boost_1_45_0/libs/math/test/test_roots.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  (C) Copyright John Maddock 2006.
 //  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)

 #include <pch.hpp>

 #include <boost/test/test_exec_monitor.hpp>
 #include <boost/test/floating_point_comparison.hpp>
 #include <boost/test/results_collector.hpp>
 #include <boost/math/special_functions/beta.hpp>
 #include <boost/math/tools/roots.hpp>
 #include <boost/test/results_collector.hpp>
 #include <boost/test/unit_test.hpp>
 #include <boost/array.hpp>

 #define BOOST_CHECK_CLOSE_EX(a, b, prec, i) \
    {\
       unsigned int failures = boost::unit_test::results_collector.results( boost::unit_test::framework::current_test_case().p_id ).p_assertions_failed;\
       BOOST_CHECK_CLOSE(a, b, prec); \
       if(failures != boost::unit_test::results_collector.results( boost::unit_test::framework::current_test_case().p_id ).p_assertions_failed)\
       {\
          std::cerr << "Failure was at row " << i << std::endl;\
          std::cerr << std::setprecision(35); \
          std::cerr << "{ " << data[i][0] << " , " << data[i][1] << " , " << data[i][2];\
          std::cerr << " , " << data[i][3] << " , " << data[i][4] << " , " << data[i][5] << " } " << std::endl;\
       }\
    }


 //
 // Implement various versions of inverse of the incomplete beta
 // using different root finding algorithms, and deliberately "bad"
 // starting conditions: that way we get all the pathological cases
 // we could ever wish for!!!
 //

 template <class T, class Policy>
 struct ibeta_roots_1   // for first order algorithms
 {
    ibeta_roots_1(T _a, T _b, T t, bool inv = false)
       : a(_a), b(_b), target(t), invert(inv) {}

    T operator()(const T& x)
    {
       return boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
    }
 private:
    T a, b, target;
    bool invert;
 };

 template <class T, class Policy>
 struct ibeta_roots_2   // for second order algorithms
 {
    ibeta_roots_2(T _a, T _b, T t, bool inv = false)
       : a(_a), b(_b), target(t), invert(inv) {}

    boost::math::tuple<T, T> operator()(const T& x)
    {
       typedef typename boost::math::lanczos::lanczos<T, Policy>::type L;
       T f = boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
       T f1 = invert ?
          -boost::math::detail::ibeta_power_terms(b, a, 1 - x, x, L(), true, Policy())
                : boost::math::detail::ibeta_power_terms(a, b, x, 1 - x, L(), true, Policy());
       T y = 1 - x;
       if(y == 0)
          y = boost::math::tools::min_value<T>() * 8;
       f1 /= y * x;

       // make sure we don't have a zero derivative:
       if(f1 == 0)
          f1 = (invert ? -1 : 1) * boost::math::tools::min_value<T>() * 64;

       return boost::math::make_tuple(f, f1);
    }
 private:
    T a, b, target;
    bool invert;
 };

 template <class T, class Policy>
 struct ibeta_roots_3   // for third order algorithms
 {
    ibeta_roots_3(T _a, T _b, T t, bool inv = false)
       : a(_a), b(_b), target(t), invert(inv) {}

    boost::math::tuple<T, T, T> operator()(const T& x)
    {
       typedef typename boost::math::lanczos::lanczos<T, Policy>::type L;
       T f = boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
       T f1 = invert ?
                -boost::math::detail::ibeta_power_terms(b, a, 1 - x, x, L(), true, Policy())
                : boost::math::detail::ibeta_power_terms(a, b, x, 1 - x, L(), true, Policy());
       T y = 1 - x;
       if(y == 0)
          y = boost::math::tools::min_value<T>() * 8;
       f1 /= y * x;
       T f2 = f1 * (-y * a + (b - 2) * x + 1) / (y * x);
       if(invert)
          f2 = -f2;

       // make sure we don't have a zero derivative:
       if(f1 == 0)
          f1 = (invert ? -1 : 1) * boost::math::tools::min_value<T>() * 64;

       return boost::math::make_tuple(f, f1, f2);
    }
 private:
    T a, b, target;
    bool invert;
 };

 double inverse_ibeta_bisect(double a, double b, double z)
 {
    typedef boost::math::policies::policy<> pol;
    bool invert = false;
    int bits = std::numeric_limits<double>::digits;

    //
    // special cases, we need to have these because there may be other
    // possible answers:
    //
    if(z == 1) return 1;
    if(z == 0) return 0;

    //
    // We need a good estimate of the error in the incomplete beta function
    // so that we don't set the desired precision too high.  Assume that 3-bits
    // are lost each time the arguments increase by a factor of 10:
    //
    using namespace std;
    int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
    if(bits_lost < 0)
       bits_lost = 3;
    else
       bits_lost += 3;
    int precision = bits - bits_lost;

    double min = 0;
    double max = 1;
    boost::math::tools::eps_tolerance<double> tol(precision);
    return boost::math::tools::bisect(ibeta_roots_1<double, pol>(a, b, z, invert), min, max, tol).first;
 }

 double inverse_ibeta_newton(double a, double b, double z)
 {
    double guess = 0.5;
    bool invert = false;
    int bits = std::numeric_limits<double>::digits;

    //
    // special cases, we need to have these because there may be other
    // possible answers:
    //
    if(z == 1) return 1;
    if(z == 0) return 0;

    //
    // We need a good estimate of the error in the incomplete beta function
    // so that we don't set the desired precision too high.  Assume that 3-bits
    // are lost each time the arguments increase by a factor of 10:
    //
    using namespace std;
    int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
    if(bits_lost < 0)
       bits_lost = 3;
    else
       bits_lost += 3;
    int precision = bits - bits_lost;

    double min = 0;
    double max = 1;
    return boost::math::tools::newton_raphson_iterate(ibeta_roots_2<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
 }

 double inverse_ibeta_halley(double a, double b, double z)
 {
    double guess = 0.5;
    bool invert = false;
    int bits = std::numeric_limits<double>::digits;

    //
    // special cases, we need to have these because there may be other
    // possible answers:
    //
    if(z == 1) return 1;
    if(z == 0) return 0;

    //
    // We need a good estimate of the error in the incomplete beta function
    // so that we don't set the desired precision too high.  Assume that 3-bits
    // are lost each time the arguments increase by a factor of 10:
    //
    using namespace std;
    int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
    if(bits_lost < 0)
       bits_lost = 3;
    else
       bits_lost += 3;
    int precision = bits - bits_lost;

    double min = 0;
    double max = 1;
    return boost::math::tools::halley_iterate(ibeta_roots_3<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
 }

 double inverse_ibeta_schroeder(double a, double b, double z)
 {
    double guess = 0.5;
    bool invert = false;
    int bits = std::numeric_limits<double>::digits;

    //
    // special cases, we need to have these because there may be other
    // possible answers:
    //
    if(z == 1) return 1;
    if(z == 0) return 0;

    //
    // We need a good estimate of the error in the incomplete beta function
    // so that we don't set the desired precision too high.  Assume that 3-bits
    // are lost each time the arguments increase by a factor of 10:
    //
    using namespace std;
    int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
    if(bits_lost < 0)
       bits_lost = 3;
    else
       bits_lost += 3;
    int precision = bits - bits_lost;

    double min = 0;
    double max = 1;
    return boost::math::tools::schroeder_iterate(ibeta_roots_3<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
 }


 template <class T>
 void test_inverses(const T& data)
 {
    using namespace std;
    typedef typename T::value_type row_type;
    typedef typename row_type::value_type value_type;

    value_type precision = static_cast<value_type>(ldexp(1.0, 1-boost::math::policies::digits<value_type, boost::math::policies::policy<> >()/2)) * 100;
    if(boost::math::policies::digits<value_type, boost::math::policies::policy<> >() < 50)
       precision = 1;   // 1% or two decimal digits, all we can hope for when the input is truncated

    for(unsigned i = 0; i < data.size(); ++i)
    {
       //
       // These inverse tests are thrown off if the output of the
       // incomplete beta is too close to 1: basically there is insuffient
       // information left in the value we're using as input to the inverse
       // to be able to get back to the original value.
       //
       if(data[i][5] == 0)
       {
          BOOST_CHECK_EQUAL(inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]), value_type(0));
          BOOST_CHECK_EQUAL(inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]), value_type(0));
          BOOST_CHECK_EQUAL(inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]), value_type(0));
          BOOST_CHECK_EQUAL(inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]), value_type(0));
       }
       else if((1 - data[i][5] > 0.001)
          && (fabs(data[i][5]) > 2 * boost::math::tools::min_value<value_type>())
          && (fabs(data[i][5]) > 2 * boost::math::tools::min_value<double>()))
       {
          value_type inv = inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]);
          BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
          inv = inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]);
          BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
          inv = inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]);
          BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
          inv = inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]);
          BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
       }
       else if(1 == data[i][5])
       {
          BOOST_CHECK_EQUAL(inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]), value_type(1));
          BOOST_CHECK_EQUAL(inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]), value_type(1));
          BOOST_CHECK_EQUAL(inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]), value_type(1));
          BOOST_CHECK_EQUAL(inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]), value_type(1));
       }

    }
 }

 template <class T>
 void test_beta(T, const char* /* name */)
 {
    //
    // The actual test data is rather verbose, so it's in a separate file
    //
    // The contents are as follows, each row of data contains
    // five items, input value a, input value b, integration limits x, beta(a, b, x) and ibeta(a, b, x):
    //
 #  include "ibeta_small_data.ipp"

    test_inverses(ibeta_small_data);

 #  include "ibeta_data.ipp"

    test_inverses(ibeta_data);

 #  include "ibeta_large_data.ipp"

    test_inverses(ibeta_large_data);
 }

 int test_main(int, char* [])
 {
    test_beta(0.1, "double");
    return 0;
 }
	// (C) Copyright John Maddock 2006.
	// 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)

	#include <pch.hpp>

	#include <boost/test/test_exec_monitor.hpp>
	#include <boost/test/floating_point_comparison.hpp>
	#include <boost/test/results_collector.hpp>
	#include <boost/math/special_functions/beta.hpp>
	#include <boost/math/tools/roots.hpp>
	#include <boost/test/results_collector.hpp>
	#include <boost/test/unit_test.hpp>
	#include <boost/array.hpp>

	#define BOOST_CHECK_CLOSE_EX(a, b, prec, i) \
	{\
	unsigned int failures = boost::unit_test::results_collector.results( boost::unit_test::framework::current_test_case().p_id ).p_assertions_failed;\
	BOOST_CHECK_CLOSE(a, b, prec); \
	if(failures != boost::unit_test::results_collector.results( boost::unit_test::framework::current_test_case().p_id ).p_assertions_failed)\
	{\
	std::cerr << "Failure was at row " << i << std::endl;\
	std::cerr << std::setprecision(35); \
	std::cerr << "{ " << data[i][0] << " , " << data[i][1] << " , " << data[i][2];\
	std::cerr << " , " << data[i][3] << " , " << data[i][4] << " , " << data[i][5] << " } " << std::endl;\
	}\
	}


	//
	// Implement various versions of inverse of the incomplete beta
	// using different root finding algorithms, and deliberately "bad"
	// starting conditions: that way we get all the pathological cases
	// we could ever wish for!!!
	//

	template <class T, class Policy>
	struct ibeta_roots_1 // for first order algorithms
	{
	ibeta_roots_1(T _a, T _b, T t, bool inv = false)
	: a(_a), b(_b), target(t), invert(inv) {}

	T operator()(const T& x)
	{
	return boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
	}
	private:
	T a, b, target;
	bool invert;
	};

	template <class T, class Policy>
	struct ibeta_roots_2 // for second order algorithms
	{
	ibeta_roots_2(T _a, T _b, T t, bool inv = false)
	: a(_a), b(_b), target(t), invert(inv) {}

	boost::math::tuple<T, T> operator()(const T& x)
	{
	typedef typename boost::math::lanczos::lanczos<T, Policy>::type L;
	T f = boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
	T f1 = invert ?
	-boost::math::detail::ibeta_power_terms(b, a, 1 - x, x, L(), true, Policy())
	: boost::math::detail::ibeta_power_terms(a, b, x, 1 - x, L(), true, Policy());
	T y = 1 - x;
	if(y == 0)
	y = boost::math::tools::min_value<T>() * 8;
	f1 /= y * x;

	// make sure we don't have a zero derivative:
	if(f1 == 0)
	f1 = (invert ? -1 : 1) * boost::math::tools::min_value<T>() * 64;

	return boost::math::make_tuple(f, f1);
	}
	private:
	T a, b, target;
	bool invert;
	};

	template <class T, class Policy>
	struct ibeta_roots_3 // for third order algorithms
	{
	ibeta_roots_3(T _a, T _b, T t, bool inv = false)
	: a(_a), b(_b), target(t), invert(inv) {}

	boost::math::tuple<T, T, T> operator()(const T& x)
	{
	typedef typename boost::math::lanczos::lanczos<T, Policy>::type L;
	T f = boost::math::detail::ibeta_imp(a, b, x, Policy(), invert, true) - target;
	T f1 = invert ?
	-boost::math::detail::ibeta_power_terms(b, a, 1 - x, x, L(), true, Policy())
	: boost::math::detail::ibeta_power_terms(a, b, x, 1 - x, L(), true, Policy());
	T y = 1 - x;
	if(y == 0)
	y = boost::math::tools::min_value<T>() * 8;
	f1 /= y * x;
	T f2 = f1 * (-y * a + (b - 2) * x + 1) / (y * x);
	if(invert)
	f2 = -f2;

	// make sure we don't have a zero derivative:
	if(f1 == 0)
	f1 = (invert ? -1 : 1) * boost::math::tools::min_value<T>() * 64;

	return boost::math::make_tuple(f, f1, f2);
	}
	private:
	T a, b, target;
	bool invert;
	};

	double inverse_ibeta_bisect(double a, double b, double z)
	{
	typedef boost::math::policies::policy<> pol;
	bool invert = false;
	int bits = std::numeric_limits<double>::digits;

	//
	// special cases, we need to have these because there may be other
	// possible answers:
	//
	if(z == 1) return 1;
	if(z == 0) return 0;

	//
	// We need a good estimate of the error in the incomplete beta function
	// so that we don't set the desired precision too high. Assume that 3-bits
	// are lost each time the arguments increase by a factor of 10:
	//
	using namespace std;
	int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
	if(bits_lost < 0)
	bits_lost = 3;
	else
	bits_lost += 3;
	int precision = bits - bits_lost;

	double min = 0;
	double max = 1;
	boost::math::tools::eps_tolerance<double> tol(precision);
	return boost::math::tools::bisect(ibeta_roots_1<double, pol>(a, b, z, invert), min, max, tol).first;
	}

	double inverse_ibeta_newton(double a, double b, double z)
	{
	double guess = 0.5;
	bool invert = false;
	int bits = std::numeric_limits<double>::digits;

	//
	// special cases, we need to have these because there may be other
	// possible answers:
	//
	if(z == 1) return 1;
	if(z == 0) return 0;

	//
	// We need a good estimate of the error in the incomplete beta function
	// so that we don't set the desired precision too high. Assume that 3-bits
	// are lost each time the arguments increase by a factor of 10:
	//
	using namespace std;
	int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
	if(bits_lost < 0)
	bits_lost = 3;
	else
	bits_lost += 3;
	int precision = bits - bits_lost;

	double min = 0;
	double max = 1;
	return boost::math::tools::newton_raphson_iterate(ibeta_roots_2<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
	}

	double inverse_ibeta_halley(double a, double b, double z)
	{
	double guess = 0.5;
	bool invert = false;
	int bits = std::numeric_limits<double>::digits;

	//
	// special cases, we need to have these because there may be other
	// possible answers:
	//
	if(z == 1) return 1;
	if(z == 0) return 0;

	//
	// We need a good estimate of the error in the incomplete beta function
	// so that we don't set the desired precision too high. Assume that 3-bits
	// are lost each time the arguments increase by a factor of 10:
	//
	using namespace std;
	int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
	if(bits_lost < 0)
	bits_lost = 3;
	else
	bits_lost += 3;
	int precision = bits - bits_lost;

	double min = 0;
	double max = 1;
	return boost::math::tools::halley_iterate(ibeta_roots_3<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
	}

	double inverse_ibeta_schroeder(double a, double b, double z)
	{
	double guess = 0.5;
	bool invert = false;
	int bits = std::numeric_limits<double>::digits;

	//
	// special cases, we need to have these because there may be other
	// possible answers:
	//
	if(z == 1) return 1;
	if(z == 0) return 0;

	//
	// We need a good estimate of the error in the incomplete beta function
	// so that we don't set the desired precision too high. Assume that 3-bits
	// are lost each time the arguments increase by a factor of 10:
	//
	using namespace std;
	int bits_lost = static_cast<int>(ceil(log10((std::max)(a, b)) * 3));
	if(bits_lost < 0)
	bits_lost = 3;
	else
	bits_lost += 3;
	int precision = bits - bits_lost;

	double min = 0;
	double max = 1;
	return boost::math::tools::schroeder_iterate(ibeta_roots_3<double, boost::math::policies::policy<> >(a, b, z, invert), guess, min, max, precision);
	}


	template <class T>
	void test_inverses(const T& data)
	{
	using namespace std;
	typedef typename T::value_type row_type;
	typedef typename row_type::value_type value_type;

	value_type precision = static_cast<value_type>(ldexp(1.0, 1-boost::math::policies::digits<value_type, boost::math::policies::policy<> >()/2)) * 100;
	if(boost::math::policies::digits<value_type, boost::math::policies::policy<> >() < 50)
	precision = 1; // 1% or two decimal digits, all we can hope for when the input is truncated

	for(unsigned i = 0; i < data.size(); ++i)
	{
	//
	// These inverse tests are thrown off if the output of the
	// incomplete beta is too close to 1: basically there is insuffient
	// information left in the value we're using as input to the inverse
	// to be able to get back to the original value.
	//
	if(data[i][5] == 0)
	{
	BOOST_CHECK_EQUAL(inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]), value_type(0));
	BOOST_CHECK_EQUAL(inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]), value_type(0));
	BOOST_CHECK_EQUAL(inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]), value_type(0));
	BOOST_CHECK_EQUAL(inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]), value_type(0));
	}
	else if((1 - data[i][5] > 0.001)
	&& (fabs(data[i][5]) > 2 * boost::math::tools::min_value<value_type>())
	&& (fabs(data[i][5]) > 2 * boost::math::tools::min_value<double>()))
	{
	value_type inv = inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]);
	BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
	inv = inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]);
	BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
	inv = inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]);
	BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
	inv = inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]);
	BOOST_CHECK_CLOSE_EX(data[i][2], inv, precision, i);
	}
	else if(1 == data[i][5])
	{
	BOOST_CHECK_EQUAL(inverse_ibeta_halley(data[i][0], data[i][1], data[i][5]), value_type(1));
	BOOST_CHECK_EQUAL(inverse_ibeta_schroeder(data[i][0], data[i][1], data[i][5]), value_type(1));
	BOOST_CHECK_EQUAL(inverse_ibeta_newton(data[i][0], data[i][1], data[i][5]), value_type(1));
	BOOST_CHECK_EQUAL(inverse_ibeta_bisect(data[i][0], data[i][1], data[i][5]), value_type(1));
	}

	}
	}

	template <class T>
	void test_beta(T, const char* /* name */)
	{
	//
	// The actual test data is rather verbose, so it's in a separate file
	//
	// The contents are as follows, each row of data contains
	// five items, input value a, input value b, integration limits x, beta(a, b, x) and ibeta(a, b, x):
	//
	# include "ibeta_small_data.ipp"

	test_inverses(ibeta_small_data);

	# include "ibeta_data.ipp"

	test_inverses(ibeta_data);

	# include "ibeta_large_data.ipp"

	test_inverses(ibeta_large_data);
	}

	int test_main(int, char* [])
	{
	test_beta(0.1, "double");
	return 0;
	}