unsupported/Eigen/src/Polynomials/PolynomialUtils.h - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2010 Manuel Yguel <manuel.yguel@gmail.com>
 //
 // 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/.

 #ifndef EIGEN_POLYNOMIAL_UTILS_H
 #define EIGEN_POLYNOMIAL_UTILS_H

 namespace Eigen {

 /** \ingroup Polynomials_Module
  * \returns the evaluation of the polynomial at x using Horner algorithm.
  *
  * \param[in] poly : the vector of coefficients of the polynomial ordered
  *  by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
  *  e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
  * \param[in] x : the value to evaluate the polynomial at.
  *
  * \note for stability:
  *   \f$ |x| \le 1 \f$
  */
 template <typename Polynomials, typename T>
 inline
 T poly_eval_horner( const Polynomials& poly, const T& x )
 {
   T val=poly[poly.size()-1];
   for(DenseIndex i=poly.size()-2; i>=0; --i ){
     val = val*x + poly[i]; }
   return val;
 }

 /** \ingroup Polynomials_Module
  * \returns the evaluation of the polynomial at x using stabilized Horner algorithm.
  *
  * \param[in] poly : the vector of coefficients of the polynomial ordered
  *  by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
  *  e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
  * \param[in] x : the value to evaluate the polynomial at.
  */
 template <typename Polynomials, typename T>
 inline
 T poly_eval( const Polynomials& poly, const T& x )
 {
   typedef typename NumTraits<T>::Real Real;

   if( numext::abs2( x ) <= Real(1) ){
     return poly_eval_horner( poly, x ); }
   else
   {
     T val=poly[0];
     T inv_x = T(1)/x;
     for( DenseIndex i=1; i<poly.size(); ++i ){
       val = val*inv_x + poly[i]; }

     return numext::pow(x,(T)(poly.size()-1)) * val;
   }
 }

 /** \ingroup Polynomials_Module
  * \returns a maximum bound for the absolute value of any root of the polynomial.
  *
  * \param[in] poly : the vector of coefficients of the polynomial ordered
  *  by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
  *  e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
  *
  *  \pre
  *   the leading coefficient of the input polynomial poly must be non zero
  */
 template <typename Polynomial>
 inline
 typename NumTraits<typename Polynomial::Scalar>::Real cauchy_max_bound( const Polynomial& poly )
 {
   using std::abs;
   typedef typename Polynomial::Scalar Scalar;
   typedef typename NumTraits<Scalar>::Real Real;

   eigen_assert( Scalar(0) != poly[poly.size()-1] );
   const Scalar inv_leading_coeff = Scalar(1)/poly[poly.size()-1];
   Real cb(0);

   for( DenseIndex i=0; i<poly.size()-1; ++i ){
     cb += abs(poly[i]*inv_leading_coeff); }
   return cb + Real(1);
 }

 /** \ingroup Polynomials_Module
  * \returns a minimum bound for the absolute value of any non zero root of the polynomial.
  * \param[in] poly : the vector of coefficients of the polynomial ordered
  *  by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
  *  e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
  */
 template <typename Polynomial>
 inline
 typename NumTraits<typename Polynomial::Scalar>::Real cauchy_min_bound( const Polynomial& poly )
 {
   using std::abs;
   typedef typename Polynomial::Scalar Scalar;
   typedef typename NumTraits<Scalar>::Real Real;

   DenseIndex i=0;
   while( i<poly.size()-1 && Scalar(0) == poly(i) ){ ++i; }
   if( poly.size()-1 == i ){
     return Real(1); }

   const Scalar inv_min_coeff = Scalar(1)/poly[i];
   Real cb(1);
   for( DenseIndex j=i+1; j<poly.size(); ++j ){
     cb += abs(poly[j]*inv_min_coeff); }
   return Real(1)/cb;
 }

 /** \ingroup Polynomials_Module
  * Given the roots of a polynomial compute the coefficients in the
  * monomial basis of the monic polynomial with same roots and minimal degree.
  * If RootVector is a vector of complexes, Polynomial should also be a vector
  * of complexes.
  * \param[in] rv : a vector containing the roots of a polynomial.
  * \param[out] poly : the vector of coefficients of the polynomial ordered
  *  by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
  *  e.g. \f$ 3 + x^2 \f$ is stored as a vector \f$ [ 3, 0, 1 ] \f$.
  */
 template <typename RootVector, typename Polynomial>
 void roots_to_monicPolynomial( const RootVector& rv, Polynomial& poly )
 {

   typedef typename Polynomial::Scalar Scalar;

   poly.setZero( rv.size()+1 );
   poly[0] = -rv[0]; poly[1] = Scalar(1);
   for( DenseIndex i=1; i< rv.size(); ++i )
   {
     for( DenseIndex j=i+1; j>0; --j ){ poly[j] = poly[j-1] - rv[i]*poly[j]; }
     poly[0] = -rv[i]*poly[0];
   }
 }

 } // end namespace Eigen

 #endif // EIGEN_POLYNOMIAL_UTILS_H
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2010 Manuel Yguel <manuel.yguel@gmail.com>
	//
	// 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/.

	#ifndef EIGEN_POLYNOMIAL_UTILS_H
	#define EIGEN_POLYNOMIAL_UTILS_H

	namespace Eigen {

	/** \ingroup Polynomials_Module
	* \returns the evaluation of the polynomial at x using Horner algorithm.
	*
	* \param[in] poly : the vector of coefficients of the polynomial ordered
	* by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
	* e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
	* \param[in] x : the value to evaluate the polynomial at.
	*
	* \note for stability:
	* \f$ \|x\| \le 1 \f$
	*/
	template <typename Polynomials, typename T>
	inline
	T poly_eval_horner( const Polynomials& poly, const T& x )
	{
	T val=poly[poly.size()-1];
	for(DenseIndex i=poly.size()-2; i>=0; --i ){
	val = val*x + poly[i]; }
	return val;
	}

	/** \ingroup Polynomials_Module
	* \returns the evaluation of the polynomial at x using stabilized Horner algorithm.
	*
	* \param[in] poly : the vector of coefficients of the polynomial ordered
	* by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
	* e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
	* \param[in] x : the value to evaluate the polynomial at.
	*/
	template <typename Polynomials, typename T>
	inline
	T poly_eval( const Polynomials& poly, const T& x )
	{
	typedef typename NumTraits<T>::Real Real;

	if( numext::abs2( x ) <= Real(1) ){
	return poly_eval_horner( poly, x ); }
	else
	{
	T val=poly[0];
	T inv_x = T(1)/x;
	for( DenseIndex i=1; i<poly.size(); ++i ){
	val = val*inv_x + poly[i]; }

	return numext::pow(x,(T)(poly.size()-1)) * val;
	}
	}

	/** \ingroup Polynomials_Module
	* \returns a maximum bound for the absolute value of any root of the polynomial.
	*
	* \param[in] poly : the vector of coefficients of the polynomial ordered
	* by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
	* e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
	*
	* \pre
	* the leading coefficient of the input polynomial poly must be non zero
	*/
	template <typename Polynomial>
	inline
	typename NumTraits<typename Polynomial::Scalar>::Real cauchy_max_bound( const Polynomial& poly )
	{
	using std::abs;
	typedef typename Polynomial::Scalar Scalar;
	typedef typename NumTraits<Scalar>::Real Real;

	eigen_assert( Scalar(0) != poly[poly.size()-1] );
	const Scalar inv_leading_coeff = Scalar(1)/poly[poly.size()-1];
	Real cb(0);

	for( DenseIndex i=0; i<poly.size()-1; ++i ){
	cb += abs(poly[i]*inv_leading_coeff); }
	return cb + Real(1);
	}

	/** \ingroup Polynomials_Module
	* \returns a minimum bound for the absolute value of any non zero root of the polynomial.
	* \param[in] poly : the vector of coefficients of the polynomial ordered
	* by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
	* e.g. \f$ 1 + 3x^2 \f$ is stored as a vector \f$ [ 1, 0, 3 ] \f$.
	*/
	template <typename Polynomial>
	inline
	typename NumTraits<typename Polynomial::Scalar>::Real cauchy_min_bound( const Polynomial& poly )
	{
	using std::abs;
	typedef typename Polynomial::Scalar Scalar;
	typedef typename NumTraits<Scalar>::Real Real;

	DenseIndex i=0;
	while( i<poly.size()-1 && Scalar(0) == poly(i) ){ ++i; }
	if( poly.size()-1 == i ){
	return Real(1); }

	const Scalar inv_min_coeff = Scalar(1)/poly[i];
	Real cb(1);
	for( DenseIndex j=i+1; j<poly.size(); ++j ){
	cb += abs(poly[j]*inv_min_coeff); }
	return Real(1)/cb;
	}

	/** \ingroup Polynomials_Module
	* Given the roots of a polynomial compute the coefficients in the
	* monomial basis of the monic polynomial with same roots and minimal degree.
	* If RootVector is a vector of complexes, Polynomial should also be a vector
	* of complexes.
	* \param[in] rv : a vector containing the roots of a polynomial.
	* \param[out] poly : the vector of coefficients of the polynomial ordered
	* by degrees i.e. poly[i] is the coefficient of degree i of the polynomial
	* e.g. \f$ 3 + x^2 \f$ is stored as a vector \f$ [ 3, 0, 1 ] \f$.
	*/
	template <typename RootVector, typename Polynomial>
	void roots_to_monicPolynomial( const RootVector& rv, Polynomial& poly )
	{

	typedef typename Polynomial::Scalar Scalar;

	poly.setZero( rv.size()+1 );
	poly[0] = -rv[0]; poly[1] = Scalar(1);
	for( DenseIndex i=1; i< rv.size(); ++i )
	{
	for( DenseIndex j=i+1; j>0; --j ){ poly[j] = poly[j-1] - rv[i]*poly[j]; }
	poly[0] = -rv[i]*poly[0];
	}
	}

	} // end namespace Eigen

	#endif // EIGEN_POLYNOMIAL_UTILS_H