src/parsec/disk-image/parsec/parsec-benchmark/pkgs/libs/gsl/src/specfunc/erfc.c - public/gem5-resources - Git at Google

 /* specfunc/erfc.c
  *
  * Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003 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 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, write to the Free Software
  * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
  */

 /* Author:  J. Theiler (modifications by G. Jungman) */

 /*
  * See Hart et al, Computer Approximations, John Wiley and Sons, New York (1968)
  * (This applies only to the erfc8 stuff, which is the part
  *  of the original code that survives. I have replaced much of
  *  the other stuff with Chebyshev fits. These are simpler and
  *  more precise than the original approximations. [GJ])
  */
 #include <config.h>
 #include <gsl/gsl_math.h>
 #include <gsl/gsl_errno.h>
 #include <gsl/gsl_sf_exp.h>
 #include <gsl/gsl_sf_erf.h>

 #include "check.h"

 #include "chebyshev.h"
 #include "cheb_eval.c"

 #define LogRootPi_  0.57236494292470008706


 static double erfc8_sum(double x)
 {
   /* estimates erfc(x) valid for 8 < x < 100 */
   /* This is based on index 5725 in Hart et al */

   static double P[] = {
       2.97886562639399288862,
       7.409740605964741794425,
       6.1602098531096305440906,
       5.019049726784267463450058,
       1.275366644729965952479585264,
       0.5641895835477550741253201704
   };
   static double Q[] = {
       3.3690752069827527677,
       9.608965327192787870698,
       17.08144074746600431571095,
       12.0489519278551290360340491,
       9.396034016235054150430579648,
       2.260528520767326969591866945,
       1.0
   };
   double num=0.0, den=0.0;
   int i;

   num = P[5];
   for (i=4; i>=0; --i) {
       num = x*num + P[i];
   }
   den = Q[6];
   for (i=5; i>=0; --i) {
       den = x*den + Q[i];
   }

   return num/den;
 }

 inline
 static double erfc8(double x)
 {
   double e;
   e = erfc8_sum(x);
   e *= exp(-x*x);
   return e;
 }

 inline
 static double log_erfc8(double x)
 {
   double e;
   e = erfc8_sum(x);
   e = log(e) - x*x;
   return e;
 }

 #if 0
 /* Abramowitz+Stegun, 7.2.14 */
 static double erfcasympsum(double x)
 {
   int i;
   double e = 1.;
   double coef = 1.;
   for (i=1; i<5; ++i) {
     /* coef *= -(2*i-1)/(2*x*x); ??? [GJ] */
     coef *= -(2*i+1)/(i*(4*x*x*x*x));
     e += coef;
     /*
     if (fabs(coef) < 1.0e-15) break;
     if (fabs(coef) > 1.0e10) break;

     [GJ]: These tests are not useful. This function is only
     used below. Took them out; they gum up the pipeline.
     */
   }
   return e;
 }
 #endif /* 0 */


 /* Abramowitz+Stegun, 7.1.5 */
 static int erfseries(double x, gsl_sf_result * result)
 {
   double coef = x;
   double e    = coef;
   double del;
   int k;
   for (k=1; k<30; ++k) {
     coef *= -x*x/k;
     del   = coef/(2.0*k+1.0);
     e += del;
   }
   result->val = 2.0 / M_SQRTPI * e;
   result->err = 2.0 / M_SQRTPI * (fabs(del) + GSL_DBL_EPSILON);
   return GSL_SUCCESS;
 }


 /* Chebyshev fit for erfc((t+1)/2), -1 < t < 1
  */
 static double erfc_xlt1_data[20] = {
   1.06073416421769980345174155056,
  -0.42582445804381043569204735291,
   0.04955262679620434040357683080,
   0.00449293488768382749558001242,
  -0.00129194104658496953494224761,
  -0.00001836389292149396270416979,
   0.00002211114704099526291538556,
  -5.23337485234257134673693179020e-7,
  -2.78184788833537885382530989578e-7,
   1.41158092748813114560316684249e-8,
   2.72571296330561699984539141865e-9,
  -2.06343904872070629406401492476e-10,
  -2.14273991996785367924201401812e-11,
   2.22990255539358204580285098119e-12,
   1.36250074650698280575807934155e-13,
  -1.95144010922293091898995913038e-14,
  -6.85627169231704599442806370690e-16,
   1.44506492869699938239521607493e-16,
   2.45935306460536488037576200030e-18,
  -9.29599561220523396007359328540e-19
 };
 static cheb_series erfc_xlt1_cs = {
   erfc_xlt1_data,
   19,
   -1, 1,
   12
 };

 /* Chebyshev fit for erfc(x) exp(x^2), 1 < x < 5, x = 2t + 3, -1 < t < 1
  */
 static double erfc_x15_data[25] = {
   0.44045832024338111077637466616,
  -0.143958836762168335790826895326,
   0.044786499817939267247056666937,
  -0.013343124200271211203618353102,
   0.003824682739750469767692372556,
  -0.001058699227195126547306482530,
   0.000283859419210073742736310108,
  -0.000073906170662206760483959432,
   0.000018725312521489179015872934,
  -4.62530981164919445131297264430e-6,
   1.11558657244432857487884006422e-6,
  -2.63098662650834130067808832725e-7,
   6.07462122724551777372119408710e-8,
  -1.37460865539865444777251011793e-8,
   3.05157051905475145520096717210e-9,
  -6.65174789720310713757307724790e-10,
   1.42483346273207784489792999706e-10,
  -3.00141127395323902092018744545e-11,
   6.22171792645348091472914001250e-12,
  -1.26994639225668496876152836555e-12,
   2.55385883033257575402681845385e-13,
  -5.06258237507038698392265499770e-14,
   9.89705409478327321641264227110e-15,
  -1.90685978789192181051961024995e-15,
   3.50826648032737849245113757340e-16
 };
 static cheb_series erfc_x15_cs = {
   erfc_x15_data,
   24,
   -1, 1,
   16
 };

 /* Chebyshev fit for erfc(x) x exp(x^2), 5 < x < 10, x = (5t + 15)/2, -1 < t < 1
  */
 static double erfc_x510_data[20] = {
   1.11684990123545698684297865808,
   0.003736240359381998520654927536,
  -0.000916623948045470238763619870,
   0.000199094325044940833965078819,
  -0.000040276384918650072591781859,
   7.76515264697061049477127605790e-6,
  -1.44464794206689070402099225301e-6,
   2.61311930343463958393485241947e-7,
  -4.61833026634844152345304095560e-8,
   8.00253111512943601598732144340e-9,
  -1.36291114862793031395712122089e-9,
   2.28570483090160869607683087722e-10,
  -3.78022521563251805044056974560e-11,
   6.17253683874528285729910462130e-12,
  -9.96019290955316888445830597430e-13,
   1.58953143706980770269506726000e-13,
  -2.51045971047162509999527428316e-14,
   3.92607828989125810013581287560e-15,
  -6.07970619384160374392535453420e-16,
   9.12600607264794717315507477670e-17
 };
 static cheb_series erfc_x510_cs = {
   erfc_x510_data,
   19,
   -1, 1,
   12
 };

 #if 0
 inline
 static double
 erfc_asymptotic(double x)
 {
   return exp(-x*x)/x * erfcasympsum(x) / M_SQRTPI;
 }
 inline
 static double
 log_erfc_asymptotic(double x)
 {
   return log(erfcasympsum(x)/x) - x*x - LogRootPi_;
 }
 #endif /* 0 */


 /*-*-*-*-*-*-*-*-*-*-*-* Functions with Error Codes *-*-*-*-*-*-*-*-*-*-*-*/

 int gsl_sf_erfc_e(double x, gsl_sf_result * result)
 {
   const double ax = fabs(x);
   double e_val, e_err;

   /* CHECK_POINTER(result) */

   if(ax <= 1.0) {
     double t = 2.0*ax - 1.0;
     gsl_sf_result c;
     cheb_eval_e(&erfc_xlt1_cs, t, &c);
     e_val = c.val;
     e_err = c.err;
   }
   else if(ax <= 5.0) {
     double ex2 = exp(-x*x);
     double t = 0.5*(ax-3.0);
     gsl_sf_result c;
     cheb_eval_e(&erfc_x15_cs, t, &c);
     e_val = ex2 * c.val;
     e_err = ex2 * (c.err + 2.0*fabs(x)*GSL_DBL_EPSILON);
   }
   else if(ax < 10.0) {
     double exterm = exp(-x*x) / ax;
     double t = (2.0*ax - 15.0)/5.0;
     gsl_sf_result c;
     cheb_eval_e(&erfc_x510_cs, t, &c);
     e_val = exterm * c.val;
     e_err = exterm * (c.err + 2.0*fabs(x)*GSL_DBL_EPSILON + GSL_DBL_EPSILON);
   }
   else {
     e_val = erfc8(ax);
     e_err = (x*x + 1.0) * GSL_DBL_EPSILON * fabs(e_val);
   }

   if(x < 0.0) {
     result->val  = 2.0 - e_val;
     result->err  = e_err;
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
   }
   else {
     result->val  = e_val;
     result->err  = e_err;
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
   }

   return GSL_SUCCESS;
 }


 int gsl_sf_log_erfc_e(double x, gsl_sf_result * result)
 {
   /* CHECK_POINTER(result) */

   if(x*x < 10.0*GSL_ROOT6_DBL_EPSILON) {
     const double y = x / M_SQRTPI;
     /* series for -1/2 Log[Erfc[Sqrt[Pi] y]] */
     const double c3 = (4.0 - M_PI)/3.0;
     const double c4 = 2.0*(1.0 - M_PI/3.0);
     const double c5 = -0.001829764677455021;  /* (96.0 - 40.0*M_PI + 3.0*M_PI*M_PI)/30.0  */
     const double c6 =  0.02629651521057465;   /* 2.0*(120.0 - 60.0*M_PI + 7.0*M_PI*M_PI)/45.0 */
     const double c7 = -0.01621575378835404;
     const double c8 =  0.00125993961762116;
     const double c9 =  0.00556964649138;
     const double c10 = -0.0045563339802;
     const double c11 =  0.0009461589032;
     const double c12 =  0.0013200243174;
     const double c13 = -0.00142906;
     const double c14 =  0.00048204;
     double series = c8 + y*(c9 + y*(c10 + y*(c11 + y*(c12 + y*(c13 + c14*y)))));
     series = y*(1.0 + y*(1.0 + y*(c3 + y*(c4 + y*(c5 + y*(c6 + y*(c7 + y*series)))))));
     result->val = -2.0 * series;
     result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
   /*
   don't like use of log1p(); added above series stuff for small x instead, should be ok [GJ]
   else if (fabs(x) < 1.0) {
     gsl_sf_result result_erf;
     gsl_sf_erf_e(x, &result_erf);
     result->val  = log1p(-result_erf.val);
     result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
   */
   else if(x > 8.0) {
     result->val = log_erfc8(x);
     result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
   else {
     gsl_sf_result result_erfc;
     gsl_sf_erfc_e(x, &result_erfc);
     result->val  = log(result_erfc.val);
     result->err  = fabs(result_erfc.err / result_erfc.val);
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
 }


 int gsl_sf_erf_e(double x, gsl_sf_result * result)
 {
   /* CHECK_POINTER(result) */

   if(fabs(x) < 1.0) {
     return erfseries(x, result);
   }
   else {
     gsl_sf_result result_erfc;
     gsl_sf_erfc_e(x, &result_erfc);
     result->val  = 1.0 - result_erfc.val;
     result->err  = result_erfc.err;
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
 }


 int gsl_sf_erf_Z_e(double x, gsl_sf_result * result)
 {
   /* CHECK_POINTER(result) */

   {
     const double ex2 = exp(-x*x/2.0);
     result->val  = ex2 / (M_SQRT2 * M_SQRTPI);
     result->err  = fabs(x * result->val) * GSL_DBL_EPSILON;
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     CHECK_UNDERFLOW(result);
     return GSL_SUCCESS;
   }
 }


 int gsl_sf_erf_Q_e(double x, gsl_sf_result * result)
 {
   /* CHECK_POINTER(result) */

   {
     gsl_sf_result result_erfc;
     int stat = gsl_sf_erfc_e(x/M_SQRT2, &result_erfc);
     result->val  = 0.5 * result_erfc.val;
     result->err  = 0.5 * result_erfc.err;
     result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return stat;
   }
 }


 int gsl_sf_hazard_e(double x, gsl_sf_result * result)
 {
   if(x < 25.0)
   {
     gsl_sf_result result_ln_erfc;
     const int stat_l = gsl_sf_log_erfc_e(x/M_SQRT2, &result_ln_erfc);
     const double lnc = -0.22579135264472743236; /* ln(sqrt(2/pi)) */
     const double arg = lnc - 0.5*x*x - result_ln_erfc.val;
     const int stat_e = gsl_sf_exp_e(arg, result);
     result->err += 3.0 * (1.0 + fabs(x)) * GSL_DBL_EPSILON * fabs(result->val);
     result->err += fabs(result_ln_erfc.err * result->val);
     return GSL_ERROR_SELECT_2(stat_l, stat_e);
   }
   else
   {
     const double ix2 = 1.0/(x*x);
     const double corrB = 1.0 - 9.0*ix2 * (1.0 - 11.0*ix2);
     const double corrM = 1.0 - 5.0*ix2 * (1.0 - 7.0*ix2 * corrB);
     const double corrT = 1.0 - ix2 * (1.0 - 3.0*ix2*corrM);
     result->val = x / corrT;
     result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
     return GSL_SUCCESS;
   }
 }


 /*-*-*-*-*-*-*-*-*-* Functions w/ Natural Prototypes *-*-*-*-*-*-*-*-*-*-*/

 #include "eval.h"

 double gsl_sf_erfc(double x)
 {
   EVAL_RESULT(gsl_sf_erfc_e(x, &result));
 }

 double gsl_sf_log_erfc(double x)
 {
   EVAL_RESULT(gsl_sf_log_erfc_e(x, &result));
 }

 double gsl_sf_erf(double x)
 {
   EVAL_RESULT(gsl_sf_erf_e(x, &result));
 }

 double gsl_sf_erf_Z(double x)
 {
   EVAL_RESULT(gsl_sf_erf_Z_e(x, &result));
 }

 double gsl_sf_erf_Q(double x)
 {
   EVAL_RESULT(gsl_sf_erf_Q_e(x, &result));
 }

 double gsl_sf_hazard(double x)
 {
   EVAL_RESULT(gsl_sf_hazard_e(x, &result));
 }
	/* specfunc/erfc.c
	*
	* Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003 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 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, write to the Free Software
	* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
	*/

	/* Author: J. Theiler (modifications by G. Jungman) */

	/*
	* See Hart et al, Computer Approximations, John Wiley and Sons, New York (1968)
	* (This applies only to the erfc8 stuff, which is the part
	* of the original code that survives. I have replaced much of
	* the other stuff with Chebyshev fits. These are simpler and
	* more precise than the original approximations. [GJ])
	*/
	#include <config.h>
	#include <gsl/gsl_math.h>
	#include <gsl/gsl_errno.h>
	#include <gsl/gsl_sf_exp.h>
	#include <gsl/gsl_sf_erf.h>

	#include "check.h"

	#include "chebyshev.h"
	#include "cheb_eval.c"

	#define LogRootPi_ 0.57236494292470008706


	static double erfc8_sum(double x)
	{
	/* estimates erfc(x) valid for 8 < x < 100 */
	/* This is based on index 5725 in Hart et al */

	static double P[] = {
	2.97886562639399288862,
	7.409740605964741794425,
	6.1602098531096305440906,
	5.019049726784267463450058,
	1.275366644729965952479585264,
	0.5641895835477550741253201704
	};
	static double Q[] = {
	3.3690752069827527677,
	9.608965327192787870698,
	17.08144074746600431571095,
	12.0489519278551290360340491,
	9.396034016235054150430579648,
	2.260528520767326969591866945,
	1.0
	};
	double num=0.0, den=0.0;
	int i;

	num = P[5];
	for (i=4; i>=0; --i) {
	num = x*num + P[i];
	}
	den = Q[6];
	for (i=5; i>=0; --i) {
	den = x*den + Q[i];
	}

	return num/den;
	}

	inline
	static double erfc8(double x)
	{
	double e;
	e = erfc8_sum(x);
	e = exp(-xx);
	return e;
	}

	inline
	static double log_erfc8(double x)
	{
	double e;
	e = erfc8_sum(x);
	e = log(e) - x*x;
	return e;
	}

	#if 0
	/* Abramowitz+Stegun, 7.2.14 */
	static double erfcasympsum(double x)
	{
	int i;
	double e = 1.;
	double coef = 1.;
	for (i=1; i<5; ++i) {
	/* coef = -(2i-1)/(2xx); ??? [GJ] */
	coef = -(2i+1)/(i(4xxx*x));
	e += coef;
	/*
	if (fabs(coef) < 1.0e-15) break;
	if (fabs(coef) > 1.0e10) break;

	[GJ]: These tests are not useful. This function is only
	used below. Took them out; they gum up the pipeline.
	*/
	}
	return e;
	}
	#endif /* 0 */


	/* Abramowitz+Stegun, 7.1.5 */
	static int erfseries(double x, gsl_sf_result * result)
	{
	double coef = x;
	double e = coef;
	double del;
	int k;
	for (k=1; k<30; ++k) {
	coef = -xx/k;
	del = coef/(2.0*k+1.0);
	e += del;
	}
	result->val = 2.0 / M_SQRTPI * e;
	result->err = 2.0 / M_SQRTPI * (fabs(del) + GSL_DBL_EPSILON);
	return GSL_SUCCESS;
	}


	/* Chebyshev fit for erfc((t+1)/2), -1 < t < 1
	*/
	static double erfc_xlt1_data[20] = {
	1.06073416421769980345174155056,
	-0.42582445804381043569204735291,
	0.04955262679620434040357683080,
	0.00449293488768382749558001242,
	-0.00129194104658496953494224761,
	-0.00001836389292149396270416979,
	0.00002211114704099526291538556,
	-5.23337485234257134673693179020e-7,
	-2.78184788833537885382530989578e-7,
	1.41158092748813114560316684249e-8,
	2.72571296330561699984539141865e-9,
	-2.06343904872070629406401492476e-10,
	-2.14273991996785367924201401812e-11,
	2.22990255539358204580285098119e-12,
	1.36250074650698280575807934155e-13,
	-1.95144010922293091898995913038e-14,
	-6.85627169231704599442806370690e-16,
	1.44506492869699938239521607493e-16,
	2.45935306460536488037576200030e-18,
	-9.29599561220523396007359328540e-19
	};
	static cheb_series erfc_xlt1_cs = {
	erfc_xlt1_data,
	19,
	-1, 1,
	12
	};

	/* Chebyshev fit for erfc(x) exp(x^2), 1 < x < 5, x = 2t + 3, -1 < t < 1
	*/
	static double erfc_x15_data[25] = {
	0.44045832024338111077637466616,
	-0.143958836762168335790826895326,
	0.044786499817939267247056666937,
	-0.013343124200271211203618353102,
	0.003824682739750469767692372556,
	-0.001058699227195126547306482530,
	0.000283859419210073742736310108,
	-0.000073906170662206760483959432,
	0.000018725312521489179015872934,
	-4.62530981164919445131297264430e-6,
	1.11558657244432857487884006422e-6,
	-2.63098662650834130067808832725e-7,
	6.07462122724551777372119408710e-8,
	-1.37460865539865444777251011793e-8,
	3.05157051905475145520096717210e-9,
	-6.65174789720310713757307724790e-10,
	1.42483346273207784489792999706e-10,
	-3.00141127395323902092018744545e-11,
	6.22171792645348091472914001250e-12,
	-1.26994639225668496876152836555e-12,
	2.55385883033257575402681845385e-13,
	-5.06258237507038698392265499770e-14,
	9.89705409478327321641264227110e-15,
	-1.90685978789192181051961024995e-15,
	3.50826648032737849245113757340e-16
	};
	static cheb_series erfc_x15_cs = {
	erfc_x15_data,
	24,
	-1, 1,
	16
	};

	/* Chebyshev fit for erfc(x) x exp(x^2), 5 < x < 10, x = (5t + 15)/2, -1 < t < 1
	*/
	static double erfc_x510_data[20] = {
	1.11684990123545698684297865808,
	0.003736240359381998520654927536,
	-0.000916623948045470238763619870,
	0.000199094325044940833965078819,
	-0.000040276384918650072591781859,
	7.76515264697061049477127605790e-6,
	-1.44464794206689070402099225301e-6,
	2.61311930343463958393485241947e-7,
	-4.61833026634844152345304095560e-8,
	8.00253111512943601598732144340e-9,
	-1.36291114862793031395712122089e-9,
	2.28570483090160869607683087722e-10,
	-3.78022521563251805044056974560e-11,
	6.17253683874528285729910462130e-12,
	-9.96019290955316888445830597430e-13,
	1.58953143706980770269506726000e-13,
	-2.51045971047162509999527428316e-14,
	3.92607828989125810013581287560e-15,
	-6.07970619384160374392535453420e-16,
	9.12600607264794717315507477670e-17
	};
	static cheb_series erfc_x510_cs = {
	erfc_x510_data,
	19,
	-1, 1,
	12
	};

	#if 0
	inline
	static double
	erfc_asymptotic(double x)
	{
	return exp(-xx)/x erfcasympsum(x) / M_SQRTPI;
	}
	inline
	static double
	log_erfc_asymptotic(double x)
	{
	return log(erfcasympsum(x)/x) - x*x - LogRootPi_;
	}
	#endif /* 0 */


	/----------- Functions with Error Codes -----------/

	int gsl_sf_erfc_e(double x, gsl_sf_result * result)
	{
	const double ax = fabs(x);
	double e_val, e_err;

	/* CHECK_POINTER(result) */

	if(ax <= 1.0) {
	double t = 2.0*ax - 1.0;
	gsl_sf_result c;
	cheb_eval_e(&erfc_xlt1_cs, t, &c);
	e_val = c.val;
	e_err = c.err;
	}
	else if(ax <= 5.0) {
	double ex2 = exp(-x*x);
	double t = 0.5*(ax-3.0);
	gsl_sf_result c;
	cheb_eval_e(&erfc_x15_cs, t, &c);
	e_val = ex2 * c.val;
	e_err = ex2 * (c.err + 2.0fabs(x)GSL_DBL_EPSILON);
	}
	else if(ax < 10.0) {
	double exterm = exp(-x*x) / ax;
	double t = (2.0*ax - 15.0)/5.0;
	gsl_sf_result c;
	cheb_eval_e(&erfc_x510_cs, t, &c);
	e_val = exterm * c.val;
	e_err = exterm * (c.err + 2.0fabs(x)GSL_DBL_EPSILON + GSL_DBL_EPSILON);
	}
	else {
	e_val = erfc8(ax);
	e_err = (xx + 1.0) GSL_DBL_EPSILON * fabs(e_val);
	}

	if(x < 0.0) {
	result->val = 2.0 - e_val;
	result->err = e_err;
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	}
	else {
	result->val = e_val;
	result->err = e_err;
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	}

	return GSL_SUCCESS;
	}


	int gsl_sf_log_erfc_e(double x, gsl_sf_result * result)
	{
	/* CHECK_POINTER(result) */

	if(xx < 10.0GSL_ROOT6_DBL_EPSILON) {
	const double y = x / M_SQRTPI;
	/* series for -1/2 Log[Erfc[Sqrt[Pi] y]] */
	const double c3 = (4.0 - M_PI)/3.0;
	const double c4 = 2.0*(1.0 - M_PI/3.0);
	const double c5 = -0.001829764677455021; /* (96.0 - 40.0M_PI + 3.0M_PIM_PI)/30.0 /
	const double c6 = 0.02629651521057465; /* 2.0(120.0 - 60.0M_PI + 7.0M_PIM_PI)/45.0 */
	const double c7 = -0.01621575378835404;
	const double c8 = 0.00125993961762116;
	const double c9 = 0.00556964649138;
	const double c10 = -0.0045563339802;
	const double c11 = 0.0009461589032;
	const double c12 = 0.0013200243174;
	const double c13 = -0.00142906;
	const double c14 = 0.00048204;
	double series = c8 + y(c9 + y(c10 + y(c11 + y(c12 + y(c13 + c14y)))));
	series = y(1.0 + y(1.0 + y(c3 + y(c4 + y(c5 + y(c6 + y(c7 + yseries)))))));
	result->val = -2.0 * series;
	result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	/*
	don't like use of log1p(); added above series stuff for small x instead, should be ok [GJ]
	else if (fabs(x) < 1.0) {
	gsl_sf_result result_erf;
	gsl_sf_erf_e(x, &result_erf);
	result->val = log1p(-result_erf.val);
	result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	*/
	else if(x > 8.0) {
	result->val = log_erfc8(x);
	result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	else {
	gsl_sf_result result_erfc;
	gsl_sf_erfc_e(x, &result_erfc);
	result->val = log(result_erfc.val);
	result->err = fabs(result_erfc.err / result_erfc.val);
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	}


	int gsl_sf_erf_e(double x, gsl_sf_result * result)
	{
	/* CHECK_POINTER(result) */

	if(fabs(x) < 1.0) {
	return erfseries(x, result);
	}
	else {
	gsl_sf_result result_erfc;
	gsl_sf_erfc_e(x, &result_erfc);
	result->val = 1.0 - result_erfc.val;
	result->err = result_erfc.err;
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	}


	int gsl_sf_erf_Z_e(double x, gsl_sf_result * result)
	{
	/* CHECK_POINTER(result) */

	{
	const double ex2 = exp(-x*x/2.0);
	result->val = ex2 / (M_SQRT2 * M_SQRTPI);
	result->err = fabs(x * result->val) * GSL_DBL_EPSILON;
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	CHECK_UNDERFLOW(result);
	return GSL_SUCCESS;
	}
	}


	int gsl_sf_erf_Q_e(double x, gsl_sf_result * result)
	{
	/* CHECK_POINTER(result) */

	{
	gsl_sf_result result_erfc;
	int stat = gsl_sf_erfc_e(x/M_SQRT2, &result_erfc);
	result->val = 0.5 * result_erfc.val;
	result->err = 0.5 * result_erfc.err;
	result->err += 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return stat;
	}
	}


	int gsl_sf_hazard_e(double x, gsl_sf_result * result)
	{
	if(x < 25.0)
	{
	gsl_sf_result result_ln_erfc;
	const int stat_l = gsl_sf_log_erfc_e(x/M_SQRT2, &result_ln_erfc);
	const double lnc = -0.22579135264472743236; /* ln(sqrt(2/pi)) */
	const double arg = lnc - 0.5xx - result_ln_erfc.val;
	const int stat_e = gsl_sf_exp_e(arg, result);
	result->err += 3.0 * (1.0 + fabs(x)) * GSL_DBL_EPSILON * fabs(result->val);
	result->err += fabs(result_ln_erfc.err * result->val);
	return GSL_ERROR_SELECT_2(stat_l, stat_e);
	}
	else
	{
	const double ix2 = 1.0/(x*x);
	const double corrB = 1.0 - 9.0ix2 (1.0 - 11.0*ix2);
	const double corrM = 1.0 - 5.0ix2 (1.0 - 7.0ix2 corrB);
	const double corrT = 1.0 - ix2 * (1.0 - 3.0ix2corrM);
	result->val = x / corrT;
	result->err = 2.0 * GSL_DBL_EPSILON * fabs(result->val);
	return GSL_SUCCESS;
	}
	}



	/--------- Functions w/ Natural Prototypes ----------*/

	#include "eval.h"

	double gsl_sf_erfc(double x)
	{
	EVAL_RESULT(gsl_sf_erfc_e(x, &result));
	}

	double gsl_sf_log_erfc(double x)
	{
	EVAL_RESULT(gsl_sf_log_erfc_e(x, &result));
	}

	double gsl_sf_erf(double x)
	{
	EVAL_RESULT(gsl_sf_erf_e(x, &result));
	}

	double gsl_sf_erf_Z(double x)
	{
	EVAL_RESULT(gsl_sf_erf_Z_e(x, &result));
	}

	double gsl_sf_erf_Q(double x)
	{
	EVAL_RESULT(gsl_sf_erf_Q_e(x, &result));
	}

	double gsl_sf_hazard(double x)
	{
	EVAL_RESULT(gsl_sf_hazard_e(x, &result));
	}