/* -*- 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 using namespace ::com::sun::star; using ::com::sun::star::uno::Reference; using ::com::sun::star::uno::Sequence; namespace chart { RegressionCurveCalculator::RegressionCurveCalculator() : m_fCorrelationCoefficient(std::numeric_limits::quiet_NaN()) , mDegree(2) , mForceIntercept(false) , mInterceptValue(std::numeric_limits::quiet_NaN()) , mPeriod(2) , mXName("x") , mYName("f(x)") , mnMovingType(0) { } RegressionCurveCalculator::~RegressionCurveCalculator() {} bool RegressionCurveCalculator::isLinearScaling( const Reference< chart2::XScaling > & xScaling ) { // no scaling means linear if( !xScaling.is()) return true; uno::Reference< lang::XServiceName > xServiceName( xScaling, uno::UNO_QUERY ); return xServiceName.is() && xServiceName->getServiceName() == "com.sun.star.chart2.LinearScaling"; } bool RegressionCurveCalculator::isLogarithmicScaling( const Reference< chart2::XScaling > & xScaling ) { uno::Reference< lang::XServiceName > xServiceName( xScaling, uno::UNO_QUERY ); return xServiceName.is() && xServiceName->getServiceName() == "com.sun.star.chart2.LogarithmicScaling"; } void RegressionCurveCalculator::setRegressionProperties( sal_Int32 aDegree, sal_Bool aForceIntercept, double aInterceptValue, sal_Int32 aPeriod, sal_Int32 nMovingType ) { if( aPeriod < 0 ) throw lang::IllegalArgumentException("aPeriod may not be < 0", static_cast(this), 3); mDegree = aDegree; mForceIntercept = aForceIntercept; mInterceptValue = aInterceptValue; mPeriod = aPeriod; mnMovingType = nMovingType; } OUString RegressionCurveCalculator::getFormattedString( const Reference< util::XNumberFormatter >& xNumFormatter, sal_Int32 nNumberFormatKey, double fNumber, const sal_Int32* pStringLength /* = nullptr */ ) { if ( pStringLength && *pStringLength <= 0 ) return "###"; OUString aResult; if( xNumFormatter.is() ) { bool bStandard = ::cppu::any2bool( ::comphelper::getNumberFormatProperty( xNumFormatter, nNumberFormatKey, "StandardFormat" ) ); if( pStringLength && bStandard ) { // round fNumber to *pStringLength characters const sal_Int32 nMinDigit = 6; // minimum significant digits for General format sal_Int32 nSignificantDigit = ( *pStringLength <= nMinDigit ? nMinDigit : *pStringLength ); aResult = ::rtl::math::doubleToUString( fNumber, rtl_math_StringFormat_G1, nSignificantDigit, '.', true ); // count characters different from significant digits (decimal separator, scientific notation) sal_Int32 nExtraChar = aResult.getLength() - *pStringLength; if ( nExtraChar > 0 && *pStringLength > nMinDigit ) { nSignificantDigit = *pStringLength - nExtraChar; if ( nSignificantDigit < nMinDigit ) nSignificantDigit = nMinDigit; aResult = ::rtl::math::doubleToUString( fNumber, rtl_math_StringFormat_G1, nSignificantDigit, '.', true ); } fNumber = ::rtl::math::stringToDouble( aResult, '.', ',' ); } aResult = xNumFormatter->convertNumberToString( nNumberFormatKey, fNumber ); } else { sal_Int32 nStringLength = 4; // default length if ( pStringLength ) nStringLength = *pStringLength; aResult = ::rtl::math::doubleToUString( fNumber, rtl_math_StringFormat_G1, nStringLength, '.', true ); } return aResult; } Sequence< geometry::RealPoint2D > SAL_CALL RegressionCurveCalculator::getCurveValues( double min, double max, ::sal_Int32 nPointCount, const Reference< chart2::XScaling >& xScalingX, const Reference< chart2::XScaling >& /* xScalingY */, sal_Bool /* bMaySkipPointsInCalculation */ ) { if( nPointCount < 2 ) throw lang::IllegalArgumentException("too few points", static_cast(this), 2); // determine if scaling and inverse scaling for x-values work bool bDoXScaling( xScalingX.is()); uno::Reference< chart2::XScaling > xInverseScaling; if( bDoXScaling ) xInverseScaling.set( xScalingX->getInverseScaling()); bDoXScaling = bDoXScaling && xInverseScaling.is(); Sequence< geometry::RealPoint2D > aResult( nPointCount ); auto pResult = aResult.getArray(); double fMin( min ); double fFact = (max - min) / double(nPointCount-1); if( bDoXScaling ) { fMin = xScalingX->doScaling( min ); fFact = (xScalingX->doScaling( max ) - fMin) / double(nPointCount-1); } for(sal_Int32 nP=0; nPdoScaling( x ); pResult[nP].X = x; pResult[nP].Y = getCurveValue( x ); } return aResult; } double SAL_CALL RegressionCurveCalculator::getCorrelationCoefficient() { return m_fCorrelationCoefficient; } OUString SAL_CALL RegressionCurveCalculator::getRepresentation() { return ImplGetRepresentation( Reference< util::XNumberFormatter >(), 0 ); } OUString SAL_CALL RegressionCurveCalculator::getFormattedRepresentation( const Reference< util::XNumberFormatsSupplier > & xNumFmtSupplier, sal_Int32 nNumberFormatKey, sal_Int32 nFormulaLength ) { // create and prepare a number formatter if( !xNumFmtSupplier.is()) return getRepresentation(); Reference< uno::XComponentContext > xContext( comphelper::getProcessComponentContext(), uno::UNO_SET_THROW ); Reference< util::XNumberFormatter > xNumFormatter( util::NumberFormatter::create(xContext), uno::UNO_QUERY_THROW ); xNumFormatter->attachNumberFormatsSupplier( xNumFmtSupplier ); if ( nFormulaLength > 0 ) return ImplGetRepresentation( xNumFormatter, nNumberFormatKey, &nFormulaLength ); return ImplGetRepresentation( xNumFormatter, nNumberFormatKey ); } void RegressionCurveCalculator::addStringToEquation( OUStringBuffer& aStrEquation, sal_Int32& nLineLength, OUStringBuffer const & aAddString, const sal_Int32* pMaxWidth) { if ( pMaxWidth && ( nLineLength + aAddString.getLength() > *pMaxWidth ) ) { // wrap line aStrEquation.append( "\n " ); // start new line with a blank nLineLength = 1; } aStrEquation.append( aAddString ); nLineLength += aAddString.getLength(); } void SAL_CALL RegressionCurveCalculator::setXYNames( const OUString& aXName, const OUString& aYName ) { if ( aXName.isEmpty() ) mXName = OUString ("x"); else mXName = aXName; if ( aYName.isEmpty() ) mYName = OUString ("f(x)"); else mYName = aYName; } } // namespace chart /* vim:set shiftwidth=4 softtabstop=4 expandtab: */