ref: a3cbab3dc2fd16ddbed40ecbe1d884e0bb4988f7
dir: /sys/src/ape/lib/ap/math/gamma.c/
#include <math.h> #include <errno.h> /* C program for floating point log gamma function gamma(x) computes the log of the absolute value of the gamma function. The sign of the gamma function is returned in the external quantity signgam. The coefficients for expansion around zero are #5243 from Hart & Cheney; for expansion around infinity they are #5404. Calls log and sin. */ int signgam; static double goobie = 0.9189385332046727417803297; static double pi = 3.1415926535897932384626434; #define M 6 #define N 8 static double p1[] = { 0.83333333333333101837e-1, -.277777777735865004e-2, 0.793650576493454e-3, -.5951896861197e-3, 0.83645878922e-3, -.1633436431e-2, }; static double p2[] = { -.42353689509744089647e5, -.20886861789269887364e5, -.87627102978521489560e4, -.20085274013072791214e4, -.43933044406002567613e3, -.50108693752970953015e2, -.67449507245925289918e1, 0.0, }; static double q2[] = { -.42353689509744090010e5, -.29803853309256649932e4, 0.99403074150827709015e4, -.15286072737795220248e4, -.49902852662143904834e3, 0.18949823415702801641e3, -.23081551524580124562e2, 0.10000000000000000000e1, }; static double asym(double arg) { double n, argsq; int i; argsq = 1 / (arg*arg); n = 0; for(i=M-1; i>=0; i--) n = n*argsq + p1[i]; return (arg-.5)*log(arg) - arg + goobie + n/arg; } static double pos(double arg) { double n, d, s; int i; if(arg < 2) return pos(arg+1)/arg; if(arg > 3) return (arg-1)*pos(arg-1); s = arg - 2; n = 0; d = 0; for(i=N-1; i>=0; i--){ n = n*s + p2[i]; d = d*s + q2[i]; } return n/d; } static double neg(double arg) { double temp; arg = -arg; temp = sin(pi*arg); if(temp == 0) { errno = EDOM; return HUGE_VAL; } if(temp < 0) temp = -temp; else signgam = -1; return -log(arg*pos(arg)*temp/pi); } double gamma(double arg) { signgam = 1; if(arg <= 0) return neg(arg); if(arg > 8) return asym(arg); return log(pos(arg)); }