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Diffstat (limited to 'src/boost/libs/multiprecision/test/test_eigen_interop.cpp')
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diff --git a/src/boost/libs/multiprecision/test/test_eigen_interop.cpp b/src/boost/libs/multiprecision/test/test_eigen_interop.cpp new file mode 100644 index 00000000..1d1f982a --- /dev/null +++ b/src/boost/libs/multiprecision/test/test_eigen_interop.cpp @@ -0,0 +1,772 @@ +// Copyright 2012 John Maddock. Distributed under the Boost +// Software License, Version 1.0. (See accompanying file +// LICENSE_1_0.txt or copy at https://www.boost.org/LICENSE_1_0.txt + +#include <boost/multiprecision/cpp_int.hpp> +#include <boost/multiprecision/cpp_dec_float.hpp> +#include <boost/multiprecision/cpp_bin_float.hpp> +#include <iostream> +#include <Eigen/Dense> + +#include <boost/multiprecision/mpfr.hpp> +#include <boost/multiprecision/logged_adaptor.hpp> +#include <boost/multiprecision/gmp.hpp> +#include <boost/multiprecision/mpc.hpp> + +#include "test.hpp" + +using namespace Eigen; + +namespace Eigen { +template <class Backend, boost::multiprecision::expression_template_option ExpressionTemplates> +struct NumTraits<boost::multiprecision::number<Backend, ExpressionTemplates> > +{ + typedef boost::multiprecision::number<Backend, ExpressionTemplates> self_type; + typedef typename boost::multiprecision::scalar_result_from_possible_complex<self_type>::type Real; + typedef self_type NonInteger; // Not correct but we can't do much better?? + typedef double Literal; + typedef self_type Nested; + enum + { + IsComplex = boost::multiprecision::number_category<self_type>::value == boost::multiprecision::number_kind_complex, + IsInteger = boost::multiprecision::number_category<self_type>::value == boost::multiprecision::number_kind_integer, + ReadCost = 1, + AddCost = 4, + MulCost = 8, + IsSigned = std::numeric_limits<self_type>::is_specialized ? std::numeric_limits<self_type>::is_signed : true, + RequireInitialization = 1, + }; + static Real epsilon() + { + return std::numeric_limits<Real>::epsilon(); + } + static Real dummy_precision() + { + return sqrt(epsilon()); + } + static Real highest() + { + return (std::numeric_limits<Real>::max)(); + } + static Real lowest() + { + return (std::numeric_limits<Real>::min)(); + } + static int digits10_imp(const boost::mpl::true_&) + { + return std::numeric_limits<Real>::digits10; + } + template <bool B> + static int digits10_imp(const boost::mpl::bool_<B>&) + { + return Real::default_precision(); + } + static int digits10() + { + return digits10_imp(boost::mpl::bool_ < std::numeric_limits<Real>::digits10 && (std::numeric_limits<Real>::digits10 != INT_MAX) ? true : false > ()); + } +}; + +#define BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(A) \ + template <class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, typename BinaryOp> \ + struct ScalarBinaryOpTraits<boost::multiprecision::number<Backend, ExpressionTemplates>, A, BinaryOp> \ + { \ + static_assert(boost::multiprecision::is_compatible_arithmetic_type<A, boost::multiprecision::number<Backend, ExpressionTemplates> >::value, "Interoperability with this arithmetic type is not supported."); \ + typedef boost::multiprecision::number<Backend, ExpressionTemplates> ReturnType; \ + }; \ + template <class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, typename BinaryOp> \ + struct ScalarBinaryOpTraits<A, boost::multiprecision::number<Backend, ExpressionTemplates>, BinaryOp> \ + { \ + static_assert(boost::multiprecision::is_compatible_arithmetic_type<A, boost::multiprecision::number<Backend, ExpressionTemplates> >::value, "Interoperability with this arithmetic type is not supported."); \ + typedef boost::multiprecision::number<Backend, ExpressionTemplates> ReturnType; \ + }; + +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(float) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(double) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(long double) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(char) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(unsigned char) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(signed char) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(short) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(unsigned short) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(int) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(unsigned int) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(long) +BOOST_MP_EIGEN_SCALAR_TRAITS_DECL(unsigned long) +#if 0 + template<class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, class Backend2, boost::multiprecision::expression_template_option ExpressionTemplates2, typename BinaryOp> + struct ScalarBinaryOpTraits<boost::multiprecision::number<Backend, ExpressionTemplates>, boost::multiprecision::number<Backend2, ExpressionTemplates2>, BinaryOp> + { + static_assert( + boost::multiprecision::is_compatible_arithmetic_type<boost::multiprecision::number<Backend2, ExpressionTemplates2>, boost::multiprecision::number<Backend, ExpressionTemplates> >::value + || boost::multiprecision::is_compatible_arithmetic_type<boost::multiprecision::number<Backend, ExpressionTemplates>, boost::multiprecision::number<Backend2, ExpressionTemplates2> >::value, "Interoperability with this arithmetic type is not supported."); + typedef typename boost::mpl::if_c<boost::is_convertible<boost::multiprecision::number<Backend2, ExpressionTemplates2>, boost::multiprecision::number<Backend, ExpressionTemplates> >::value, + boost::multiprecision::number<Backend, ExpressionTemplates>, boost::multiprecision::number<Backend2, ExpressionTemplates2> >::type ReturnType; + }; + + template<unsigned D, typename BinaryOp> + struct ScalarBinaryOpTraits<boost::multiprecision::number<boost::multiprecision::backends::mpc_complex_backend<D>, boost::multiprecision::et_on>, boost::multiprecision::mpfr_float, BinaryOp> + { + typedef boost::multiprecision::number<boost::multiprecision::backends::mpc_complex_backend<D>, boost::multiprecision::et_on> ReturnType; + }; + + template<typename BinaryOp> + struct ScalarBinaryOpTraits<boost::multiprecision::mpfr_float, boost::multiprecision::mpc_complex, BinaryOp> + { + typedef boost::multiprecision::number<boost::multiprecision::backends::mpc_complex_backend<0>, boost::multiprecision::et_on> ReturnType; + }; + + template<class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, typename BinaryOp> + struct ScalarBinaryOpTraits<boost::multiprecision::number<Backend, ExpressionTemplates>, boost::multiprecision::number<Backend, ExpressionTemplates>, BinaryOp> + { + typedef boost::multiprecision::number<Backend, ExpressionTemplates> ReturnType; + }; +#endif +template <class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, class tag, class Arg1, class Arg2, class Arg3, class Arg4, typename BinaryOp> +struct ScalarBinaryOpTraits<boost::multiprecision::number<Backend, ExpressionTemplates>, boost::multiprecision::detail::expression<tag, Arg1, Arg2, Arg3, Arg4>, BinaryOp> +{ + static_assert(boost::is_convertible<typename boost::multiprecision::detail::expression<tag, Arg1, Arg2, Arg3, Arg4>::result_type, boost::multiprecision::number<Backend, ExpressionTemplates> >::value, "Interoperability with this arithmetic type is not supported."); + typedef boost::multiprecision::number<Backend, ExpressionTemplates> ReturnType; +}; + +template <class tag, class Arg1, class Arg2, class Arg3, class Arg4, class Backend, boost::multiprecision::expression_template_option ExpressionTemplates, typename BinaryOp> +struct ScalarBinaryOpTraits<boost::multiprecision::detail::expression<tag, Arg1, Arg2, Arg3, Arg4>, boost::multiprecision::number<Backend, ExpressionTemplates>, BinaryOp> +{ + static_assert(boost::is_convertible<typename boost::multiprecision::detail::expression<tag, Arg1, Arg2, Arg3, Arg4>::result_type, boost::multiprecision::number<Backend, ExpressionTemplates> >::value, "Interoperability with this arithmetic type is not supported."); + typedef boost::multiprecision::number<Backend, ExpressionTemplates> ReturnType; +}; + +} // namespace Eigen + +template <class T> +struct related_number +{ + typedef T type; +}; +/* +template <> +struct related_number<boost::multiprecision::cpp_bin_float_50> +{ + typedef boost::multiprecision::cpp_bin_float_quad type; +}; +template <> +struct related_number<boost::multiprecision::cpp_dec_float_100> +{ + typedef boost::multiprecision::cpp_dec_float_50 type; +};*/ + +template <class Num> +void example1() +{ + // expected results first: + Matrix<Num, 2, 2> r1, r2; + r1 << 3, 5, 4, 8; + r2 << -1, -1, 2, 0; + Matrix<Num, 3, 1> r3; + r3 << -1, -4, -6; + + Matrix<Num, 2, 2> a; + a << 1, 2, 3, 4; + Matrix<Num, Dynamic, Dynamic> b(2, 2); + b << 2, 3, 1, 4; + std::cout << "a + b =\n" + << a + b << std::endl; + BOOST_CHECK_EQUAL(a + b, r1); + std::cout << "a - b =\n" + << a - b << std::endl; + BOOST_CHECK_EQUAL(a - b, r2); + std::cout << "Doing a += b;" << std::endl; + a += b; + std::cout << "Now a =\n" + << a << std::endl; + Matrix<Num, 3, 1> v(1, 2, 3); + Matrix<Num, 3, 1> w(1, 0, 0); + std::cout << "-v + w - v =\n" + << -v + w - v << std::endl; + BOOST_CHECK_EQUAL(-v + w - v, r3); +} + +template <class Num> +void example2() +{ + Matrix<Num, 2, 2> a; + a << 1, 2, 3, 4; + Matrix<Num, 3, 1> v(1, 2, 3); + std::cout << "a * 2.5 =\n" + << a * 2.5 << std::endl; + std::cout << "0.1 * v =\n" + << 0.1 * v << std::endl; + std::cout << "Doing v *= 2;" << std::endl; + v *= 2; + std::cout << "Now v =\n" + << v << std::endl; + Num n(4); + std::cout << "Doing v *= Num;" << std::endl; + v *= n; + std::cout << "Now v =\n" + << v << std::endl; + typedef typename related_number<Num>::type related_type; + related_type r(6); + std::cout << "Doing v *= RelatedType;" << std::endl; + v *= r; + std::cout << "Now v =\n" + << v << std::endl; + std::cout << "RelatedType * v =\n" + << r * v << std::endl; + std::cout << "Doing v *= RelatedType^2;" << std::endl; + v *= r * r; + std::cout << "Now v =\n" + << v << std::endl; + std::cout << "RelatedType^2 * v =\n" + << r * r * v << std::endl; + + static_assert(boost::is_same<typename Eigen::ScalarBinaryOpTraits<Num, related_type, Eigen::internal::scalar_product_op<Num, related_type> >::ReturnType, Num>::value, "Incorrect type."); +} + +template <class Num> +void example3() +{ + using namespace std; + Matrix<Num, Dynamic, Dynamic> a = Matrix<Num, Dynamic, Dynamic>::Random(2, 2); + cout << "Here is the matrix a\n" + << a << endl; + cout << "Here is the matrix a^T\n" + << a.transpose() << endl; + cout << "Here is the conjugate of a\n" + << a.conjugate() << endl; + cout << "Here is the matrix a^*\n" + << a.adjoint() << endl; +} + +template <class Num> +void example4() +{ + Matrix<Num, 2, 2> mat; + mat << 1, 2, + 3, 4; + Matrix<Num, 2, 1> u(-1, 1), v(2, 0); + std::cout << "Here is mat*mat:\n" + << mat * mat << std::endl; + std::cout << "Here is mat*u:\n" + << mat * u << std::endl; + std::cout << "Here is u^T*mat:\n" + << u.transpose() * mat << std::endl; + std::cout << "Here is u^T*v:\n" + << u.transpose() * v << std::endl; + std::cout << "Here is u*v^T:\n" + << u * v.transpose() << std::endl; + std::cout << "Let's multiply mat by itself" << std::endl; + mat = mat * mat; + std::cout << "Now mat is mat:\n" + << mat << std::endl; +} + +template <class Num> +void example5() +{ + using namespace std; + Matrix<Num, 3, 1> v(1, 2, 3); + Matrix<Num, 3, 1> w(0, 1, 2); + cout << "Dot product: " << v.dot(w) << endl; + Num dp = v.adjoint() * w; // automatic conversion of the inner product to a scalar + cout << "Dot product via a matrix product: " << dp << endl; + cout << "Cross product:\n" + << v.cross(w) << endl; +} + +template <class Num> +void example6() +{ + using namespace std; + Matrix<Num, 2, 2> mat; + mat << 1, 2, + 3, 4; + cout << "Here is mat.sum(): " << mat.sum() << endl; + cout << "Here is mat.prod(): " << mat.prod() << endl; + cout << "Here is mat.mean(): " << mat.mean() << endl; + cout << "Here is mat.minCoeff(): " << mat.minCoeff() << endl; + cout << "Here is mat.maxCoeff(): " << mat.maxCoeff() << endl; + cout << "Here is mat.trace(): " << mat.trace() << endl; +} + +template <class Num> +void example7() +{ + using namespace std; + + Array<Num, Dynamic, Dynamic> m(2, 2); + + // assign some values coefficient by coefficient + m(0, 0) = 1.0; + m(0, 1) = 2.0; + m(1, 0) = 3.0; + m(1, 1) = m(0, 1) + m(1, 0); + + // print values to standard output + cout << m << endl + << endl; + + // using the comma-initializer is also allowed + m << 1.0, 2.0, + 3.0, 4.0; + + // print values to standard output + cout << m << endl; +} + +template <class Num> +void example8() +{ + using namespace std; + Array<Num, Dynamic, Dynamic> a(3, 3); + Array<Num, Dynamic, Dynamic> b(3, 3); + a << 1, 2, 3, + 4, 5, 6, + 7, 8, 9; + b << 1, 2, 3, + 1, 2, 3, + 1, 2, 3; + + // Adding two arrays + cout << "a + b = " << endl + << a + b << endl + << endl; + // Subtracting a scalar from an array + cout << "a - 2 = " << endl + << a - 2 << endl; +} + +template <class Num> +void example9() +{ + using namespace std; + Array<Num, Dynamic, Dynamic> a(2, 2); + Array<Num, Dynamic, Dynamic> b(2, 2); + a << 1, 2, + 3, 4; + b << 5, 6, + 7, 8; + cout << "a * b = " << endl + << a * b << endl; +} + +template <class Num> +void example10() +{ + using namespace std; + Array<Num, Dynamic, 1> a = Array<Num, Dynamic, 1>::Random(5); + a *= 2; + cout << "a =" << endl + << a << endl; + cout << "a.abs() =" << endl + << a.abs() << endl; + cout << "a.abs().sqrt() =" << endl + << a.abs().sqrt() << endl; + cout << "a.min(a.abs().sqrt()) =" << endl + << a.std::min)(a.abs().sqrt()) << endl; +} + +template <class Num> +void example11() +{ + using namespace std; + Matrix<Num, Dynamic, Dynamic> m(2, 2); + Matrix<Num, Dynamic, Dynamic> n(2, 2); + Matrix<Num, Dynamic, Dynamic> result(2, 2); + m << 1, 2, + 3, 4; + n << 5, 6, + 7, 8; + result = m * n; + cout << "-- Matrix m*n: --" << endl + << result << endl + << endl; + result = m.array() * n.array(); + cout << "-- Array m*n: --" << endl + << result << endl + << endl; + result = m.cwiseProduct(n); + cout << "-- With cwiseProduct: --" << endl + << result << endl + << endl; + result = m.array() + 4; + cout << "-- Array m + 4: --" << endl + << result << endl + << endl; +} + +template <class Num> +void example12() +{ + using namespace std; + Matrix<Num, Dynamic, Dynamic> m(2, 2); + Matrix<Num, Dynamic, Dynamic> n(2, 2); + Matrix<Num, Dynamic, Dynamic> result(2, 2); + m << 1, 2, + 3, 4; + n << 5, 6, + 7, 8; + + result = (m.array() + 4).matrix() * m; + cout << "-- Combination 1: --" << endl + << result << endl + << endl; + result = (m.array() * n.array()).matrix() * m; + cout << "-- Combination 2: --" << endl + << result << endl + << endl; +} + +template <class Num> +void example13() +{ + using namespace std; + Matrix<Num, Dynamic, Dynamic> m(4, 4); + m << 1, 2, 3, 4, + 5, 6, 7, 8, + 9, 10, 11, 12, + 13, 14, 15, 16; + cout << "Block in the middle" << endl; + cout << m.template block<2, 2>(1, 1) << endl + << endl; + for (int i = 1; i <= 3; ++i) + { + cout << "Block of size " << i << "x" << i << endl; + cout << m.block(0, 0, i, i) << endl + << endl; + } +} + +template <class Num> +void example14() +{ + using namespace std; + Array<Num, 2, 2> m; + m << 1, 2, + 3, 4; + Array<Num, 4, 4> a = Array<Num, 4, 4>::Constant(0.6); + cout << "Here is the array a:" << endl + << a << endl + << endl; + a.template block<2, 2>(1, 1) = m; + cout << "Here is now a with m copied into its central 2x2 block:" << endl + << a << endl + << endl; + a.block(0, 0, 2, 3) = a.block(2, 1, 2, 3); + cout << "Here is now a with bottom-right 2x3 block copied into top-left 2x2 block:" << endl + << a << endl + << endl; +} + +template <class Num> +void example15() +{ + using namespace std; + Eigen::Matrix<Num, Dynamic, Dynamic> m(3, 3); + m << 1, 2, 3, + 4, 5, 6, + 7, 8, 9; + cout << "Here is the matrix m:" << endl + << m << endl; + cout << "2nd Row: " << m.row(1) << endl; + m.col(2) += 3 * m.col(0); + cout << "After adding 3 times the first column into the third column, the matrix m is:\n"; + cout << m << endl; +} + +template <class Num> +void example16() +{ + using namespace std; + Matrix<Num, 4, 4> m; + m << 1, 2, 3, 4, + 5, 6, 7, 8, + 9, 10, 11, 12, + 13, 14, 15, 16; + cout << "m.leftCols(2) =" << endl + << m.leftCols(2) << endl + << endl; + cout << "m.bottomRows<2>() =" << endl + << m.template bottomRows<2>() << endl + << endl; + m.topLeftCorner(1, 3) = m.bottomRightCorner(3, 1).transpose(); + cout << "After assignment, m = " << endl + << m << endl; +} + +template <class Num> +void example17() +{ + using namespace std; + Array<Num, Dynamic, 1> v(6); + v << 1, 2, 3, 4, 5, 6; + cout << "v.head(3) =" << endl + << v.head(3) << endl + << endl; + cout << "v.tail<3>() = " << endl + << v.template tail<3>() << endl + << endl; + v.segment(1, 4) *= 2; + cout << "after 'v.segment(1,4) *= 2', v =" << endl + << v << endl; +} + +template <class Num> +void example18() +{ + using namespace std; + Matrix<Num, 2, 2> mat; + mat << 1, 2, + 3, 4; + cout << "Here is mat.sum(): " << mat.sum() << endl; + cout << "Here is mat.prod(): " << mat.prod() << endl; + cout << "Here is mat.mean(): " << mat.mean() << endl; + cout << "Here is mat.minCoeff(): " << mat.minCoeff() << endl; + cout << "Here is mat.maxCoeff(): " << mat.maxCoeff() << endl; + cout << "Here is mat.trace(): " << mat.trace() << endl; + + BOOST_CHECK_EQUAL(mat.sum(), 10); + BOOST_CHECK_EQUAL(mat.prod(), 24); + BOOST_CHECK_EQUAL(mat.mean(), Num(5) / 2); + BOOST_CHECK_EQUAL(mat.minCoeff(), 1); + BOOST_CHECK_EQUAL(mat.maxCoeff(), 4); + BOOST_CHECK_EQUAL(mat.trace(), 5); +} + +template <class Num> +void example18a() +{ + using namespace std; + Matrix<Num, 2, 2> mat; + mat << 1, 2, + 3, 4; + cout << "Here is mat.sum(): " << mat.sum() << endl; + cout << "Here is mat.prod(): " << mat.prod() << endl; + cout << "Here is mat.mean(): " << mat.mean() << endl; + //cout << "Here is mat.minCoeff(): " << mat.minCoeff() << endl; + //cout << "Here is mat.maxCoeff(): " << mat.maxCoeff() << endl; + cout << "Here is mat.trace(): " << mat.trace() << endl; +} + +template <class Num> +void example19() +{ + using namespace std; + Matrix<Num, Dynamic, 1> v(2); + Matrix<Num, Dynamic, Dynamic> m(2, 2), n(2, 2); + + v << -1, + 2; + + m << 1, -2, + -3, 4; + cout << "v.squaredNorm() = " << v.squaredNorm() << endl; + cout << "v.norm() = " << v.norm() << endl; + cout << "v.lpNorm<1>() = " << v.template lpNorm<1>() << endl; + cout << "v.lpNorm<Infinity>() = " << v.template lpNorm<Infinity>() << endl; + cout << endl; + cout << "m.squaredNorm() = " << m.squaredNorm() << endl; + cout << "m.norm() = " << m.norm() << endl; + cout << "m.lpNorm<1>() = " << m.template lpNorm<1>() << endl; + cout << "m.lpNorm<Infinity>() = " << m.template lpNorm<Infinity>() << endl; +} + +template <class Num> +void example20() +{ + using namespace std; + Matrix<Num, 3, 3> A; + Matrix<Num, 3, 1> b; + A << 1, 2, 3, 4, 5, 6, 7, 8, 10; + b << 3, 3, 4; + cout << "Here is the matrix A:\n" + << A << endl; + cout << "Here is the vector b:\n" + << b << endl; + Matrix<Num, 3, 1> x = A.colPivHouseholderQr().solve(b); + cout << "The solution is:\n" + << x << endl; +} + +template <class Num> +void example21() +{ + using namespace std; + Matrix<Num, 2, 2> A, b; + A << 2, -1, -1, 3; + b << 1, 2, 3, 1; + cout << "Here is the matrix A:\n" + << A << endl; + cout << "Here is the right hand side b:\n" + << b << endl; + Matrix<Num, 2, 2> x = A.ldlt().solve(b); + cout << "The solution is:\n" + << x << endl; +} + +template <class Num> +void example22() +{ + using namespace std; + Matrix<Num, Dynamic, Dynamic> A = Matrix<Num, Dynamic, Dynamic>::Random(100, 100); + Matrix<Num, Dynamic, Dynamic> b = Matrix<Num, Dynamic, Dynamic>::Random(100, 50); + Matrix<Num, Dynamic, Dynamic> x = A.fullPivLu().solve(b); + Matrix<Num, Dynamic, Dynamic> axmb = A * x - b; + double relative_error = static_cast<double>(abs(axmb.norm() / b.norm())); // norm() is L2 norm + cout << "norm1 = " << axmb.norm() << endl; + cout << "norm2 = " << b.norm() << endl; + cout << "The relative error is:\n" + << relative_error << endl; +} + +template <class Num> +void example23() +{ + using namespace std; + Matrix<Num, 2, 2> A; + A << 1, 2, 2, 3; + cout << "Here is the matrix A:\n" + << A << endl; + SelfAdjointEigenSolver<Matrix<Num, 2, 2> > eigensolver(A); + if (eigensolver.info() != Success) + { + std::cout << "Eigenvalue solver failed!" << endl; + } + else + { + cout << "The eigenvalues of A are:\n" + << eigensolver.eigenvalues() << endl; + cout << "Here's a matrix whose columns are eigenvectors of A \n" + << "corresponding to these eigenvalues:\n" + << eigensolver.eigenvectors() << endl; + } +} + +template <class Num> +void example24() +{ + using namespace std; + Matrix<Num, 3, 3> A; + A << 1, 2, 1, + 2, 1, 0, + -1, 1, 2; + cout << "Here is the matrix A:\n" + << A << endl; + cout << "The determinant of A is " << A.determinant() << endl; + cout << "The inverse of A is:\n" + << A.inverse() << endl; +} + +template <class Num> +void test_integer_type() +{ + example1<Num>(); + //example2<Num>(); + example18<Num>(); +} + +template <class Num> +void test_float_type() +{ + std::cout << "Epsilon = " << Eigen::NumTraits<Num>::epsilon() << std::endl; + std::cout << "Dummy Prec = " << Eigen::NumTraits<Num>::dummy_precision() << std::endl; + std::cout << "Highest = " << Eigen::NumTraits<Num>::highest() << std::endl; + std::cout << "Lowest = " << Eigen::NumTraits<Num>::lowest() << std::endl; + std::cout << "Digits10 = " << Eigen::NumTraits<Num>::digits10() << std::endl; + + example1<Num>(); + example2<Num>(); + example4<Num>(); + example5<Num>(); + example6<Num>(); + example7<Num>(); + example8<Num>(); + example9<Num>(); + example10<Num>(); + example11<Num>(); + example12<Num>(); + example13<Num>(); + example14<Num>(); + example15<Num>(); + example16<Num>(); + example17<Num>(); + example18<Num>(); + example19<Num>(); + example20<Num>(); + example21<Num>(); + example22<Num>(); + example23<Num>(); + example24<Num>(); +} + +template <class Num> +void test_complex_type() +{ + std::cout << "Epsilon = " << Eigen::NumTraits<Num>::epsilon() << std::endl; + std::cout << "Dummy Prec = " << Eigen::NumTraits<Num>::dummy_precision() << std::endl; + std::cout << "Highest = " << Eigen::NumTraits<Num>::highest() << std::endl; + std::cout << "Lowest = " << Eigen::NumTraits<Num>::lowest() << std::endl; + std::cout << "Digits10 = " << Eigen::NumTraits<Num>::digits10() << std::endl; + + example1<Num>(); + example2<Num>(); + example3<Num>(); + example4<Num>(); + example5<Num>(); + example7<Num>(); + example8<Num>(); + example9<Num>(); + example11<Num>(); + example12<Num>(); + example13<Num>(); + example14<Num>(); + example15<Num>(); + example16<Num>(); + example17<Num>(); + example18a<Num>(); + example19<Num>(); + example20<Num>(); + example21<Num>(); + example22<Num>(); + // example23<Num>(); //requires comparisons. + example24<Num>(); +} + +namespace boost { +namespace multiprecision { + +template <unsigned D> +inline void log_postfix_event(const mpc_complex_backend<D>& val, const char* event_description) +{ + if (mpfr_nan_p(mpc_realref(val.data()))) + { + std::cout << "Found a NaN! " << event_description << std::endl; + } +} + +} +} // namespace boost::multiprecision + +int main() +{ + using namespace boost::multiprecision; + test_complex_type<mpc_complex>(); +#if 0 + test_integer_type<int>(); + + test_float_type<double>(); + test_complex_type<std::complex<double> >(); + + test_float_type<boost::multiprecision::cpp_dec_float_100>(); + test_float_type<boost::multiprecision::cpp_bin_float_50>(); + test_float_type<boost::multiprecision::mpfr_float>(); + + test_integer_type<boost::multiprecision::int256_t>(); + test_integer_type<boost::multiprecision::cpp_int>(); + test_integer_type<boost::multiprecision::cpp_rational>(); + test_integer_type<boost::multiprecision::mpz_int>(); + test_integer_type<boost::multiprecision::mpq_rational>(); + +#endif + return 0; +} |