/* specfunc/gsl_sf_gamma.h * * Copyright (C) 1996, 1997, 1998, 1999, 2000 Gerard Jungman * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or (at * your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* Author: G. Jungman */ #ifndef __GSL_SF_GAMMA_H__ #define __GSL_SF_GAMMA_H__ #include #undef __BEGIN_DECLS #undef __END_DECLS #ifdef __cplusplus # define __BEGIN_DECLS extern "C" { # define __END_DECLS } #else # define __BEGIN_DECLS /* empty */ # define __END_DECLS /* empty */ #endif __BEGIN_DECLS /* Log[Gamma(x)], x not a negative integer * Uses real Lanczos method. * Returns the real part of Log[Gamma[x]] when x < 0, * i.e. Log[|Gamma[x]|]. * * exceptions: GSL_EDOM, GSL_EROUND */ int gsl_sf_lngamma_e(double x, gsl_sf_result * result); double gsl_sf_lngamma(const double x); /* Log[Gamma(x)], x not a negative integer * Uses real Lanczos method. Determines * the sign of Gamma[x] as well as Log[|Gamma[x]|] for x < 0. * So Gamma[x] = sgn * Exp[result_lg]. * * exceptions: GSL_EDOM, GSL_EROUND */ int gsl_sf_lngamma_sgn_e(double x, gsl_sf_result * result_lg, double *sgn); /* Gamma(x), x not a negative integer * Uses real Lanczos method. * * exceptions: GSL_EDOM, GSL_EOVRFLW, GSL_EROUND */ int gsl_sf_gamma_e(const double x, gsl_sf_result * result); double gsl_sf_gamma(const double x); /* Regulated Gamma Function, x > 0 * Gamma^*(x) = Gamma(x)/(Sqrt[2Pi] x^(x-1/2) exp(-x)) * = (1 + 1/(12x) + ...), x->Inf * A useful suggestion of Temme. * * exceptions: GSL_EDOM */ int gsl_sf_gammastar_e(const double x, gsl_sf_result * result); double gsl_sf_gammastar(const double x); /* 1/Gamma(x) * Uses real Lanczos method. * * exceptions: GSL_EUNDRFLW, GSL_EROUND */ int gsl_sf_gammainv_e(const double x, gsl_sf_result * result); double gsl_sf_gammainv(const double x); /* Log[Gamma(z)] for z complex, z not a negative integer * Uses complex Lanczos method. Note that the phase part (arg) * is not well-determined when |z| is very large, due * to inevitable roundoff in restricting to (-Pi,Pi]. * This will raise the GSL_ELOSS exception when it occurs. * The absolute value part (lnr), however, never suffers. * * Calculates: * lnr = log|Gamma(z)| * arg = arg(Gamma(z)) in (-Pi, Pi] * * exceptions: GSL_EDOM, GSL_ELOSS */ int gsl_sf_lngamma_complex_e(double zr, double zi, gsl_sf_result * lnr, gsl_sf_result * arg); /* x^n / n! * * x >= 0.0, n >= 0 * exceptions: GSL_EDOM, GSL_EOVRFLW, GSL_EUNDRFLW */ int gsl_sf_taylorcoeff_e(const int n, const double x, gsl_sf_result * result); double gsl_sf_taylorcoeff(const int n, const double x); /* n! * * exceptions: GSL_EDOM, GSL_EOVRFLW */ int gsl_sf_fact_e(const unsigned int n, gsl_sf_result * result); double gsl_sf_fact(const unsigned int n); /* n!! = n(n-2)(n-4) ... * * exceptions: GSL_EDOM, GSL_EOVRFLW */ int gsl_sf_doublefact_e(const unsigned int n, gsl_sf_result * result); double gsl_sf_doublefact(const unsigned int n); /* log(n!) * Faster than ln(Gamma(n+1)) for n < 170; defers for larger n. * * exceptions: none */ int gsl_sf_lnfact_e(const unsigned int n, gsl_sf_result * result); double gsl_sf_lnfact(const unsigned int n); /* log(n!!) * * exceptions: none */ int gsl_sf_lndoublefact_e(const unsigned int n, gsl_sf_result * result); double gsl_sf_lndoublefact(const unsigned int n); /* log(n choose m) * * exceptions: GSL_EDOM */ int gsl_sf_lnchoose_e(unsigned int n, unsigned int m, gsl_sf_result * result); double gsl_sf_lnchoose(unsigned int n, unsigned int m); /* n choose m * * exceptions: GSL_EDOM, GSL_EOVRFLW */ int gsl_sf_choose_e(unsigned int n, unsigned int m, gsl_sf_result * result); double gsl_sf_choose(unsigned int n, unsigned int m); /* Logarithm of Pochhammer (Apell) symbol * log( (a)_x ) * where (a)_x := Gamma[a + x]/Gamma[a] * * a > 0, a+x > 0 * * exceptions: GSL_EDOM */ int gsl_sf_lnpoch_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_lnpoch(const double a, const double x); /* Logarithm of Pochhammer (Apell) symbol, with sign information. * result = log( |(a)_x| ) * sgn = sgn( (a)_x ) * where (a)_x := Gamma[a + x]/Gamma[a] * * a != neg integer, a+x != neg integer * * exceptions: GSL_EDOM */ int gsl_sf_lnpoch_sgn_e(const double a, const double x, gsl_sf_result * result, double * sgn); /* Pochhammer (Apell) symbol * (a)_x := Gamma[a + x]/Gamma[x] * * a != neg integer, a+x != neg integer * * exceptions: GSL_EDOM, GSL_EOVRFLW */ int gsl_sf_poch_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_poch(const double a, const double x); /* Relative Pochhammer (Apell) symbol * ((a,x) - 1)/x * where (a,x) = (a)_x := Gamma[a + x]/Gamma[a] * * exceptions: GSL_EDOM */ int gsl_sf_pochrel_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_pochrel(const double a, const double x); /* Normalized Incomplete Gamma Function * * Q(a,x) = 1/Gamma(a) Integral[ t^(a-1) e^(-t), {t,x,Infinity} ] * * a >= 0, x >= 0 * Q(a,0) := 1 * Q(0,x) := 0, x != 0 * * exceptions: GSL_EDOM */ int gsl_sf_gamma_inc_Q_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_gamma_inc_Q(const double a, const double x); /* Complementary Normalized Incomplete Gamma Function * * P(a,x) = 1/Gamma(a) Integral[ t^(a-1) e^(-t), {t,0,x} ] * * a > 0, x >= 0 * * exceptions: GSL_EDOM */ int gsl_sf_gamma_inc_P_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_gamma_inc_P(const double a, const double x); /* Non-normalized Incomplete Gamma Function * * Gamma(a,x) := Integral[ t^(a-1) e^(-t), {t,x,Infinity} ] * * x >= 0.0 * Gamma(a, 0) := Gamma(a) * * exceptions: GSL_EDOM */ int gsl_sf_gamma_inc_e(const double a, const double x, gsl_sf_result * result); double gsl_sf_gamma_inc(const double a, const double x); /* Logarithm of Beta Function * Log[B(a,b)] * * a > 0, b > 0 * exceptions: GSL_EDOM */ int gsl_sf_lnbeta_e(const double a, const double b, gsl_sf_result * result); double gsl_sf_lnbeta(const double a, const double b); int gsl_sf_lnbeta_sgn_e(const double x, const double y, gsl_sf_result * result, double * sgn); /* Beta Function * B(a,b) * * a > 0, b > 0 * exceptions: GSL_EDOM, GSL_EOVRFLW, GSL_EUNDRFLW */ int gsl_sf_beta_e(const double a, const double b, gsl_sf_result * result); double gsl_sf_beta(const double a, const double b); /* Normalized Incomplete Beta Function * B_x(a,b)/B(a,b) * * a > 0, b > 0, 0 <= x <= 1 * exceptions: GSL_EDOM, GSL_EUNDRFLW */ int gsl_sf_beta_inc_e(const double a, const double b, const double x, gsl_sf_result * result); double gsl_sf_beta_inc(const double a, const double b, const double x); /* The maximum x such that gamma(x) is not * considered an overflow. */ #define GSL_SF_GAMMA_XMAX 171.0 /* The maximum n such that gsl_sf_fact(n) does not give an overflow. */ #define GSL_SF_FACT_NMAX 170 /* The maximum n such that gsl_sf_doublefact(n) does not give an overflow. */ #define GSL_SF_DOUBLEFACT_NMAX 297 __END_DECLS #endif /* __GSL_SF_GAMMA_H__ */