boost_1_45_0/libs/math/tools/bessel_data.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //  Copyright (c) 2007 John Maddock
 //  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)
 //
 // Computes test data for the various bessel functions using
 // archived - deliberately naive - version of the code.
 // We'll rely on the high precision of boost::math::ntl::RR to get us out of
 // trouble and not worry about how long the calculations take.
 // This provides a reasonably independent set of test data to
 // compare against newly added asymptotic expansions etc.
 //
 #include <fstream>

 #include <boost/math/bindings/rr.hpp>
 #include <boost/math/tools/test_data.hpp>

 #include <boost/math/special_functions/bessel.hpp>

 using namespace boost::math::tools;
 using namespace boost::math;
 using namespace boost::math::detail;
 using namespace std;

 // Compute J(v, x) and Y(v, x) simultaneously by Steed's method, see
 // Barnett et al, Computer Physics Communications, vol 8, 377 (1974)
 template <typename T>
 int bessel_jy_bare(T v, T x, T* J, T* Y, int kind = need_j|need_y)
 {
     // Jv1 = J_(v+1), Yv1 = Y_(v+1), fv = J_(v+1) / J_v
     // Ju1 = J_(u+1), Yu1 = Y_(u+1), fu = J_(u+1) / J_u
     T u, Jv, Ju, Yv, Yv1, Yu, Yu1, fv, fu;
     T W, p, q, gamma, current, prev, next;
     bool reflect = false;
     int n, k, s;

     using namespace std;
     using namespace boost::math::tools;
     using namespace boost::math::constants;

     if (v < 0)
     {
         reflect = true;
         v = -v;                             // v is non-negative from here
         kind = need_j|need_y;               // need both for reflection formula
     }
     n = real_cast<int>(v + 0.5L);
     u = v - n;                              // -1/2 <= u < 1/2

     if (x < 0)
     {
        *J = *Y = policies::raise_domain_error<T>("",
           "Real argument x=%1% must be non-negative, complex number result not supported", x, policies::policy<>());
         return 1;
     }
     if (x == 0)
     {
        *J = *Y = policies::raise_overflow_error<T>(
           "", 0, policies::policy<>());
        return 1;
     }

     // x is positive until reflection
     W = T(2) / (x * pi<T>());               // Wronskian
     if (x <= 2)                           // x in (0, 2]
     {
        if(temme_jy(u, x, &Yu, &Yu1, policies::policy<>()))             // Temme series
         {
            // domain error:
            *J = *Y = Yu;
            return 1;
         }
         prev = Yu;
         current = Yu1;
         for (k = 1; k <= n; k++)            // forward recurrence for Y
         {
             next = 2 * (u + k) * current / x - prev;
             prev = current;
             current = next;
         }
         Yv = prev;
         Yv1 = current;
         CF1_jy(v, x, &fv, &s, policies::policy<>());                 // continued fraction CF1
         Jv = W / (Yv * fv - Yv1);           // Wronskian relation
     }
     else                                    // x in (2, \infty)
     {
         // Get Y(u, x):
         CF1_jy(v, x, &fv, &s, policies::policy<>());
         // tiny initial value to prevent overflow
         T init = sqrt(tools::min_value<T>());
         prev = fv * s * init;
         current = s * init;
         for (k = n; k > 0; k--)             // backward recurrence for J
         {
             next = 2 * (u + k) * current / x - prev;
             prev = current;
             current = next;
         }
         T ratio = (s * init) / current;     // scaling ratio
         // can also call CF1() to get fu, not much difference in precision
         fu = prev / current;
         CF2_jy(u, x, &p, &q, policies::policy<>());                  // continued fraction CF2
         T t = u / x - fu;                   // t = J'/J
         gamma = (p - t) / q;
         Ju = sign(current) * sqrt(W / (q + gamma * (p - t)));

         Jv = Ju * ratio;                    // normalization

         Yu = gamma * Ju;
         Yu1 = Yu * (u/x - p - q/gamma);

         // compute Y:
         prev = Yu;
         current = Yu1;
         for (k = 1; k <= n; k++)            // forward recurrence for Y
         {
             next = 2 * (u + k) * current / x - prev;
             prev = current;
             current = next;
         }
         Yv = prev;
     }

     if (reflect)
     {
         T z = (u + n % 2) * pi<T>();
         *J = cos(z) * Jv - sin(z) * Yv;     // reflection formula
         *Y = sin(z) * Jv + cos(z) * Yv;
     }
     else
     {
         *J = Jv;
         *Y = Yv;
     }

     return 0;
 }

 int progress = 0;

 template <class T>
 T cyl_bessel_j_bare(T v, T x)
 {
    T j, y;
    bessel_jy_bare(v, x, &j, &y);

    std::cout << progress++ << ":   J(" << v << ", " << x << ") = " << j << std::endl;

    if(fabs(j) > 1e30)
       throw std::domain_error("");

    return j;
 }

 template <class T>
 T cyl_bessel_i_bare(T v, T x)
 {
    using namespace std;
    if(x < 0)
    {
       // better have integer v:
       if(floor(v) == v)
       {
          T r = cyl_bessel_i_bare(v, -x);
          if(tools::real_cast<int>(v) & 1)
             r = -r;
          return r;
       }
       else
          return policies::raise_domain_error<T>(
             "",
             "Got x = %1%, but we need x >= 0", x, policies::policy<>());
    }
    if(x == 0)
    {
       return (v == 0) ? 1 : 0;
    }
    T I, K;
    boost::math::detail::bessel_ik(v, x, &I, &K, 0xffff, policies::policy<>());

    std::cout << progress++ << ":   I(" << v << ", " << x << ") = " << I << std::endl;

    if(fabs(I) > 1e30)
       throw std::domain_error("");

    return I;
 }

 template <class T>
 T cyl_bessel_k_bare(T v, T x)
 {
    using namespace std;
    if(x < 0)
    {
       return policies::raise_domain_error<T>(
          "",
          "Got x = %1%, but we need x > 0", x, policies::policy<>());
    }
    if(x == 0)
    {
       return (v == 0) ? policies::raise_overflow_error<T>("", 0, policies::policy<>())
          : policies::raise_domain_error<T>(
          "",
          "Got x = %1%, but we need x > 0", x, policies::policy<>());
    }
    T I, K;
    bessel_ik(v, x, &I, &K, 0xFFFF, policies::policy<>());

    std::cout << progress++ << ":   K(" << v << ", " << x << ") = " << K << std::endl;

    if(fabs(K) > 1e30)
       throw std::domain_error("");

    return K;
 }

 template <class T>
 T cyl_neumann_bare(T v, T x)
 {
    T j, y;
    bessel_jy(v, x, &j, &y, 0xFFFF, policies::policy<>());

    std::cout << progress++ << ":   Y(" << v << ", " << x << ") = " << y << std::endl;

    if(fabs(y) > 1e30)
       throw std::domain_error("");

    return y;
 }

 template <class T>
 T sph_bessel_j_bare(T v, T x)
 {
    std::cout << progress++ << ":   j(" << v << ", " << x << ") = ";
    if((v < 0) || (floor(v) != v))
       throw std::domain_error("");
    T r = sqrt(constants::pi<T>() / (2 * x)) * cyl_bessel_j_bare(v+0.5, x);
    std::cout << r << std::endl;
    return r;
 }

 template <class T>
 T sph_bessel_y_bare(T v, T x)
 {
    std::cout << progress++ << ":   y(" << v << ", " << x << ") = ";
    if((v < 0) || (floor(v) != v))
       throw std::domain_error("");
    T r = sqrt(constants::pi<T>() / (2 * x)) * cyl_neumann_bare(v+0.5, x);
    std::cout << r << std::endl;
    return r;
 }

 enum
 {
    func_J = 0,
    func_Y,
    func_I,
    func_K,
    func_j,
    func_y
 };

 int main(int argc, char* argv[])
 {
    std::cout << std::setprecision(17) << std::scientific;
    std::cout << sph_bessel_j_bare(0., 0.1185395751953125e4) << std::endl;
    std::cout << sph_bessel_j_bare(22., 0.6540834903717041015625) << std::endl;

    parameter_info<boost::math::ntl::RR> arg1, arg2;
    test_data<boost::math::ntl::RR> data;

    boost::math::ntl::RR::SetPrecision(1000);
    boost::math::ntl::RR::SetOutputPrecision(40);

    int functype = 0;
    std::string letter = "J";

    if(argc == 2)
    {
       if(std::strcmp(argv[1], "--Y") == 0)
       {
          functype = func_Y;
          letter = "Y";
       }
       else if(std::strcmp(argv[1], "--I") == 0)
       {
          functype = func_I;
          letter = "I";
       }
       else if(std::strcmp(argv[1], "--K") == 0)
       {
          functype = func_K;
          letter = "K";
       }
       else if(std::strcmp(argv[1], "--j") == 0)
       {
          functype = func_j;
          letter = "j";
       }
       else if(std::strcmp(argv[1], "--y") == 0)
       {
          functype = func_y;
          letter = "y";
       }
       else
          assert(0);
    }

    bool cont;
    std::string line;

    std::cout << "Welcome.\n"
       "This program will generate spot tests for the Bessel " << letter << " function\n\n";
    do{
       get_user_parameter_info(arg1, "v");
       get_user_parameter_info(arg2, "x");
       boost::math::ntl::RR (*fp)(boost::math::ntl::RR, boost::math::ntl::RR);
       if(functype == func_J)
          fp = cyl_bessel_j_bare;
       else if(functype == func_I)
          fp = cyl_bessel_i_bare;
       else if(functype == func_K)
          fp = cyl_bessel_k_bare;
       else if(functype == func_Y)
          fp = cyl_neumann_bare;
       else if(functype == func_j)
          fp = sph_bessel_j_bare;
       else if(functype == func_y)
          fp = sph_bessel_y_bare;
       else
          assert(0);

       data.insert(fp, arg1, arg2);

       std::cout << "Any more data [y/n]?";
       std::getline(std::cin, line);
       boost::algorithm::trim(line);
       cont = (line == "y");
    }while(cont);

    std::cout << "Enter name of test data file [default=bessel_j_data.ipp]";
    std::getline(std::cin, line);
    boost::algorithm::trim(line);
    if(line == "")
       line = "bessel_j_data.ipp";
    std::ofstream ofs(line.c_str());
    line.erase(line.find('.'));
    ofs << std::scientific;
    write_code(ofs, data, line.c_str());

    return 0;
 }
	// Copyright (c) 2007 John Maddock
	// 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)
	//
	// Computes test data for the various bessel functions using
	// archived - deliberately naive - version of the code.
	// We'll rely on the high precision of boost::math::ntl::RR to get us out of
	// trouble and not worry about how long the calculations take.
	// This provides a reasonably independent set of test data to
	// compare against newly added asymptotic expansions etc.
	//
	#include <fstream>

	#include <boost/math/bindings/rr.hpp>
	#include <boost/math/tools/test_data.hpp>

	#include <boost/math/special_functions/bessel.hpp>

	using namespace boost::math::tools;
	using namespace boost::math;
	using namespace boost::math::detail;
	using namespace std;

	// Compute J(v, x) and Y(v, x) simultaneously by Steed's method, see
	// Barnett et al, Computer Physics Communications, vol 8, 377 (1974)
	template <typename T>
	int bessel_jy_bare(T v, T x, T* J, T* Y, int kind = need_j\|need_y)
	{
	// Jv1 = J_(v+1), Yv1 = Y_(v+1), fv = J_(v+1) / J_v
	// Ju1 = J_(u+1), Yu1 = Y_(u+1), fu = J_(u+1) / J_u
	T u, Jv, Ju, Yv, Yv1, Yu, Yu1, fv, fu;
	T W, p, q, gamma, current, prev, next;
	bool reflect = false;
	int n, k, s;

	using namespace std;
	using namespace boost::math::tools;
	using namespace boost::math::constants;

	if (v < 0)
	{
	reflect = true;
	v = -v; // v is non-negative from here
	kind = need_j\|need_y; // need both for reflection formula
	}
	n = real_cast<int>(v + 0.5L);
	u = v - n; // -1/2 <= u < 1/2

	if (x < 0)
	{
	J = Y = policies::raise_domain_error<T>("",
	"Real argument x=%1% must be non-negative, complex number result not supported", x, policies::policy<>());
	return 1;
	}
	if (x == 0)
	{
	J = Y = policies::raise_overflow_error<T>(
	"", 0, policies::policy<>());
	return 1;
	}

	// x is positive until reflection
	W = T(2) / (x * pi<T>()); // Wronskian
	if (x <= 2) // x in (0, 2]
	{
	if(temme_jy(u, x, &Yu, &Yu1, policies::policy<>())) // Temme series
	{
	// domain error:
	J = Y = Yu;
	return 1;
	}
	prev = Yu;
	current = Yu1;
	for (k = 1; k <= n; k++) // forward recurrence for Y
	{
	next = 2 * (u + k) * current / x - prev;
	prev = current;
	current = next;
	}
	Yv = prev;
	Yv1 = current;
	CF1_jy(v, x, &fv, &s, policies::policy<>()); // continued fraction CF1
	Jv = W / (Yv * fv - Yv1); // Wronskian relation
	}
	else // x in (2, \infty)
	{
	// Get Y(u, x):
	CF1_jy(v, x, &fv, &s, policies::policy<>());
	// tiny initial value to prevent overflow
	T init = sqrt(tools::min_value<T>());
	prev = fv * s * init;
	current = s * init;
	for (k = n; k > 0; k--) // backward recurrence for J
	{
	next = 2 * (u + k) * current / x - prev;
	prev = current;
	current = next;
	}
	T ratio = (s * init) / current; // scaling ratio
	// can also call CF1() to get fu, not much difference in precision
	fu = prev / current;
	CF2_jy(u, x, &p, &q, policies::policy<>()); // continued fraction CF2
	T t = u / x - fu; // t = J'/J
	gamma = (p - t) / q;
	Ju = sign(current) * sqrt(W / (q + gamma * (p - t)));

	Jv = Ju * ratio; // normalization

	Yu = gamma * Ju;
	Yu1 = Yu * (u/x - p - q/gamma);

	// compute Y:
	prev = Yu;
	current = Yu1;
	for (k = 1; k <= n; k++) // forward recurrence for Y
	{
	next = 2 * (u + k) * current / x - prev;
	prev = current;
	current = next;
	}
	Yv = prev;
	}

	if (reflect)
	{
	T z = (u + n % 2) * pi<T>();
	J = cos(z) Jv - sin(z) * Yv; // reflection formula
	Y = sin(z) Jv + cos(z) * Yv;
	}
	else
	{
	*J = Jv;
	*Y = Yv;
	}

	return 0;
	}

	int progress = 0;

	template <class T>
	T cyl_bessel_j_bare(T v, T x)
	{
	T j, y;
	bessel_jy_bare(v, x, &j, &y);

	std::cout << progress++ << ": J(" << v << ", " << x << ") = " << j << std::endl;

	if(fabs(j) > 1e30)
	throw std::domain_error("");

	return j;
	}

	template <class T>
	T cyl_bessel_i_bare(T v, T x)
	{
	using namespace std;
	if(x < 0)
	{
	// better have integer v:
	if(floor(v) == v)
	{
	T r = cyl_bessel_i_bare(v, -x);
	if(tools::real_cast<int>(v) & 1)
	r = -r;
	return r;
	}
	else
	return policies::raise_domain_error<T>(
	"",
	"Got x = %1%, but we need x >= 0", x, policies::policy<>());
	}
	if(x == 0)
	{
	return (v == 0) ? 1 : 0;
	}
	T I, K;
	boost::math::detail::bessel_ik(v, x, &I, &K, 0xffff, policies::policy<>());

	std::cout << progress++ << ": I(" << v << ", " << x << ") = " << I << std::endl;

	if(fabs(I) > 1e30)
	throw std::domain_error("");

	return I;
	}

	template <class T>
	T cyl_bessel_k_bare(T v, T x)
	{
	using namespace std;
	if(x < 0)
	{
	return policies::raise_domain_error<T>(
	"",
	"Got x = %1%, but we need x > 0", x, policies::policy<>());
	}
	if(x == 0)
	{
	return (v == 0) ? policies::raise_overflow_error<T>("", 0, policies::policy<>())
	: policies::raise_domain_error<T>(
	"",
	"Got x = %1%, but we need x > 0", x, policies::policy<>());
	}
	T I, K;
	bessel_ik(v, x, &I, &K, 0xFFFF, policies::policy<>());

	std::cout << progress++ << ": K(" << v << ", " << x << ") = " << K << std::endl;

	if(fabs(K) > 1e30)
	throw std::domain_error("");

	return K;
	}

	template <class T>
	T cyl_neumann_bare(T v, T x)
	{
	T j, y;
	bessel_jy(v, x, &j, &y, 0xFFFF, policies::policy<>());

	std::cout << progress++ << ": Y(" << v << ", " << x << ") = " << y << std::endl;

	if(fabs(y) > 1e30)
	throw std::domain_error("");

	return y;
	}

	template <class T>
	T sph_bessel_j_bare(T v, T x)
	{
	std::cout << progress++ << ": j(" << v << ", " << x << ") = ";
	if((v < 0) \|\| (floor(v) != v))
	throw std::domain_error("");
	T r = sqrt(constants::pi<T>() / (2 * x)) * cyl_bessel_j_bare(v+0.5, x);
	std::cout << r << std::endl;
	return r;
	}

	template <class T>
	T sph_bessel_y_bare(T v, T x)
	{
	std::cout << progress++ << ": y(" << v << ", " << x << ") = ";
	if((v < 0) \|\| (floor(v) != v))
	throw std::domain_error("");
	T r = sqrt(constants::pi<T>() / (2 * x)) * cyl_neumann_bare(v+0.5, x);
	std::cout << r << std::endl;
	return r;
	}

	enum
	{
	func_J = 0,
	func_Y,
	func_I,
	func_K,
	func_j,
	func_y
	};

	int main(int argc, char* argv[])
	{
	std::cout << std::setprecision(17) << std::scientific;
	std::cout << sph_bessel_j_bare(0., 0.1185395751953125e4) << std::endl;
	std::cout << sph_bessel_j_bare(22., 0.6540834903717041015625) << std::endl;

	parameter_info<boost::math::ntl::RR> arg1, arg2;
	test_data<boost::math::ntl::RR> data;

	boost::math::ntl::RR::SetPrecision(1000);
	boost::math::ntl::RR::SetOutputPrecision(40);

	int functype = 0;
	std::string letter = "J";

	if(argc == 2)
	{
	if(std::strcmp(argv[1], "--Y") == 0)
	{
	functype = func_Y;
	letter = "Y";
	}
	else if(std::strcmp(argv[1], "--I") == 0)
	{
	functype = func_I;
	letter = "I";
	}
	else if(std::strcmp(argv[1], "--K") == 0)
	{
	functype = func_K;
	letter = "K";
	}
	else if(std::strcmp(argv[1], "--j") == 0)
	{
	functype = func_j;
	letter = "j";
	}
	else if(std::strcmp(argv[1], "--y") == 0)
	{
	functype = func_y;
	letter = "y";
	}
	else
	assert(0);
	}

	bool cont;
	std::string line;

	std::cout << "Welcome.\n"
	"This program will generate spot tests for the Bessel " << letter << " function\n\n";
	do{
	get_user_parameter_info(arg1, "v");
	get_user_parameter_info(arg2, "x");
	boost::math::ntl::RR (*fp)(boost::math::ntl::RR, boost::math::ntl::RR);
	if(functype == func_J)
	fp = cyl_bessel_j_bare;
	else if(functype == func_I)
	fp = cyl_bessel_i_bare;
	else if(functype == func_K)
	fp = cyl_bessel_k_bare;
	else if(functype == func_Y)
	fp = cyl_neumann_bare;
	else if(functype == func_j)
	fp = sph_bessel_j_bare;
	else if(functype == func_y)
	fp = sph_bessel_y_bare;
	else
	assert(0);

	data.insert(fp, arg1, arg2);

	std::cout << "Any more data [y/n]?";
	std::getline(std::cin, line);
	boost::algorithm::trim(line);
	cont = (line == "y");
	}while(cont);

	std::cout << "Enter name of test data file [default=bessel_j_data.ipp]";
	std::getline(std::cin, line);
	boost::algorithm::trim(line);
	if(line == "")
	line = "bessel_j_data.ipp";
	std::ofstream ofs(line.c_str());
	line.erase(line.find('.'));
	ofs << std::scientific;
	write_code(ofs, data, line.c_str());

	return 0;
	}