/* * Mathlib : A C Library of Special Functions * Copyright (C) 1998 Ross Ihaka * Copyright (C) 2000--2015 The R Core Team * Copyright (C) 2004--2015 The R Foundation * based on AS 91 (C) 1979 Royal Statistical Society * * 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 2 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, a copy is available at * https://www.R-project.org/Licenses/ * * DESCRIPTION * * Compute the quantile function of the gamma distribution. * * NOTES * * This function is based on the Applied Statistics * Algorithm AS 91 ("ppchi2") and via pgamma(.) AS 239. * * R core improvements: * o lower_tail, log_p * o non-trivial result for p outside [0.000002, 0.999998] * o p ~ 1 no longer gives +Inf; final Newton step(s) * * REFERENCES * * Best, D. J. and D. E. Roberts (1975). * Percentage Points of the Chi-Squared Distribution. * Applied Statistics 24, page 385. */ #include "nmath.h" #include "dpq.h" #ifdef DEBUG_qgamma # define DEBUG_q #endif attribute_hidden double qchisq_appr(double p, double nu, double g /* = log Gamma(nu/2) */, int lower_tail, int log_p, double tol /* EPS1 */) { #define C7 4.67 #define C8 6.66 #define C9 6.73 #define C10 13.32 double alpha, a, c, ch, p1; double p2, q, t, x; /* test arguments and initialise */ #ifdef IEEE_754 if (ISNAN(p) || ISNAN(nu)) return p + nu; #endif R_Q_P01_check(p); if (nu <= 0) ML_WARN_return_NAN; alpha = 0.5 * nu;/* = [pq]gamma() shape */ c = alpha-1; if(nu < (-1.24)*(p1 = R_DT_log(p))) { /* for small chi-squared */ /* log(alpha) + g = log(alpha) + log(gamma(alpha)) = * = log(alpha*gamma(alpha)) = lgamma(alpha+1) suffers from * catastrophic cancellation when alpha << 1 */ double lgam1pa = (alpha < 0.5) ? lgamma1p(alpha) : (log(alpha) + g); ch = exp((lgam1pa + p1)/alpha + M_LN2); #ifdef DEBUG_qgamma REprintf(" small chi-sq., ch0 = %g\n", ch); #endif } else if(nu > 0.32) { /* using Wilson and Hilferty estimate */ x = qnorm(p, 0, 1, lower_tail, log_p); p1 = 2./(9*nu); ch = nu*pow(x*sqrt(p1) + 1-p1, 3); #ifdef DEBUG_qgamma REprintf(" nu > .32: Wilson-Hilferty; x = %7g\n", x); #endif /* approximation for p tending to 1: */ if( ch > 2.2*nu + 6 ) ch = -2*(R_DT_Clog(p) - c*log(0.5*ch) + g); } else { /* "small nu" : 1.24*(-log(p)) <= nu <= 0.32 */ ch = 0.4; a = R_DT_Clog(p) + g + c*M_LN2; #ifdef DEBUG_qgamma REprintf(" nu <= .32: a = %7g\n", a); #endif do { q = ch; p1 = 1. / (1+ch*(C7+ch)); p2 = ch*(C9+ch*(C8+ch)); t = -0.5 +(C7+2*ch)*p1 - (C9+ch*(C10+3*ch))/p2; ch -= (1- exp(a+0.5*ch)*p2*p1)/t; } while(fabs(q - ch) > tol * fabs(ch)); } return ch; } double qgamma(double p, double alpha, double scale, int lower_tail, int log_p) /* shape = alpha */ { #define EPS1 1e-2 #define EPS2 5e-7/* final precision of AS 91 */ #define EPS_N 1e-15/* precision of Newton step / iterations */ #define LN_EPS -36.043653389117156 /* = log(.Machine$double.eps) iff IEEE_754 */ #define MAXIT 1000/* was 20 */ #define pMIN 1e-100 /* was 0.000002 = 2e-6 */ #define pMAX (1-1e-14)/* was (1-1e-12) and 0.999998 = 1 - 2e-6 */ const static double i420 = 1./ 420., i2520 = 1./ 2520., i5040 = 1./ 5040; double p_, a, b, c, g, ch, ch0, p1; double p2, q, s1, s2, s3, s4, s5, s6, t, x; int i, max_it_Newton = 1; /* test arguments and initialise */ #ifdef IEEE_754 if (ISNAN(p) || ISNAN(alpha) || ISNAN(scale)) return p + alpha + scale; #endif R_Q_P01_boundaries(p, 0., ML_POSINF); if (alpha < 0 || scale <= 0) ML_WARN_return_NAN; if (alpha == 0) /* all mass at 0 : */ return 0.; if (alpha < 1e-10) { /* Warning seems unnecessary now: */ #ifdef _DO_WARN_qgamma_ MATHLIB_WARNING(_("value of shape (%g) is extremely small: results may be unreliable"), alpha); #endif max_it_Newton = 7;/* may still be increased below */ } p_ = R_DT_qIv(p);/* lower_tail prob (in any case) */ #ifdef DEBUG_qgamma REprintf("qgamma(p=%7g, alpha=%7g, scale=%7g, l.t.=%2d, log_p=%2d): ", p,alpha,scale, lower_tail, log_p); #endif g = lgammafn(alpha);/* log Gamma(v/2) */ /*----- Phase I : Starting Approximation */ ch = qchisq_appr(p, /* nu= 'df' = */ 2*alpha, /* lgamma(nu/2)= */ g, lower_tail, log_p, /* tol= */ EPS1); if(!R_FINITE(ch)) { /* forget about all iterations! */ max_it_Newton = 0; goto END; } if(ch < EPS2) {/* Corrected according to AS 91; MM, May 25, 1999 */ max_it_Newton = 20; goto END;/* and do Newton steps */ } /* FIXME: This (cutoff to {0, +Inf}) is far from optimal * ----- when log_p or !lower_tail, but NOT doing it can be even worse */ if(p_ > pMAX || p_ < pMIN) { /* did return ML_POSINF or 0.; much better: */ max_it_Newton = 20; goto END;/* and do Newton steps */ } #ifdef DEBUG_qgamma REprintf("\t==> ch = %10g:", ch); #endif /*----- Phase II: Iteration * Call pgamma() [AS 239] and calculate seven term taylor series */ c = alpha-1; s6 = (120+c*(346+127*c)) * i5040; /* used below, is "const" */ ch0 = ch;/* save initial approx. */ for(i=1; i <= MAXIT; i++ ) { q = ch; p1 = 0.5*ch; p2 = p_ - pgamma_raw(p1, alpha, /*lower_tail*/TRUE, /*log_p*/FALSE); #ifdef DEBUG_qgamma if(i == 1) REprintf(" Ph.II iter; ch=%g, p2=%g\n", ch, p2); if(i >= 2) REprintf(" it=%d, ch=%g, p2=%g\n", i, ch, p2); #endif #ifdef IEEE_754 if(!R_FINITE(p2) || ch <= 0) #else if(errno != 0 || ch <= 0) #endif { ch = ch0; max_it_Newton = 27; goto END; }/*was return ML_NAN;*/ t = p2*exp(alpha*M_LN2+g+p1-c*log(ch)); b = t/ch; a = 0.5*t - b*c; s1 = (210+ a*(140+a*(105+a*(84+a*(70+60*a))))) * i420; s2 = (420+ a*(735+a*(966+a*(1141+1278*a)))) * i2520; s3 = (210+ a*(462+a*(707+932*a))) * i2520; s4 = (252+ a*(672+1182*a) + c*(294+a*(889+1740*a))) * i5040; s5 = (84+2264*a + c*(1175+606*a)) * i2520; ch += t*(1+0.5*t*s1-b*c*(s1-b*(s2-b*(s3-b*(s4-b*(s5-b*s6)))))); if(fabs(q - ch) < EPS2*ch) goto END; if(fabs(q - ch) > 0.1*ch) {/* diverging? -- also forces ch > 0 */ if(ch < q) ch = 0.9 * q; else ch = 1.1 * q; } } /* no convergence in MAXIT iterations -- but we add Newton now... */ #ifdef DEBUG_q MATHLIB_WARNING3("qgamma(%g) not converged in %d iterations; rel.ch=%g\n", p, MAXIT, ch/fabs(q - ch)); #endif /* was * ML_WARNING(ME_PRECISION, "qgamma"); * does nothing in R !*/ END: /* PR# 2214 : From: Morten Welinder , Fri, 25 Oct 2002 16:50 -------- To: R-bugs@biostat.ku.dk Subject: qgamma precision * With a final Newton step, double accuracy, e.g. for (p= 7e-4; nu= 0.9) * * Improved (MM): - only if rel.Err > EPS_N (= 1e-15); * - also for lower_tail = FALSE or log_p = TRUE * - optionally *iterate* Newton */ x = 0.5*scale*ch; if(max_it_Newton) { /* always use log scale */ if (!log_p) { p = log(p); log_p = TRUE; } if(x == 0) { const double _1_p = 1. + 1e-7; const double _1_m = 1. - 1e-7; x = DBL_MIN; p_ = pgamma(x, alpha, scale, lower_tail, log_p); if(( lower_tail && p_ > p * _1_p) || (!lower_tail && p_ < p * _1_m)) return(0.); /* else: continue, using x = DBL_MIN instead of 0 */ } else p_ = pgamma(x, alpha, scale, lower_tail, log_p); if(p_ == ML_NEGINF) return 0; /* PR#14710 */ for(i = 1; i <= max_it_Newton; i++) { p1 = p_ - p; #ifdef DEBUG_qgamma if(i == 1) REprintf("\n it=%d: p=%g, x = %g, p.=%g; p1=d{p}=%g\n", i, p, x, p_, p1); if(i >= 2) REprintf(" x{it= %d} = %g, p.=%g, p1=d{p}=%g\n", i, x, p_, p1); #endif if(fabs(p1) < fabs(EPS_N * p)) break; /* else */ if((g = dgamma(x, alpha, scale, log_p)) == R_D__0) { #ifdef DEBUG_q if(i == 1) REprintf("no final Newton step because dgamma(*)== 0!\n"); #endif break; } /* else : * delta x = f(x)/f'(x); * if(log_p) f(x) := log P(x) - p; f'(x) = d/dx log P(x) = P' / P * ==> f(x)/f'(x) = f*P / P' = f*exp(p_) / P' (since p_ = log P(x)) */ t = log_p ? p1*exp(p_ - g) : p1/g ;/* = "delta x" */ t = lower_tail ? x - t : x + t; p_ = pgamma (t, alpha, scale, lower_tail, log_p); if (fabs(p_ - p) > fabs(p1) || (i > 1 && fabs(p_ - p) == fabs(p1)) /* <- against flip-flop */) { /* no improvement */ #ifdef DEBUG_qgamma if(i == 1 && max_it_Newton > 1) REprintf("no Newton step done since delta{p} >= last delta\n"); #endif break; } /* else : */ #ifdef Harmful_notably_if_max_it_Newton_is_1 /* control step length: this could have started at the initial approximation */ if(t > 1.1*x) t = 1.1*x; else if(t < 0.9*x) t = 0.9*x; #endif x = t; } } return x; }