src/third_party/musl/src/math/tgamma.c - cobalt - Git at Google

 /*
 "A Precision Approximation of the Gamma Function" - Cornelius Lanczos (1964)
 "Lanczos Implementation of the Gamma Function" - Paul Godfrey (2001)
 "An Analysis of the Lanczos Gamma Approximation" - Glendon Ralph Pugh (2004)

 approximation method:

                         (x - 0.5)         S(x)
 Gamma(x) = (x + g - 0.5)         *  ----------------
                                     exp(x + g - 0.5)

 with
                  a1      a2      a3            aN
 S(x) ~= [ a0 + ----- + ----- + ----- + ... + ----- ]
                x + 1   x + 2   x + 3         x + N

 with a0, a1, a2, a3,.. aN constants which depend on g.

 for x < 0 the following reflection formula is used:

 Gamma(x)*Gamma(-x) = -pi/(x sin(pi x))

 most ideas and constants are from boost and python
 */
 #include "libm.h"

 static const double pi = 3.141592653589793238462643383279502884;

 /* sin(pi x) with x > 0x1p-100, if sin(pi*x)==0 the sign is arbitrary */
 static double sinpi(double x)
 {
 	int n;

 	/* argument reduction: x = |x| mod 2 */
 	/* spurious inexact when x is odd int */
 	x = x * 0.5;
 	x = 2 * (x - floor(x));

 	/* reduce x into [-.25,.25] */
 	n = 4 * x;
 	n = (n+1)/2;
 	x -= n * 0.5;

 	x *= pi;
 	switch (n) {
 	default: /* case 4 */
 	case 0:
 		return __sin(x, 0, 0);
 	case 1:
 		return __cos(x, 0);
 	case 2:
 		return __sin(-x, 0, 0);
 	case 3:
 		return -__cos(x, 0);
 	}
 }

 #define N 12
 //static const double g = 6.024680040776729583740234375;
 static const double gmhalf = 5.524680040776729583740234375;
 static const double Snum[N+1] = {
 	23531376880.410759688572007674451636754734846804940,
 	42919803642.649098768957899047001988850926355848959,
 	35711959237.355668049440185451547166705960488635843,
 	17921034426.037209699919755754458931112671403265390,
 	6039542586.3520280050642916443072979210699388420708,
 	1439720407.3117216736632230727949123939715485786772,
 	248874557.86205415651146038641322942321632125127801,
 	31426415.585400194380614231628318205362874684987640,
 	2876370.6289353724412254090516208496135991145378768,
 	186056.26539522349504029498971604569928220784236328,
 	8071.6720023658162106380029022722506138218516325024,
 	210.82427775157934587250973392071336271166969580291,
 	2.5066282746310002701649081771338373386264310793408,
 };
 static const double Sden[N+1] = {
 	0, 39916800, 120543840, 150917976, 105258076, 45995730, 13339535,
 	2637558, 357423, 32670, 1925, 66, 1,
 };
 /* n! for small integer n */
 static const double fact[] = {
 	1, 1, 2, 6, 24, 120, 720, 5040.0, 40320.0, 362880.0, 3628800.0, 39916800.0,
 	479001600.0, 6227020800.0, 87178291200.0, 1307674368000.0, 20922789888000.0,
 	355687428096000.0, 6402373705728000.0, 121645100408832000.0,
 	2432902008176640000.0, 51090942171709440000.0, 1124000727777607680000.0,
 };

 /* S(x) rational function for positive x */
 static double S(double x)
 {
 	double_t num = 0, den = 0;
 	int i;

 	/* to avoid overflow handle large x differently */
 	if (x < 8)
 		for (i = N; i >= 0; i--) {
 			num = num * x + Snum[i];
 			den = den * x + Sden[i];
 		}
 	else
 		for (i = 0; i <= N; i++) {
 			num = num / x + Snum[i];
 			den = den / x + Sden[i];
 		}
 	return num/den;
 }

 double tgamma(double x)
 {
 	union {double f; uint64_t i;} u = {x};
 	double absx, y;
 	double_t dy, z, r;
 	uint32_t ix = u.i>>32 & 0x7fffffff;
 	int sign = u.i>>63;

 	/* special cases */
 	if (ix >= 0x7ff00000)
 		/* tgamma(nan)=nan, tgamma(inf)=inf, tgamma(-inf)=nan with invalid */
 		return x + INFINITY;
 	if (ix < (0x3ff-54)<<20)
 		/* |x| < 2^-54: tgamma(x) ~ 1/x, +-0 raises div-by-zero */
 		return 1/x;

 	/* integer arguments */
 	/* raise inexact when non-integer */
 	if (x == floor(x)) {
 		if (sign)
 			return 0/0.0;
 		if (x <= sizeof fact/sizeof *fact)
 			return fact[(int)x - 1];
 	}

 	/* x >= 172: tgamma(x)=inf with overflow */
 	/* x =< -184: tgamma(x)=+-0 with underflow */
 	if (ix >= 0x40670000) { /* |x| >= 184 */
 		if (sign) {
 			FORCE_EVAL((float)(0x1p-126/x));
 			if (floor(x) * 0.5 == floor(x * 0.5))
 				return 0;
 			return -0.0;
 		}
 		x *= 0x1p1023;
 		return x;
 	}

 	absx = sign ? -x : x;

 	/* handle the error of x + g - 0.5 */
 	y = absx + gmhalf;
 	if (absx > gmhalf) {
 		dy = y - absx;
 		dy -= gmhalf;
 	} else {
 		dy = y - gmhalf;
 		dy -= absx;
 	}

 	z = absx - 0.5;
 	r = S(absx) * exp(-y);
 	if (x < 0) {
 		/* reflection formula for negative x */
 		/* sinpi(absx) is not 0, integers are already handled */
 		r = -pi / (sinpi(absx) * absx * r);
 		dy = -dy;
 		z = -z;
 	}
 	r += dy * (gmhalf+0.5) * r / y;
 	z = pow(y, 0.5*z);
 	y = r * z * z;
 	return y;
 }

 #if 0
 double __lgamma_r(double x, int *sign)
 {
 	double r, absx;

 	*sign = 1;

 	/* special cases */
 	if (!isfinite(x))
 		/* lgamma(nan)=nan, lgamma(+-inf)=inf */
 		return x*x;

 	/* integer arguments */
 	if (x == floor(x) && x <= 2) {
 		/* n <= 0: lgamma(n)=inf with divbyzero */
 		/* n == 1,2: lgamma(n)=0 */
 		if (x <= 0)
 			return 1/0.0;
 		return 0;
 	}

 	absx = fabs(x);

 	/* lgamma(x) ~ -log(|x|) for tiny |x| */
 	if (absx < 0x1p-54) {
 		*sign = 1 - 2*!!signbit(x);
 		return -log(absx);
 	}

 	/* use tgamma for smaller |x| */
 	if (absx < 128) {
 		x = tgamma(x);
 		*sign = 1 - 2*!!signbit(x);
 		return log(fabs(x));
 	}

 	/* second term (log(S)-g) could be more precise here.. */
 	/* or with stirling: (|x|-0.5)*(log(|x|)-1) + poly(1/|x|) */
 	r = (absx-0.5)*(log(absx+gmhalf)-1) + (log(S(absx)) - (gmhalf+0.5));
 	if (x < 0) {
 		/* reflection formula for negative x */
 		x = sinpi(absx);
 		*sign = 2*!!signbit(x) - 1;
 		r = log(pi/(fabs(x)*absx)) - r;
 	}
 	return r;
 }

 weak_alias(__lgamma_r, lgamma_r);
 #endif
	/*
	"A Precision Approximation of the Gamma Function" - Cornelius Lanczos (1964)
	"Lanczos Implementation of the Gamma Function" - Paul Godfrey (2001)
	"An Analysis of the Lanczos Gamma Approximation" - Glendon Ralph Pugh (2004)

	approximation method:

	(x - 0.5) S(x)
	Gamma(x) = (x + g - 0.5) * ----------------
	exp(x + g - 0.5)

	with
	a1 a2 a3 aN
	S(x) ~= [ a0 + ----- + ----- + ----- + ... + ----- ]
	x + 1 x + 2 x + 3 x + N

	with a0, a1, a2, a3,.. aN constants which depend on g.

	for x < 0 the following reflection formula is used:

	Gamma(x)*Gamma(-x) = -pi/(x sin(pi x))

	most ideas and constants are from boost and python
	*/
	#include "libm.h"

	static const double pi = 3.141592653589793238462643383279502884;

	/* sin(pi x) with x > 0x1p-100, if sin(pix)==0 the sign is arbitrary /
	static double sinpi(double x)
	{
	int n;

	/* argument reduction: x = \|x\| mod 2 */
	/* spurious inexact when x is odd int */
	x = x * 0.5;
	x = 2 * (x - floor(x));

	/* reduce x into [-.25,.25] */
	n = 4 * x;
	n = (n+1)/2;
	x -= n * 0.5;

	x *= pi;
	switch (n) {
	default: /* case 4 */
	case 0:
	return __sin(x, 0, 0);
	case 1:
	return __cos(x, 0);
	case 2:
	return __sin(-x, 0, 0);
	case 3:
	return -__cos(x, 0);
	}
	}

	#define N 12
	//static const double g = 6.024680040776729583740234375;
	static const double gmhalf = 5.524680040776729583740234375;
	static const double Snum[N+1] = {
	23531376880.410759688572007674451636754734846804940,
	42919803642.649098768957899047001988850926355848959,
	35711959237.355668049440185451547166705960488635843,
	17921034426.037209699919755754458931112671403265390,
	6039542586.3520280050642916443072979210699388420708,
	1439720407.3117216736632230727949123939715485786772,
	248874557.86205415651146038641322942321632125127801,
	31426415.585400194380614231628318205362874684987640,
	2876370.6289353724412254090516208496135991145378768,
	186056.26539522349504029498971604569928220784236328,
	8071.6720023658162106380029022722506138218516325024,
	210.82427775157934587250973392071336271166969580291,
	2.5066282746310002701649081771338373386264310793408,
	};
	static const double Sden[N+1] = {
	0, 39916800, 120543840, 150917976, 105258076, 45995730, 13339535,
	2637558, 357423, 32670, 1925, 66, 1,
	};
	/* n! for small integer n */
	static const double fact[] = {
	1, 1, 2, 6, 24, 120, 720, 5040.0, 40320.0, 362880.0, 3628800.0, 39916800.0,
	479001600.0, 6227020800.0, 87178291200.0, 1307674368000.0, 20922789888000.0,
	355687428096000.0, 6402373705728000.0, 121645100408832000.0,
	2432902008176640000.0, 51090942171709440000.0, 1124000727777607680000.0,
	};

	/* S(x) rational function for positive x */
	static double S(double x)
	{
	double_t num = 0, den = 0;
	int i;

	/* to avoid overflow handle large x differently */
	if (x < 8)
	for (i = N; i >= 0; i--) {
	num = num * x + Snum[i];
	den = den * x + Sden[i];
	}
	else
	for (i = 0; i <= N; i++) {
	num = num / x + Snum[i];
	den = den / x + Sden[i];
	}
	return num/den;
	}

	double tgamma(double x)
	{
	union {double f; uint64_t i;} u = {x};
	double absx, y;
	double_t dy, z, r;
	uint32_t ix = u.i>>32 & 0x7fffffff;
	int sign = u.i>>63;

	/* special cases */
	if (ix >= 0x7ff00000)
	/* tgamma(nan)=nan, tgamma(inf)=inf, tgamma(-inf)=nan with invalid */
	return x + INFINITY;
	if (ix < (0x3ff-54)<<20)
	/* \|x\| < 2^-54: tgamma(x) ~ 1/x, +-0 raises div-by-zero */
	return 1/x;

	/* integer arguments */
	/* raise inexact when non-integer */
	if (x == floor(x)) {
	if (sign)
	return 0/0.0;
	if (x <= sizeof fact/sizeof *fact)
	return fact[(int)x - 1];
	}

	/* x >= 172: tgamma(x)=inf with overflow */
	/* x =< -184: tgamma(x)=+-0 with underflow */
	if (ix >= 0x40670000) { /* \|x\| >= 184 */
	if (sign) {
	FORCE_EVAL((float)(0x1p-126/x));
	if (floor(x) * 0.5 == floor(x * 0.5))
	return 0;
	return -0.0;
	}
	x *= 0x1p1023;
	return x;
	}

	absx = sign ? -x : x;

	/* handle the error of x + g - 0.5 */
	y = absx + gmhalf;
	if (absx > gmhalf) {
	dy = y - absx;
	dy -= gmhalf;
	} else {
	dy = y - gmhalf;
	dy -= absx;
	}

	z = absx - 0.5;
	r = S(absx) * exp(-y);
	if (x < 0) {
	/* reflection formula for negative x */
	/* sinpi(absx) is not 0, integers are already handled */
	r = -pi / (sinpi(absx) * absx * r);
	dy = -dy;
	z = -z;
	}
	r += dy * (gmhalf+0.5) * r / y;
	z = pow(y, 0.5*z);
	y = r * z * z;
	return y;
	}

	#if 0
	double __lgamma_r(double x, int *sign)
	{
	double r, absx;

	*sign = 1;

	/* special cases */
	if (!isfinite(x))
	/* lgamma(nan)=nan, lgamma(+-inf)=inf */
	return x*x;

	/* integer arguments */
	if (x == floor(x) && x <= 2) {
	/* n <= 0: lgamma(n)=inf with divbyzero */
	/* n == 1,2: lgamma(n)=0 */
	if (x <= 0)
	return 1/0.0;
	return 0;
	}

	absx = fabs(x);

	/* lgamma(x) ~ -log(\|x\|) for tiny \|x\| */
	if (absx < 0x1p-54) {
	sign = 1 - 2!!signbit(x);
	return -log(absx);
	}

	/* use tgamma for smaller \|x\| */
	if (absx < 128) {
	x = tgamma(x);
	sign = 1 - 2!!signbit(x);
	return log(fabs(x));
	}

	/* second term (log(S)-g) could be more precise here.. */
	/* or with stirling: (\|x\|-0.5)(log(\|x\|)-1) + poly(1/\|x\|) /
	r = (absx-0.5)*(log(absx+gmhalf)-1) + (log(S(absx)) - (gmhalf+0.5));
	if (x < 0) {
	/* reflection formula for negative x */
	x = sinpi(absx);
	sign = 2!!signbit(x) - 1;
	r = log(pi/(fabs(x)*absx)) - r;
	}
	return r;
	}

	weak_alias(__lgamma_r, lgamma_r);
	#endif