WSJT-X/boost/libs/math/test/test_ellint_d.hpp

// Copyright John Maddock 2015.
//  Use, modification and distribution are subject to 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)

#ifdef _MSC_VER
#  pragma warning(disable : 4756) // overflow in constant arithmetic
// Constants are too big for float case, but this doesn't matter for test.
#endif

#include <boost/math/concepts/real_concept.hpp>
#define BOOST_TEST_MAIN
#include <boost/test/unit_test.hpp>
#include <boost/test/floating_point_comparison.hpp>
#include <boost/math/special_functions/math_fwd.hpp>
#include <boost/array.hpp>
#include "functor.hpp"

#include "handle_test_result.hpp"
#include "table_type.hpp"

#ifndef SC_
#define SC_(x) static_cast<typename table_type<T>::type>(BOOST_JOIN(x, L))
#endif

template <class Real, typename T>
void do_test_ellint_d2(const T& data, const char* type_name, const char* test)
{
#if !(defined(ERROR_REPORTING_MODE) && !defined(ELLINT_D2_FUNCTION_TO_TEST))
   typedef Real                   value_type;

   std::cout << "Testing: " << test << std::endl;

#ifdef ELLINT_D2_FUNCTION_TO_TEST
   value_type(*fp2)(value_type, value_type) = ELLINT_D2_FUNCTION_TO_TEST;
#elif defined(BOOST_MATH_NO_DEDUCED_FUNCTION_POINTERS)
    value_type (*fp2)(value_type, value_type) = boost::math::ellint_d<value_type, value_type>;
#else
    value_type (*fp2)(value_type, value_type) = boost::math::ellint_d;
#endif
    boost::math::tools::test_result<value_type> result;

    result = boost::math::tools::test_hetero<Real>(
      data,
      bind_func<Real>(fp2, 1, 0),
      extract_result<Real>(2));
   handle_test_result(result, data[result.worst()], result.worst(),
      type_name, "ellint_d", test);

   std::cout << std::endl;
#endif
}

template <class Real, typename T>
void do_test_ellint_d1(T& data, const char* type_name, const char* test)
{
#if !(defined(ERROR_REPORTING_MODE) && !defined(ELLINT_D1_FUNCTION_TO_TEST))
   typedef Real                   value_type;
    boost::math::tools::test_result<value_type> result;

   std::cout << "Testing: " << test << std::endl;

#ifdef ELLINT_D1_FUNCTION_TO_TEST
   value_type(*fp1)(value_type) = ELLINT_D1_FUNCTION_TO_TEST;
#elif defined(BOOST_MATH_NO_DEDUCED_FUNCTION_POINTERS)
   value_type (*fp1)(value_type) = boost::math::ellint_d<value_type>;
#else
   value_type (*fp1)(value_type) = boost::math::ellint_d;
#endif
   result = boost::math::tools::test_hetero<Real>(
      data,
      bind_func<Real>(fp1, 0),
      extract_result<Real>(1));
   handle_test_result(result, data[result.worst()], result.worst(),
      type_name, "ellint_d (complete)", test);

   std::cout << std::endl;
#endif
}

template <typename T>
void test_spots(T, const char* type_name)
{
    BOOST_MATH_STD_USING
    // Function values calculated on http://functions.wolfram.com/
    // Note that Mathematica's EllipticE accepts k^2 as the second parameter.
    static const boost::array<boost::array<T, 3>, 10> data1 = {{
       { { SC_(0.5), SC_(0.5), SC_(0.040348098248931543984282958654503585) } },
        {{ SC_(0), SC_(0.5), SC_(0) }},
        { { SC_(1), SC_(0.5), SC_(0.28991866293419922467977188008516755) } },
        { { SC_(1), T(1), SC_(0.38472018607562056416055864584160775) } },
        { { SC_(-1), T(1), SC_(-0.38472018607562056416055864584160775) } },
        { { SC_(-1), T(0.5), SC_(-0.28991866293419922467977188008516755) } },
        { { SC_(-10), T(0.5), SC_(-5.2996914501577855803123384771117708) } },
        { { SC_(10), SC_(-0.5), SC_(5.2996914501577855803123384771117708) } },
    }};

    do_test_ellint_d2<T>(data1, type_name, "Elliptic Integral E: Mathworld Data");

#include "ellint_d2_data.ipp"

    do_test_ellint_d2<T>(ellint_d2_data, type_name, "Elliptic Integral D: Random Data");

    // Function values calculated on http://functions.wolfram.com/
    // Note that Mathematica's EllipticE accepts k^2 as the second parameter.
    static const boost::array<boost::array<T, 2>, 3> data2 = {{
       { { SC_(0.5), SC_(0.87315258189267554964563356323264341) } },
       { { SC_(1.0) / 1024, SC_(0.78539844427788694671464428063604776) } },
       { { boost::math::tools::root_epsilon<T>(), SC_(0.78539816339744830961566084581987572) } }
    }};

    do_test_ellint_d1<T>(data2, type_name, "Elliptic Integral E: Mathworld Data");

#include "ellint_d_data.ipp"

    do_test_ellint_d1<T>(ellint_d_data, type_name, "Elliptic Integral D: Random Data");

    BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(1)), std::domain_error);
    BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(-1)), std::domain_error);
    BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(1.5)), std::domain_error);
    BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(-1.5)), std::domain_error);
}
Squashed 'boost/' content from commit b4feb19f2 git-subtree-dir: boost git-subtree-split: b4feb19f287ee92d87a9624b5d36b7cf46aeadeb 2018-06-09 21:48:32 +01:00			`// Copyright John Maddock 2015.`
			`// Use, modification and distribution are subject to 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)`

			`#ifdef _MSC_VER`
			`# pragma warning(disable : 4756) // overflow in constant arithmetic`
			`// Constants are too big for float case, but this doesn't matter for test.`
			`#endif`

			`#include <boost/math/concepts/real_concept.hpp>`
			`#define BOOST_TEST_MAIN`
			`#include <boost/test/unit_test.hpp>`
			`#include <boost/test/floating_point_comparison.hpp>`
			`#include <boost/math/special_functions/math_fwd.hpp>`
			`#include <boost/array.hpp>`
			`#include "functor.hpp"`

			`#include "handle_test_result.hpp"`
			`#include "table_type.hpp"`

			`#ifndef SC_`
			`#define SC_(x) static_cast<typename table_type<T>::type>(BOOST_JOIN(x, L))`
			`#endif`

			`template <class Real, typename T>`
			`void do_test_ellint_d2(const T& data, const char* type_name, const char* test)`
			`{`
			`#if !(defined(ERROR_REPORTING_MODE) && !defined(ELLINT_D2_FUNCTION_TO_TEST))`
			`typedef Real value_type;`

			`std::cout << "Testing: " << test << std::endl;`

			`#ifdef ELLINT_D2_FUNCTION_TO_TEST`
			`value_type(*fp2)(value_type, value_type) = ELLINT_D2_FUNCTION_TO_TEST;`
			`#elif defined(BOOST_MATH_NO_DEDUCED_FUNCTION_POINTERS)`
			`value_type (*fp2)(value_type, value_type) = boost::math::ellint_d<value_type, value_type>;`
			`#else`
			`value_type (*fp2)(value_type, value_type) = boost::math::ellint_d;`
			`#endif`
			`boost::math::tools::test_result<value_type> result;`

			`result = boost::math::tools::test_hetero<Real>(`
			`data,`
			`bind_func<Real>(fp2, 1, 0),`
			`extract_result<Real>(2));`
			`handle_test_result(result, data[result.worst()], result.worst(),`
			`type_name, "ellint_d", test);`

			`std::cout << std::endl;`
			`#endif`
			`}`

			`template <class Real, typename T>`
			`void do_test_ellint_d1(T& data, const char* type_name, const char* test)`
			`{`
			`#if !(defined(ERROR_REPORTING_MODE) && !defined(ELLINT_D1_FUNCTION_TO_TEST))`
			`typedef Real value_type;`
			`boost::math::tools::test_result<value_type> result;`

			`std::cout << "Testing: " << test << std::endl;`

			`#ifdef ELLINT_D1_FUNCTION_TO_TEST`
			`value_type(*fp1)(value_type) = ELLINT_D1_FUNCTION_TO_TEST;`
			`#elif defined(BOOST_MATH_NO_DEDUCED_FUNCTION_POINTERS)`
			`value_type (*fp1)(value_type) = boost::math::ellint_d<value_type>;`
			`#else`
			`value_type (*fp1)(value_type) = boost::math::ellint_d;`
			`#endif`
			`result = boost::math::tools::test_hetero<Real>(`
			`data,`
			`bind_func<Real>(fp1, 0),`
			`extract_result<Real>(1));`
			`handle_test_result(result, data[result.worst()], result.worst(),`
			`type_name, "ellint_d (complete)", test);`

			`std::cout << std::endl;`
			`#endif`
			`}`

			`template <typename T>`
			`void test_spots(T, const char* type_name)`
			`{`
			`BOOST_MATH_STD_USING`
			`// Function values calculated on http://functions.wolfram.com/`
			`// Note that Mathematica's EllipticE accepts k^2 as the second parameter.`
			`static const boost::array<boost::array<T, 3>, 10> data1 = {{`
			`{ { SC_(0.5), SC_(0.5), SC_(0.040348098248931543984282958654503585) } },`
			`{{ SC_(0), SC_(0.5), SC_(0) }},`
			`{ { SC_(1), SC_(0.5), SC_(0.28991866293419922467977188008516755) } },`
			`{ { SC_(1), T(1), SC_(0.38472018607562056416055864584160775) } },`
			`{ { SC_(-1), T(1), SC_(-0.38472018607562056416055864584160775) } },`
			`{ { SC_(-1), T(0.5), SC_(-0.28991866293419922467977188008516755) } },`
			`{ { SC_(-10), T(0.5), SC_(-5.2996914501577855803123384771117708) } },`
			`{ { SC_(10), SC_(-0.5), SC_(5.2996914501577855803123384771117708) } },`
			`}};`

			`do_test_ellint_d2<T>(data1, type_name, "Elliptic Integral E: Mathworld Data");`

			`#include "ellint_d2_data.ipp"`

			`do_test_ellint_d2<T>(ellint_d2_data, type_name, "Elliptic Integral D: Random Data");`

			`// Function values calculated on http://functions.wolfram.com/`
			`// Note that Mathematica's EllipticE accepts k^2 as the second parameter.`
			`static const boost::array<boost::array<T, 2>, 3> data2 = {{`
			`{ { SC_(0.5), SC_(0.87315258189267554964563356323264341) } },`
			`{ { SC_(1.0) / 1024, SC_(0.78539844427788694671464428063604776) } },`
			`{ { boost::math::tools::root_epsilon<T>(), SC_(0.78539816339744830961566084581987572) } }`
			`}};`

			`do_test_ellint_d1<T>(data2, type_name, "Elliptic Integral E: Mathworld Data");`

			`#include "ellint_d_data.ipp"`

			`do_test_ellint_d1<T>(ellint_d_data, type_name, "Elliptic Integral D: Random Data");`

			`BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(1)), std::domain_error);`
			`BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(-1)), std::domain_error);`
			`BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(1.5)), std::domain_error);`
			`BOOST_MATH_CHECK_THROW(boost::math::ellint_d(T(-1.5)), std::domain_error);`
			`}`