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/* rgammaf.c
*
* Reciprocal gamma function
*
*
*
* SYNOPSIS:
*
* float x, y, rgammaf();
*
* y = rgammaf( x );
*
*
*
* DESCRIPTION:
*
* Returns one divided by the gamma function of the argument.
*
* The function is approximated by a Chebyshev expansion in
* the interval [0,1]. Range reduction is by recurrence
* for arguments between -34.034 and +34.84425627277176174.
* 1/MAXNUMF is returned for positive arguments outside this
* range.
*
* The reciprocal gamma function has no singularities,
* but overflow and underflow may occur for large arguments.
* These conditions return either MAXNUMF or 1/MAXNUMF with
* appropriate sign.
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE -34,+34 100000 8.9e-7 1.1e-7
*/
�
/*
Cephes Math Library Release 2.2: June, 1992
Copyright 1985, 1987, 1992 by Stephen L. Moshier
Direct inquiries to 30 Frost Street, Cambridge, MA 02140
*/
#include <math.h>
/* Chebyshev coefficients for reciprocal gamma function
* in interval 0 to 1. Function is 1/(x gamma(x)) - 1
*/
static float R[] = {
1.08965386454418662084E-9,
-3.33964630686836942556E-8,
2.68975996440595483619E-7,
2.96001177518801696639E-6,
-8.04814124978471142852E-5,
4.16609138709688864714E-4,
5.06579864028608725080E-3,
-6.41925436109158228810E-2,
-4.98558728684003594785E-3,
1.27546015610523951063E-1
};
static char name[] = "rgammaf";
extern float PIF, MAXLOGF, MAXNUMF;
float chbevlf(float, float *, int);
float expf(float), logf(float), sinf(float), lgamf(float);
float rgammaf(float xx)
{
float x, w, y, z;
int sign;
x = xx;
if( x > 34.84425627277176174)
{
mtherr( name, UNDERFLOW );
return(1.0/MAXNUMF);
}
if( x < -34.034 )
{
w = -x;
z = sinf( PIF*w );
if( z == 0.0 )
return(0.0);
if( z < 0.0 )
{
sign = 1;
z = -z;
}
else
sign = -1;
y = logf( w * z / PIF ) + lgamf(w);
if( y < -MAXLOGF )
{
mtherr( name, UNDERFLOW );
return( sign * 1.0 / MAXNUMF );
}
if( y > MAXLOGF )
{
mtherr( name, OVERFLOW );
return( sign * MAXNUMF );
}
return( sign * expf(y));
}
z = 1.0;
w = x;
while( w > 1.0 ) /* Downward recurrence */
{
w -= 1.0;
z *= w;
}
while( w < 0.0 ) /* Upward recurrence */
{
z /= w;
w += 1.0;
}
if( w == 0.0 ) /* Nonpositive integer */
return(0.0);
if( w == 1.0 ) /* Other integer */
return( 1.0/z );
y = w * ( 1.0 + chbevlf( 4.0*w-2.0, R, 10 ) ) / z;
return(y);
}
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