test/eigen2/gsl_helper.h - platform/external/eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra. Eigen itself is part of the KDE project.
 //
 // Copyright (C) 2008 Gael Guennebaud <g.gael@free.fr>
 //
 // 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_GSL_HELPER
 #define EIGEN_GSL_HELPER

 #include <Eigen/Core>

 #include <gsl/gsl_blas.h>
 #include <gsl/gsl_multifit.h>
 #include <gsl/gsl_eigen.h>
 #include <gsl/gsl_linalg.h>
 #include <gsl/gsl_complex.h>
 #include <gsl/gsl_complex_math.h>

 namespace Eigen {

 template<typename Scalar, bool IsComplex = NumTraits<Scalar>::IsComplex> struct GslTraits
 {
   typedef gsl_matrix* Matrix;
   typedef gsl_vector* Vector;
   static Matrix createMatrix(int rows, int cols) { return gsl_matrix_alloc(rows,cols); }
   static Vector createVector(int size) { return gsl_vector_alloc(size); }
   static void free(Matrix& m) { gsl_matrix_free(m); m=0; }
   static void free(Vector& m) { gsl_vector_free(m); m=0; }
   static void prod(const Matrix& m, const Vector& v, Vector& x) { gsl_blas_dgemv(CblasNoTrans,1,m,v,0,x); }
   static void cholesky(Matrix& m) { gsl_linalg_cholesky_decomp(m); }
   static void cholesky_solve(const Matrix& m, const Vector& b, Vector& x) { gsl_linalg_cholesky_solve(m,b,x); }
   static void eigen_symm(const Matrix& m, Vector& eval, Matrix& evec)
   {
     gsl_eigen_symmv_workspace * w = gsl_eigen_symmv_alloc(m->size1);
     Matrix a = createMatrix(m->size1, m->size2);
     gsl_matrix_memcpy(a, m);
     gsl_eigen_symmv(a,eval,evec,w);
     gsl_eigen_symmv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
     gsl_eigen_symmv_free(w);
     free(a);
   }
   static void eigen_symm_gen(const Matrix& m, const Matrix& _b, Vector& eval, Matrix& evec)
   {
     gsl_eigen_gensymmv_workspace * w = gsl_eigen_gensymmv_alloc(m->size1);
     Matrix a = createMatrix(m->size1, m->size2);
     Matrix b = createMatrix(_b->size1, _b->size2);
     gsl_matrix_memcpy(a, m);
     gsl_matrix_memcpy(b, _b);
     gsl_eigen_gensymmv(a,b,eval,evec,w);
     gsl_eigen_symmv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
     gsl_eigen_gensymmv_free(w);
     free(a);
   }
 };

 template<typename Scalar> struct GslTraits<Scalar,true>
 {
   typedef gsl_matrix_complex* Matrix;
   typedef gsl_vector_complex* Vector;
   static Matrix createMatrix(int rows, int cols) { return gsl_matrix_complex_alloc(rows,cols); }
   static Vector createVector(int size) { return gsl_vector_complex_alloc(size); }
   static void free(Matrix& m) { gsl_matrix_complex_free(m); m=0; }
   static void free(Vector& m) { gsl_vector_complex_free(m); m=0; }
   static void cholesky(Matrix& m) { gsl_linalg_complex_cholesky_decomp(m); }
   static void cholesky_solve(const Matrix& m, const Vector& b, Vector& x) { gsl_linalg_complex_cholesky_solve(m,b,x); }
   static void prod(const Matrix& m, const Vector& v, Vector& x)
   { gsl_blas_zgemv(CblasNoTrans,gsl_complex_rect(1,0),m,v,gsl_complex_rect(0,0),x); }
   static void eigen_symm(const Matrix& m, gsl_vector* &eval, Matrix& evec)
   {
     gsl_eigen_hermv_workspace * w = gsl_eigen_hermv_alloc(m->size1);
     Matrix a = createMatrix(m->size1, m->size2);
     gsl_matrix_complex_memcpy(a, m);
     gsl_eigen_hermv(a,eval,evec,w);
     gsl_eigen_hermv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
     gsl_eigen_hermv_free(w);
     free(a);
   }
   static void eigen_symm_gen(const Matrix& m, const Matrix& _b, gsl_vector* &eval, Matrix& evec)
   {
     gsl_eigen_genhermv_workspace * w = gsl_eigen_genhermv_alloc(m->size1);
     Matrix a = createMatrix(m->size1, m->size2);
     Matrix b = createMatrix(_b->size1, _b->size2);
     gsl_matrix_complex_memcpy(a, m);
     gsl_matrix_complex_memcpy(b, _b);
     gsl_eigen_genhermv(a,b,eval,evec,w);
     gsl_eigen_hermv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
     gsl_eigen_genhermv_free(w);
     free(a);
   }
 };

 template<typename MatrixType>
 void convert(const MatrixType& m, gsl_matrix* &res)
 {
 //   if (res)
 //     gsl_matrix_free(res);
   res = gsl_matrix_alloc(m.rows(), m.cols());
   for (int i=0 ; i<m.rows() ; ++i)
     for (int j=0 ; j<m.cols(); ++j)
       gsl_matrix_set(res, i, j, m(i,j));
 }

 template<typename MatrixType>
 void convert(const gsl_matrix* m, MatrixType& res)
 {
   res.resize(int(m->size1), int(m->size2));
   for (int i=0 ; i<res.rows() ; ++i)
     for (int j=0 ; j<res.cols(); ++j)
       res(i,j) = gsl_matrix_get(m,i,j);
 }

 template<typename VectorType>
 void convert(const VectorType& m, gsl_vector* &res)
 {
   if (res) gsl_vector_free(res);
   res = gsl_vector_alloc(m.size());
   for (int i=0 ; i<m.size() ; ++i)
       gsl_vector_set(res, i, m[i]);
 }

 template<typename VectorType>
 void convert(const gsl_vector* m, VectorType& res)
 {
   res.resize (m->size);
   for (int i=0 ; i<res.rows() ; ++i)
     res[i] = gsl_vector_get(m, i);
 }

 template<typename MatrixType>
 void convert(const MatrixType& m, gsl_matrix_complex* &res)
 {
   res = gsl_matrix_complex_alloc(m.rows(), m.cols());
   for (int i=0 ; i<m.rows() ; ++i)
     for (int j=0 ; j<m.cols(); ++j)
     {
       gsl_matrix_complex_set(res, i, j,
         gsl_complex_rect(m(i,j).real(), m(i,j).imag()));
     }
 }

 template<typename MatrixType>
 void convert(const gsl_matrix_complex* m, MatrixType& res)
 {
   res.resize(int(m->size1), int(m->size2));
   for (int i=0 ; i<res.rows() ; ++i)
     for (int j=0 ; j<res.cols(); ++j)
       res(i,j) = typename MatrixType::Scalar(
         GSL_REAL(gsl_matrix_complex_get(m,i,j)),
         GSL_IMAG(gsl_matrix_complex_get(m,i,j)));
 }

 template<typename VectorType>
 void convert(const VectorType& m, gsl_vector_complex* &res)
 {
   res = gsl_vector_complex_alloc(m.size());
   for (int i=0 ; i<m.size() ; ++i)
       gsl_vector_complex_set(res, i, gsl_complex_rect(m[i].real(), m[i].imag()));
 }

 template<typename VectorType>
 void convert(const gsl_vector_complex* m, VectorType& res)
 {
   res.resize(m->size);
   for (int i=0 ; i<res.rows() ; ++i)
     res[i] = typename VectorType::Scalar(
         GSL_REAL(gsl_vector_complex_get(m, i)),
         GSL_IMAG(gsl_vector_complex_get(m, i)));
 }

 }

 #endif // EIGEN_GSL_HELPER
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra. Eigen itself is part of the KDE project.
	//
	// Copyright (C) 2008 Gael Guennebaud <g.gael@free.fr>
	//
	// 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_GSL_HELPER
	#define EIGEN_GSL_HELPER

	#include <Eigen/Core>

	#include <gsl/gsl_blas.h>
	#include <gsl/gsl_multifit.h>
	#include <gsl/gsl_eigen.h>
	#include <gsl/gsl_linalg.h>
	#include <gsl/gsl_complex.h>
	#include <gsl/gsl_complex_math.h>

	namespace Eigen {

	template<typename Scalar, bool IsComplex = NumTraits<Scalar>::IsComplex> struct GslTraits
	{
	typedef gsl_matrix* Matrix;
	typedef gsl_vector* Vector;
	static Matrix createMatrix(int rows, int cols) { return gsl_matrix_alloc(rows,cols); }
	static Vector createVector(int size) { return gsl_vector_alloc(size); }
	static void free(Matrix& m) { gsl_matrix_free(m); m=0; }
	static void free(Vector& m) { gsl_vector_free(m); m=0; }
	static void prod(const Matrix& m, const Vector& v, Vector& x) { gsl_blas_dgemv(CblasNoTrans,1,m,v,0,x); }
	static void cholesky(Matrix& m) { gsl_linalg_cholesky_decomp(m); }
	static void cholesky_solve(const Matrix& m, const Vector& b, Vector& x) { gsl_linalg_cholesky_solve(m,b,x); }
	static void eigen_symm(const Matrix& m, Vector& eval, Matrix& evec)
	{
	gsl_eigen_symmv_workspace * w = gsl_eigen_symmv_alloc(m->size1);
	Matrix a = createMatrix(m->size1, m->size2);
	gsl_matrix_memcpy(a, m);
	gsl_eigen_symmv(a,eval,evec,w);
	gsl_eigen_symmv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
	gsl_eigen_symmv_free(w);
	free(a);
	}
	static void eigen_symm_gen(const Matrix& m, const Matrix& _b, Vector& eval, Matrix& evec)
	{
	gsl_eigen_gensymmv_workspace * w = gsl_eigen_gensymmv_alloc(m->size1);
	Matrix a = createMatrix(m->size1, m->size2);
	Matrix b = createMatrix(_b->size1, _b->size2);
	gsl_matrix_memcpy(a, m);
	gsl_matrix_memcpy(b, _b);
	gsl_eigen_gensymmv(a,b,eval,evec,w);
	gsl_eigen_symmv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
	gsl_eigen_gensymmv_free(w);
	free(a);
	}
	};

	template<typename Scalar> struct GslTraits<Scalar,true>
	{
	typedef gsl_matrix_complex* Matrix;
	typedef gsl_vector_complex* Vector;
	static Matrix createMatrix(int rows, int cols) { return gsl_matrix_complex_alloc(rows,cols); }
	static Vector createVector(int size) { return gsl_vector_complex_alloc(size); }
	static void free(Matrix& m) { gsl_matrix_complex_free(m); m=0; }
	static void free(Vector& m) { gsl_vector_complex_free(m); m=0; }
	static void cholesky(Matrix& m) { gsl_linalg_complex_cholesky_decomp(m); }
	static void cholesky_solve(const Matrix& m, const Vector& b, Vector& x) { gsl_linalg_complex_cholesky_solve(m,b,x); }
	static void prod(const Matrix& m, const Vector& v, Vector& x)
	{ gsl_blas_zgemv(CblasNoTrans,gsl_complex_rect(1,0),m,v,gsl_complex_rect(0,0),x); }
	static void eigen_symm(const Matrix& m, gsl_vector* &eval, Matrix& evec)
	{
	gsl_eigen_hermv_workspace * w = gsl_eigen_hermv_alloc(m->size1);
	Matrix a = createMatrix(m->size1, m->size2);
	gsl_matrix_complex_memcpy(a, m);
	gsl_eigen_hermv(a,eval,evec,w);
	gsl_eigen_hermv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
	gsl_eigen_hermv_free(w);
	free(a);
	}
	static void eigen_symm_gen(const Matrix& m, const Matrix& _b, gsl_vector* &eval, Matrix& evec)
	{
	gsl_eigen_genhermv_workspace * w = gsl_eigen_genhermv_alloc(m->size1);
	Matrix a = createMatrix(m->size1, m->size2);
	Matrix b = createMatrix(_b->size1, _b->size2);
	gsl_matrix_complex_memcpy(a, m);
	gsl_matrix_complex_memcpy(b, _b);
	gsl_eigen_genhermv(a,b,eval,evec,w);
	gsl_eigen_hermv_sort(eval, evec, GSL_EIGEN_SORT_VAL_ASC);
	gsl_eigen_genhermv_free(w);
	free(a);
	}
	};

	template<typename MatrixType>
	void convert(const MatrixType& m, gsl_matrix* &res)
	{
	// if (res)
	// gsl_matrix_free(res);
	res = gsl_matrix_alloc(m.rows(), m.cols());
	for (int i=0 ; i<m.rows() ; ++i)
	for (int j=0 ; j<m.cols(); ++j)
	gsl_matrix_set(res, i, j, m(i,j));
	}

	template<typename MatrixType>
	void convert(const gsl_matrix* m, MatrixType& res)
	{
	res.resize(int(m->size1), int(m->size2));
	for (int i=0 ; i<res.rows() ; ++i)
	for (int j=0 ; j<res.cols(); ++j)
	res(i,j) = gsl_matrix_get(m,i,j);
	}

	template<typename VectorType>
	void convert(const VectorType& m, gsl_vector* &res)
	{
	if (res) gsl_vector_free(res);
	res = gsl_vector_alloc(m.size());
	for (int i=0 ; i<m.size() ; ++i)
	gsl_vector_set(res, i, m[i]);
	}

	template<typename VectorType>
	void convert(const gsl_vector* m, VectorType& res)
	{
	res.resize (m->size);
	for (int i=0 ; i<res.rows() ; ++i)
	res[i] = gsl_vector_get(m, i);
	}

	template<typename MatrixType>
	void convert(const MatrixType& m, gsl_matrix_complex* &res)
	{
	res = gsl_matrix_complex_alloc(m.rows(), m.cols());
	for (int i=0 ; i<m.rows() ; ++i)
	for (int j=0 ; j<m.cols(); ++j)
	{
	gsl_matrix_complex_set(res, i, j,
	gsl_complex_rect(m(i,j).real(), m(i,j).imag()));
	}
	}

	template<typename MatrixType>
	void convert(const gsl_matrix_complex* m, MatrixType& res)
	{
	res.resize(int(m->size1), int(m->size2));
	for (int i=0 ; i<res.rows() ; ++i)
	for (int j=0 ; j<res.cols(); ++j)
	res(i,j) = typename MatrixType::Scalar(
	GSL_REAL(gsl_matrix_complex_get(m,i,j)),
	GSL_IMAG(gsl_matrix_complex_get(m,i,j)));
	}

	template<typename VectorType>
	void convert(const VectorType& m, gsl_vector_complex* &res)
	{
	res = gsl_vector_complex_alloc(m.size());
	for (int i=0 ; i<m.size() ; ++i)
	gsl_vector_complex_set(res, i, gsl_complex_rect(m[i].real(), m[i].imag()));
	}

	template<typename VectorType>
	void convert(const gsl_vector_complex* m, VectorType& res)
	{
	res.resize(m->size);
	for (int i=0 ; i<res.rows() ; ++i)
	res[i] = typename VectorType::Scalar(
	GSL_REAL(gsl_vector_complex_get(m, i)),
	GSL_IMAG(gsl_vector_complex_get(m, i)));
	}

	}

	#endif // EIGEN_GSL_HELPER