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

 /* roots/test.c
  *
  * Copyright (C) 1996, 1997, 1998, 1999, 2000 Reid Priedhorsky, Brian Gough
  *
  * 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.
  */

 #include <config.h>
 #include <stdlib.h>
 #include <gsl/gsl_math.h>
 #include <gsl/gsl_test.h>
 #include <gsl/gsl_roots.h>
 #include <gsl/gsl_errno.h>
 #include <gsl/gsl_ieee_utils.h>

 #include "roots.h"
 #include "test.h"

 /* stopping parameters */
 const double EPSREL = (10 * GSL_DBL_EPSILON);
 const double EPSABS = (10 * GSL_DBL_EPSILON);
 const unsigned int MAX_ITERATIONS = 150;

 void my_error_handler (const char *reason, const char *file,
                        int line, int err);

 #define WITHIN_TOL(a, b, epsrel, epsabs) \
  ((fabs((a) - (b)) < (epsrel) * GSL_MIN(fabs(a), fabs(b)) + (epsabs)))

 int
 main (void)
 {
   gsl_function F_sin, F_cos, F_func1, F_func2, F_func3, F_func4,
     F_func5, F_func6;

   gsl_function_fdf FDF_sin, FDF_cos, FDF_func1, FDF_func2, FDF_func3, FDF_func4,
     FDF_func5, FDF_func6;

   const gsl_root_fsolver_type * fsolver[4] ;
   const gsl_root_fdfsolver_type * fdfsolver[4] ;

   const gsl_root_fsolver_type ** T;
   const gsl_root_fdfsolver_type ** S;

   gsl_ieee_env_setup();

   fsolver[0] = gsl_root_fsolver_bisection;
   fsolver[1] = gsl_root_fsolver_brent;
   fsolver[2] = gsl_root_fsolver_falsepos;
   fsolver[3] = 0;

   fdfsolver[0] = gsl_root_fdfsolver_newton;
   fdfsolver[1] = gsl_root_fdfsolver_secant;
   fdfsolver[2] = gsl_root_fdfsolver_steffenson;
   fdfsolver[3] = 0;

   F_sin = create_function (sin_f) ;
   F_cos = create_function (cos_f) ;
   F_func1 = create_function (func1) ;
   F_func2 = create_function (func2) ;
   F_func3 = create_function (func3) ;
   F_func4 = create_function (func4) ;
   F_func5 = create_function (func5) ;
   F_func6 = create_function (func6) ;

   FDF_sin = create_fdf (sin_f, sin_df, sin_fdf) ;
   FDF_cos = create_fdf (cos_f, cos_df, cos_fdf) ;
   FDF_func1 = create_fdf (func1, func1_df, func1_fdf) ;
   FDF_func2 = create_fdf (func2, func2_df, func2_fdf) ;
   FDF_func3 = create_fdf (func3, func3_df, func3_fdf) ;
   FDF_func4 = create_fdf (func4, func4_df, func4_fdf) ;
   FDF_func5 = create_fdf (func5, func5_df, func5_fdf) ;
   FDF_func6 = create_fdf (func6, func6_df, func6_fdf) ;

   gsl_set_error_handler (&my_error_handler);

   for (T = fsolver ; *T != 0 ; T++)
     {
       test_f (*T, "sin(x) [3, 4]", &F_sin, 3.0, 4.0, M_PI);
       test_f (*T, "sin(x) [-4, -3]", &F_sin, -4.0, -3.0, -M_PI);
       test_f (*T, "sin(x) [-1/3, 1]", &F_sin, -1.0 / 3.0, 1.0, 0.0);
       test_f (*T, "cos(x) [0, 3]", &F_cos, 0.0, 3.0, M_PI / 2.0);
       test_f (*T, "cos(x) [-3, 0]", &F_cos, -3.0, 0.0, -M_PI / 2.0);
       test_f (*T, "x^20 - 1 [0.1, 2]", &F_func1, 0.1, 2.0, 1.0);
       test_f (*T, "sqrt(|x|)*sgn(x)", &F_func2, -1.0 / 3.0, 1.0, 0.0);
       test_f (*T, "x^2 - 1e-8 [0, 1]", &F_func3, 0.0, 1.0, sqrt (1e-8));
       test_f (*T, "x exp(-x) [-1/3, 2]", &F_func4, -1.0 / 3.0, 2.0, 0.0);
       test_f (*T, "(x - 1)^7 [0.9995, 1.0002]", &F_func6, 0.9995, 1.0002, 1.0);

       test_f_e (*T, "invalid range check [4, 0]", &F_sin, 4.0, 0.0, M_PI);
       test_f_e (*T, "invalid range check [1, 1]", &F_sin, 1.0, 1.0, M_PI);
       test_f_e (*T, "invalid range check [0.1, 0.2]", &F_sin, 0.1, 0.2, M_PI);
     }

   for (S = fdfsolver ; *S != 0 ; S++)
     {
       test_fdf (*S,"sin(x) {3.4}", &FDF_sin, 3.4, M_PI);
       test_fdf (*S,"sin(x) {-3.3}", &FDF_sin, -3.3, -M_PI);
       test_fdf (*S,"sin(x) {0.5}", &FDF_sin, 0.5, 0.0);
       test_fdf (*S,"cos(x) {0.6}", &FDF_cos, 0.6, M_PI / 2.0);
       test_fdf (*S,"cos(x) {-2.5}", &FDF_cos, -2.5, -M_PI / 2.0);
       test_fdf (*S,"x^{20} - 1 {0.9}", &FDF_func1, 0.9, 1.0);
       test_fdf (*S,"x^{20} - 1 {1.1}", &FDF_func1, 1.1, 1.0);
       test_fdf (*S,"sqrt(|x|)*sgn(x) {1.001}", &FDF_func2, 0.001, 0.0);
       test_fdf (*S,"x^2 - 1e-8 {1}", &FDF_func3, 1.0, sqrt (1e-8));
       test_fdf (*S,"x exp(-x) {-2}", &FDF_func4, -2.0, 0.0);
       test_fdf_e (*S,"max iterations x -> +Inf, x exp(-x) {2}", &FDF_func4, 2.0, 0.0);
       test_fdf_e (*S,"max iterations x -> -Inf, 1/(1 + exp(-x)) {0}", &FDF_func5, 0.0, 0.0);
     }

   test_fdf (gsl_root_fdfsolver_steffenson,
             "(x - 1)^7 {0.9}", &FDF_func6, 0.9, 1.0);

   /* now summarize the results */

   exit (gsl_test_summary ());
 }


 /* Using gsl_root_bisection, find the root of the function pointed to by f,
    using the interval [lower_bound, upper_bound]. Check if f succeeded and
    that it was accurate enough. */

 void
 test_f (const gsl_root_fsolver_type * T, const char * description, gsl_function *f,
         double lower_bound, double upper_bound, double correct_root)
 {
   int status;
   size_t iterations = 0;
   double r, a, b;
   double x_lower, x_upper;
   gsl_root_fsolver * s;

   x_lower = lower_bound;
   x_upper = upper_bound;

   s = gsl_root_fsolver_alloc(T);
   gsl_root_fsolver_set(s, f, x_lower, x_upper) ;

   do
     {
       iterations++ ;

       gsl_root_fsolver_iterate (s);

       r = gsl_root_fsolver_root(s);

       a = gsl_root_fsolver_x_lower(s);
       b = gsl_root_fsolver_x_upper(s);

       if (a > b)
         gsl_test (GSL_FAILURE, "interval is invalid (%g,%g)", a, b);

       if (r < a || r > b)
         gsl_test (GSL_FAILURE, "r lies outside interval %g (%g,%g)", r, a, b);

       status = gsl_root_test_interval (a,b, EPSABS, EPSREL);
     }
   while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);


   gsl_test (status, "%s, %s (%g obs vs %g expected) ",
             gsl_root_fsolver_name(s), description,
             gsl_root_fsolver_root(s), correct_root);

   if (iterations == MAX_ITERATIONS)
     {
       gsl_test (GSL_FAILURE, "exceeded maximum number of iterations");
     }

   /* check the validity of the returned result */

   if (!WITHIN_TOL (r, correct_root, EPSREL, EPSABS))
     {
       gsl_test (GSL_FAILURE, "incorrect precision (%g obs vs %g expected)",
                 r, correct_root);

     }

   gsl_root_fsolver_free(s);
 }

 void
 test_f_e (const gsl_root_fsolver_type * T,
           const char * description, gsl_function *f,
           double lower_bound, double upper_bound, double correct_root)
 {
   int status;
   size_t iterations = 0;
   double x_lower, x_upper;
   gsl_root_fsolver * s;

   x_lower = lower_bound;
   x_upper = upper_bound;

   s = gsl_root_fsolver_alloc(T);
   status = gsl_root_fsolver_set(s, f, x_lower, x_upper) ;

   gsl_test (status != GSL_EINVAL, "%s (set), %s", T->name, description);

   if (status == GSL_EINVAL)
     {
       gsl_root_fsolver_free(s);
       return ;
     }

   do
     {
       iterations++ ;
       gsl_root_fsolver_iterate (s);
       x_lower = gsl_root_fsolver_x_lower(s);
       x_upper = gsl_root_fsolver_x_lower(s);
       status = gsl_root_test_interval (x_lower, x_upper,
                                       EPSABS, EPSREL);
     }
   while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

   gsl_test (!status, "%s, %s", gsl_root_fsolver_name(s), description,
             gsl_root_fsolver_root(s) - correct_root);

   gsl_root_fsolver_free(s);
 }

 void
 test_fdf (const gsl_root_fdfsolver_type * T, const char * description,
         gsl_function_fdf *fdf, double root, double correct_root)
 {
   int status;
   size_t iterations = 0;
   double prev = 0 ;

   gsl_root_fdfsolver * s = gsl_root_fdfsolver_alloc(T);
   gsl_root_fdfsolver_set (s, fdf, root) ;

   do
     {
       iterations++ ;
       prev = gsl_root_fdfsolver_root(s);
       gsl_root_fdfsolver_iterate (s);
       status = gsl_root_test_delta(gsl_root_fdfsolver_root(s), prev,
                                    EPSABS, EPSREL);
     }
   while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

   gsl_test (status, "%s, %s (%g obs vs %g expected) ",
             gsl_root_fdfsolver_name(s), description,
             gsl_root_fdfsolver_root(s), correct_root);

   if (iterations == MAX_ITERATIONS)
     {
       gsl_test (GSL_FAILURE, "exceeded maximum number of iterations");
     }

   /* check the validity of the returned result */

   if (!WITHIN_TOL (gsl_root_fdfsolver_root(s), correct_root,
                    EPSREL, EPSABS))
     {
       gsl_test (GSL_FAILURE, "incorrect precision (%g obs vs %g expected)",
                 gsl_root_fdfsolver_root(s), correct_root);

     }
   gsl_root_fdfsolver_free(s);
 }

 void
 test_fdf_e (const gsl_root_fdfsolver_type * T,
             const char * description, gsl_function_fdf *fdf,
             double root, double correct_root)
 {
   int status;
   size_t iterations = 0;
   double prev = 0 ;

   gsl_root_fdfsolver * s = gsl_root_fdfsolver_alloc(T);
   status = gsl_root_fdfsolver_set (s, fdf, root) ;

   gsl_test (status, "%s (set), %s", T->name, description);

   do
     {
       iterations++ ;
       prev = gsl_root_fdfsolver_root(s);
       gsl_root_fdfsolver_iterate (s);
       status = gsl_root_test_delta(gsl_root_fdfsolver_root(s), prev,
                                    EPSABS, EPSREL);
     }
   while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

   gsl_test (!status, "%s, %s", gsl_root_fdfsolver_name(s),
             description, gsl_root_fdfsolver_root(s) - correct_root);
   gsl_root_fdfsolver_free(s);
 }

 void
 my_error_handler (const char *reason, const char *file, int line, int err)
 {
   if (0)
     printf ("(caught [%s:%d: %s (%d)])\n", file, line, reason, err);
 }
	/* roots/test.c
	*
	* Copyright (C) 1996, 1997, 1998, 1999, 2000 Reid Priedhorsky, Brian Gough
	*
	* 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.
	*/

	#include <config.h>
	#include <stdlib.h>
	#include <gsl/gsl_math.h>
	#include <gsl/gsl_test.h>
	#include <gsl/gsl_roots.h>
	#include <gsl/gsl_errno.h>
	#include <gsl/gsl_ieee_utils.h>

	#include "roots.h"
	#include "test.h"

	/* stopping parameters */
	const double EPSREL = (10 * GSL_DBL_EPSILON);
	const double EPSABS = (10 * GSL_DBL_EPSILON);
	const unsigned int MAX_ITERATIONS = 150;

	void my_error_handler (const char reason, const char file,
	int line, int err);

	#define WITHIN_TOL(a, b, epsrel, epsabs) \
	((fabs((a) - (b)) < (epsrel) * GSL_MIN(fabs(a), fabs(b)) + (epsabs)))

	int
	main (void)
	{
	gsl_function F_sin, F_cos, F_func1, F_func2, F_func3, F_func4,
	F_func5, F_func6;

	gsl_function_fdf FDF_sin, FDF_cos, FDF_func1, FDF_func2, FDF_func3, FDF_func4,
	FDF_func5, FDF_func6;

	const gsl_root_fsolver_type * fsolver[4] ;
	const gsl_root_fdfsolver_type * fdfsolver[4] ;

	const gsl_root_fsolver_type ** T;
	const gsl_root_fdfsolver_type ** S;

	gsl_ieee_env_setup();

	fsolver[0] = gsl_root_fsolver_bisection;
	fsolver[1] = gsl_root_fsolver_brent;
	fsolver[2] = gsl_root_fsolver_falsepos;
	fsolver[3] = 0;

	fdfsolver[0] = gsl_root_fdfsolver_newton;
	fdfsolver[1] = gsl_root_fdfsolver_secant;
	fdfsolver[2] = gsl_root_fdfsolver_steffenson;
	fdfsolver[3] = 0;

	F_sin = create_function (sin_f) ;
	F_cos = create_function (cos_f) ;
	F_func1 = create_function (func1) ;
	F_func2 = create_function (func2) ;
	F_func3 = create_function (func3) ;
	F_func4 = create_function (func4) ;
	F_func5 = create_function (func5) ;
	F_func6 = create_function (func6) ;

	FDF_sin = create_fdf (sin_f, sin_df, sin_fdf) ;
	FDF_cos = create_fdf (cos_f, cos_df, cos_fdf) ;
	FDF_func1 = create_fdf (func1, func1_df, func1_fdf) ;
	FDF_func2 = create_fdf (func2, func2_df, func2_fdf) ;
	FDF_func3 = create_fdf (func3, func3_df, func3_fdf) ;
	FDF_func4 = create_fdf (func4, func4_df, func4_fdf) ;
	FDF_func5 = create_fdf (func5, func5_df, func5_fdf) ;
	FDF_func6 = create_fdf (func6, func6_df, func6_fdf) ;

	gsl_set_error_handler (&my_error_handler);

	for (T = fsolver ; *T != 0 ; T++)
	{
	test_f (*T, "sin(x) [3, 4]", &F_sin, 3.0, 4.0, M_PI);
	test_f (*T, "sin(x) [-4, -3]", &F_sin, -4.0, -3.0, -M_PI);
	test_f (*T, "sin(x) [-1/3, 1]", &F_sin, -1.0 / 3.0, 1.0, 0.0);
	test_f (*T, "cos(x) [0, 3]", &F_cos, 0.0, 3.0, M_PI / 2.0);
	test_f (*T, "cos(x) [-3, 0]", &F_cos, -3.0, 0.0, -M_PI / 2.0);
	test_f (*T, "x^20 - 1 [0.1, 2]", &F_func1, 0.1, 2.0, 1.0);
	test_f (T, "sqrt(\|x\|)sgn(x)", &F_func2, -1.0 / 3.0, 1.0, 0.0);
	test_f (*T, "x^2 - 1e-8 [0, 1]", &F_func3, 0.0, 1.0, sqrt (1e-8));
	test_f (*T, "x exp(-x) [-1/3, 2]", &F_func4, -1.0 / 3.0, 2.0, 0.0);
	test_f (*T, "(x - 1)^7 [0.9995, 1.0002]", &F_func6, 0.9995, 1.0002, 1.0);

	test_f_e (*T, "invalid range check [4, 0]", &F_sin, 4.0, 0.0, M_PI);
	test_f_e (*T, "invalid range check [1, 1]", &F_sin, 1.0, 1.0, M_PI);
	test_f_e (*T, "invalid range check [0.1, 0.2]", &F_sin, 0.1, 0.2, M_PI);
	}

	for (S = fdfsolver ; *S != 0 ; S++)
	{
	test_fdf (*S,"sin(x) {3.4}", &FDF_sin, 3.4, M_PI);
	test_fdf (*S,"sin(x) {-3.3}", &FDF_sin, -3.3, -M_PI);
	test_fdf (*S,"sin(x) {0.5}", &FDF_sin, 0.5, 0.0);
	test_fdf (*S,"cos(x) {0.6}", &FDF_cos, 0.6, M_PI / 2.0);
	test_fdf (*S,"cos(x) {-2.5}", &FDF_cos, -2.5, -M_PI / 2.0);
	test_fdf (*S,"x^{20} - 1 {0.9}", &FDF_func1, 0.9, 1.0);
	test_fdf (*S,"x^{20} - 1 {1.1}", &FDF_func1, 1.1, 1.0);
	test_fdf (S,"sqrt(\|x\|)sgn(x) {1.001}", &FDF_func2, 0.001, 0.0);
	test_fdf (*S,"x^2 - 1e-8 {1}", &FDF_func3, 1.0, sqrt (1e-8));
	test_fdf (*S,"x exp(-x) {-2}", &FDF_func4, -2.0, 0.0);
	test_fdf_e (*S,"max iterations x -> +Inf, x exp(-x) {2}", &FDF_func4, 2.0, 0.0);
	test_fdf_e (*S,"max iterations x -> -Inf, 1/(1 + exp(-x)) {0}", &FDF_func5, 0.0, 0.0);
	}

	test_fdf (gsl_root_fdfsolver_steffenson,
	"(x - 1)^7 {0.9}", &FDF_func6, 0.9, 1.0);

	/* now summarize the results */

	exit (gsl_test_summary ());
	}


	/* Using gsl_root_bisection, find the root of the function pointed to by f,
	using the interval [lower_bound, upper_bound]. Check if f succeeded and
	that it was accurate enough. */

	void
	test_f (const gsl_root_fsolver_type * T, const char * description, gsl_function *f,
	double lower_bound, double upper_bound, double correct_root)
	{
	int status;
	size_t iterations = 0;
	double r, a, b;
	double x_lower, x_upper;
	gsl_root_fsolver * s;

	x_lower = lower_bound;
	x_upper = upper_bound;

	s = gsl_root_fsolver_alloc(T);
	gsl_root_fsolver_set(s, f, x_lower, x_upper) ;

	do
	{
	iterations++ ;

	gsl_root_fsolver_iterate (s);

	r = gsl_root_fsolver_root(s);

	a = gsl_root_fsolver_x_lower(s);
	b = gsl_root_fsolver_x_upper(s);

	if (a > b)
	gsl_test (GSL_FAILURE, "interval is invalid (%g,%g)", a, b);

	if (r < a \|\| r > b)
	gsl_test (GSL_FAILURE, "r lies outside interval %g (%g,%g)", r, a, b);

	status = gsl_root_test_interval (a,b, EPSABS, EPSREL);
	}
	while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);


	gsl_test (status, "%s, %s (%g obs vs %g expected) ",
	gsl_root_fsolver_name(s), description,
	gsl_root_fsolver_root(s), correct_root);

	if (iterations == MAX_ITERATIONS)
	{
	gsl_test (GSL_FAILURE, "exceeded maximum number of iterations");
	}

	/* check the validity of the returned result */

	if (!WITHIN_TOL (r, correct_root, EPSREL, EPSABS))
	{
	gsl_test (GSL_FAILURE, "incorrect precision (%g obs vs %g expected)",
	r, correct_root);

	}

	gsl_root_fsolver_free(s);
	}

	void
	test_f_e (const gsl_root_fsolver_type * T,
	const char * description, gsl_function *f,
	double lower_bound, double upper_bound, double correct_root)
	{
	int status;
	size_t iterations = 0;
	double x_lower, x_upper;
	gsl_root_fsolver * s;

	x_lower = lower_bound;
	x_upper = upper_bound;

	s = gsl_root_fsolver_alloc(T);
	status = gsl_root_fsolver_set(s, f, x_lower, x_upper) ;

	gsl_test (status != GSL_EINVAL, "%s (set), %s", T->name, description);

	if (status == GSL_EINVAL)
	{
	gsl_root_fsolver_free(s);
	return ;
	}

	do
	{
	iterations++ ;
	gsl_root_fsolver_iterate (s);
	x_lower = gsl_root_fsolver_x_lower(s);
	x_upper = gsl_root_fsolver_x_lower(s);
	status = gsl_root_test_interval (x_lower, x_upper,
	EPSABS, EPSREL);
	}
	while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

	gsl_test (!status, "%s, %s", gsl_root_fsolver_name(s), description,
	gsl_root_fsolver_root(s) - correct_root);

	gsl_root_fsolver_free(s);
	}

	void
	test_fdf (const gsl_root_fdfsolver_type * T, const char * description,
	gsl_function_fdf *fdf, double root, double correct_root)
	{
	int status;
	size_t iterations = 0;
	double prev = 0 ;

	gsl_root_fdfsolver * s = gsl_root_fdfsolver_alloc(T);
	gsl_root_fdfsolver_set (s, fdf, root) ;

	do
	{
	iterations++ ;
	prev = gsl_root_fdfsolver_root(s);
	gsl_root_fdfsolver_iterate (s);
	status = gsl_root_test_delta(gsl_root_fdfsolver_root(s), prev,
	EPSABS, EPSREL);
	}
	while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

	gsl_test (status, "%s, %s (%g obs vs %g expected) ",
	gsl_root_fdfsolver_name(s), description,
	gsl_root_fdfsolver_root(s), correct_root);

	if (iterations == MAX_ITERATIONS)
	{
	gsl_test (GSL_FAILURE, "exceeded maximum number of iterations");
	}

	/* check the validity of the returned result */

	if (!WITHIN_TOL (gsl_root_fdfsolver_root(s), correct_root,
	EPSREL, EPSABS))
	{
	gsl_test (GSL_FAILURE, "incorrect precision (%g obs vs %g expected)",
	gsl_root_fdfsolver_root(s), correct_root);

	}
	gsl_root_fdfsolver_free(s);
	}

	void
	test_fdf_e (const gsl_root_fdfsolver_type * T,
	const char * description, gsl_function_fdf *fdf,
	double root, double correct_root)
	{
	int status;
	size_t iterations = 0;
	double prev = 0 ;

	gsl_root_fdfsolver * s = gsl_root_fdfsolver_alloc(T);
	status = gsl_root_fdfsolver_set (s, fdf, root) ;

	gsl_test (status, "%s (set), %s", T->name, description);

	do
	{
	iterations++ ;
	prev = gsl_root_fdfsolver_root(s);
	gsl_root_fdfsolver_iterate (s);
	status = gsl_root_test_delta(gsl_root_fdfsolver_root(s), prev,
	EPSABS, EPSREL);
	}
	while (status == GSL_CONTINUE && iterations < MAX_ITERATIONS);

	gsl_test (!status, "%s, %s", gsl_root_fdfsolver_name(s),
	description, gsl_root_fdfsolver_root(s) - correct_root);
	gsl_root_fdfsolver_free(s);
	}

	void
	my_error_handler (const char reason, const char file, int line, int err)
	{
	if (0)
	printf ("(caught [%s:%d: %s (%d)])\n", file, line, reason, err);
	}