boost_1_45_0/libs/numeric/ublas/test/test53.cpp - nest-learning-thermostat/5.1.7/boost - Git at Google

 //
 //  Copyright (c) 2000-2002
 //  Joerg Walter, Mathias Koch
 //
 //  Distributed under the Boost Software License, Version 1.0. (See
 //  accompanying file LICENSE_1_0.txt or copy at
 //  http://www.boost.org/LICENSE_1_0.txt)
 //
 //  The authors gratefully acknowledge the support of
 //  GeNeSys mbH & Co. KG in producing this work.
 //

 #include "test5.hpp"

 // Test matrix expression templates
 template<class M, int N>
 struct test_my_matrix {
     typedef typename M::value_type value_type;

     template<class MP>
     void test_with (MP &m1, MP &m2, MP &m3) const {
         {
             value_type t;

             // Default Construct
             default_construct<MP>::test ();

             // Copy and swap
             initialize_matrix (m1);
             initialize_matrix (m2);
             m1 = m2;
             std::cout << "m1 = m2 = " << m1 << std::endl;
             m1.assign_temporary (m2);
             std::cout << "m1.assign_temporary (m2) = " << m1 << std::endl;
             m1.swap (m2);
             std::cout << "m1.swap (m2) = " << m1 << " " << m2 << std::endl;

             // Zero assignment
             m1 = ublas::zero_matrix<> (m1.size1 (), m1.size2 ());
             std::cout << "m1.zero_matrix = " << m1 << std::endl;
             m1 = m2;

             // Unary matrix operations resulting in a matrix
             initialize_matrix (m1);
             m2 = - m1;
             std::cout << "- m1 = " << m2 << std::endl;
             m2 = ublas::conj (m1);
             std::cout << "conj (m1) = " << m2 << std::endl;

             // Binary matrix operations resulting in a matrix
             initialize_matrix (m1);
             initialize_matrix (m2);
             m3 = m1 + m2;
             std::cout << "m1 + m2 = " << m3 << std::endl;
             m3 = m1 - m2;
             std::cout << "m1 - m2 = " << m3 << std::endl;

             // Scaling a matrix
             t = N;
             initialize_matrix (m1);
             m2 = value_type (1.) * m1;
             std::cout << "1. * m1 = " << m2 << std::endl;
             m2 = t * m1;
             std::cout << "N * m1 = " << m2 << std::endl;
             initialize_matrix (m1);
             m2 = m1 * value_type (1.);
             std::cout << "m1 * 1. = " << m2 << std::endl;
             m2 = m1 * t;
             std::cout << "m1 * N = " << m2 << std::endl;

             // Some assignments
             initialize_matrix (m1);
             initialize_matrix (m2);
             m2 += m1;
             std::cout << "m2 += m1 = " << m2 << std::endl;
             m2 -= m1;
             std::cout << "m2 -= m1 = " << m2 << std::endl;
             m2 = m2 + m1;
             std::cout << "m2 = m2 + m1 = " << m2 << std::endl;
             m2 = m2 - m1;
             std::cout << "m2 = m2 - m1 = " << m2 << std::endl;
             m1 *= value_type (1.);
             std::cout << "m1 *= 1. = " << m1 << std::endl;
             m1 *= t;
             std::cout << "m1 *= N = " << m1 << std::endl;

             // Transpose
             initialize_matrix (m1);
             // Transpose of a triangular isn't triangular of the same kind
             std::cout << "trans (m1) = " << ublas::trans (m1) << std::endl;

             // Hermitian
             initialize_matrix (m1);
             // Hermitian of a triangular isn't hermitian of the same kind
             std::cout << "herm (m1) = " << ublas::herm (m1) << std::endl;

             // Matrix multiplication
             initialize_matrix (m1);
             initialize_matrix (m2);
             m3 = ublas::prod (m1, m2);
             std::cout << "prod (m1, m2) = " << m3 << std::endl;
         }
     }
     void operator () () const {
         {
             M m1 (N, N), m2 (N, N), m3 (N, N);
             test_with (m1, m2, m3);

 #ifdef USE_RANGE
             ublas::matrix_range<M> mr1 (m1, ublas::range (0, N), ublas::range (0, N)),
                                    mr2 (m2, ublas::range (0, N), ublas::range (0, N)),
                                    mr3 (m3, ublas::range (0, N), ublas::range (0, N));
             test_with (mr1, mr2, mr3);
 #endif

 #ifdef USE_SLICE
             ublas::matrix_slice<M> ms1 (m1, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
                                    ms2 (m2, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
                                    ms3 (m3, ublas::slice (0, 1, N), ublas::slice (0, 1, N));
             test_with (ms1, ms2, ms3);
 #endif
         }

 #ifdef USE_ADAPTOR
         {
             M m1 (N, N), m2 (N, N), m3 (N, N);
             ublas::triangular_adaptor<M> tam1 (m1), tam2 (m2), tam3 (m3);
             test_with (tam1, tam2, tam3);

 #ifdef USE_RANGE
             ublas::matrix_range<ublas::triangular_adaptor<M> > mr1 (tam1, ublas::range (0, N), ublas::range (0, N)),
                                                                mr2 (tam2, ublas::range (0, N), ublas::range (0, N)),
                                                                mr3 (tam3, ublas::range (0, N), ublas::range (0, N));
             test_with (mr1, mr2, mr3);
 #endif

 #ifdef USE_SLICE
             ublas::matrix_slice<ublas::triangular_adaptor<M> > ms1 (tam1, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
                                                                ms2 (tam2, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
                                                                ms3 (tam3, ublas::slice (0, 1, N), ublas::slice (0, 1, N));
             test_with (ms1, ms2, ms3);
 #endif
         }
 #endif
     }
 };

 // Test matrix
 void test_matrix () {
     std::cout << "test_matrix" << std::endl;

 #ifdef USE_BOUNDED_ARRAY
 #ifdef USE_FLOAT
     std::cout << "float, bounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, ublas::bounded_array<float, 3 * 3> >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
     std::cout << "double, bounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, ublas::bounded_array<double, 3 * 3> >, 3 > () ();
 #endif

 #ifdef USE_STD_COMPLEX
 #ifdef USE_FLOAT
     std::cout << "std::complex<float>, bounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, ublas::bounded_array<std::complex<float>, 3 * 3> >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
     std::cout << "std::complex<double>, bounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, ublas::bounded_array<std::complex<double>, 3 * 3> >, 3 > () ();
 #endif
 #endif
 #endif

 #ifdef USE_UNBOUNDED_ARRAY
 #ifdef USE_FLOAT
     std::cout << "float, unbounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, ublas::unbounded_array<float> >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
     std::cout << "double, unbounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, ublas::unbounded_array<double> >, 3 > () ();
 #endif

 #ifdef USE_STD_COMPLEX
 #ifdef USE_FLOAT
     std::cout << "std::complex<float>, unbounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, ublas::unbounded_array<std::complex<float> > >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
     std::cout << "std::complex<double>, unbounded_array" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, ublas::unbounded_array<std::complex<double> > >, 3 > () ();
 #endif
 #endif
 #endif

 #ifdef USE_STD_VECTOR
 #ifdef USE_FLOAT
     std::cout << "float, std::vector" << std::endl;
     test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, std::vector<float> >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
     std::cout << "double, std::vector" << std::endl;
     test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, std::vector<double> >, 3 > () ();
 #endif

 #ifdef USE_STD_COMPLEX
 #ifdef USE_FLOAT
     std::cout << "std::complex<float>, std::vector" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, std::vector<std::complex<float> > >, 3 > () ();
 #endif

 #ifdef USE_DOUBLE
 std::cout << "std::complex<double>, std::vector" << std::endl;
     test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, std::vector<std::complex<double> > >, 3 > () ();
 #endif
 #endif
 #endif
 }
	//
	// Copyright (c) 2000-2002
	// Joerg Walter, Mathias Koch
	//
	// Distributed under the Boost Software License, Version 1.0. (See
	// accompanying file LICENSE_1_0.txt or copy at
	// http://www.boost.org/LICENSE_1_0.txt)
	//
	// The authors gratefully acknowledge the support of
	// GeNeSys mbH & Co. KG in producing this work.
	//

	#include "test5.hpp"

	// Test matrix expression templates
	template<class M, int N>
	struct test_my_matrix {
	typedef typename M::value_type value_type;

	template<class MP>
	void test_with (MP &m1, MP &m2, MP &m3) const {
	{
	value_type t;

	// Default Construct
	default_construct<MP>::test ();

	// Copy and swap
	initialize_matrix (m1);
	initialize_matrix (m2);
	m1 = m2;
	std::cout << "m1 = m2 = " << m1 << std::endl;
	m1.assign_temporary (m2);
	std::cout << "m1.assign_temporary (m2) = " << m1 << std::endl;
	m1.swap (m2);
	std::cout << "m1.swap (m2) = " << m1 << " " << m2 << std::endl;

	// Zero assignment
	m1 = ublas::zero_matrix<> (m1.size1 (), m1.size2 ());
	std::cout << "m1.zero_matrix = " << m1 << std::endl;
	m1 = m2;

	// Unary matrix operations resulting in a matrix
	initialize_matrix (m1);
	m2 = - m1;
	std::cout << "- m1 = " << m2 << std::endl;
	m2 = ublas::conj (m1);
	std::cout << "conj (m1) = " << m2 << std::endl;

	// Binary matrix operations resulting in a matrix
	initialize_matrix (m1);
	initialize_matrix (m2);
	m3 = m1 + m2;
	std::cout << "m1 + m2 = " << m3 << std::endl;
	m3 = m1 - m2;
	std::cout << "m1 - m2 = " << m3 << std::endl;

	// Scaling a matrix
	t = N;
	initialize_matrix (m1);
	m2 = value_type (1.) * m1;
	std::cout << "1. * m1 = " << m2 << std::endl;
	m2 = t * m1;
	std::cout << "N * m1 = " << m2 << std::endl;
	initialize_matrix (m1);
	m2 = m1 * value_type (1.);
	std::cout << "m1 * 1. = " << m2 << std::endl;
	m2 = m1 * t;
	std::cout << "m1 * N = " << m2 << std::endl;

	// Some assignments
	initialize_matrix (m1);
	initialize_matrix (m2);
	m2 += m1;
	std::cout << "m2 += m1 = " << m2 << std::endl;
	m2 -= m1;
	std::cout << "m2 -= m1 = " << m2 << std::endl;
	m2 = m2 + m1;
	std::cout << "m2 = m2 + m1 = " << m2 << std::endl;
	m2 = m2 - m1;
	std::cout << "m2 = m2 - m1 = " << m2 << std::endl;
	m1 *= value_type (1.);
	std::cout << "m1 *= 1. = " << m1 << std::endl;
	m1 *= t;
	std::cout << "m1 *= N = " << m1 << std::endl;

	// Transpose
	initialize_matrix (m1);
	// Transpose of a triangular isn't triangular of the same kind
	std::cout << "trans (m1) = " << ublas::trans (m1) << std::endl;

	// Hermitian
	initialize_matrix (m1);
	// Hermitian of a triangular isn't hermitian of the same kind
	std::cout << "herm (m1) = " << ublas::herm (m1) << std::endl;

	// Matrix multiplication
	initialize_matrix (m1);
	initialize_matrix (m2);
	m3 = ublas::prod (m1, m2);
	std::cout << "prod (m1, m2) = " << m3 << std::endl;
	}
	}
	void operator () () const {
	{
	M m1 (N, N), m2 (N, N), m3 (N, N);
	test_with (m1, m2, m3);

	#ifdef USE_RANGE
	ublas::matrix_range<M> mr1 (m1, ublas::range (0, N), ublas::range (0, N)),
	mr2 (m2, ublas::range (0, N), ublas::range (0, N)),
	mr3 (m3, ublas::range (0, N), ublas::range (0, N));
	test_with (mr1, mr2, mr3);
	#endif

	#ifdef USE_SLICE
	ublas::matrix_slice<M> ms1 (m1, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
	ms2 (m2, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
	ms3 (m3, ublas::slice (0, 1, N), ublas::slice (0, 1, N));
	test_with (ms1, ms2, ms3);
	#endif
	}

	#ifdef USE_ADAPTOR
	{
	M m1 (N, N), m2 (N, N), m3 (N, N);
	ublas::triangular_adaptor<M> tam1 (m1), tam2 (m2), tam3 (m3);
	test_with (tam1, tam2, tam3);

	#ifdef USE_RANGE
	ublas::matrix_range<ublas::triangular_adaptor<M> > mr1 (tam1, ublas::range (0, N), ublas::range (0, N)),
	mr2 (tam2, ublas::range (0, N), ublas::range (0, N)),
	mr3 (tam3, ublas::range (0, N), ublas::range (0, N));
	test_with (mr1, mr2, mr3);
	#endif

	#ifdef USE_SLICE
	ublas::matrix_slice<ublas::triangular_adaptor<M> > ms1 (tam1, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
	ms2 (tam2, ublas::slice (0, 1, N), ublas::slice (0, 1, N)),
	ms3 (tam3, ublas::slice (0, 1, N), ublas::slice (0, 1, N));
	test_with (ms1, ms2, ms3);
	#endif
	}
	#endif
	}
	};

	// Test matrix
	void test_matrix () {
	std::cout << "test_matrix" << std::endl;

	#ifdef USE_BOUNDED_ARRAY
	#ifdef USE_FLOAT
	std::cout << "float, bounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, ublas::bounded_array<float, 3 * 3> >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "double, bounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, ublas::bounded_array<double, 3 * 3> >, 3 > () ();
	#endif

	#ifdef USE_STD_COMPLEX
	#ifdef USE_FLOAT
	std::cout << "std::complex<float>, bounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, ublas::bounded_array<std::complex<float>, 3 * 3> >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "std::complex<double>, bounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, ublas::bounded_array<std::complex<double>, 3 * 3> >, 3 > () ();
	#endif
	#endif
	#endif

	#ifdef USE_UNBOUNDED_ARRAY
	#ifdef USE_FLOAT
	std::cout << "float, unbounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, ublas::unbounded_array<float> >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "double, unbounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, ublas::unbounded_array<double> >, 3 > () ();
	#endif

	#ifdef USE_STD_COMPLEX
	#ifdef USE_FLOAT
	std::cout << "std::complex<float>, unbounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, ublas::unbounded_array<std::complex<float> > >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "std::complex<double>, unbounded_array" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, ublas::unbounded_array<std::complex<double> > >, 3 > () ();
	#endif
	#endif
	#endif

	#ifdef USE_STD_VECTOR
	#ifdef USE_FLOAT
	std::cout << "float, std::vector" << std::endl;
	test_my_matrix<ublas::triangular_matrix<float, ublas::lower, ublas::row_major, std::vector<float> >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "double, std::vector" << std::endl;
	test_my_matrix<ublas::triangular_matrix<double, ublas::lower, ublas::row_major, std::vector<double> >, 3 > () ();
	#endif

	#ifdef USE_STD_COMPLEX
	#ifdef USE_FLOAT
	std::cout << "std::complex<float>, std::vector" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<float>, ublas::lower, ublas::row_major, std::vector<std::complex<float> > >, 3 > () ();
	#endif

	#ifdef USE_DOUBLE
	std::cout << "std::complex<double>, std::vector" << std::endl;
	test_my_matrix<ublas::triangular_matrix<std::complex<double>, ublas::lower, ublas::row_major, std::vector<std::complex<double> > >, 3 > () ();
	#endif
	#endif
	#endif
	}