main/chart2/source/tools/PotentialRegressionCurveCalculator.cxx - openoffice - Git at Google

 /**************************************************************
  *
  * 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.
  *
  *************************************************************/


 // MARKER(update_precomp.py): autogen include statement, do not remove
 #include "precompiled_chart2.hxx"
 #include "PotentialRegressionCurveCalculator.hxx"
 #include "macros.hxx"
 #include "RegressionCalculationHelper.hxx"

 #include <rtl/math.hxx>
 #include <rtl/ustrbuf.hxx>

 using namespace ::com::sun::star;

 using ::rtl::OUString;
 using ::rtl::OUStringBuffer;

 namespace chart
 {

 PotentialRegressionCurveCalculator::PotentialRegressionCurveCalculator() :
         m_fSlope( 0.0 ),
         m_fIntercept( 0.0 )
 {
     ::rtl::math::setNan( & m_fSlope );
     ::rtl::math::setNan( & m_fIntercept );
 }

 PotentialRegressionCurveCalculator::~PotentialRegressionCurveCalculator()
 {}

 // ____ XRegressionCurveCalculator ____
 void SAL_CALL PotentialRegressionCurveCalculator::recalculateRegression(
     const uno::Sequence< double >& aXValues,
     const uno::Sequence< double >& aYValues )
     throw (uno::RuntimeException)
 {
     RegressionCalculationHelper::tDoubleVectorPair aValues(
         RegressionCalculationHelper::cleanup(
             aXValues, aYValues,
             RegressionCalculationHelper::isValidAndBothPositive()));

     const size_t nMax = aValues.first.size();
     if( nMax == 0 )
     {
         ::rtl::math::setNan( & m_fSlope );
         ::rtl::math::setNan( & m_fIntercept );
         ::rtl::math::setNan( & m_fCorrelationCoeffitient );
         return;
     }

     double fAverageX = 0.0, fAverageY = 0.0;
     size_t i = 0;
     for( i = 0; i < nMax; ++i )
     {
         fAverageX += log( aValues.first[i] );
         fAverageY += log( aValues.second[i] );
     }

     const double fN = static_cast< double >( nMax );
     fAverageX /= fN;
     fAverageY /= fN;

     double fQx = 0.0, fQy = 0.0, fQxy = 0.0;
     for( i = 0; i < nMax; ++i )
     {
         double fDeltaX = log( aValues.first[i] ) - fAverageX;
         double fDeltaY = log( aValues.second[i] ) - fAverageY;

         fQx  += fDeltaX * fDeltaX;
         fQy  += fDeltaY * fDeltaY;
         fQxy += fDeltaX * fDeltaY;
     }

     m_fSlope = fQxy / fQx;
     m_fIntercept = fAverageY - m_fSlope * fAverageX;
     m_fCorrelationCoeffitient = fQxy / sqrt( fQx * fQy );

     m_fIntercept = exp( m_fIntercept );
 }

 double SAL_CALL PotentialRegressionCurveCalculator::getCurveValue( double x )
     throw (lang::IllegalArgumentException,
            uno::RuntimeException)
 {
     double fResult;
     ::rtl::math::setNan( & fResult );

     if( ! ( ::rtl::math::isNan( m_fSlope ) ||
             ::rtl::math::isNan( m_fIntercept )))
     {
         fResult = m_fIntercept * pow( x, m_fSlope );
     }

     return fResult;
 }

 uno::Sequence< geometry::RealPoint2D > SAL_CALL PotentialRegressionCurveCalculator::getCurveValues(
     double min, double max, ::sal_Int32 nPointCount,
     const uno::Reference< chart2::XScaling >& xScalingX,
     const uno::Reference< chart2::XScaling >& xScalingY,
     ::sal_Bool bMaySkipPointsInCalculation )
     throw (lang::IllegalArgumentException,
            uno::RuntimeException)
 {
     if( bMaySkipPointsInCalculation &&
         isLogarithmicScaling( xScalingX ) &&
         isLogarithmicScaling( xScalingY ))
     {
         // optimize result
         uno::Sequence< geometry::RealPoint2D > aResult( 2 );
         aResult[0].X = min;
         aResult[0].Y = this->getCurveValue( min );
         aResult[1].X = max;
         aResult[1].Y = this->getCurveValue( max );

         return aResult;
     }
     return RegressionCurveCalculator::getCurveValues( min, max, nPointCount, xScalingX, xScalingY, bMaySkipPointsInCalculation );
 }

 OUString PotentialRegressionCurveCalculator::ImplGetRepresentation(
     const uno::Reference< util::XNumberFormatter >& xNumFormatter,
     ::sal_Int32 nNumberFormatKey ) const
 {
     OUStringBuffer aBuf( C2U( "f(x) = " ));

     if( m_fIntercept == 0.0 )
     {
         aBuf.append( sal_Unicode( '0' ));
     }
     else if( m_fSlope == 0.0 )
     {
         aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fIntercept ));
     }
     else
     {
         if( ! rtl::math::approxEqual( m_fIntercept, 1.0 ) )
         {
             aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fIntercept ));
             aBuf.append( sal_Unicode( ' ' ));
         }
         if( m_fSlope != 0.0 )
         {
             aBuf.appendAscii( RTL_CONSTASCII_STRINGPARAM( "x^" ));
             aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fSlope ));
         }
     }

     return aBuf.makeStringAndClear();
 }

 } //  namespace chart
	/**************************************************************
	*
	* 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.
	*
	*************************************************************/



	// MARKER(update_precomp.py): autogen include statement, do not remove
	#include "precompiled_chart2.hxx"
	#include "PotentialRegressionCurveCalculator.hxx"
	#include "macros.hxx"
	#include "RegressionCalculationHelper.hxx"

	#include <rtl/math.hxx>
	#include <rtl/ustrbuf.hxx>

	using namespace ::com::sun::star;

	using ::rtl::OUString;
	using ::rtl::OUStringBuffer;

	namespace chart
	{

	PotentialRegressionCurveCalculator::PotentialRegressionCurveCalculator() :
	m_fSlope( 0.0 ),
	m_fIntercept( 0.0 )
	{
	::rtl::math::setNan( & m_fSlope );
	::rtl::math::setNan( & m_fIntercept );
	}

	PotentialRegressionCurveCalculator::~PotentialRegressionCurveCalculator()
	{}

	// ____ XRegressionCurveCalculator ____
	void SAL_CALL PotentialRegressionCurveCalculator::recalculateRegression(
	const uno::Sequence< double >& aXValues,
	const uno::Sequence< double >& aYValues )
	throw (uno::RuntimeException)
	{
	RegressionCalculationHelper::tDoubleVectorPair aValues(
	RegressionCalculationHelper::cleanup(
	aXValues, aYValues,
	RegressionCalculationHelper::isValidAndBothPositive()));

	const size_t nMax = aValues.first.size();
	if( nMax == 0 )
	{
	::rtl::math::setNan( & m_fSlope );
	::rtl::math::setNan( & m_fIntercept );
	::rtl::math::setNan( & m_fCorrelationCoeffitient );
	return;
	}

	double fAverageX = 0.0, fAverageY = 0.0;
	size_t i = 0;
	for( i = 0; i < nMax; ++i )
	{
	fAverageX += log( aValues.first[i] );
	fAverageY += log( aValues.second[i] );
	}

	const double fN = static_cast< double >( nMax );
	fAverageX /= fN;
	fAverageY /= fN;

	double fQx = 0.0, fQy = 0.0, fQxy = 0.0;
	for( i = 0; i < nMax; ++i )
	{
	double fDeltaX = log( aValues.first[i] ) - fAverageX;
	double fDeltaY = log( aValues.second[i] ) - fAverageY;

	fQx += fDeltaX * fDeltaX;
	fQy += fDeltaY * fDeltaY;
	fQxy += fDeltaX * fDeltaY;
	}

	m_fSlope = fQxy / fQx;
	m_fIntercept = fAverageY - m_fSlope * fAverageX;
	m_fCorrelationCoeffitient = fQxy / sqrt( fQx * fQy );

	m_fIntercept = exp( m_fIntercept );
	}

	double SAL_CALL PotentialRegressionCurveCalculator::getCurveValue( double x )
	throw (lang::IllegalArgumentException,
	uno::RuntimeException)
	{
	double fResult;
	::rtl::math::setNan( & fResult );

	if( ! ( ::rtl::math::isNan( m_fSlope ) \|\|
	::rtl::math::isNan( m_fIntercept )))
	{
	fResult = m_fIntercept * pow( x, m_fSlope );
	}

	return fResult;
	}

	uno::Sequence< geometry::RealPoint2D > SAL_CALL PotentialRegressionCurveCalculator::getCurveValues(
	double min, double max, ::sal_Int32 nPointCount,
	const uno::Reference< chart2::XScaling >& xScalingX,
	const uno::Reference< chart2::XScaling >& xScalingY,
	::sal_Bool bMaySkipPointsInCalculation )
	throw (lang::IllegalArgumentException,
	uno::RuntimeException)
	{
	if( bMaySkipPointsInCalculation &&
	isLogarithmicScaling( xScalingX ) &&
	isLogarithmicScaling( xScalingY ))
	{
	// optimize result
	uno::Sequence< geometry::RealPoint2D > aResult( 2 );
	aResult[0].X = min;
	aResult[0].Y = this->getCurveValue( min );
	aResult[1].X = max;
	aResult[1].Y = this->getCurveValue( max );

	return aResult;
	}
	return RegressionCurveCalculator::getCurveValues( min, max, nPointCount, xScalingX, xScalingY, bMaySkipPointsInCalculation );
	}

	OUString PotentialRegressionCurveCalculator::ImplGetRepresentation(
	const uno::Reference< util::XNumberFormatter >& xNumFormatter,
	::sal_Int32 nNumberFormatKey ) const
	{
	OUStringBuffer aBuf( C2U( "f(x) = " ));

	if( m_fIntercept == 0.0 )
	{
	aBuf.append( sal_Unicode( '0' ));
	}
	else if( m_fSlope == 0.0 )
	{
	aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fIntercept ));
	}
	else
	{
	if( ! rtl::math::approxEqual( m_fIntercept, 1.0 ) )
	{
	aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fIntercept ));
	aBuf.append( sal_Unicode( ' ' ));
	}
	if( m_fSlope != 0.0 )
	{
	aBuf.appendAscii( RTL_CONSTASCII_STRINGPARAM( "x^" ));
	aBuf.append( getFormattedString( xNumFormatter, nNumberFormatKey, m_fSlope ));
	}
	}

	return aBuf.makeStringAndClear();
	}

	} // namespace chart