtl::math::isNan(fTest) ) { bHasValidDoubles=true; break; } } if( bHasValidDoubles ) nNumberFormatKey = DiagramHelper::getDateNumberFormat( xNumberFormatsSupplier ); } } } } } bFormatSet = true; } } if( !bFormatSet ) { typedef ::std::map< sal_Int32, sal_Int32 > tNumberformatFrequency; tNumberformatFrequency aKeyMap; try { Reference< XChartTypeContainer > xCTCnt( xCorrespondingCoordinateSystem, uno::UNO_QUERY_THROW ); if( xCTCnt.is() ) { ::rtl::OUString aRoleToMatch; if( nDimensionIndex == 0 ) aRoleToMatch = C2U("values-x"); Sequence< Reference< XChartType > > aChartTypes( xCTCnt->getChartTypes()); for( sal_Int32 nCTIdx=0; nCTIdx xDSCnt( aChartTypes[nCTIdx], uno::UNO_QUERY_THROW ); Sequence< Reference< XDataSeries > > aDataSeriesSeq( xDSCnt->getDataSeries()); for( sal_Int32 nSeriesIdx=0; nSeriesIdx xDataSeries(aDataSeriesSeq[nSeriesIdx]); Reference< data::XDataSource > xSource( xDataSeries, uno::UNO_QUERY_THROW ); if( nDimensionIndex == 1 ) { //only take those series into accoutn that are attached to this axis sal_Int32 nAttachedAxisIndex = DataSeriesHelper::getAttachedAxisIndex(xDataSeries); if( nAttachedAxisIndex != nAxisIndex ) continue; } Reference< data::XLabeledDataSequence > xLabeledSeq( DataSeriesHelper::getDataSequenceByRole( xSource, aRoleToMatch ) ); if( !xLabeledSeq.is() && nDimensionIndex==0 ) { ScaleData aData = xAxis->getScaleData(); xLabeledSeq = aData.Categories; } if( xLabeledSeq.is() ) { Reference< data::XDataSequence > xSeq( xLabeledSeq->getValues()); if( xSeq.is() ) { sal_Int32 nKey = xSeq->getNumberFormatKeyByIndex( -1 ); // initialize the value if( aKeyMap.find( nKey ) == aKeyMap.end()) aKeyMap[ nKey ] = 0; // increase frequency aKeyMap[ nKey ] = (aKeyMap[ nKey ] + 1); } } } } } } catch( const uno::Exception & ex ) { ASSERT_EXCEPTION( ex ); } if( ! aKeyMap.empty()) { sal_Int32 nMaxFreq = 0; // find most frequent key for( tNumberformatFrequency::const_iterator aIt = aKeyMap.begin(); aIt != aKeyMap.end(); ++aIt ) { OSL_TRACE( "NumberFormatKey %d appears %d times", (*aIt).first, (*aIt).second ); // all values must at least be 1 if( (*aIt).second > nMaxFreq ) { nNumberFormatKey = (*aIt).first; bNumberFormatKeyFoundViaAttachedData = true; nMaxFreq = (*aIt).second; } } } if( bSearchForParallelAxisIfNothingIsFound ) { //no format is set to this axis and no data is set to this axis //--> try to obtain the format from the parallel y-axis if( !bNumberFormatKeyFoundViaAttachedData && nDimensionIndex == 1 ) { sal_Int32 nParallelAxisIndex = (nAxisIndex==1) ?0 :1; Reference< XAxis > xParallelAxis( AxisHelper::getAxis( 1, nParallelAxisIndex, xCorrespondingCoordinateSystem ) ); nNumberFormatKey = AxisHelper::getExplicitNumberFormatKeyForAxis( xParallelAxis, xCorrespondingCoordinateSystem, xNumberFormatsSupplier, false ); } } } } return nNumberFormatKey; } Reference< XAxis > AxisHelper::createAxis( sal_Int32 nDimensionIndex , sal_Int32 nAxisIndex // 0==main or 1==secondary axis , const Reference< XCoordinateSystem >& xCooSys , const Reference< uno::XComponentContext > & xContext , ReferenceSizeProvider * pRefSizeProvider ) { if( !xContext.is() || !xCooSys.is() ) return NULL; if( nDimensionIndex >= xCooSys->getDimension() ) return NULL; Reference< XAxis > xAxis( xContext->getServiceManager()->createInstanceWithContext( C2U( "com.sun.star.chart2.Axis" ), xContext ), uno::UNO_QUERY ); OSL_ASSERT( xAxis.is()); if( xAxis.is()) { xCooSys->setAxisByDimension( nDimensionIndex, xAxis, nAxisIndex ); if( nAxisIndex>0 )//when inserting secondary axes copy some things from the main axis { ::com::sun::star::chart::ChartAxisPosition eNewAxisPos( ::com::sun::star::chart::ChartAxisPosition_END ); Reference< XAxis > xMainAxis( xCooSys->getAxisByDimension( nDimensionIndex, 0 ) ); if( xMainAxis.is() ) { ScaleData aScale = xAxis->getScaleData(); ScaleData aMainScale = xMainAxis->getScaleData(); aScale.AxisType = aMainScale.AxisType; aScale.AutoDateAxis = aMainScale.AutoDateAxis; aScale.Categories = aMainScale.Categories; aScale.Orientation = aMainScale.Orientation; xAxis->setScaleData( aScale ); //ensure that the second axis is not placed on the main axis Reference< beans::XPropertySet > xMainProp( xMainAxis, uno::UNO_QUERY ); if( xMainProp.is() ) { ::com::sun::star::chart::ChartAxisPosition eMainAxisPos( ::com::sun::star::chart::ChartAxisPosition_ZERO ); xMainProp->getPropertyValue(C2U( "CrossoverPosition" )) >>= eMainAxisPos; if( ::com::sun::star::chart::ChartAxisPosition_END == eMainAxisPos ) eNewAxisPos = ::com::sun::star::chart::ChartAxisPosition_START; } } Reference< beans::XPropertySet > xProp( xAxis, uno::UNO_QUERY ); if( xProp.is() ) xProp->setPropertyValue(C2U( "CrossoverPosition" ), uno::makeAny(eNewAxisPos) ); } Reference< beans::XPropertySet > xProp( xAxis, uno::UNO_QUERY ); if( xProp.is() ) try { // set correct initial AutoScale if( pRefSizeProvider ) pRefSizeProvider->setValuesAtPropertySet( xProp ); } catch( uno::Exception& e ) { ASSERT_EXCEPTION( e ); } } return xAxis; } Reference< XAxis > AxisHelper::createAxis( sal_Int32 nDimensionIndex, bool bMainAxis , const Reference< chart2::XDiagram >& xDiagram , const Reference< uno::XComponentContext >& xContext , ReferenceSizeProvider * pRefSizeProvider ) { OSL_ENSURE( xContext.is(), "need a context to create an axis" ); if( !xContext.is() ) return NULL; sal_Int32 nAxisIndex = bMainAxis ? MAIN_AXIS_INDEX : SECONDARY_AXIS_INDEX; sal_Int32 nCooSysIndex = 0; Reference< XCoordinateSystem > xCooSys = AxisHelper::getCoordinateSystemByIndex( xDiagram, nCooSysIndex ); // create axis return AxisHelper::createAxis( nDimensionIndex, nAxisIndex, xCooSys, xContext, pRefSizeProvider ); } void AxisHelper::showAxis( sal_Int32 nDimensionIndex, bool bMainAxis , const Reference< chart2::XDiagram >& xDiagram , const Reference< uno::XComponentContext >& xContext , ReferenceSizeProvider * pRefSizeProvider ) { if( !xDiagram.is() ) return; bool bNewAxisCreated = false; Reference< XAxis > xAxis( AxisHelper::getAxis( nDimensionIndex, bMainAxis, xDiagram ) ); if( !xAxis.is() && xContext.is() ) { // create axis bNewAxisCreated = true; xAxis.set( AxisHelper::createAxis( nDimensionIndex, bMainAxis, xDiagram, xContext, pRefSizeProvider ) ); } OSL_ASSERT( xAxis.is()); if( !bNewAxisCreated ) //default is true already if created AxisHelper::makeAxisVisible( xAxis ); } void AxisHelper::showGrid( sal_Int32 nDimensionIndex, sal_Int32 nCooSysIndex, bool bMainGrid , const Reference< XDiagram >& xDiagram , const Reference< uno::XComponentContext >& /*xContext*/ ) { if( !xDiagram.is() ) return; Reference< XCoordinateSystem > xCooSys = AxisHelper::getCoordinateSystemByIndex( xDiagram, nCooSysIndex ); if(!xCooSys.is()) return; Reference< XAxis > xAxis( AxisHelper::getAxis( nDimensionIndex, MAIN_AXIS_INDEX, xCooSys ) ); if(!xAxis.is()) { //hhhh todo create axis without axis visibility } if(!xAxis.is()) return; if( bMainGrid ) AxisHelper::makeGridVisible( xAxis->getGridProperties() ); else { Sequence< Reference< beans::XPropertySet > > aSubGrids( xAxis->getSubGridProperties() ); for( sal_Int32 nN=0; nN& xAxis ) { Reference< beans::XPropertySet > xProps( xAxis, uno::UNO_QUERY ); if( xProps.is() ) { xProps->setPropertyValue( C2U( "Show" ), uno::makeAny( sal_True ) ); LineProperties::SetLineVisible( xProps ); xProps->setPropertyValue( C2U( "DisplayLabels" ), uno::makeAny( sal_True ) ); } } void AxisHelper::makeGridVisible( const Reference< beans::XPropertySet >& xGridProperties ) { if( xGridProperties.is() ) { xGridProperties->setPropertyValue( C2U( "Show" ), uno::makeAny( sal_True ) ); LineProperties::SetLineVisible( xGridProperties ); } } void AxisHelper::hideAxis( sal_Int32 nDimensionIndex, bool bMainAxis , const Reference< XDiagram >& xDiagram ) { AxisHelper::makeAxisInvisible( AxisHelper::getAxis( nDimensionIndex, bMainAxis, xDiagram ) ); } void AxisHelper::makeAxisInvisible( const Reference< XAxis >& xAxis ) { Reference< beans::XPropertySet > xProps( xAxis, uno::UNO_QUERY ); if( xProps.is() ) { xProps->setPropertyValue( C2U( "Show" ), uno::makeAny( sal_False ) ); } } void AxisHelper::hideAxisIfNoDataIsAttached( const Reference< XAxis >& xAxis, const Reference< XDiagram >& xDiagram ) { //axis is hidden if no data is attached anymore but data is available bool bOtherSeriesAttachedToThisAxis = false; ::std::vector< Reference< chart2::XDataSeries > > aSeriesVector( DiagramHelper::getDataSeriesFromDiagram( xDiagram ) ); ::std::vector< Reference< chart2::XDataSeries > >::const_iterator aIt = aSeriesVector.begin(); for( ; aIt != aSeriesVector.end(); ++aIt) { uno::Reference< chart2::XAxis > xCurrentAxis( DiagramHelper::getAttachedAxis( *aIt, xDiagram ), uno::UNO_QUERY ); if( xCurrentAxis==xAxis ) { bOtherSeriesAttachedToThisAxis = true; break; } } if(!bOtherSeriesAttachedToThisAxis && !aSeriesVector.empty() ) AxisHelper::makeAxisInvisible( xAxis ); } void AxisHelper::hideGrid( sal_Int32 nDimensionIndex, sal_Int32 nCooSysIndex, bool bMainGrid , const Reference< XDiagram >& xDiagram ) { if( !xDiagram.is() ) return; Reference< XCoordinateSystem > xCooSys = AxisHelper::getCoordinateSystemByIndex( xDiagram, nCooSysIndex ); if(!xCooSys.is()) return; Reference< XAxis > xAxis( AxisHelper::getAxis( nDimensionIndex, MAIN_AXIS_INDEX, xCooSys ) ); if(!xAxis.is()) return; if( bMainGrid ) AxisHelper::makeGridInvisible( xAxis->getGridProperties() ); else { Sequence< Reference< beans::XPropertySet > > aSubGrids( xAxis->getSubGridProperties() ); for( sal_Int32 nN=0; nN& xGridProperties ) { if( xGridProperties.is() ) { xGridProperties->setPropertyValue( C2U( "Show" ), uno::makeAny( sal_False ) ); } } sal_Bool AxisHelper::isGridShown( sal_Int32 nDimensionIndex, sal_Int32 nCooSysIndex, bool bMainGrid , const Reference< ::com::sun::star::chart2::XDiagram >& xDiagram ) { sal_Bool bRet = false; Reference< XCoordinateSystem > xCooSys = AxisHelper::getCoordinateSystemByIndex( xDiagram, nCooSysIndex ); if(!xCooSys.is()) return bRet; Reference< XAxis > xAxis( AxisHelper::getAxis( nDimensionIndex, MAIN_AXIS_INDEX, xCooSys ) ); if(!xAxis.is()) return bRet; if( bMainGrid ) bRet = AxisHelper::isGridVisible( xAxis->getGridProperties() ); else { Sequence< Reference< beans::XPropertySet > > aSubGrids( xAxis->getSubGridProperties() ); if( aSubGrids.getLength() ) bRet = AxisHelper::isGridVisible( aSubGrids[0] ); } return bRet; } Reference< XCoordinateSystem > AxisHelper::getCoordinateSystemByIndex( const Reference< XDiagram >& xDiagram, sal_Int32 nIndex ) { Reference< XCoordinateSystemContainer > xCooSysContainer( xDiagram, uno::UNO_QUERY ); if(!xCooSysContainer.is()) return NULL; Sequence< Reference< XCoordinateSystem > > aCooSysList = xCooSysContainer->getCoordinateSystems(); if(0<=nIndex && nIndex AxisHelper::getAxis( sal_Int32 nDimensionIndex, bool bMainAxis , const Reference< XDiagram >& xDiagram ) { Reference< XAxis > xRet; try { Reference< XCoordinateSystem > xCooSys = AxisHelper::getCoordinateSystemByIndex( xDiagram, 0 ); xRet.set( AxisHelper::getAxis( nDimensionIndex, bMainAxis ? 0 : 1, xCooSys ) ); } catch( const uno::Exception & ) { } return xRet; } Reference< XAxis > AxisHelper::getAxis( sal_Int32 nDimensionIndex, sal_Int32 nAxisIndex , const Reference< XCoordinateSystem >& xCooSys ) { Reference< XAxis > xRet; try { if( xCooSys.is() ) xRet.set( xCooSys->getAxisByDimension( nDimensionIndex, nAxisIndex ) ); } catch( const uno::Exception & ) { } return xRet; } Reference< XAxis > AxisHelper::getCrossingMainAxis( const Reference< XAxis >& xAxis , const Reference< XCoordinateSystem >& xCooSys ) { sal_Int32 nDimensionIndex = 0; sal_Int32 nAxisIndex = 0; AxisHelper::getIndicesForAxis( xAxis, xCooSys, nDimensionIndex, nAxisIndex ); if( 2==nDimensionIndex ) { nDimensionIndex=1; bool bSwapXY = false; Reference< beans::XPropertySet > xCooSysProp( xCooSys, uno::UNO_QUERY ); if( xCooSysProp.is() && (xCooSysProp->getPropertyValue( C2U("SwapXAndYAxis") ) >>= bSwapXY) && bSwapXY ) nDimensionIndex=0; } else if( 1==nDimensionIndex ) nDimensionIndex=0; else nDimensionIndex=1; return AxisHelper::getAxis( nDimensionIndex, 0, xCooSys ); } Reference< XAxis > AxisHelper::getParallelAxis( const Reference< XAxis >& xAxis , const Reference< XDiagram >& xDiagram ) { try { sal_Int32 nCooSysIndex=-1; sal_Int32 nDimensionIndex=-1; sal_Int32 nAxisIndex=-1; if( getIndicesForAxis( xAxis, xDiagram, nCooSysIndex, nDimensionIndex, nAxisIndex ) ) { sal_Int32 nParallelAxisIndex = (nAxisIndex==1) ?0 :1; return getAxis( nDimensionIndex, nParallelAxisIndex, getCoordinateSystemByIndex( xDiagram, nCooSysIndex ) ); } } catch( uno::RuntimeException& ) { } return 0; } sal_Bool AxisHelper::isAxisShown( sal_Int32 nDimensionIndex, bool bMainAxis , const Reference< XDiagram >& xDiagram ) { return AxisHelper::isAxisVisible( AxisHelper::getAxis( nDimensionIndex, bMainAxis, xDiagram ) ); } sal_Bool AxisHelper::isAxisVisible( const Reference< XAxis >& xAxis ) { sal_Bool bRet = false; Reference< beans::XPropertySet > xProps( xAxis, uno::UNO_QUERY ); if( xProps.is() ) { xProps->getPropertyValue( C2U( "Show" ) ) >>= bRet; bRet = bRet && ( LineProperties::IsLineVisible( xProps ) || areAxisLabelsVisible( xProps ) ); } return bRet; } sal_Bool AxisHelper::areAxisLabelsVisible( const Reference< beans::XPropertySet >& xAxisProperties ) { sal_Bool bRet = false; if( xAxisProperties.is() ) { xAxisProperties->getPropertyValue( C2U( "DisplayLabels" ) ) >>= bRet; } return bRet; } sal_Bool AxisHelper::isGridVisible( const Reference< beans::XPropertySet >& xGridProperies ) { sal_Bool bRet = false; if( xGridProperies.is() ) { xGridProperies->getPropertyValue( C2U( "Show" ) ) >>= bRet; bRet = bRet && LineProperties::IsLineVisible( xGridProperies ); } return bRet; } Reference< beans::XPropertySet > AxisHelper::getGridProperties( const Reference< XCoordinateSystem >& xCooSys , sal_Int32 nDimensionIndex, sal_Int32 nAxisIndex, sal_Int32 nSubGridIndex ) { Reference< beans::XPropertySet > xRet; Reference< XAxis > xAxis( AxisHelper::getAxis( nDimensionIndex, nAxisIndex, xCooSys ) ); if( xAxis.is() ) { if( nSubGridIndex<0 ) xRet.set( xAxis->getGridProperties() ); else { Sequence< Reference< beans::XPropertySet > > aSubGrids( xAxis->getSubGridProperties() ); if( nSubGridIndex >= 0 && nSubGridIndex < aSubGrids.getLength() ) xRet.set( aSubGrids[nSubGridIndex] ); } } return xRet; } sal_Int32 AxisHelper::getDimensionIndexOfAxis( const Reference< XAxis >& xAxis , const Reference< XDiagram >& xDiagram ) { sal_Int32 nDimensionIndex = -1; sal_Int32 nCooSysIndex = -1; sal_Int32 nAxisIndex = -1; AxisHelper::getIndicesForAxis( xAxis, xDiagram, nCooSysIndex , nDimensionIndex, nAxisIndex ); return nDimensionIndex; } bool AxisHelper::getIndicesForAxis( const Reference< XAxis >& xAxis , const Reference< XCoordinateSystem >& xCooSys , sal_Int32& rOutDimensionIndex, sal_Int32& rOutAxisIndex ) { //returns true if indices are found rOutDimensionIndex = -1; rOutAxisIndex = -1; if( xCooSys.is() && xAxis.is() ) { Reference< XAxis > xCurrentAxis; sal_Int32 nDimensionCount( xCooSys->getDimension() ); for( sal_Int32 nDimensionIndex = 0; nDimensionIndex < nDimensionCount; nDimensionIndex++ ) { sal_Int32 nMaxAxisIndex = xCooSys->getMaximumAxisIndexByDimension(nDimensionIndex); for( sal_Int32 nAxisIndex = 0; nAxisIndex <= nMaxAxisIndex; nAxisIndex++ ) { xCurrentAxis = xCooSys->getAxisByDimension(nDimensionIndex,nAxisIndex); if( xCurrentAxis == xAxis ) { rOutDimensionIndex = nDimensionIndex; rOutAxisIndex = nAxisIndex; return true; } } } } return false; } bool AxisHelper::getIndicesForAxis( const Reference< XAxis >& xAxis, const Reference< XDiagram >& xDiagram , sal_Int32& rOutCooSysIndex, sal_Int32& rOutDimensionIndex, sal_Int32& rOutAxisIndex ) { //returns true if indices are found rOutCooSysIndex = -1; rOutDimensionIndex = -1; rOutAxisIndex = -1; Reference< XCoordinateSystemContainer > xCooSysContainer( xDiagram, uno::UNO_QUERY ); if(xCooSysContainer.is()) { Sequence< Reference< XCoordinateSystem > > aCooSysList = xCooSysContainer->getCoordinateSystems(); for( sal_Int32 nC=0; nC > AxisHelper::getAllAxesOfCoordinateSystem( const Reference< XCoordinateSystem >& xCooSys , bool bOnlyVisible /* = false */ ) { std::vector< Reference< XAxis > > aAxisVector; if(xCooSys.is()) { sal_Int32 nDimensionIndex = 0; sal_Int32 nMaxDimensionIndex = xCooSys->getDimension() -1; if( nMaxDimensionIndex>=0 ) { for(nDimensionIndex=0; nDimensionIndex<=nMaxDimensionIndex; ++nDimensionIndex) { const sal_Int32 nMaximumAxisIndex = xCooSys->getMaximumAxisIndexByDimension(nDimensionIndex); for(sal_Int32 nAxisIndex=0; nAxisIndex<=nMaximumAxisIndex; ++nAxisIndex) { try { Reference< XAxis > xAxis( xCooSys->getAxisByDimension( nDimensionIndex, nAxisIndex ) ); bool bAddAxis = true; if( xAxis.is() ) { if( bOnlyVisible ) { Reference< beans::XPropertySet > xAxisProp( xAxis, uno::UNO_QUERY ); if( !xAxisProp.is() || !(xAxisProp->getPropertyValue( C2U("Show")) >>= bAddAxis) ) bAddAxis = false; } if( bAddAxis ) aAxisVector.push_back( xAxis ); } } catch( const uno::Exception & ex ) { ASSERT_EXCEPTION( ex ); } } } } } return aAxisVector; } Sequence< Reference< XAxis > > AxisHelper::getAllAxesOfDiagram( const Reference< XDiagram >& xDiagram , bool bOnlyVisible ) { std::vector< Reference< XAxis > > aAxisVector; Reference< XCoordinateSystemContainer > xCooSysContainer( xDiagram, uno::UNO_QUERY ); if(xCooSysContainer.is()) { Sequence< Reference< XCoordinateSystem > > aCooSysList = xCooSysContainer->getCoordinateSystems(); sal_Int32 nC = 0; for( nC=0; nC > aAxesPerCooSys( AxisHelper::getAllAxesOfCoordinateSystem( aCooSysList[nC], bOnlyVisible ) ); aAxisVector.insert( aAxisVector.end(), aAxesPerCooSys.begin(), aAxesPerCooSys.end() ); } } return ContainerHelper::ContainerToSequence( aAxisVector ); } Sequence< Reference< beans::XPropertySet > > AxisHelper::getAllGrids( const Reference< XDiagram >& xDiagram ) { Sequence< Reference< XAxis > > aAllAxes( AxisHelper::getAllAxesOfDiagram( xDiagram ) ); std::vector< Reference< beans::XPropertySet > > aGridVector; sal_Int32 nA = 0; for( nA=0; nA xAxis( aAllAxes[nA] ); if(!xAxis.is()) continue; Reference< beans::XPropertySet > xGridProperties( xAxis->getGridProperties() ); if( xGridProperties.is() ) aGridVector.push_back( xGridProperties ); Sequence< Reference< beans::XPropertySet > > aSubGrids( xAxis->getSubGridProperties() );; sal_Int32 nSubGrid = 0; for( nSubGrid = 0; nSubGrid < aSubGrids.getLength(); ++nSubGrid ) { Reference< beans::XPropertySet > xSubGrid( aSubGrids[nSubGrid] ); if( xSubGrid.is() ) aGridVector.push_back( xSubGrid ); } } return ContainerHelper::ContainerToSequence( aGridVector ); } void AxisHelper::getAxisOrGridPossibilities( Sequence< sal_Bool >& rPossibilityList , const Reference< XDiagram>& xDiagram, sal_Bool bAxis ) { rPossibilityList.realloc(6); sal_Int32 nDimensionCount = DiagramHelper::getDimension( xDiagram ); //set possibilities: sal_Int32 nIndex=0; Reference< XChartType > xChartType = DiagramHelper::getChartTypeByIndex( xDiagram, 0 ); for(nIndex=0;nIndex<3;nIndex++) rPossibilityList[nIndex]=ChartTypeHelper::isSupportingMainAxis(xChartType,nDimensionCount,nIndex); for(nIndex=3;nIndex<6;nIndex++) if( bAxis ) rPossibilityList[nIndex]=ChartTypeHelper::isSupportingSecondaryAxis(xChartType,nDimensionCount,nIndex-3); else rPossibilityList[nIndex] = rPossibilityList[nIndex-3]; } bool AxisHelper::isSecondaryYAxisNeeded( const Reference< XCoordinateSystem >& xCooSys ) { Reference< chart2::XChartTypeContainer > xCTCnt( xCooSys, uno::UNO_QUERY ); if( xCTCnt.is() ) { Sequence< Reference< chart2::XChartType > > aChartTypes( xCTCnt->getChartTypes() ); for( sal_Int32 i=0; i xSeriesContainer( aChartTypes[i] , uno::UNO_QUERY ); if( !xSeriesContainer.is() ) continue; Sequence< Reference< XDataSeries > > aSeriesList( xSeriesContainer->getDataSeries() ); for( sal_Int32 nS = aSeriesList.getLength(); nS-- ; ) { Reference< beans::XPropertySet > xProp( aSeriesList[nS], uno::UNO_QUERY ); if(xProp.is()) { sal_Int32 nAttachedAxisIndex = 0; if( ( xProp->getPropertyValue( C2U( "AttachedAxisIndex" ) ) >>= nAttachedAxisIndex ) && nAttachedAxisIndex>0 ) return true; } } } } return false; } bool AxisHelper::shouldAxisBeDisplayed( const Reference< XAxis >& xAxis , const Reference< XCoordinateSystem >& xCooSys ) { bool bRet = false; if( xAxis.is() && xCooSys.is() ) { sal_Int32 nDimensionIndex=-1; sal_Int32 nAxisIndex=-1; if( AxisHelper::getIndicesForAxis( xAxis, xCooSys, nDimensionIndex, nAxisIndex ) ) { sal_Int32 nDimensionCount = xCooSys->getDimension(); Reference< XChartType > xChartType( AxisHelper::getChartTypeByIndex( xCooSys, 0 ) ); bool bMainAxis = (nAxisIndex==MAIN_AXIS_INDEX); if( bMainAxis ) bRet = ChartTypeHelper::isSupportingMainAxis(xChartType,nDimensionCount,nDimensionIndex); else bRet = ChartTypeHelper::isSupportingSecondaryAxis(xChartType,nDimensionCount,nDimensionIndex); } } return bRet; } void AxisHelper::getAxisOrGridExcistence( Sequence< sal_Bool >& rExistenceList , const Reference< XDiagram>& xDiagram, sal_Bool bAxis ) { rExistenceList.realloc(6); if(bAxis) { sal_Int32 nN; Reference< XAxis > xAxis; for(nN=0;nN<3;nN++) rExistenceList[nN] = AxisHelper::isAxisShown( nN, true, xDiagram ); for(nN=3;nN<6;nN++) rExistenceList[nN] = AxisHelper::isAxisShown( nN%3, false, xDiagram ); } else { sal_Int32 nN; for(nN=0;nN<3;nN++) rExistenceList[nN] = AxisHelper::isGridShown( nN, 0, true, xDiagram ); for(nN=3;nN<6;nN++) rExistenceList[nN] = AxisHelper::isGridShown( nN%3, 0, false, xDiagram ); } } bool AxisHelper::changeVisibilityOfAxes( const Reference< XDiagram >& xDiagram , const Sequence< sal_Bool >& rOldExistenceList , const Sequence< sal_Bool >& rNewExistenceList , const Reference< uno::XComponentContext >& xContext , ReferenceSizeProvider * pRefSizeProvider ) { bool bChanged = false; for(sal_Int32 nN=0;nN<6;nN++) { if(rOldExistenceList[nN]!=rNewExistenceList[nN]) { bChanged = true; if(rNewExistenceList[nN]) { AxisHelper::showAxis( nN%3, nN<3, xDiagram, xContext, pRefSizeProvider ); } else AxisHelper::hideAxis( nN%3, nN<3, xDiagram ); } } return bChanged; } bool AxisHelper::changeVisibilityOfGrids( const Reference< XDiagram >& xDiagram , const Sequence< sal_Bool >& rOldExistenceList , const Sequence< sal_Bool >& rNewExistenceList , const Reference< uno::XComponentContext >& xContext ) { bool bChanged = false; for(sal_Int32 nN=0;nN<6;nN++) { if(rOldExistenceList[nN]!=rNewExistenceList[nN]) { bChanged = true; if(rNewExistenceList[nN]) AxisHelper::showGrid( nN%3, 0, nN<3, xDiagram, xContext ); else AxisHelper::hideGrid( nN%3, 0, nN<3, xDiagram ); } } return bChanged; } Reference< XCoordinateSystem > AxisHelper::getCoordinateSystemOfAxis( const Reference< XAxis >& xAxis , const Reference< XDiagram >& xDiagram ) { Reference< XCoordinateSystem > xRet; Reference< XCoordinateSystemContainer > xCooSysContainer( xDiagram, uno::UNO_QUERY ); if( xCooSysContainer.is() ) { Reference< XCoordinateSystem > xCooSys; Sequence< Reference< XCoordinateSystem > > aCooSysList( xCooSysContainer->getCoordinateSystems() ); for( sal_Int32 nCooSysIndex = 0; nCooSysIndex < aCooSysList.getLength(); ++nCooSysIndex ) { xCooSys = aCooSysList[nCooSysIndex]; std::vector< Reference< XAxis > > aAllAxis( AxisHelper::getAllAxesOfCoordinateSystem( xCooSys ) ); ::std::vector< Reference< XAxis > >::iterator aFound = ::std::find( aAllAxis.begin(), aAllAxis.end(), xAxis ); if( aFound != aAllAxis.end()) { xRet.set( xCooSys ); break; } } } return xRet; } Reference< XChartType > AxisHelper::getChartTypeByIndex( const Reference< XCoordinateSystem >& xCooSys, sal_Int32 nIndex ) { Reference< XChartType > xChartType; Reference< XChartTypeContainer > xChartTypeContainer( xCooSys, uno::UNO_QUERY ); if( xChartTypeContainer.is() ) { Sequence< Reference< XChartType > > aChartTypeList( xChartTypeContainer->getChartTypes() ); if( nIndex >= 0 && nIndex < aChartTypeList.getLength() ) xChartType.set( aChartTypeList[nIndex] ); } return xChartType; } void AxisHelper::setRTLAxisLayout( const Reference< XCoordinateSystem >& xCooSys ) { if( xCooSys.is() ) { bool bCartesian = xCooSys->getViewServiceName().equals( CHART2_COOSYSTEM_CARTESIAN_VIEW_SERVICE_NAME ); if( bCartesian ) { bool bVertical = false; Reference< beans::XPropertySet > xCooSysProp( xCooSys, uno::UNO_QUERY ); if( xCooSysProp.is() ) xCooSysProp->getPropertyValue( C2U("SwapXAndYAxis") ) >>= bVertical; sal_Int32 nHorizontalAxisDimension = bVertical ? 1 : 0; sal_Int32 nVerticalAxisDimension = bVertical ? 0 : 1; try { //reverse direction for horizontal main axis Reference< chart2::XAxis > xHorizontalMainAxis( AxisHelper::getAxis( nHorizontalAxisDimension, MAIN_AXIS_INDEX, xCooSys ) ); if( xHorizontalMainAxis.is() ) { chart2::ScaleData aScale = xHorizontalMainAxis->getScaleData(); aScale.Orientation = chart2::AxisOrientation_REVERSE; xHorizontalMainAxis->setScaleData(aScale); } //mathematical direction for vertical main axis Reference< chart2::XAxis > xVerticalMainAxis( AxisHelper::getAxis( nVerticalAxisDimension, MAIN_AXIS_INDEX, xCooSys ) ); if( xVerticalMainAxis.is() ) { chart2::ScaleData aScale = xVerticalMainAxis->getScaleData(); aScale.Orientation = chart2::AxisOrientation_MATHEMATICAL; xVerticalMainAxis->setScaleData(aScale); } } catch( uno::Exception & ex ) { ASSERT_EXCEPTION( ex ); } try { //reverse direction for horizontal secondary axis Reference< chart2::XAxis > xHorizontalSecondaryAxis( AxisHelper::getAxis( nHorizontalAxisDimension, SECONDARY_AXIS_INDEX, xCooSys ) ); if( xHorizontalSecondaryAxis.is() ) { chart2::ScaleData aScale = xHorizontalSecondaryAxis->getScaleData(); aScale.Orientation = chart2::AxisOrientation_REVERSE; xHorizontalSecondaryAxis->setScaleData(aScale); } //mathematical direction for vertical secondary axis Reference< chart2::XAxis > xVerticalSecondaryAxis( AxisHelper::getAxis( nVerticalAxisDimension, SECONDARY_AXIS_INDEX, xCooSys ) ); if( xVerticalSecondaryAxis.is() ) { chart2::ScaleData aScale = xVerticalSecondaryAxis->getScaleData(); aScale.Orientation = chart2::AxisOrientation_MATHEMATICAL; xVerticalSecondaryAxis->setScaleData(aScale); } } catch( uno::Exception & ex ) { ASSERT_EXCEPTION( ex ); } } } } Reference< XChartType > AxisHelper::getFirstChartTypeWithSeriesAttachedToAxisIndex( const Reference< chart2::XDiagram >& xDiagram, const sal_Int32 nAttachedAxisIndex ) { Reference< XChartType > xChartType; ::std::vector< Reference< XDataSeries > > aSeriesVector( DiagramHelper::getDataSeriesFromDiagram( xDiagram ) ); ::std::vector< Reference< XDataSeries > >::const_iterator aIter = aSeriesVector.begin(); for( ; aIter != aSeriesVector.end(); aIter++ ) { sal_Int32 nCurrentIndex = DataSeriesHelper::getAttachedAxisIndex( *aIter ); if( nAttachedAxisIndex == nCurrentIndex ) { xChartType = DiagramHelper::getChartTypeOfSeries( xDiagram, *aIter ); if(xChartType.is()) break; } } return xChartType; } bool AxisHelper::isAxisPositioningEnabled() { const SvtSaveOptions::ODFDefaultVersion nCurrentVersion( SvtSaveOptions().GetODFDefaultVersion() ); return nCurrentVersion >= SvtSaveOptions::ODFVER_012; } //............................................................................. } //namespace chart //.............................................................................