boost_1_45_0/libs/math/doc/sf_and_dist/tr1_ref.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [section:tr1_ref TR1 C Functions Quick Reference]


 [h4 Supported TR1 Functions]

    namespace boost{ namespace math{ namespace tr1{ extern "C"{

    // [5.2.1.1] associated Laguerre polynomials:
    double assoc_laguerre(unsigned n, unsigned m, double x);
    float assoc_laguerref(unsigned n, unsigned m, float x);
    long double assoc_laguerrel(unsigned n, unsigned m, long double x);

    // [5.2.1.2] associated Legendre functions:
    double assoc_legendre(unsigned l, unsigned m, double x);
    float assoc_legendref(unsigned l, unsigned m, float x);
    long double assoc_legendrel(unsigned l, unsigned m, long double x);

    // [5.2.1.3] beta function:
    double beta(double x, double y);
    float betaf(float x, float y);
    long double betal(long double x, long double y);

    // [5.2.1.4] (complete) elliptic integral of the first kind:
    double comp_ellint_1(double k);
    float comp_ellint_1f(float k);
    long double comp_ellint_1l(long double k);

    // [5.2.1.5] (complete) elliptic integral of the second kind:
    double comp_ellint_2(double k);
    float comp_ellint_2f(float k);
    long double comp_ellint_2l(long double k);

    // [5.2.1.6] (complete) elliptic integral of the third kind:
    double comp_ellint_3(double k, double nu);
    float comp_ellint_3f(float k, float nu);
    long double comp_ellint_3l(long double k, long double nu);

    // [5.2.1.8] regular modified cylindrical Bessel functions:
    double cyl_bessel_i(double nu, double x);
    float cyl_bessel_if(float nu, float x);
    long double cyl_bessel_il(long double nu, long double x);

    // [5.2.1.9] cylindrical Bessel functions (of the first kind):
    double cyl_bessel_j(double nu, double x);
    float cyl_bessel_jf(float nu, float x);
    long double cyl_bessel_jl(long double nu, long double x);

    // [5.2.1.10] irregular modified cylindrical Bessel functions:
    double cyl_bessel_k(double nu, double x);
    float cyl_bessel_kf(float nu, float x);
    long double cyl_bessel_kl(long double nu, long double x);

    // [5.2.1.11] cylindrical Neumann functions;
    // cylindrical Bessel functions (of the second kind):
    double cyl_neumann(double nu, double x);
    float cyl_neumannf(float nu, float x);
    long double cyl_neumannl(long double nu, long double x);

    // [5.2.1.12] (incomplete) elliptic integral of the first kind:
    double ellint_1(double k, double phi);
    float ellint_1f(float k, float phi);
    long double ellint_1l(long double k, long double phi);

    // [5.2.1.13] (incomplete) elliptic integral of the second kind:
    double ellint_2(double k, double phi);
    float ellint_2f(float k, float phi);
    long double ellint_2l(long double k, long double phi);

    // [5.2.1.14] (incomplete) elliptic integral of the third kind:
    double ellint_3(double k, double nu, double phi);
    float ellint_3f(float k, float nu, float phi);
    long double ellint_3l(long double k, long double nu, long double phi);

    // [5.2.1.15] exponential integral:
    double expint(double x);
    float expintf(float x);
    long double expintl(long double x);

    // [5.2.1.16] Hermite polynomials:
    double hermite(unsigned n, double x);
    float hermitef(unsigned n, float x);
    long double hermitel(unsigned n, long double x);

    // [5.2.1.18] Laguerre polynomials:
    double laguerre(unsigned n, double x);
    float laguerref(unsigned n, float x);
    long double laguerrel(unsigned n, long double x);

    // [5.2.1.19] Legendre polynomials:
    double legendre(unsigned l, double x);
    float legendref(unsigned l, float x);
    long double legendrel(unsigned l, long double x);

    // [5.2.1.20] Riemann zeta function:
    double riemann_zeta(double);
    float riemann_zetaf(float);
    long double riemann_zetal(long double);

    // [5.2.1.21] spherical Bessel functions (of the first kind):
    double sph_bessel(unsigned n, double x);
    float sph_besself(unsigned n, float x);
    long double sph_bessell(unsigned n, long double x);

    // [5.2.1.22] spherical associated Legendre functions:
    double sph_legendre(unsigned l, unsigned m, double theta);
    float sph_legendref(unsigned l, unsigned m, float theta);
    long double sph_legendrel(unsigned l, unsigned m, long double theta);

    // [5.2.1.23] spherical Neumann functions;
    // spherical Bessel functions (of the second kind):
    double sph_neumann(unsigned n, double x);
    float sph_neumannf(unsigned n, float x);
    long double sph_neumannl(unsigned n, long double x);

    }}}} // namespaces

 In addition sufficient additional overloads of the `double` versions of the
 above functions are provided, so that calling the function with any mixture
 of `float`, `double`, `long double`, or /integer/ arguments is supported, with the
 return type determined by the __arg_pomotion_rules.

 For example:

    expintf(2.0f);  // float version, returns float.
    expint(2.0f);   // also calls the float version and returns float.
    expint(2.0);    // double version, returns double.
    expintl(2.0L);  // long double version, returns a long double.
    expint(2.0L);   // also calls the long double version.
    expint(2);      // integer argument is treated as a double, returns double.

 [h4 Quick Reference]

    // [5.2.1.1] associated Laguerre polynomials:
    double assoc_laguerre(unsigned n, unsigned m, double x);
    float assoc_laguerref(unsigned n, unsigned m, float x);
    long double assoc_laguerrel(unsigned n, unsigned m, long double x);

 The assoc_laguerre functions return:

 [equation laguerre_1]

 See also __laguerre for the full template (header only) version of this function.

    // [5.2.1.2] associated Legendre functions:
    double assoc_legendre(unsigned l, unsigned m, double x);
    float assoc_legendref(unsigned l, unsigned m, float x);
    long double assoc_legendrel(unsigned l, unsigned m, long double x);

 The assoc_legendre functions return:

 [equation legendre_1b]

 See also __legendre for the full template (header only) version of this function.

    // [5.2.1.3] beta function:
    double beta(double x, double y);
    float betaf(float x, float y);
    long double betal(long double x, long double y);

 Returns the beta function of /x/ and /y/:

 [equation beta1]

 See also __beta for the full template (header only) version of this function.

    // [5.2.1.4] (complete) elliptic integral of the first kind:
    double comp_ellint_1(double k);
    float comp_ellint_1f(float k);
    long double comp_ellint_1l(long double k);

 Returns the complete elliptic integral of the first kind of /k/:

 [equation ellint6]

 See also __ellint_1 for the full template (header only) version of this function.

    // [5.2.1.5] (complete) elliptic integral of the second kind:
    double comp_ellint_2(double k);
    float comp_ellint_2f(float k);
    long double comp_ellint_2l(long double k);

 Returns the complete elliptic integral of the second kind of /k/:

 [equation ellint7]

 See also __ellint_2 for the full template (header only) version of this function.

    // [5.2.1.6] (complete) elliptic integral of the third kind:
    double comp_ellint_3(double k, double nu);
    float comp_ellint_3f(float k, float nu);
    long double comp_ellint_3l(long double k, long double nu);

 Returns the complete elliptic integral of the third kind of /k/ and /nu/:

 [equation ellint8]

 See also __ellint_3 for the full template (header only) version of this function.

    // [5.2.1.8] regular modified cylindrical Bessel functions:
    double cyl_bessel_i(double nu, double x);
    float cyl_bessel_if(float nu, float x);
    long double cyl_bessel_il(long double nu, long double x);

 Returns the modified bessel function of the first kind of /nu/ and /x/:

 [equation mbessel2]

 See also __cyl_bessel_i for the full template (header only) version of this function.

    // [5.2.1.9] cylindrical Bessel functions (of the first kind):
    double cyl_bessel_j(double nu, double x);
    float cyl_bessel_jf(float nu, float x);
    long double cyl_bessel_jl(long double nu, long double x);

 Returns the bessel function of the first kind of /nu/ and /x/:

 [equation bessel2]

 See also __cyl_bessel_j for the full template (header only) version of this function.

    // [5.2.1.10] irregular modified cylindrical Bessel functions:
    double cyl_bessel_k(double nu, double x);
    float cyl_bessel_kf(float nu, float x);
    long double cyl_bessel_kl(long double nu, long double x);

 Returns the modified bessel function of the second kind of /nu/ and /x/:

 [equation mbessel3]

 See also __cyl_bessel_k for the full template (header only) version of this function.

    // [5.2.1.11] cylindrical Neumann functions;
    // cylindrical Bessel functions (of the second kind):
    double cyl_neumann(double nu, double x);
    float cyl_neumannf(float nu, float x);
    long double cyl_neumannl(long double nu, long double x);

 Returns the bessel function of the second kind (Neumann function) of /nu/ and /x/:

 [equation bessel3]

 See also __cyl_neumann for the full template (header only) version of this function.

    // [5.2.1.12] (incomplete) elliptic integral of the first kind:
    double ellint_1(double k, double phi);
    float ellint_1f(float k, float phi);
    long double ellint_1l(long double k, long double phi);

 Returns the incomplete elliptic integral of the first kind of /k/ and /phi/:

 [equation ellint2]

 See also __ellint_1 for the full template (header only) version of this function.

    // [5.2.1.13] (incomplete) elliptic integral of the second kind:
    double ellint_2(double k, double phi);
    float ellint_2f(float k, float phi);
    long double ellint_2l(long double k, long double phi);

 Returns the incomplete elliptic integral of the second kind of /k/ and /phi/:

 [equation ellint3]

 See also __ellint_2 for the full template (header only) version of this function.

    // [5.2.1.14] (incomplete) elliptic integral of the third kind:
    double ellint_3(double k, double nu, double phi);
    float ellint_3f(float k, float nu, float phi);
    long double ellint_3l(long double k, long double nu, long double phi);

 Returns the incomplete elliptic integral of the third kind of /k/, /nu/ and /phi/:

 [equation ellint4]

 See also __ellint_3 for the full template (header only) version of this function.

    // [5.2.1.15] exponential integral:
    double expint(double x);
    float expintf(float x);
    long double expintl(long double x);

 Returns the exponential integral Ei of /x/:

 [equation expint_i_1]

 See also __expint for the full template (header only) version of this function.

    // [5.2.1.16] Hermite polynomials:
    double hermite(unsigned n, double x);
    float hermitef(unsigned n, float x);
    long double hermitel(unsigned n, long double x);

 Returns the n'th Hermite polynomial of /x/:

 [equation hermite_0]

 See also __hermite for the full template (header only) version of this function.

    // [5.2.1.18] Laguerre polynomials:
    double laguerre(unsigned n, double x);
    float laguerref(unsigned n, float x);
    long double laguerrel(unsigned n, long double x);

 Returns the n'th Laguerre polynomial of /x/:

 [equation laguerre_0]

 See also __laguerre for the full template (header only) version of this function.

    // [5.2.1.19] Legendre polynomials:
    double legendre(unsigned l, double x);
    float legendref(unsigned l, float x);
    long double legendrel(unsigned l, long double x);

 Returns the l'th Legendre polynomial of /x/:

 [equation legendre_0]

 See also __legendre for the full template (header only) version of this function.

    // [5.2.1.20] Riemann zeta function:
    double riemann_zeta(double);
    float riemann_zetaf(float);
    long double riemann_zetal(long double);

 Returns the Riemann Zeta function of /x/:

 [equation zeta1]

 See also __zeta for the full template (header only) version of this function.

    // [5.2.1.21] spherical Bessel functions (of the first kind):
    double sph_bessel(unsigned n, double x);
    float sph_besself(unsigned n, float x);
    long double sph_bessell(unsigned n, long double x);

 Returns the spherical Bessel function of the first kind of /x/ j[sub n](x):

 [equation sbessel2]

 See also __sph_bessel for the full template (header only) version of this function.

    // [5.2.1.22] spherical associated Legendre functions:
    double sph_legendre(unsigned l, unsigned m, double theta);
    float sph_legendref(unsigned l, unsigned m, float theta);
    long double sph_legendrel(unsigned l, unsigned m, long double theta);

 Returns the spherical associated Legendre function of /l/, /m/ and /theta/:

 [equation spherical_3]

 See also __spherical_harmonic for the full template (header only) version of this function.

    // [5.2.1.23] spherical Neumann functions;
    // spherical Bessel functions (of the second kind):
    double sph_neumann(unsigned n, double x);
    float sph_neumannf(unsigned n, float x);
    long double sph_neumannl(unsigned n, long double x);

 Returns the spherical Neumann function of /x/ y[sub n](x):

 [equation sbessel2]

 See also __sph_bessel for the full template (header only) version of this function.


 [h4 Currently Unsupported TR1 Functions]

    // [5.2.1.7] confluent hypergeometric functions:
    double conf_hyperg(double a, double c, double x);
    float conf_hypergf(float a, float c, float x);
    long double conf_hypergl(long double a, long double c, long double x);

    // [5.2.1.17] hypergeometric functions:
    double hyperg(double a, double b, double c, double x);
    float hypergf(float a, float b, float c, float x);
    long double hypergl(long double a, long double b, long double c,
    long double x);

 [note These two functions are not implemented as they are not believed
 to be numerically stable.]


 [endsect]

 [/
   Copyright 2008, 2009 John Maddock and Paul A. Bristow.
   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).
 ]
	[section:tr1_ref TR1 C Functions Quick Reference]


	[h4 Supported TR1 Functions]

	namespace boost{ namespace math{ namespace tr1{ extern "C"{

	// [5.2.1.1] associated Laguerre polynomials:
	double assoc_laguerre(unsigned n, unsigned m, double x);
	float assoc_laguerref(unsigned n, unsigned m, float x);
	long double assoc_laguerrel(unsigned n, unsigned m, long double x);

	// [5.2.1.2] associated Legendre functions:
	double assoc_legendre(unsigned l, unsigned m, double x);
	float assoc_legendref(unsigned l, unsigned m, float x);
	long double assoc_legendrel(unsigned l, unsigned m, long double x);

	// [5.2.1.3] beta function:
	double beta(double x, double y);
	float betaf(float x, float y);
	long double betal(long double x, long double y);

	// [5.2.1.4] (complete) elliptic integral of the first kind:
	double comp_ellint_1(double k);
	float comp_ellint_1f(float k);
	long double comp_ellint_1l(long double k);

	// [5.2.1.5] (complete) elliptic integral of the second kind:
	double comp_ellint_2(double k);
	float comp_ellint_2f(float k);
	long double comp_ellint_2l(long double k);

	// [5.2.1.6] (complete) elliptic integral of the third kind:
	double comp_ellint_3(double k, double nu);
	float comp_ellint_3f(float k, float nu);
	long double comp_ellint_3l(long double k, long double nu);

	// [5.2.1.8] regular modified cylindrical Bessel functions:
	double cyl_bessel_i(double nu, double x);
	float cyl_bessel_if(float nu, float x);
	long double cyl_bessel_il(long double nu, long double x);

	// [5.2.1.9] cylindrical Bessel functions (of the first kind):
	double cyl_bessel_j(double nu, double x);
	float cyl_bessel_jf(float nu, float x);
	long double cyl_bessel_jl(long double nu, long double x);

	// [5.2.1.10] irregular modified cylindrical Bessel functions:
	double cyl_bessel_k(double nu, double x);
	float cyl_bessel_kf(float nu, float x);
	long double cyl_bessel_kl(long double nu, long double x);

	// [5.2.1.11] cylindrical Neumann functions;
	// cylindrical Bessel functions (of the second kind):
	double cyl_neumann(double nu, double x);
	float cyl_neumannf(float nu, float x);
	long double cyl_neumannl(long double nu, long double x);

	// [5.2.1.12] (incomplete) elliptic integral of the first kind:
	double ellint_1(double k, double phi);
	float ellint_1f(float k, float phi);
	long double ellint_1l(long double k, long double phi);

	// [5.2.1.13] (incomplete) elliptic integral of the second kind:
	double ellint_2(double k, double phi);
	float ellint_2f(float k, float phi);
	long double ellint_2l(long double k, long double phi);

	// [5.2.1.14] (incomplete) elliptic integral of the third kind:
	double ellint_3(double k, double nu, double phi);
	float ellint_3f(float k, float nu, float phi);
	long double ellint_3l(long double k, long double nu, long double phi);

	// [5.2.1.15] exponential integral:
	double expint(double x);
	float expintf(float x);
	long double expintl(long double x);

	// [5.2.1.16] Hermite polynomials:
	double hermite(unsigned n, double x);
	float hermitef(unsigned n, float x);
	long double hermitel(unsigned n, long double x);

	// [5.2.1.18] Laguerre polynomials:
	double laguerre(unsigned n, double x);
	float laguerref(unsigned n, float x);
	long double laguerrel(unsigned n, long double x);

	// [5.2.1.19] Legendre polynomials:
	double legendre(unsigned l, double x);
	float legendref(unsigned l, float x);
	long double legendrel(unsigned l, long double x);

	// [5.2.1.20] Riemann zeta function:
	double riemann_zeta(double);
	float riemann_zetaf(float);
	long double riemann_zetal(long double);

	// [5.2.1.21] spherical Bessel functions (of the first kind):
	double sph_bessel(unsigned n, double x);
	float sph_besself(unsigned n, float x);
	long double sph_bessell(unsigned n, long double x);

	// [5.2.1.22] spherical associated Legendre functions:
	double sph_legendre(unsigned l, unsigned m, double theta);
	float sph_legendref(unsigned l, unsigned m, float theta);
	long double sph_legendrel(unsigned l, unsigned m, long double theta);

	// [5.2.1.23] spherical Neumann functions;
	// spherical Bessel functions (of the second kind):
	double sph_neumann(unsigned n, double x);
	float sph_neumannf(unsigned n, float x);
	long double sph_neumannl(unsigned n, long double x);

	}}}} // namespaces

	In addition sufficient additional overloads of the `double` versions of the
	above functions are provided, so that calling the function with any mixture
	of `float`, `double`, `long double`, or /integer/ arguments is supported, with the
	return type determined by the __arg_pomotion_rules.

	For example:

	expintf(2.0f); // float version, returns float.
	expint(2.0f); // also calls the float version and returns float.
	expint(2.0); // double version, returns double.
	expintl(2.0L); // long double version, returns a long double.
	expint(2.0L); // also calls the long double version.
	expint(2); // integer argument is treated as a double, returns double.

	[h4 Quick Reference]

	// [5.2.1.1] associated Laguerre polynomials:
	double assoc_laguerre(unsigned n, unsigned m, double x);
	float assoc_laguerref(unsigned n, unsigned m, float x);
	long double assoc_laguerrel(unsigned n, unsigned m, long double x);

	The assoc_laguerre functions return:

	[equation laguerre_1]

	See also __laguerre for the full template (header only) version of this function.

	// [5.2.1.2] associated Legendre functions:
	double assoc_legendre(unsigned l, unsigned m, double x);
	float assoc_legendref(unsigned l, unsigned m, float x);
	long double assoc_legendrel(unsigned l, unsigned m, long double x);

	The assoc_legendre functions return:

	[equation legendre_1b]

	See also __legendre for the full template (header only) version of this function.

	// [5.2.1.3] beta function:
	double beta(double x, double y);
	float betaf(float x, float y);
	long double betal(long double x, long double y);

	Returns the beta function of /x/ and /y/:

	[equation beta1]

	See also __beta for the full template (header only) version of this function.

	// [5.2.1.4] (complete) elliptic integral of the first kind:
	double comp_ellint_1(double k);
	float comp_ellint_1f(float k);
	long double comp_ellint_1l(long double k);

	Returns the complete elliptic integral of the first kind of /k/:

	[equation ellint6]

	See also __ellint_1 for the full template (header only) version of this function.

	// [5.2.1.5] (complete) elliptic integral of the second kind:
	double comp_ellint_2(double k);
	float comp_ellint_2f(float k);
	long double comp_ellint_2l(long double k);

	Returns the complete elliptic integral of the second kind of /k/:

	[equation ellint7]

	See also __ellint_2 for the full template (header only) version of this function.

	// [5.2.1.6] (complete) elliptic integral of the third kind:
	double comp_ellint_3(double k, double nu);
	float comp_ellint_3f(float k, float nu);
	long double comp_ellint_3l(long double k, long double nu);

	Returns the complete elliptic integral of the third kind of /k/ and /nu/:

	[equation ellint8]

	See also __ellint_3 for the full template (header only) version of this function.

	// [5.2.1.8] regular modified cylindrical Bessel functions:
	double cyl_bessel_i(double nu, double x);
	float cyl_bessel_if(float nu, float x);
	long double cyl_bessel_il(long double nu, long double x);

	Returns the modified bessel function of the first kind of /nu/ and /x/:

	[equation mbessel2]

	See also __cyl_bessel_i for the full template (header only) version of this function.

	// [5.2.1.9] cylindrical Bessel functions (of the first kind):
	double cyl_bessel_j(double nu, double x);
	float cyl_bessel_jf(float nu, float x);
	long double cyl_bessel_jl(long double nu, long double x);

	Returns the bessel function of the first kind of /nu/ and /x/:

	[equation bessel2]

	See also __cyl_bessel_j for the full template (header only) version of this function.

	// [5.2.1.10] irregular modified cylindrical Bessel functions:
	double cyl_bessel_k(double nu, double x);
	float cyl_bessel_kf(float nu, float x);
	long double cyl_bessel_kl(long double nu, long double x);

	Returns the modified bessel function of the second kind of /nu/ and /x/:

	[equation mbessel3]

	See also __cyl_bessel_k for the full template (header only) version of this function.

	// [5.2.1.11] cylindrical Neumann functions;
	// cylindrical Bessel functions (of the second kind):
	double cyl_neumann(double nu, double x);
	float cyl_neumannf(float nu, float x);
	long double cyl_neumannl(long double nu, long double x);

	Returns the bessel function of the second kind (Neumann function) of /nu/ and /x/:

	[equation bessel3]

	See also __cyl_neumann for the full template (header only) version of this function.

	// [5.2.1.12] (incomplete) elliptic integral of the first kind:
	double ellint_1(double k, double phi);
	float ellint_1f(float k, float phi);
	long double ellint_1l(long double k, long double phi);

	Returns the incomplete elliptic integral of the first kind of /k/ and /phi/:

	[equation ellint2]

	See also __ellint_1 for the full template (header only) version of this function.

	// [5.2.1.13] (incomplete) elliptic integral of the second kind:
	double ellint_2(double k, double phi);
	float ellint_2f(float k, float phi);
	long double ellint_2l(long double k, long double phi);

	Returns the incomplete elliptic integral of the second kind of /k/ and /phi/:

	[equation ellint3]

	See also __ellint_2 for the full template (header only) version of this function.

	// [5.2.1.14] (incomplete) elliptic integral of the third kind:
	double ellint_3(double k, double nu, double phi);
	float ellint_3f(float k, float nu, float phi);
	long double ellint_3l(long double k, long double nu, long double phi);

	Returns the incomplete elliptic integral of the third kind of /k/, /nu/ and /phi/:

	[equation ellint4]

	See also __ellint_3 for the full template (header only) version of this function.

	// [5.2.1.15] exponential integral:
	double expint(double x);
	float expintf(float x);
	long double expintl(long double x);

	Returns the exponential integral Ei of /x/:

	[equation expint_i_1]

	See also __expint for the full template (header only) version of this function.

	// [5.2.1.16] Hermite polynomials:
	double hermite(unsigned n, double x);
	float hermitef(unsigned n, float x);
	long double hermitel(unsigned n, long double x);

	Returns the n'th Hermite polynomial of /x/:

	[equation hermite_0]

	See also __hermite for the full template (header only) version of this function.

	// [5.2.1.18] Laguerre polynomials:
	double laguerre(unsigned n, double x);
	float laguerref(unsigned n, float x);
	long double laguerrel(unsigned n, long double x);

	Returns the n'th Laguerre polynomial of /x/:

	[equation laguerre_0]

	See also __laguerre for the full template (header only) version of this function.

	// [5.2.1.19] Legendre polynomials:
	double legendre(unsigned l, double x);
	float legendref(unsigned l, float x);
	long double legendrel(unsigned l, long double x);

	Returns the l'th Legendre polynomial of /x/:

	[equation legendre_0]

	See also __legendre for the full template (header only) version of this function.

	// [5.2.1.20] Riemann zeta function:
	double riemann_zeta(double);
	float riemann_zetaf(float);
	long double riemann_zetal(long double);

	Returns the Riemann Zeta function of /x/:

	[equation zeta1]

	See also __zeta for the full template (header only) version of this function.

	// [5.2.1.21] spherical Bessel functions (of the first kind):
	double sph_bessel(unsigned n, double x);
	float sph_besself(unsigned n, float x);
	long double sph_bessell(unsigned n, long double x);

	Returns the spherical Bessel function of the first kind of /x/ j[sub n](x):

	[equation sbessel2]

	See also __sph_bessel for the full template (header only) version of this function.

	// [5.2.1.22] spherical associated Legendre functions:
	double sph_legendre(unsigned l, unsigned m, double theta);
	float sph_legendref(unsigned l, unsigned m, float theta);
	long double sph_legendrel(unsigned l, unsigned m, long double theta);

	Returns the spherical associated Legendre function of /l/, /m/ and /theta/:

	[equation spherical_3]

	See also __spherical_harmonic for the full template (header only) version of this function.

	// [5.2.1.23] spherical Neumann functions;
	// spherical Bessel functions (of the second kind):
	double sph_neumann(unsigned n, double x);
	float sph_neumannf(unsigned n, float x);
	long double sph_neumannl(unsigned n, long double x);

	Returns the spherical Neumann function of /x/ y[sub n](x):

	[equation sbessel2]

	See also __sph_bessel for the full template (header only) version of this function.



	[h4 Currently Unsupported TR1 Functions]

	// [5.2.1.7] confluent hypergeometric functions:
	double conf_hyperg(double a, double c, double x);
	float conf_hypergf(float a, float c, float x);
	long double conf_hypergl(long double a, long double c, long double x);

	// [5.2.1.17] hypergeometric functions:
	double hyperg(double a, double b, double c, double x);
	float hypergf(float a, float b, float c, float x);
	long double hypergl(long double a, long double b, long double c,
	long double x);

	[note These two functions are not implemented as they are not believed
	to be numerically stable.]


	[endsect]

	[/
	Copyright 2008, 2009 John Maddock and Paul A. Bristow.
	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).
	]