codegen: Drop unnecessary comma expressions in member access

[vala-lang.git] / vapi / gsl.vapi

/* gsl.vapi
 *
 * Copyright (C) 2008  Matias De la Puente
 *
 * This library is free software; you can redistribute it and/or
 * modify it under the terms of the GNU Lesser General Public
 * License as published by the Free Software Foundation; either
 * version 2.1 of the License, or (at your option) any later version.

 * This library 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
 * Lesser General Public License for more details.

 * You should have received a copy of the GNU Lesser General Public
 * License along with this library; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301  USA
 *
 * Author:
 *      Matias De la Puente <mfpuente.ar@gmail.com>
 */
 
namespace Gsl
{
        /*
         * Physical Constants
         */
        [CCode (cprefix="GSL_CONST_NUM_", cheader_filename="gsl/gsl_const_num.h")]
        public enum ConstNum
        {
                FINE_STRUCTURE,
                AVOGADRO,
                YOTTA,
                ZETTA,
                EXA,
                PETA,
                TERA,
                GIGA,
                MEGA,
                KILO,
                MILLI,
                MICRO,
                NANO,
                PICO,
                FEMTO,
                ATTO,
                ZEPTO,
                YOCTO
        }
        
        [CCode (cprefix="GSL_CONST_CGS_", cheader_filename="gsl/gsl_const_cgs.h")]
        public enum ConstCGS
        {
                SPEED_OF_LIGHT,
                GRAVITATIONAL_CONSTANT,
                PLANCKS_CONSTANT_H,
                PLANCKS_CONSTANT_HBAR,
                ASTRONOMICAL_UNIT,
                LIGHT_YEAR,
                PARSEC,
                GRAV_ACCEL,
                ELECTRON_VOLT,
                MASS_ELECTRON,
                MASS_MUON,
                MASS_PROTON,
                MASS_NEUTRON,
                RYDBERG,
                BOLTZMANN,
                BOHR_MAGNETON,
                NUCLEAR_MAGNETON,
                ELECTRON_MAGNETIC_MOMENT,
                PROTON_MAGNETIC_MOMENT,
                MOLAR_GAS,
                STANDARD_GAS_VOLUME,
                MINUTE,
                HOUR,
                DAY,
                WEEK,
                INCH,
                FOOT,
                YARD,
                MILE,
                NAUTICAL_MILE,
                FATHOM,
                MIL,
                POINT,
                TEXPOINT,
                MICRON,
                ANGSTROM,
                HECTARE,
                ACRE,
                BARN,
                LITER,
                US_GALLON,
                QUART,
                PINT,
                CUP,
                FLUID_OUNCE,
                TABLESPOON,
                TEASPOON,
                CANADIAN_GALLON,
                UK_GALLON,
                MILES_PER_HOUR,
                KILOMETERS_PER_HOUR,
                KNOT,
                POUND_MASS,
                OUNCE_MASS,
                TON,
                METRIC_TON,
                UK_TON,
                TROY_OUNCE,
                CARAT,
                UNIFIED_ATOMIC_MASS,
                GRAM_FORCE,
                POUND_FORCE,
                KILOPOUND_FORCE,
                POUNDAL,
                CALORIE,
                BTU,
                THERM,
                HORSEPOWER,
                BAR,
                STD_ATMOSPHERE,
                TORR,
                METER_OF_MERCURY,
                INCH_OF_MERCURY,
                INCH_OF_WATER,
                PSI,
                POISE,
                STOKES,
                FARADAY,
                ELECTRON_CHARGE,
                GAUSS,
                STILB,
                LUMEN,
                LUX,
                PHOT,
                FOOTCANDLE,
                LAMBERT,
                FOOTLAMBERT,
                CURIE,
                ROENTGEN,
                RAD,
                SOLAR_MASS,
                BOHR_RADIUS,
                NEWTON,
                DYNE,
                JOULE,
                ERG,
                STEFAN_BOLTZMANN_CONSTANT,
                THOMSON_CROSS_SECTION
        }
        
        [CCode (cprefix="GSL_CONST_CGSM_", cheader_filename="gsl/gsl_const_cgsm.h")]
        public enum ConstCGSM
        {
                SPEED_OF_LIGHT,
                GRAVITATIONAL_CONSTANT,
                PLANCKS_CONSTANT_H,
                PLANCKS_CONSTANT_HBAR,
                ASTRONOMICAL_UNIT,
                LIGHT_YEAR,
                PARSEC,
                GRAV_ACCEL,
                ELECTRON_VOLT,
                MASS_ELECTRON,
                MASS_MUON,
                MASS_PROTON,
                MASS_NEUTRON,
                RYDBERG,
                BOLTZMANN,
                BOHR_MAGNETON,
                NUCLEAR_MAGNETON,
                ELECTRON_MAGNETIC_MOMENT,
                PROTON_MAGNETIC_MOMENT,
                MOLAR_GAS,
                STANDARD_GAS_VOLUME,
                MINUTE,
                HOUR,
                DAY,
                WEEK,
                INCH,
                FOOT,
                YARD,
                MILE,
                NAUTICAL_MILE,
                FATHOM,
                MIL,
                POINT,
                TEXPOINT,
                MICRON,
                ANGSTROM,
                HECTARE,
                ACRE,
                BARN,
                LITER,
                US_GALLON,
                QUART,
                PINT,
                CUP,
                FLUID_OUNCE,
                TABLESPOON,
                TEASPOON,
                CANADIAN_GALLON,
                UK_GALLON,
                MILES_PER_HOUR,
                KILOMETERS_PER_HOUR,
                KNOT,
                POUND_MASS,
                OUNCE_MASS,
                TON,
                METRIC_TON,
                UK_TON,
                TROY_OUNCE,
                CARAT,
                UNIFIED_ATOMIC_MASS,
                GRAM_FORCE,
                POUND_FORCE,
                KILOPOUND_FORCE,
                POUNDAL,
                CALORIE,
                BTU,
                THERM,
                HORSEPOWER,
                BAR,
                STD_ATMOSPHERE,
                TORR,
                METER_OF_MERCURY,
                INCH_OF_MERCURY,
                INCH_OF_WATER,
                PSI,
                POISE,
                STOKES,
                FARADAY,
                ELECTRON_CHARGE,
                GAUSS,
                STILB,
                LUMEN,
                LUX,
                PHOT,
                FOOTCANDLE,
                LAMBERT,
                FOOTLAMBERT,
                CURIE,
                ROENTGEN,
                RAD,
                SOLAR_MASS,
                BOHR_RADIUS,
                NEWTON,
                DYNE,
                JOULE,
                ERG,
                STEFAN_BOLTZMANN_CONSTANT,
                THOMSON_CROSS_SECTION
        }

        [CCode (cprefix="GSL_CONST_MKS_", cheader_filename="gsl/gsl_const_mks.h")]
        public enum ConstMKS
        {
                SPEED_OF_LIGHT,
                GRAVITATIONAL_CONSTANT,
                PLANCKS_CONSTANT_H,
                PLANCKS_CONSTANT_HBAR,
                ASTRONOMICAL_UNIT,
                LIGHT_YEAR,
                PARSEC,
                GRAV_ACCEL,
                ELECTRON_VOLT,
                MASS_ELECTRON,
                MASS_MUON,
                MASS_PROTON,
                MASS_NEUTRON,
                RYDBERG,
                BOLTZMANN,
                BOHR_MAGNETON,
                NUCLEAR_MAGNETON,
                ELECTRON_MAGNETIC_MOMENT,
                PROTON_MAGNETIC_MOMENT,
                MOLAR_GAS,
                STANDARD_GAS_VOLUME,
                MINUTE,
                HOUR,
                DAY,
                WEEK,
                INCH,
                FOOT,
                YARD,
                MILE,
                NAUTICAL_MILE,
                FATHOM,
                MIL,
                POINT,
                TEXPOINT,
                MICRON,
                ANGSTROM,
                HECTARE,
                ACRE,
                BARN,
                LITER,
                US_GALLON,
                QUART,
                PINT,
                CUP,
                FLUID_OUNCE,
                TABLESPOON,
                TEASPOON,
                CANADIAN_GALLON,
                UK_GALLON,
                MILES_PER_HOUR,
                KILOMETERS_PER_HOUR,
                KNOT,
                POUND_MASS,
                OUNCE_MASS,
                TON,
                METRIC_TON,
                UK_TON,
                TROY_OUNCE,
                CARAT,
                UNIFIED_ATOMIC_MASS,
                GRAM_FORCE,
                POUND_FORCE,
                KILOPOUND_FORCE,
                POUNDAL,
                CALORIE,
                BTU,
                THERM,
                HORSEPOWER,
                BAR,
                STD_ATMOSPHERE,
                TORR,
                METER_OF_MERCURY,
                INCH_OF_MERCURY,
                INCH_OF_WATER,
                PSI,
                POISE,
                STOKES,
                FARADAY,
                ELECTRON_CHARGE,
                GAUSS,
                STILB,
                LUMEN,
                LUX,
                PHOT,
                FOOTCANDLE,
                LAMBERT,
                FOOTLAMBERT,
                CURIE,
                ROENTGEN,
                RAD,
                SOLAR_MASS,
                BOHR_RADIUS,
                NEWTON,
                DYNE,
                JOULE,
                ERG,
                STEFAN_BOLTZMANN_CONSTANT,
                THOMSON_CROSS_SECTION,
                VACUUM_PERMITTIVITY,
                VACUUM_PERMEABILITY,
                DEBYE
        }

        [CCode (cprefix="GSL_CONST_MKSA_", cheader_filename="gsl/gsl_const_mksa.h")]
        public enum ConstMKSA
        {
                SPEED_OF_LIGHT,
                GRAVITATIONAL_CONSTANT,
                PLANCKS_CONSTANT_H,
                PLANCKS_CONSTANT_HBAR,
                ASTRONOMICAL_UNIT,
                LIGHT_YEAR,
                PARSEC,
                GRAV_ACCEL,
                ELECTRON_VOLT,
                MASS_ELECTRON,
                MASS_MUON,
                MASS_PROTON,
                MASS_NEUTRON,
                RYDBERG,
                BOLTZMANN,
                BOHR_MAGNETON,
                NUCLEAR_MAGNETON,
                ELECTRON_MAGNETIC_MOMENT,
                PROTON_MAGNETIC_MOMENT,
                MOLAR_GAS,
                STANDARD_GAS_VOLUME,
                MINUTE,
                HOUR,
                DAY,
                WEEK,
                INCH,
                FOOT,
                YARD,
                MILE,
                NAUTICAL_MILE,
                FATHOM,
                MIL,
                POINT,
                TEXPOINT,
                MICRON,
                ANGSTROM,
                HECTARE,
                ACRE,
                BARN,
                LITER,
                US_GALLON,
                QUART,
                PINT,
                CUP,
                FLUID_OUNCE,
                TABLESPOON,
                TEASPOON,
                CANADIAN_GALLON,
                UK_GALLON,
                MILES_PER_HOUR,
                KILOMETERS_PER_HOUR,
                KNOT,
                POUND_MASS,
                OUNCE_MASS,
                TON,
                METRIC_TON,
                UK_TON,
                TROY_OUNCE,
                CARAT,
                UNIFIED_ATOMIC_MASS,
                GRAM_FORCE,
                POUND_FORCE,
                KILOPOUND_FORCE,
                POUNDAL,
                CALORIE,
                BTU,
                THERM,
                HORSEPOWER,
                BAR,
                STD_ATMOSPHERE,
                TORR,
                METER_OF_MERCURY,
                INCH_OF_MERCURY,
                INCH_OF_WATER,
                PSI,
                POISE,
                STOKES,
                FARADAY,
                ELECTRON_CHARGE,
                GAUSS,
                STILB,
                LUMEN,
                LUX,
                PHOT,
                FOOTCANDLE,
                LAMBERT,
                FOOTLAMBERT,
                CURIE,
                ROENTGEN,
                RAD,
                SOLAR_MASS,
                BOHR_RADIUS,
                NEWTON,
                DYNE,
                JOULE,
                ERG,
                STEFAN_BOLTZMANN_CONSTANT,
                THOMSON_CROSS_SECTION,
                VACUUM_PERMITTIVITY,
                VACUUM_PERMEABILITY,
                DEBYE
        }
        
        
        /*
         * Error Handling
         */
        [CCode (cprefix="GSL_", cheader_filename="gsl/gsl_errno.h")]
        public enum Status
        {
                SUCCESS,
                FAILURE,
                CONTINUE,
                EDOM,
                ERANGE,
                EFAULT,
                EINVAL,
                EFAILED,
                EFACTOR,
                ESANITY,
                ENOMEM,
                EBADFUNC,
                ERUNAWAY,
                EMAXITER,
                EZERODIV,
                EBADTOL,
                ETOL,
                EUNDRFLW,
                EOVRFLW,
                ELOSS,
                EROUND,
                EBADLEN,
                ENOTSQR,
                ESING,
                EDIVERGE,
                EUNSUP,
                EUNIMPL,
                ECACHE,
                ETABLE,
                ENOPROG,
                ENOPROGJ,
                ETOLF,
                ETOLX,
                ETOLG,
                EOF
        }
        
        [CCode (cprefix="GSL_PREC_", cheader_filename="gsl/gsl_mode.h")]
        public enum Mode
        {
                DOUBLE,
                SINGLE,
                APPROX
        }

        [CCode (has_target = false)]
        public delegate void ErrorHandler (string reason, string file, int line, int errno);
        [CCode (has_target = false)]
        public delegate void StreamHandler (string label, string file, int line, string reason);
        
        [CCode (lower_case_cprefix="gsl_", cheader_filename="gsl/gsl_errno.h")]
        namespace Error
        {
                public static void error (string reason, string file, int line, int errno);
                public static unowned string strerror (int errno);
                public static ErrorHandler set_error_handler (ErrorHandler? new_handler);
                public static ErrorHandler set_error_handler_off ();
        }
        
        [CCode (lower_case_cprefix="gsl_", cheader_filename="gsl/gsl_errno.h")]
        namespace Stream
        {
                [CCode (cname="gsl_stream_printf")]
                public static void printf (string label, string file, int line, string reason);
                public static StreamHandler set_stream_handler (StreamHandler new_handler);
                public static GLib.FileStream set_stream (GLib.FileStream new_stream);
        }
        
        
        /*
         * Mathematical Functions
         */
        [CCode (cprefix="", cheader_filename="gsl/gsl_math.h")]
        public enum MathConst
        {
                M_E,
                M_LOG2E,
                M_LOG10E,
                M_SQRT2,
                M_SQRT1_2,
                M_SQRT3,
                M_PI,
                M_PI_2,
                M_PI_4,
                M_2_SQRTPI,
                M_1_PI,
                M_2_PI,
                M_LN10,
                M_LN2,
                M_LNPI,
                M_EULER
        }
        
        /* The isnan, isinf and finite are define in the double type. The elementary functions are in GLib.Math */

        [CCode (has_target = false)]
        public delegate double _Function (double x, void* params);
        [CCode (has_target = false)]
        public delegate void _FunctionFdf (double x, void* params, out double f, out double df);
        
        [SimpleType]
        [CCode (cname="gsl_function", cheader_filename="gsl/gsl_math.h")]
        public struct Function
        {
                public _Function function;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_function_fdf", cheader_filename="gsl/gsl_math.h")]
        public struct FunctionFdf
        {
                public _Function f;
                public _Function df;
                public _FunctionFdf fdf;
                public void* params;
        }
        
        
        /*
         * Complex Numbers
         */
        [SimpleType]
        [CCode (cname="gsl_complex", cheader_filename="gsl/gsl_complex.h,gsl/gsl_complex_math.h")]
        public struct Complex
        {
                [CCode (cname="dat[0]")]
                public double real;
                [CCode (cname="dat[1]")]
                public double imag;
                public static Complex rect (double x, double y);
                public static Complex polar (double r, double theta);
                
                public static double arg (Complex z);
                public static double abs (Complex z);
                public static double abs2 (Complex z);
                public static double logabs (Complex z);

                public static Complex add (Complex a, Complex b);
                public static Complex sub (Complex a, Complex b);
                public static Complex mul (Complex a, Complex b);
                public static Complex div (Complex a, Complex b);
                public static Complex add_real (Complex a, double x);
                public static Complex sub_real (Complex a, double x);
                public static Complex mul_real (Complex a, double x);
                public static Complex div_real (Complex a, double x);
                public static Complex add_imag (Complex a, double y);
                public static Complex sub_imag (Complex a, double y);
                public static Complex mul_imag (Complex a, double y);
                public static Complex div_imag (Complex a, double y);
                public static Complex conjugate (Complex z);
                public static Complex inverse (Complex z);
                public static Complex negative (Complex z);
                
                public static Complex sqrt (Complex z);
                public static Complex sqrt_real (double x);
                public static Complex pow (Complex z, Complex a);
                public static Complex pow_real (Complex z, double x);
                public static Complex exp (Complex z);
                public static Complex log (Complex z);
                public static Complex log10 (Complex z);
                public static Complex log_b (Complex z, Complex b);
                
                public static Complex sin (Complex z);
                public static Complex cos (Complex z);
                public static Complex tan (Complex z);
                public static Complex sec (Complex z);
                public static Complex csc (Complex z);
                public static Complex cot (Complex z);
                
                public static Complex arcsin (Complex z);
                public static Complex arcsin_real (double z);
                public static Complex arccos (Complex z);
                public static Complex arccos_real (double z);
                public static Complex arctan (Complex z);
                public static Complex arcsec (Complex z);
                public static Complex arcsec_real (double z);
                public static Complex arccsc (Complex z);
                public static Complex arccsc_real (double z);
                public static Complex arccot (Complex z);
                
                public static Complex sinh (Complex z);
                public static Complex cosh (Complex z);
                public static Complex tanh (Complex z);
                public static Complex sech (Complex z);
                public static Complex csch (Complex z);
                public static Complex coth (Complex z);
                
                public static Complex arcsinh (Complex z);
                public static Complex arccosh (Complex z);
                public static Complex arccosh_real (double z);
                public static Complex arctanh (Complex z);
                public static Complex arctanh_real (double z);
                public static Complex arcsech (Complex z);
                public static Complex arccsch (Complex z);
                public static Complex arccoth (Complex z);
        }
        
        
        /*
         * Polynomials
         */
        [CCode (lower_case_cprefix="gsl_poly_", cheader_filename="gsl/gsl_poly.h")]
        namespace Poly
        {
                public static double eval (double[] c, double x);
                public static Complex complex_eval (double[] c, Complex z);
                [CCode (cname="gsl_complex_poly_complex_eval")]
                public static Complex poly_complex_eval (Complex[] c, Complex z);
                                
                public static int dd_init ([CCode (array_length = false)] double[] dd, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size);
                public static double dd_eval ([CCode (array_length = false)] double[] dd, [CCode (array_length = false)] double[] xa, size_t size, double x);
                public static int dd_taylor ([CCode (array_length = false)] double[] c, double xp, [CCode (array_length = false)] double[] dd, [CCode (array_length = false)] double[] xa, size_t size, [CCode (array_length = false)] double[] w);
                
                public static int solve_quadratic (double a, double b, double c, out double x0, out double x1);
                public static int complex_solve_quadratic (double a, double b, double c, out Complex z0, out Complex z1);
                
                public static int solve_cubic (double a, double b, double c, out double x0, out double x1, out double x2);
                public static int complex_solve_cubic (double a, double b, double c, out Complex z0, out Complex z1, out Complex z2);
        }
        
        [Compact]
        [CCode (cname="gsl_poly_complex_workspace", cheader_filename="gsl/gsl_poly.h")]
        public class PolyComplexWorkspace
        {
                public size_t nc;
                public double* matrix;
                
                [CCode (cname="gsl_poly_complex_workspace_alloc")]
                public PolyComplexWorkspace (size_t n);
                [CCode (cname="gsl_poly_complex_solve")]
                public static int solve (double[]a, PolyComplexWorkspace w, out double z);
        }
        
        
        /*
         * Special Functions
         */
        [SimpleType]
        [CCode (cname="gsl_sf_result", cheader_filename="gsl/gsl_sf_result.h")]
        public struct Result
        {
                public double val;
                public double err;
        }
        
        [SimpleType]
        [CCode (cname="gsl_sf_result_e10", cheader_filename="gsl/gsl_sf_result.h")]
        public struct ResultE10
        {
                public double val;
                public double err;
                public int e10;
        }
        
        [CCode (lower_case_cprefix="gsl_sf_airy_", cheader_filename="gsl/gsl_sf_airy.h")]
        namespace Airy
        {
                public static double Ai (double x, Mode mode);
                public static int Ai_e (double x, Mode mode, out Result result);
                public static double Bi (double x, Mode mode);
                public static int Bi_e (double x, Mode mode, out Result result);
                public static double Ai_scaled (double x, Mode mode);
                public static int Ai_scaled_e (double x, Mode mode, out Result result);
                public static double Bi_scaled (double x, Mode mode);
                public static int Bi_scaled_e (double x, Mode mode, out Result result);
                
                public static double Ai_deriv (double x, Mode mode);
                public static int Ai_deriv_e (double x, Mode mode, out Result result);
                public static double Bi_deriv (double x, Mode mode);
                public static int Bi_deriv_e (double x, Mode mode, out Result result);
                public static double Ai_deriv_scaled (double x, Mode mode);
                public static int Ai_deriv_scaled_e (double x, Mode mode, out Result result);
                public static double Bi_deriv_scaled (double x, Mode mode);
                public static int Bi_deriv_scaled_e (double x, Mode mode, out Result result);
                
                public static double zero_Ai (uint s);
                public static int zero_Ai_e (uint s, out Result result);
                public static double zero_Bi (uint s);
                public static int zero_Bi_e (uint s, out Result result);
                
                public static double zero_Ai_deriv (uint s);
                public static int zero_Ai_deriv_e (uint s, out Result result);
                public static double zero_Bi_deriv (uint s);
                public static int zero_Bi_deriv_e (uint s, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_bessel_", cheader_filename="gsl/gsl_sf_bessel.h")]
        namespace Bessel
        {
                public static double J0 (double x);
                public static int J0_e (double x, out Result result);
                public static double J1 (double x);
                public static int J1_e (double x, out Result result);
                public static double Jn (int n, double x);
                public static int Jn_e (int n, double x, out Result result);
                public static int Jn_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double Y0 (double x);
                public static int Y0_e (double x, out Result result);
                public static double Y1 (double x);
                public static int Y1_e (double x, out Result result);
                public static double Yn (int n, double x);
                public static int Yn_e (int n, double x, out Result result);
                public static int Yn_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double I0 (double x);
                public static int I0_e (double x, out Result result);
                public static double I1 (double x);
                public static int I1_e (double x, out Result result);
                public static double In (int n, double x);
                public static int In_e (int n, double x, out Result result);
                public static int In_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                public static double I0_scaled (double x);
                public static int I0_scaled_e (double x, out Result result);
                public static double I1_scaled (double x);
                public static int I1_scaled_e (double x, out Result result);
                public static double In_scaled (int n, double x);
                public static int In_scaled_e (int n, double x, out Result result);
                public static int In_scaled_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double K0 (double x);
                public static int K0_e (double x, out Result result);
                public static double K1 (double x);
                public static int K1_e (double x, out Result result);
                public static double Kn (int n, double x);
                public static int Kn_e (int n, double x, out Result result);
                public static int Kn_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                public static double K0_scaled (double x);
                public static int K0_scaled_e (double x, out Result result);
                public static double K1_scaled (double x);
                public static int K1_scaled_e (double x, out Result result);
                public static double Kn_scaled (int n, double x);
                public static int Kn_scaled_e (int n, double x, out Result result);
                public static int Kn_scaled_array (int nmin, int nmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double j0 (double x);
                public static int j0_e (double x, out Result result);
                public static double j1 (double x);
                public static int j1_e (double x, out Result result);
                public static double j2 (double x);
                public static int j2_e (double x, out Result result);
                public static double jl (int l, double x);
                public static int jl_e (int l, double x, out Result result);
                public static int jl_array (int lmax, double x, [CCode (array_length = false)] double[] result_array);
                public static int jl_steed_array (int lmax, double x, [CCode (array_length = false)] double[] jl_x_array);
                
                public static double y0 (double x);
                public static int y0_e (double x, out Result result);
                public static double y1 (double x);
                public static int y1_e (double x, out Result result);
                public static double y2 (double x);
                public static int y2_e (double x, out Result result);
                public static double yl (int l, double x);
                public static int yl_e (int l, double x, out Result result);
                public static int yl_array (int lmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double i0_scaled (double x);
                public static int i0_scaled_e (double x, out Result result);
                public static double i1_scaled (double x);
                public static int i1_scaled_e (double x, out Result result);
                public static double i2_scaled (double x);
                public static int i2_scaled_e (double x, out Result result);
                public static double il_scaled (int l, double x);
                public static int il_scaled_e (int l, double x, out Result result);
                public static int il_scaled_array (int lmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double k0_scaled (double x);
                public static int k0_scaled_e (double x, out Result result);
                public static double k1_scaled (double x);
                public static int k1_scaled_e (double x, out Result result);
                public static double k2_scaled (double x);
                public static int k2_scaled_e (double x, out Result result);
                public static double kl_scaled (int l, double x);
                public static int kl_scaled_e (int l, double x, out Result result);
                public static int kl_scaled_array (int lmax, double x, [CCode (array_length = false)] double[] result_array);
                
                public static double Jnu (double nu, double x);
                public static int Jnu_e (double nu, double x, out Result result);
                public static int sequence_Jnu_e (double nu, Mode mode, size_t size, [CCode (array_length = false)] double[] v);
                
                public static double Ynu (double nu, double x);
                public static int Ynu_e (double nu, double x, out Result result);
                
                public static double Inu (double nu, double x);
                public static int Inu_e (double nu, double x, out Result result);
                public static double Inu_scaled (double nu, double x);
                public static int Inu_scaled_e (double nu, double x, out Result result);
                
                public static double Knu (double nu, double x);
                public static int Knu_e (double nu, double x, out Result result);
                public static double lnKnu (double nu, double x);
                public static int lnKnu_e (double nu, double x, out Result result);
                public static double Knu_scaled (double nu, double x);
                public static int Knu_scaled_e (double nu, double x, out Result result);
                
                public static double zero_J0 (uint s);
                public static int zero_J0_e (uint s, out Result result);
                public static double zero_J1 (uint s);
                public static int zero_J1_e (uint s, out Result result);
                public static double zero_Jnu (double nu, uint s);
                public static int zero_Jnu_e (double nu, uint s, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_clausen.h")]
        namespace Clausen
        {
                public static double clausen (double x);
                public static int clausen_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_coulomb.h")]
        namespace Hydrogenic
        {
                public static double hydrogenicR_1 (double z, double r);
                public static int hydrogenicR_1_e (double z, double r, out Result result);
                public static double hydrogenicR (int n, int l, double z, double r);
                public static int hydrogenicR_e (int n, int l, double z, double r, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_coulomb_wave_", cheader_filename="gsl/gsl_sf_coulomb.h")]
        namespace CoulombWave
        {
                public static int FG_e (double eta, double x, double l_f, int k, out Result f, out Result fp, out Result g, out Result gp, out double exp_f, out double exp_g);
                public static int F_array (double l_min, int kmax, double eta, double x, [CCode (array_length = false)] double[] fc_array, out double f_exponent);
                public static int FG_array (double l_min, int kmax, double eta, double x, [CCode (array_length = false)] double[] fc_array, [CCode (array_length = false)] double[] gc_array, out double f_exponent, out double g_exponent);
                public static int FGp_array (double l_min, int kmax, double eta, double x, [CCode (array_length = false)] double[] fc_array, [CCode (array_length = false)] double[] fcp_array, [CCode (array_length = false)] double[] gc_array, [CCode (array_length = false)] double[] gcp_array, out double f_exponent, out double g_exponent);
                public static int sphF_array (double l_min, int kmax, double eta, double x, [CCode (array_length = false)] double[] fc_array, [CCode (array_length = false)] double[] f_exponent);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_coulomb_", cheader_filename="gsl/gsl_sf_coulomb.h")]
        namespace Coulomb
        {
                public static int CL_e (double l, double eta, out Result result);
                public static int CL_array (double lmin, int kmax, double eta, [CCode (array_length = false)] double[] cl);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_coupling_", cheader_filename="gsl/gsl_coupling.h")]
        namespace Coupling
        {
                public static double 3j (int two_ja, int two_jb, int two_jc, int two_ma, int two_mb, int two_mc);
                public static int 3j_e (int two_ja, int two_jb, int two_jc, int two_ma, int two_mb, int two_mc, out Result result);
                
                public static double 6j (int two_ja, int two_jb, int two_jc, int two_jd, int two_je, int two_jf);
                public static int 6j_e (int two_ja, int two_jb, int two_jc, int two_jd, int two_je, int two_jf, out Result result);

                public static double 9j (int two_ja, int two_jb, int two_jc, int two_jd, int two_je, int two_jf, int two_jg, int two_jh, int two_ji);
                public static int 9j_e (int two_ja, int two_jb, int two_jc, int two_jd, int two_je, int two_jf, int two_jg, int two_jh, int two_ji, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_dawson.h")]
        namespace Dawson
        {
                public static double dawson (double x);
                public static int dawson_e (double x, out Result result);
        }
        
        [CCode (cheader_filename="gsl/gsl_sf_debye.h")]
        namespace Debye 
        {
                [CCode (cname="gsl_sf_debye_1")]
                public static double D1 (double x);
                [CCode (cname="gsl_sf_debye_1_e")]
                public static int D1_e (double x, out Result result);
                [CCode (cname="gsl_sf_debye_2")]
                public static double D2 (double x);
                [CCode (cname="gsl_sf_debye_2_e")]
                public static int D2_e (double x, out Result result);
                [CCode (cname="gsl_sf_debye_3")]
                public static double D3 (double x);
                [CCode (cname="gsl_sf_debye_3_e")]
                public static int D3_e (double x, out Result result);
                [CCode (cname="gsl_sf_debye_4")]
                public static double D4 (double x);
                [CCode (cname="gsl_sf_debye_4_e")]
                public static int D4_e (double x, out Result result);
                [CCode (cname="gsl_sf_debye_5")]
                public static double D5 (double x);
                [CCode (cname="gsl_sf_debye_5_e")]
                public static int D5_e (double x, out Result result);
                [CCode (cname="gsl_sf_debye_6")]
                public static double D6 (double x);
                [CCode (cname="gsl_sf_debye_6_e")]
                public static int D6_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_dilog.h")]
        namespace Dilog
        {
                public static double dilog (double x);
                public static int dilog_e (double x, out Result result);
                public static int complex_dilog_e (double r, double theta, out Result result_re, out Result result_im);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_multiply_", cheader_filename="gsl/gsl_sf_elementary.h")]
        namespace Multiply
        {
                public static int e (double x, double y, out Result result);
                public static int err_e (double x, double dx, double y, double dy, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_ellint_", cheader_filename="gsl/gsl_sf_ellint.h")]
        namespace EllInt
        {
                public static double Kcomp (double k, Mode mode);
                public static int Kcomp_e (double k, Mode mode, out Result result);
                public static double Ecomp (double k, Mode mode);
                public static int Ecomp_e (double k, Mode mode, out Result result);
                public static double Pcomp (double k, double n, Mode mode);
                public static int Pcomp_e (double k, double n, Mode mode, out Result result);
                
                public static double F (double phi, double k, Mode mode);
                public static int F_e (double phi, double k, Mode mode, out Result result);
                public static double E (double phi, double k, Mode mode);
                public static int E_e (double phi, double k, Mode mode, out Result result);
                public static double P (double phi, double k, double n, Mode mode);
                public static int P_e (double phi, double k, double n, Mode mode, out Result result);
                public static double D (double phi, double k, double n, Mode mode);
                public static int D_e (double phi, double k, double n, Mode mode, out Result result);
                
                public static double RC (double x, double y, Mode mode);
                public static int RC_e (double x, double y, Mode mode, out Result result);
                public static double RD (double x, double y, double z, Mode mode);
                public static int RD_e (double x, double y, double z, Mode mode, out Result result);
                public static double RF (double x, double y, double z, Mode mode);
                public static int RF_e (double x, double y, double z, Mode mode, out Result result);
                public static double RJ (double x, double y, double z, double p, Mode mode);
                public static int RJ_e (double x, double y, double z, double p, Mode mode, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_elljac_", cheader_filename="gsl/gsl_elljac.h")]
        namespace EllJac
        {
                public static int e (double u, double m, out double sn, out double cn, out double dn);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_erf.h")]
        namespace Erf
        {
                public static double erf (double x);
                public static int erf_e (double x, out Result result);
                public static double erf_Z (double x);
                public static int erf_Z_e (double x, out Result result);
                public static double erf_Q (double x);
                public static int erf_Q_e (double x, out Result result);
                public static double erfc (double x);
                public static int erfc_e (double x, out Result result);
                public static double log_erfc (double x);
                public static int log_erfc_e (double x, out Result result);
                public static double hazard (double x);
                public static int hazard_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_exp.h")]
        namespace Exp
        {
                public static double exp (double x);
                public static int exp_e (double x, out Result result);
                public static int exp_e10_e (double x, out ResultE10 result);
                public static double exp_mult (double x, double y);
                public static int exp_mult_e (double x, double y, out Result result);
                public static int exp_mult_e10_e (double x, double y, out ResultE10 result);
                public static int exp_err_e (double x, double dx, out Result result);
                public static int exp_err_e10_e (double x, double dx, out ResultE10 result);
                public static int exp_mul_err_e (double x, double dx, double y, double dy, out Result result);
                public static int exp_mul_err_e10_e (double x, double dx, double y, double dy, out ResultE10 result);   
                public static double expm1 (double x);
                public static int expm1_e (double x, out Result result);
                public static double exprel (double x);
                public static int exprel_e (double x, out Result result);
                public static double exprel_2 (double x);
                public static int exprel_2_e (double x, out Result result);
                public static double exprel_n (int n, double x);
                public static int exprel_n_e (int n, double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_expint.h")]
        namespace Expint
        {
                public static double expint_E1 (double x);
                public static int expint_E1_e (double x, out Result result);
                public static double expint_E2 (double x);
                public static int expint_E2_e (double x, out Result result);
                public static double expint_En (int n, double x);
                public static int expint_En_e (int n, double x, out Result result);
                public static double expint_Ei (double x);
                public static int expint_Ei_e (double x, out Result result);
                public static double expint_Ei_3 (double x);
                public static int expint_Ei_3_e (double x, out Result result);
                public static double Shi (double x);
                public static int Shi_e (double x, out Result result);
                public static double Chi (double x);
                public static int Chi_e (double x, out Result result);
                public static double Si (double x);
                public static int Si_e (double x, out Result result);
                public static double Ci (double x);
                public static int Ci_e (double x, out Result result);
                public static double atanint (double x);
                public static double atanint_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_fermi_dirac_", cheader_filename="gsl/gsl_sf_fermi_dirach.h")]
        namespace FermiDirac
        {
                public static double m1 (double x);
                public static int m1_e (double x, out Result result);
                [CCode (cname="gsl_sf_fermi_dirac_0")]
                public static double F0 (double x);
                [CCode (cname="gsl_sf_fermi_dirac_0_e")]
                public static int F0_e (double x, out Result result);
                [CCode (cname="gsl_sf_fermi_dirac_1")]
                public static double F1 (double x);
                [CCode (cname="gsl_sf_fermi_dirac_1_e")]
                public static int F1_e (double x, out Result result);
                [CCode (cname="gsl_sf_fermi_dirac_2")]
                public static double F2 (double x);
                [CCode (cname="gsl_sf_fermi_dirac_2_e")]
                public static int F2_e (double x, out Result result);
                [CCode (cname="gsl_sf_fermi_dirac_int")]
                public static double Fint (int j, double x);
                [CCode (cname="gsl_sf_fermi_dirac_int_e")]
                public static int Fint_e (int j, double x, out Result result);
                public static double mhalf (double x);
                public static int mhalf_e (double x, out Result result);
                public static double half (double x);
                public static int half_e (double x, out Result result);
                public static double 3half (double x);
                public static int 3half_e (double x, out Result result);
                public static double inc_0 (double x, double b);
                public static int inc_0_e (double x, double b, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_gamma.h")]
        namespace GammaBeta
        {
                public static double gamma (double x);
                public static int gamma_e (double x, out Result result);
                public static double lngamma (double x);
                public static int lngamma_e (double x, out Result result);
                public static int lngamma_sgn_e (double x, out Result result, out double sgn);
                public static double gammastar (double x);
                public static int gammastar_e (double x, out Result result);
                public static double gammainv (double x);
                public static int gammainv_e (double x, out Result result);
                public static int lngamma_complex_e (double zr, double zi, out Result lnr, out Result arg);
                
                public static double fact (uint n);
                public static int fact_e (uint n, out Result result);
                public static double doublefact (uint n);
                public static int doublefact_e (uint n, out Result result);
                public static double lnfact (uint n);
                public static int lnfact_e (uint n, out Result result);
                public static double lndoublefact (uint n);
                public static int lndoublefact_e (uint n, out Result result);
                public static double choose (uint n, uint m);
                public static int choose_e (uint n, uint m, out Result result);
                public static double lnchoose (uint n, uint m);
                public static int lnchoose_e (uint n, uint m, out Result result);
                public static double taylorcoeff (int n, double x);
                public static int taylorcoeff_e (int n, double x, out Result result);
                
                public static double poch (double a, double x);
                public static int poch_e (double a, double x, out Result result);
                public static double lnpoch (double a, double x);
                public static int lnpoch_e (double a, double x, out Result result);
                public static int lnpoch_sgn_e (double a, double x, out Result result, out double sgn);
                public static double pochrel (double a, double x);
                public static int pochrel_e (double a, double x, out Result result);
                
                public static double gamma_inc (double a, double x);
                public static int gamma_inc_e (double a, double x, out Result result);
                public static double gamma_inc_Q (double a, double x);
                public static int gamma_inc_Q_e (double a, double x, out Result result);
                public static double gamma_inc_P (double a, double x);
                public static int gamma_inc_P_e (double a, double x, out Result result);

                public static double beta (double a, double b);
                public static int beta_e (double a, double b, out Result result);
                public static double lnbeta (double a, double b);
                public static int lnbeta_e (double a, double b, out Result result);
                
                public static double beta_inc (double a, double b, double x);
                public static int beta_inc_e (double a, double b, double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_gegenpoly_", cheader_filename="gsl/gsl_sf_gegenbauer.h")]
        namespace GegenPoly
        {
                [CCode (cname="gsl_sf_gegenpoly_1")]
                public static double C1 (double lambda, double x);
                [CCode (cname="gsl_sf_gegenpoly_1_e")]
                public static double C1_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_gegenpoly_2")]
                public static double C2 (double lambda, double x);
                [CCode (cname="gsl_sf_gegenpoly_2_e")]
                public static double C2_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_gegenpoly_3")]
                public static double C3 (double lambda, double x);
                [CCode (cname="gsl_sf_gegenpoly_3_e")]
                public static double C3_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_gegenpoly_n")]
                public static double Cn (double lambda, double x);
                [CCode (cname="gsl_sf_gegenpoly_n_e")]
                public static double Cn_e (double lambda, double x, out Result result);
                public static int array (int nmax, double lambda, double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_hyperg_", cheader_filename="gsl/gsl_sf_hyperg.h")]
        namespace Hyperg
        {
                public static double 0F1 (double c, double x);
                public static int 0F1_e (double c, double x, out Result result);
                public static double 1F1_int (int m, int n, double x);
                public static int 1F1_int_e (int m, int n, double x, out Result result);
                public static double 1F1 (double a, double b, double x);
                public static int 1F1_e (double a, double b, double x, out Result result);
                public static double U_int (int m, int n, double x);
                public static int U_int_e (int m, int n, double x, out Result result);
                public static int U_int_e10_e (int m, int n, double x, out ResultE10 result);
                public static double U (double a, double b, double x);
                public static int U_e (double a, double b, double x, out Result result);
                public static int U_e10_e (double a, double b, double x, out ResultE10 result);
                public static double 2F1 (double a, double b, double c, double x);
                public static int 2F1_e (double a, double b, double c, double x, out Result result);
                public static double 2F1_conj (double aR, double aI, double c, double x);
                public static int 2F1_conj_e (double aR, double aI, double c, double x, out Result result);
                public static double 2F1_renorm (double a, double b, double c, double x);
                public static int 2F1_renorm_e (double a, double b, double c, double x, out Result result);
                public static double 2F1_conj_renorm (double aR, double aI, double c, double x);
                public static int 2F1_conj_renorm_e (double aR, double aI, double c, double x, out Result result);
                public static double 2F0 (double a, double b, double x);
                public static int 2F0_e (double a, double b, double x, out Result result);
        }
        
        [CCode (cheader_filename="gsl/gsl_sf_laguerre.h")]
        namespace Laguerre
        {
                [CCode (cname="gsl_sf_laguerre_1")]
                public static double L1 (double a, double x);
                [CCode (cname="gsl_sf_laguerre_1_e")]
                public static double L1_e (double a, double x, out Result result);
                [CCode (cname="gsl_sf_laguerre_2")]
                public static double L2 (double a, double x);
                [CCode (cname="gsl_sf_laguerre_2_e")]
                public static double L2_e (double a, double x, out Result result);
                [CCode (cname="gsl_sf_laguerre_3")]
                public static double L3 (double a, double x);
                [CCode (cname="gsl_sf_laguerre_3_e")]
                public static double L3_e (double a, double x, out Result result);
                [CCode (cname="gsl_sf_laguerre_n")]
                public static double Ln (int n, double a, double x);
                [CCode (cname="gsl_sf_laguerre_n_e")]
                public static double Ln_e (int n, double a, double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_lambert_", cheader_filename="gsl/gsl_sf_lambert.h")]
        namespace Lambert
        {
                public static double W0 (double x);
                public static int W0_e (double x, out Result result);
                public static double Wm1 (double x);
                public static int Wm1_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_legendre_", cheader_filename="gsl/gsl_sf_legendre.h")]
        namespace LegendrePoly
        {
                public static double P1 (double x);
                public static int P1_e (double x, out Result result);
                public static double P2 (double x);
                public static int P2_e (double x, out Result result);
                public static double P3 (double x);
                public static int P3_e (double x, out Result result);
                public static double Pl (int l, double x);
                public static int Pl_e (int l, double x, out Result result);
                public static int Pl_array (int lmax, double x, [CCode (array_length = false)] double[] result_array);
                public static int Pl_deriv_array (int lmax, double x, [CCode (array_length = false)] double[] result_array, [CCode (array_length = false)] double[] result_deriv_array);
                public static double Q0 (double x);
                public static int Q0_e (double x, out Result result);           
                public static double Q1 (double x);
                public static int Q1_e (double x, out Result result);           
                public static double Ql (int l, double x);
                public static int Ql_e (int l, double x, out Result result);
                
                public static double Plm (int l, int m, double x);
                public static int Plm_e (int l, int m, double x, out Result result);
                public static int Plm_array (int lmax, int m, double x, [CCode (array_length = false)] double[] result_array);
                public static int Plm_deriv_array (int lmax, int m, double x, double[] result_array, [CCode (array_length = false)] double[] result_deriv_array);
                public static double sphPlm (int l, int m, double x);
                public static int sphPlm_e (int l, int m, double x, out Result result);
                public static int sphPlm_array (int lmax, int m, double x, [CCode (array_length = false)] double[] result_array);
                public static int sphPlm_deriv_array (int lmax, int m, double x, double[] result_array, [CCode (array_length = false)] double[] result_deriv_array);
                public static int array_size (int lmax, int m);
                
                [CCode (cname="gsl_sf_conicalP_half")]
                public static double conicalP_half (double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_half_e")]
                public static int conicalP_half_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_conicalP_mhalf")]
                public static double conicalP_mhalf (double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_mhalf_e")]
                public static int conicalP_mhalf_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_conicalP_0")]
                public static double conicalP_0 (double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_0_e")]
                public static int conicalP_0_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_conicalP_1")]
                public static double conicalP_1 (double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_1_e")]
                public static int conicalP_1_e (double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_conicalP_sph_reg")]
                public static double conicalP_sph_reg (int l, double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_sph_reg_e")]
                public static int conicalP_sph_reg_e (int l, double lambda, double x, out Result result);
                [CCode (cname="gsl_sf_conicalP_cyl_reg")]
                public static double conicalP_cyl_reg (int m, double lambda, double x);
                [CCode (cname="gsl_sf_conicalP_cyl_reg_e")]
                public static int conicalP_cyl_reg_e (int m, double lambda, double x, out Result result);
                
                public static double H3d_0 (double lambda, double eta);
                public static int H3d_0_e (double lambda, double eta, out Result result);
                public static double H3d_1 (double lambda, double eta);
                public static int H3d_1_e (double lambda, double eta, out Result result);
                public static double H3d (int l, double lambda, double eta);
                public static int H3d_e (int l, double lambda, double eta, out Result result);
                public static int H3d_array (int lmax, double lambda, double eta, [CCode (array_length = false)] double[] result_array);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_log.h")]
        namespace Log
        {
                public static double log (double x);
                public static int log_e (double x, out Result result);
                public static double log_abs (double x);
                public static int log_abs_e (double x, out Result result);
                public static int complex_log_e (double zr, double zi, out Result result, out Result theta);
                public static double log_1plusx (double x);
                public static int log_1plusx_e (double x, out Result result);
                public static double log_1plusx_mx (double x);
                public static int log_1plusx_mx_e (double x, out Result result);
        }
        
        [Compact]
        [CCode (cname="gsl_sf_mathieu_workspace", cprefix="gsl_sf_mathieu_", cheader_filename="gsl/gsl_sf_mathieu.h")]
        public class MathieuWorkspace
        {
                public size_t size;
                public size_t even_order;
                public size_t odd_order;
                public int extra_values;
                public double qa;
                public double qb;
                public double* aa;
                public double* bb;
                public double* dd;
                public double* ee;
                public double* tt;
                public double* e2;
                public double* zz;
                public Vector eval;
                public Matrix evec;
                public EigenSymmvWorkspace wmat;
                
                public static int a_array (int order_min, int order_max, double qq, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
                public static int b_array (int order_min, int order_max, double qq, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
                public static int a (int order, double qq, out Result result);
                public static int b (int order, double qq, out Result result);
                public static int a_coeff (int order, double qq, double aa, [CCode (array_length = false)] double[] coeff);
                public static int b_coeff (int order, double qq, double aa, [CCode (array_length = false)] double[] coeff);
                
                [CCode (cname="gsl_sf_mathieu_alloc")]
                public MathieuWorkspace (size_t nn, double qq);

                public static int ce (int order, double qq, double zz, out Result result);
                public static int se (int order, double qq, double zz, out Result result);
                public static int ce_array (int nmin, int nmax, double qq, double zz, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
                public static int se_array (int nmin, int nmax, double qq, double zz, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
                
                public static int Mc (int kind, int order, double qq, double zz, out Result result);
                public static int Ms (int kind, int order, double qq, double zz, out Result result);
                public static int Mc_array (int kind, int nmin, int nmax, double qq, double zz, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
                public static int Ms_array (int kind, int nmin, int nmax, double qq, double zz, MathieuWorkspace work, [CCode (array_length = false)] double[] result_array);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_pow_int.h")]
        namespace Pow
        {
                public static double pow_int (double x, int n);
                public static int pow_int_e (double x, int n, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_psi.h")]
        namespace Psi
        {
                public static double psi_int (int n);
                public static int psi_int_e (int n, out Result result);
                public static double psi (double x);
                public static int psi_e (double x, out Result result);
                public static double psi_1piy (double y);
                public static int psi_1piy_e (double y, out Result result);

                public static double psi_1_int (int n);
                public static int psi_1_int_e (int n, out Result result);
                public static double psi_1 (double x);
                public static int psi_1_e (double x, out Result result);
                
                public static double psi_n (int n, double x);
                public static int psi_e_n (int n, double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_synchrotron.h")]
        namespace Synchrotron
        {
                public static double synchrotron_1 (double x);
                public static int synchrotron_1_e (double x, out Result result);
                public static double synchrotron_2 (double x);
                public static double synchrotron_2_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_transport.h")]
        namespace Transport
        {
                public static double transport_2 (double x);
                public static int transport_2_e (double x, out Result result);
                public static double transport_3 (double x);
                public static int transport_3_e (double x, out Result result);
                public static double transport_4 (double x);
                public static int transport_4_e (double x, out Result result);
                public static double transport_5 (double x);
                public static int transport_5_e (double x, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_trig.h")]
        namespace Trig
        {
                public static double sin (double x);
                public static int sin_e (double x, out Result result);
                public static double cos (double x);
                public static int cos_e (double x, out Result result);
                public static double hypot (double x, double y);
                public static int hypot_e (double x, double y, out Result result);
                public static double sinc (double x);
                public static int sinc_e (double x, out Result result);
                public static double complex_sin_e (double zr, double zi, out Result szr, out Result szi);
                public static double complex_cos_e (double zr, double zi, out Result czr, out Result czi);
                public static double complex_logsin_e (double zr, double zi, out Result lszr, out Result lszi);
                public static double lnsinh (double x);
                public static int lnsinh_e (double x, out Result result);
                public static double lncosh (double x);
                public static int lncosh_e (double x, out Result result);
                public static int polar_to_rect (double r, double theta, out Result x, out Result y);
                public static int rect_to_polar (double x, double y, out Result r, out Result theta);
                public static double angle_restrict_symm (double theta);
                public static int angle_restrict_symm_e (out double theta);
                public static double angle_restrict_pos (double theta);
                public static int angle_restrict_pos_e (out double theta);
                public static int sin_err_e (double x, double dx, out Result result);
                public static int cos_err_e (double x, double dx, out Result result);
        }
        
        [CCode (lower_case_cprefix="gsl_sf_", cheader_filename="gsl/gsl_sf_zeta.h")]
        namespace Zeta
        {
                public static double zeta_int (int n);
                public static int zeta_int_e (int n, out Result result);
                public static double zeta (double s);
                public static int zeta_e (double s, out Result result);
                public static double zetam1_int (int n);
                public static int zetam1_int_e (int n, out Result result);
                public static double zetam1 (double s);
                public static int zetam1_e (double s, out Result result);
                public static double hzeta (double s, double q);
                public static int hzeta_e (double s, double q, out Result result);
                public static double eta_int (int n);
                public static int eta_int_e (int n, out Result result);
                public static double eta (double s);
                public static int eta_e (double s, out Result result);
        }
        
        
        /*
         * Blocks, Vectors and Matrices
         */
        [Compact]
        [CCode (cname="gsl_block", cheader_filename="gsl/gsl_block_double.h")]
        public class Block
        {
                public size_t size;
                public double* data;
                
                [CCode (cname="gsl_block_alloc")]
                public Block (size_t n);
                [CCode (cname="gsl_block_calloc")]
                public Block.with_zeros (size_t n);
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Block b, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
        }
        
        [Compact]
        [CCode (cname="gsl_block_complex", cheader_filename="gsl/gsl_block_complex_double.h")]
        public class BlockComplex
        {
                public size_t size;
                public double* data;
                
                [CCode (cname="gsl_block_complex_alloc")]
                public BlockComplex (size_t n);
                [CCode (cname="gsl_block_complex_calloc")]
                public BlockComplex.with_zeros (size_t n);
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, BlockComplex b, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
        }
        
        [SimpleType]
        [CCode (cname="gsl_vector_view", cheader_filename="gsl/gsl_vector_double.h")]
        public struct VectorView
        {
                public unowned Vector vector;
                
                public static VectorView array (double[] v);
                public static VectorView array_with_stride ([CCode (array_length = false)] double[] v, size_t stride, size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_vector", cheader_filename="gsl/gsl_vector_double.h")]
        public class Vector
        {
                public size_t size;
                public size_t stride;
                public double* data;
                public Block block;
                public int owner;
                
                [CCode (cname="gsl_vector_alloc")]
                public Vector (size_t n);
                [CCode (cname="gsl_vector_calloc")]
                public Vector.with_zeros (size_t n);
                [CCode (cname="gsl_vector_alloc_from_block")]
                public Vector.from_block (Block b, size_t offset, size_t n, size_t stride);
                [CCode (cname="gsl_vector_alloc_from_vector")]
                public Vector.from_vector (Vector v, size_t offset, size_t n, size_t stride);
                
                public double @get (size_t i);
                public void @set (size_t i, double x);
                public double* ptr (size_t i);
                
                public void set_all (double x);
                public void set_zero ();
                public void set_basis (size_t i);
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Vector v, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
                
                public VectorView subvector (size_t offset, size_t n);
                public VectorView subvector_with_stride (size_t offset, size_t stride, size_t n);
                
                public int memcpy (Vector src);
                public int swap (Vector w);
                
                public int swap_elements (size_t i, size_t j);
                public int reverse ();
                
                public int add (Vector b);
                public int sub (Vector b);
                public int mul (Vector b);
                public int div (Vector b);
                public int scale (double x);
                public int add_constant (double x);
                
                public double max ();
                public double min ();
                public void minmax (out double min_out, out double max_out);
                public size_t max_index ();
                public size_t min_index ();
                public void minmax_index (out size_t imin, out size_t imax);
                
                public bool isnull ();
                public bool ispos ();
                public bool isneg ();
                public bool isnonneg ();
        }

        [SimpleType]
        [CCode (cname="gsl_vector_complex_view", cheader_filename="gsl/gsl_vector_complex_double.h")]
        public struct VectorComplexView
        {
                public unowned VectorComplex vector;
                
                public static VectorComplexView array (double[] v);
                public static VectorComplexView array_with_stride ([CCode (array_length = false)] double[] v, size_t stride, size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_vector_complex", cheader_filename="gsl/gsl_vector_complex_double.h")]
        public class VectorComplex
        {
                public size_t size;
                public size_t stride;
                public double* data;
                public BlockComplex block;
                public int owner;
                
                [CCode (cname="gsl_vector_complex_alloc")]
                public VectorComplex (size_t n);
                [CCode (cname="gsl_vector_complex_calloc")]
                public VectorComplex.with_zeros (size_t n);
                [CCode (cname="gsl_vector_complex_alloc_from_block")]
                public VectorComplex.from_block (BlockComplex b, size_t offset, size_t n, size_t stride);
                [CCode (cname="gsl_vector_complex_alloc_from_vector")]
                public VectorComplex.from_vector (VectorComplex v, size_t offset, size_t n, size_t stride);
                
                public Complex @get (size_t i);
                public void @set (size_t i, Complex x);
                public Complex* ptr (size_t i);
                
                public void set_all (Complex x);
                public void set_zero ();
                public void set_basis (size_t i);
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, VectorComplex v, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
                
                public VectorComplexView subvector (size_t i, size_t n);
                public VectorComplexView subvector_with_stride (size_t i, size_t stride, size_t n);
                public VectorView complex_real ();
                public VectorView complex_imag ();
                
                public int memcpy (VectorComplex src);
                public int swap (VectorComplex w);
                
                public int swap_elements (size_t i, size_t j);
                public int reverse ();
                
                public int add (VectorComplex b);
                public int sub (VectorComplex b);
                public int mul (VectorComplex b);
                public int div (VectorComplex b);
                public int scale (double x);
                public int add_constant (double x);
                
                public double max ();
                public double min ();
                public void minmax (out double min_out, out double max_out);
                public size_t max_index ();
                public size_t min_index ();
                public void minmax_index (out size_t imin, out size_t imax);
                
                public bool isnull ();
                public bool ispos ();
                public bool isneg ();
                public bool isnonneg ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_matrix_view", cheader_filename="gsl/gsl_matrix_double.h")]
        public struct MatrixView
        {
                public unowned Matrix matrix;
                
                public static MatrixView array ([CCode (array_length = false)] double[] v, size_t n1, size_t n2);
                public static MatrixView array_with_tda ([CCode (array_length = false)] double[] v, size_t n1, size_t n2, size_t tda);
                public static MatrixView vector (Vector v, size_t n1, size_t n2);
                public static MatrixView vectr_with_tda (Vector v, size_t n1, size_t n2, size_t tda);
        }
        
        [Compact]
        [CCode (cname="gsl_matrix", cheader_filename="gsl/gsl_matrix_double.h")]
        public class Matrix
        {
                public size_t size1;
                public size_t size2;
                public size_t tda;
                public double* data;
                public Block block;
                public int owner;
                
                [CCode (cname="gsl_matrix_alloc")]
                public Matrix (size_t n1, size_t n2);
                [CCode (cname="gsl_matrix_calloc")]
                public Matrix.with_zeros (size_t n1, size_t n2);
                [CCode (cname="gsl_matrix_alloc_from_block")]
                public Matrix.from_block (Block b, size_t offset, size_t n1, size_t n2, size_t d2);
                [CCode (cname="gsl_matrix_alloc_from_matrix")]
                public Matrix.from_matrix (Matrix m, size_t k1, size_t k2, size_t n1, size_t n2);

                public Vector alloc_row_from_matrix (size_t i);
                public Vector alloc_col_from_matrix (size_t j);
                                
                public double @get (size_t i, size_t j);
                public void @set (size_t i, size_t j, double x);
                public double* ptr (size_t i, size_t j);
                
                public void set_all (double x);
                public void set_zero ();
                public void set_identity ();
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Matrix m, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
                
                public MatrixView submatrix (size_t k, size_t k2, size_t n1, size_t n2);
                public VectorView row (size_t i);
                public VectorView column (size_t j);
                public VectorView subrow (size_t i, size_t offset, size_t n);
                public VectorView subcolumn (size_t i, size_t offset, size_t n);
                public VectorView diagonal ();
                public VectorView subdiagonal (size_t k);
                public VectorView superdiagonal (size_t k);
                
                public int memcpy (Matrix src);
                public int swap (Matrix m2);
                
                public static int get_row (Vector v, Matrix m, size_t i);
                public static int get_col (Vector v, Matrix m, size_t j);
                public int set_row (size_t i, Vector v);
                public int set_col (size_t j, Vector v);
                
                public int swap_rows (size_t i, size_t j);
                public int swap_columns (size_t i, size_t j);
                public int swap_rowcol (size_t i, size_t j);
                public int transpose_memcpy (Matrix src);
                public int transpose ();
                
                public int add (Matrix b);
                public int sub (Matrix b);
                public int mul_elements (Matrix b);
                public int div_elements (Matrix b);
                public int scale (double x);
                public int add_constant (double x);
                public int add_diagonal (double x);
                
                public double max ();
                public double min ();
                public void minmax (out double min_out, out double max_out);
                public void max_index (out size_t imax, out size_t jmax);
                public void min_index (out size_t imin, out size_t jmin);
                public void minmax_index (out size_t imin, out size_t jmin, out size_t imax, out size_t jmax);
                
                public bool isnull ();
                public bool ispos ();
                public bool isneg ();
                public bool isnonneg ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_matrix_complex_view", cheader_filename="gsl/gsl_matrix_complex_double.h")]
        public struct MatrixComplexView
        {
                public unowned MatrixComplex matrix;
                
                public static MatrixComplexView array ([CCode (array_length = false)] double[] v, size_t n1, size_t n2);
                public static MatrixComplexView array_with_tda ([CCode (array_length = false)] double[] v, size_t n1, size_t n2, size_t tda);
                public static MatrixComplexView vector (VectorComplex v, size_t n1, size_t n2);
                public static MatrixComplexView vectr_with_tda (VectorComplex v, size_t n1, size_t n2, size_t tda);
        }

        [Compact]
        [CCode (cname="gsl_matrix_complex", cheader_filename="gsl/gsl_matrix_complex_double.h")]
        public class MatrixComplex
        {
                public size_t size1;
                public size_t size2;
                public size_t tda;
                public double* data;
                public BlockComplex block;
                public int owner;
                
                [CCode (cname="gsl_matrix_complex_alloc")]
                public MatrixComplex (size_t n1, size_t n2);
                [CCode (cname="gsl_matrix_complex_calloc")]
                public MatrixComplex.with_zeros (size_t n1, size_t n2);
                [CCode (cname="gsl_matrix_complex_alloc_from_block")]
                public MatrixComplex.from_block (BlockComplex b, size_t offset, size_t n1, size_t n2, size_t d2);
                [CCode (cname="gsl_matrix_complex_alloc_from_matrix")]
                public MatrixComplex.from_matrix (MatrixComplex m, size_t k1, size_t k2, size_t n1, size_t n2);

                public VectorComplex alloc_row_from_matrix (size_t i);
                public VectorComplex alloc_col_from_matrix (size_t j);          

                public double @get (size_t i, size_t j);
                public void @set (size_t i, size_t j, double x);
                public double* ptr (size_t i, size_t j);
                
                public void set_all (double x);
                public void set_zero ();
                public void set_identity ();
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, MatrixComplex m, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
                
                public MatrixComplexView submatrix (size_t k, size_t k2, size_t n1, size_t n2);
                public VectorComplexView row (size_t i);
                public VectorComplexView column (size_t j);
                public VectorComplexView subrow (size_t i, size_t offset, size_t n);
                public VectorComplexView subcolumn (size_t i, size_t offset, size_t n);
                public VectorComplexView diagonal ();
                public VectorComplexView subdiagonal (size_t k);
                public VectorComplexView superdiagonal (size_t k);
                
                public int memcpy (MatrixComplex src);
                public int swap (MatrixComplex m2);
                
                public static int get_row (VectorComplex v, MatrixComplex m, size_t i);
                public static int get_col (VectorComplex v, MatrixComplex m, size_t j);
                public int set_row (size_t i, VectorComplex v);
                public int set_col (size_t j, VectorComplex v);
                
                public int swap_rows (size_t i, size_t j);
                public int swap_columns (size_t i, size_t j);
                public int swap_rowcol (size_t i, size_t j);
                public int transpose_memcpy (MatrixComplex src);
                public int transpose ();
                
                public int add (MatrixComplex b);
                public int sub (MatrixComplex b);
                public int mul_elements (MatrixComplex b);
                public int div_elements (MatrixComplex b);
                public int scale (double x);
                public int add_constant (double x);
                public int add_diagonal (double x);
                
                public double max ();
                public double min ();
                public void minmax (out double min_out, out double max_out);
                public void max_index (out size_t imax, out size_t jmax);
                public void min_index (out size_t imin, out size_t jmin);
                public void minmax_index (out size_t imin, out size_t jmin, out size_t imax, out size_t jmax);
                
                public bool isnull ();
                public bool ispos ();
                public bool isneg ();
                public bool isnonneg ();
        }
        
        
        /*
         * Permutations
         */
        [Compact]
        [CCode (cname="gsl_permutation", cheader_filename="gsl/gsl_permutation.h")]
        public class Permutation
        {
                public size_t size;
                public size_t* data;
                
                [CCode (cname="gsl_permutation_alloc")]
                public Permutation (size_t n);
                [CCode (cname="gsl_permutation_calloc")]
                public Permutation.with_zeros (size_t n);
                
                public void init ();
                public int memcpy (Permutation src);
                
                public size_t @get (size_t i);
                public int swap (size_t i, size_t j);
                
                public int valid ();
                
                public void reverse ();
                public int inverse (Permutation p);
                public int next ();
                public int prev ();
                
                public int mul (Permutation pa, Permutation pb);
                        
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Permutation p, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
                
                public int linear_to_canonical (Permutation p);
                public int canonical_to_linear (Permutation q);
                public size_t inversions ();
                public size_t linear_cycles ();
                public size_t canonical_cycles ();
        }
        
        [CCode (lower_case_cprefix="gsl_", cheader_filename="gsl/gsl_permute_double.h")]
        namespace Permute
        {
                public static int permute (size_t* p, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int permute_inverse (size_t* p, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
        }
        
        [CCode (cheader_filename="gsl/gsl_permute_complex_double.h")]
        namespace PermuteComplex
        {
                [CCode (cname="gsl_permute_complex")]
                public static int permute (size_t* p, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                [CCode (cname="gsl_permute_complex_inverse")]
                public static int permute_inverse (size_t* p, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
        }
        
        [CCode (cheader_filename="gsl/gsl_permute_vector_double.h")]
        namespace PermuteVector
        {
                [CCode (cname="gsl_permute_vector")]
                public static int permute (Permutation p, Vector v);
                [CCode (cname="gsl_permute_vector_inverse")]
                public static int permute_inverse (Permutation p, Vector v);
        }

        [CCode (cheader_filename="gsl/gsl_permute_vector_complex_double.h")]
        namespace PermuteVectorComplex
        {
                [CCode (cname="gsl_permute_vector_complex")]
                public static int permute (Permutation p, Vector v);
                [CCode (cname="gsl_permute_vector_complex_inverse")]
                public static int permute_inverse (Permutation p, Vector v);
        }


        /*
         * Combinations
         */
        [Compact]
        [CCode (cname="gsl_combination", cheader_filename="gsl/gsl_combination.h")]
        public class Combination
        {
                public size_t n;
                public size_t k;
                public size_t* data;
                
                [CCode (cname="gsl_combination_alloc")]
                public Combination (size_t n, size_t k);
                [CCode (cname="gsl_combination_calloc")]
                public Combination.with_zeros (size_t n, size_t k);

                public void init_first ();
                public void init_last ();
                public int memcpy (Combination src);
                
                public size_t @get (size_t i);
                
                public int valid ();
                
                public int next ();
                public int prev ();
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Combination c, string format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
        }
        
        
        /*
         * Sorting
         */
        [CCode (lower_case_cprefix="gsl_sort_", cheader_filename="gsl/gsl_sort_double.h")]
        namespace Sort
        {
                [CCode (cname="gsl_sort")]
                public static void sort ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                [CCode (cname="gsl_sort_index")]
                public static void sort_index ([CCode (array_length = false)] size_t[] p, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int smallest ([CCode (array_length = false)] double[] dest, size_t k, [CCode (array_length = false)] double[] src, size_t stride, size_t n);
                public static int smallest_index ([CCode (array_length = false)] size_t[] p, size_t k, [CCode (array_length = false)] double[] src, size_t stride, size_t n);
                public static int largest ([CCode (array_length = false)] double[] dest, size_t k, [CCode (array_length = false)] double[] src, size_t stride, size_t n);
                public static int largest_index ([CCode (array_length = false)] size_t[] p, size_t k, [CCode (array_length = false)] double[] src, size_t stride, size_t n);
        }
        
        [CCode (lower_case_cprefix="gsl_sort_vector_", cheader_filename="gsl/gsl_sort_vector_double.h")]
        namespace SortVector
        {
                [CCode (cname="gsl_sort_vector")]
                public static void sort (Vector v);
                [CCode (cname="gsl_sort_vector_index")]
                public static int sort_index (Permutation p, Vector v);
                public static int smallest ([CCode (array_length = false)] double[] dest, size_t k, Vector v);
                public static int smallest_index ([CCode (array_length = false)] size_t[] p, size_t k, Vector v);
                public static int largest ([CCode (array_length = false)] double[] dest, size_t k, Vector v);
                public static int largest_index ([CCode (array_length = false)] size_t[] p, size_t k, Vector v);
        }
        
        
        /*
         * Linear Algebra
         */
        [CCode (lower_case_cprefix="gsl_linalg_", cheader_filename="gsl/gsl_linalg.h")]
        namespace LinAlg
        {
                public static int LU_decomp (Matrix A, Permutation p, out int signum);
                public static int complex_LU_decomp (MatrixComplex A, Permutation p, out int signum);
                public static int LU_solve (Matrix LU, Permutation p, Vector b, Vector x);
                public static int complex_LU_solve (MatrixComplex LU, Permutation p, VectorComplex b, VectorComplex x);
                public static int LU_svx (Matrix LU, Permutation p, Vector x);
                public static int complex_LU_svx (MatrixComplex LU, Permutation p, VectorComplex x);
                public static int LU_refine (Matrix A, Matrix LU, Permutation p, Vector b, Vector x, Vector residual);
                public static int complex_LU_refine (MatrixComplex A, MatrixComplex LU, Permutation p, VectorComplex b, VectorComplex x, VectorComplex residual);
                public static int LU_invert (Matrix LU, Permutation p, Matrix inverse);
                public static int complex_LU_invert (MatrixComplex LU, Permutation p, Matrix inverse);
                public static double LU_det (Matrix LU, int signum);
                public static Complex complex_LU_det (MatrixComplex LU, int signum);
                public static double LU_lndet (Matrix LU);
                public static double complex_LU_lndet (MatrixComplex LU);
                public static int LU_sgndet (Matrix LU, int signum);
                public static Complex complex_LU_sgndet (MatrixComplex LU, int signum);
                
                public static int QR_decomp (Matrix A, Vector tau);
                public static int QR_solve (Matrix QR, Vector tau, Vector b, Vector x);
                public static int QR_svx (Matrix QR, Vector tau, Vector x);
                public static int QR_lssolve (Matrix QR, Vector tau, Vector b, Vector x, Vector residual);
                public static int QR_QTvec (Matrix QR, Vector tau, Vector v);
                public static int QR_Qvec (Matrix QR, Vector tau, Vector v);
                public static int QR_QTmat (Matrix QR, Vector tau, Matrix A);
                public static int QR_Rsolve (Matrix QR, Vector b, Vector x);
                public static int QR_Rsvx (Matrix QR, Vector x);
                public static int QR_unpack (Matrix QR, Vector tau, Matrix Q, Matrix R);
                public static int QR_QRsolve (Matrix Q, Matrix R, Vector b, Vector x);
                public static int QR_update (Matrix Q, Matrix R, Vector w, Vector v);
                public static int R_solve (Matrix R, Vector b, Vector x);
                public static int R_svx (Matrix R, Vector x);
                
                public static int QRPT_decomp (Matrix A, Vector tau, Permutation p, out int signum, Vector norm);
                public static int QRPT_decomp2 (Matrix A, Matrix q, Matrix r, Vector tau, Permutation p, out int signum, Vector norm);
                public static int QRPT_solve (Matrix QR, Vector tau, Permutation p, Vector b, Vector x);
                public static int QRPT_svx (Matrix QR, Vector tau, Permutation p, Vector x);
                public static int QRPT_QRsolve (Matrix Q, Matrix R, Permutation p, Vector b, Vector x);
                public static int QRPT_update (Matrix Q, Matrix R, Permutation p, Vector u, Vector v);
                public static int QRPT_Rsolve (Matrix QR, Permutation p, Vector b, Vector x);
                public static int QRPT_Rsvx (Matrix QR, Permutation p, Vector x);
                
                public static int SV_decomp (Matrix A, Matrix V, Vector S, Vector work);
                public static int SV_decomp_mod (Matrix A, Matrix X, Matrix V, Vector S, Vector work);
                public static int SV_decomp_jacobi (Matrix A, Matrix V, Vector S);
                public static int SV_solve (Matrix U, Matrix V, Vector S, Vector b, Vector x);
                
                public static int cholesky_decomp (Matrix A);
                public static int complex_cholesky_decomp (MatrixComplex A);
                public static int cholesky_solve (Matrix cholesky, Vector b, Vector x);
                public static int complex_cholesky_solve (MatrixComplex cholesky, VectorComplex b, VectorComplex x);
                public static int cholesky_svx (Matrix cholesky, Vector x);
                public static int complex_cholesky_svx (MatrixComplex cholesky, VectorComplex x);
                
                public static int symmtd_decomp (Matrix A, Vector tau);
                public static int symmtd_unpack (Matrix A, Vector tau, Matrix Q, Vector diag, Vector subdiag);
                public static int symmtd_unpack_T (Matrix A, Vector diag, Vector subdiag);
                
                public static int hermtd_decomp (MatrixComplex A, VectorComplex tau);
                public static int hermtd_unpack (MatrixComplex A, VectorComplex tau, MatrixComplex Q, Vector diag, Vector subdiag);
                public static int hermtd_unpack_T (MatrixComplex A, Vector diag, Vector subdiag);
                
                public static int hessenberg_decomp (Matrix A, Vector tau);
                public static int hessenberg_unpack (Matrix H, Vector tau, Matrix U);
                public static int hessenberg_unpack_accum (Matrix H, Vector tau, Matrix V);
                public static int hessenberg_set_zero (Matrix H);
                
                public static int hesstri_decomp (Matrix A, Matrix B, Matrix U, Matrix V, Vector work);
                
                public static int bidiag_decomp (Matrix A, Vector tau_U, Vector tau_V);
                public static int bidiag_unpack (Matrix A, Vector tau_U, Matrix U, Vector tau_V, Matrix V, Vector diag, Vector superdiag);
                public static int bidiag_unpack2 (Matrix A, Vector tau_U, Vector tau_V, Matrix V);
                public static int bidiag_unpack_B (Matrix A, Vector diag, Vector superdiag);
                
                public static int householder_tansform (Vector v);
                public static Complex complex_householder_transform (VectorComplex V);
                public static int householder_hm (double tau, Vector v, Matrix A);
                public static int complex_householder_hm (Complex tau, VectorComplex V, MatrixComplex A);
                public static int householder_mh (double tau, Vector v, Matrix A);
                public static int complex_householder_mh (Complex tau, VectorComplex V, MatrixComplex A);
                public static int householder_hv (double tau, Vector v, Vector w);
                public static int complex_householder_hv (Complex tau, VectorComplex V, VectorComplex w);
                
                public static int HH_solve (Matrix A, Vector b, Vector x);
                public static int HH_svx (Matrix A, Vector x);
                
                public static int solve_tridiag (Vector diag, Vector e, Vector f, Vector b, Vector x);
                public static int solve_symm_tridiag (Vector diag, Vector e, Vector b, Vector x);
                public static int solve_cyc_tridiag (Vector diag, Vector e, Vector f, Vector b, Vector x);
                public static int solve_symm_cyc_tridiag (Vector diag, Vector e, Vector b, Vector x);
                
                public static int balance_matrix (Matrix A, Vector D);
        }
        
        
        /*
         * Eigensystems
         */
        [CCode (cname="gsl_eigen_sort_t", cprefix="GSL_EIGEN_SORT_", cheader_filename="gsl/gsl_eigen.h")]
        public enum EigenSortType
        {
                VAL_ASC,
                VAL_DESC,
                ABS_ASC,
                ABS_DESC                
        }
        
        [Compact]
        [CCode (cname="gsl_eigen_symm_workspace", free_function="gsl_eigen_symm_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenSymmWorkspace
        {
                public size_t size;
                public double* d;
                public double* sd;
                
                [CCode (cname="gsl_eigen_symm_alloc")]
                public EigenSymmWorkspace (size_t n);
                [CCode (cname="gsl_eigen_symm", instance_pos=-1)]
                public int init (Matrix A, Vector eval);
        }
        
        [Compact]
        [CCode (cname="gsl_eigen_symmv_workspace", free_function="gsl_eigen_symmv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenSymmvWorkspace
        {
                public size_t size;
                public double* d;
                public double* sd;
                public double* gc;
                public double* gs;
                
                [CCode (cname="gsl_eigen_symmv_alloc")]
                public EigenSymmvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_symmv", instance_pos=-1)]
                public int init (Matrix A, Vector eval, Matrix evec);
        }
        
        [Compact]
        [CCode (cname="gsl_eigen_herm_workspace", free_function="gsl_eigen_herm_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenHermWorkspace
        {
                public size_t size;
                public double* d;
                public double* sd;
                public double* tau;
                
                [CCode (cname="gsl_eigen_herm_alloc")]
                public EigenHermWorkspace (size_t n);
                [CCode (cname="gsl_eigen_herm", instance_pos=-1)]
                public int init (MatrixComplex A, VectorComplex eval);
        }
        
        [Compact]
        [CCode (cname="gsl_eigen_hermv_workspace", free_function="gsl_eigen_hermv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenHermvWorkspace
        {
                public size_t size;
                public double* d;
                public double* sd;
                public double* tau;
                public double* gc;
                public double* gs;
                
                [CCode (cname="gsl_eigen_hermv_alloc")]
                public EigenHermvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_hermv", instance_pos=-1)]
                public int init (MatrixComplex A, VectorComplex eval, MatrixComplex evec);
        }
        
        [Compact]
        [CCode (cname="gsl_eigen_nonsymm_workspace", free_function="gsl_eigen_nonsymm_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenNonsymmWorkspace
        {
                public size_t size;
                public Vector diag;
                public Vector tau;
                public Matrix Z;
                public int do_balance;
                size_t n_evals;
                
                [CCode (cname="gsl_eigen_nonsymm_alloc")]
                public EigenNonsymmWorkspace (size_t n);
                [CCode (cname="gsl_eigen_nonsymm_params", instance_pos=-1)]
                public void params (int compute_t, int balance);
                [CCode (cname="gsl_eigen_nonsymm", instance_pos=-1)]
                public int init (Matrix A, VectorComplex eval);
                [CCode (cname="gsl_eigen_nonsymm_Z", instance_pos=-1)]
                public int init_Z (Matrix A, VectorComplex eval, Matrix Z);
        }

        [Compact]
        [CCode (cname="gsl_eigen_nonsymmv_workspace", free_function="gsl_eigen_nonsymmv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenNonsymmvWorkspace
        {
                public size_t size;
                public Vector work;
                public Vector work2;
                public Vector work3;
                public Matrix Z;
                public EigenNonsymmWorkspace nonsymm_workspace_p;
                
                [CCode (cname="gsl_eigen_nonsymmv_alloc")]
                public EigenNonsymmvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_nonsymmv", instance_pos=-1)]
                public int init (Matrix A, VectorComplex eval, MatrixComplex evec);
                [CCode (cname="gsl_eigen_nonsymmv_Z", instance_pos=-1)]
                public int init_Z (Matrix A, VectorComplex eval, MatrixComplex evec, Matrix Z);
        }

        [Compact]
        [CCode (cname="gsl_eigen_gensymm_workspace", free_function="gsl_eigen_gensymm_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGensymmWorkspace
        {
                public size_t size;
                public EigenSymmWorkspace symm_workspace_p;
                
                [CCode (cname="gsl_eigen_gensymm_alloc")]
                public EigenGensymmWorkspace (size_t n);
                [CCode (cname="gsl_eigen_gensymm", instance_pos=-1)]
                public int init (Matrix A, Matrix B, Vector eval);
        }

        [Compact]
        [CCode (cname="gsl_eigen_gensymmv_workspace", free_function="gsl_eigen_gensymmv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGensymmvWorkspace
        {
                public size_t size;
                public EigenSymmvWorkspace symmv_workspace_p;
                
                [CCode (cname="gsl_eigen_gensymmv_alloc")]
                public EigenGensymmvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_gensymmv", instance_pos=-1)]
                public int init (Matrix A, Matrix B, Vector eval, Matrix evec);
        }

        [Compact]
        [CCode (cname="gsl_eigen_genherm_workspace", free_function="gsl_eigen_genherm_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGenhermWorkspace
        {
                public size_t size;
                public EigenHermWorkspace herm_workspace_p;
                
                [CCode (cname="gsl_eigen_genherm_alloc")]
                public EigenGenhermWorkspace (size_t n);
                [CCode (cname="gsl_eigen_genherm", instance_pos=-1)]
                public int init (MatrixComplex A, MatrixComplex B, Vector eval);
        }

        [Compact]
        [CCode (cname="gsl_eigen_genhermv_workspace", free_function="gsl_eigen_genhermv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGenhermvWorkspace
        {
                public size_t size;
                public EigenHermvWorkspace hermv_workspace_p;
                
                [CCode (cname="gsl_eigen_genhermv_alloc")]
                public EigenGenhermvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_genhermv", instance_pos=-1)]
                public int init (MatrixComplex A, MatrixComplex B, Vector eval, MatrixComplex evec);
        }

        [Compact]
        [CCode (cname="gsl_eigen_gen_workspace", free_function="gsl_eigen_gen_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGenWorkspace
        {
                public size_t size;
                public Vector work;
                public size_t n_evals;
                public size_t max_iterations;
                public size_t n_iter;
                public double eshift;
                public int needtop;
                public double atol;
                public double btol;
                public double ascale;
                public double bscale;
                public Matrix H;
                public Matrix R;
                public int compute_s;
                public int compute_t;
                public Matrix Q;
                public Matrix Z;
                
                [CCode (cname="gsl_eigen_gen_alloc")]
                public EigenGenWorkspace (size_t n);
                [CCode (cname="gsl_eigen_gen_params", instance_pos=-1)]
                public void params (int compute_s, int compute_t, int balance);
                [CCode (cname="gsl_eigen_gen", instance_pos=-1)]
                public int init (Matrix A, Matrix B, VectorComplex alpha, Vector beta);
                [CCode (cname="gsl_eigen_gen_QZ", instance_pos=-1)]
                public int init_QZ (Matrix A, Matrix B, VectorComplex alpha, Vector beta, Matrix Q, Matrix Z);
        }

        [Compact]
        [CCode (cname="gsl_eigen_genv_workspace", free_function="gsl_eigen_genv_free", cheader_filename="gsl/gsl_eigen.h")]
        public class EigenGenvWorkspace
        {
                public size_t size;
                public Vector work1;
                public Vector work2;
                public Vector work3;
                public Vector work4;
                public Vector work5;
                public Vector work6;
                public Matrix Q;
                public Matrix Z;
                public EigenGenWorkspace gen_workspace_p;
                
                [CCode (cname="gsl_eigen_genv_alloc")]
                public EigenGenvWorkspace (size_t n);
                [CCode (cname="gsl_eigen_genv", instance_pos=-1)]
                public int init (Matrix A, Matrix B, VectorComplex alpha, Vector beta, MatrixComplex evec);
                [CCode (cname="gsl_eigen_genv_QZ", instance_pos=-1)]
                public int init_QZ (Matrix A, Matrix B, VectorComplex alpha, Vector beta, MatrixComplex evec, Matrix Q, Matrix Z);
        }
        
        [CCode (lower_case_cprefix="gsl_eigen_", cheader_filename="gsl/gsl_eigen.h")]
        namespace EigenSort
        {
                public static int symmv_sort (Vector eval, Matrix evec, EigenSortType sort_type);
                public static int hermv_sort (Vector eval, MatrixComplex evec, EigenSortType sort_type);
                public static int nonsymmv_sort (VectorComplex eval, MatrixComplex evec, EigenSortType sort_type);
                public static int gensymmv_sort (Vector eval, Matrix evec, EigenSortType sort_type);
                public static int genhermv_sort (Vector eval, MatrixComplex evec, EigenSortType sort_type);
                public static int genv_sort (VectorComplex alpha, Vector beta, MatrixComplex evec, EigenSortType sort_type);
        }
        
        
        /*
         * Fast Fourier Transforms (FFTs)
         */
        [CCode (cname="gsl_fft_direction", cheader_filename="gsl/gsl_fft.h")]
        public enum FFTDirection
        {
                forward = -1,
                backward = 1
        }
        
        [Compact]
        [CCode (cname="gsl_fft_complex_wavetable", cheader_filename="gsl/gsl_fft_complex.h")]
        public class FFTComplexWavetable
        {
                public size_t n;
                public size_t nf;
                public size_t factor[64];
                public Complex twiddle[64];
                public Complex trig;
                
                [CCode (cname="gsl_fft_complex_wavetable_alloc")]
                public FFTComplexWavetable (size_t n);
                public int memcpy (FFTComplexWavetable src);
        }
        
        [Compact]
        [CCode (cname="gsl_fft_complex_workspace", cheader_filename="gsl/gsl_fft_complex.h")]
        public class FFTComplexWorkspace
        {
                size_t n;
                double *scratch;
                
                [CCode (cname="gsl_fft_complex_workspace_alloc")]
                public FFTComplexWorkspace (size_t n);
        }
        
        [Compact]
        [CCode (lower_case_cprefix="gsl_fft_complex_", cheader_filename="gsl/gsl_fft_complex.h")]
        namespace FFTComplex
        {
                public static int radix2_forward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTDirection sign);
                public static int radix2_backward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_dif_forward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_dif_transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTDirection sign);
                public static int radix2_dif_backward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_dif_inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                
                public static int forward ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTComplexWavetable wavetable, FFTComplexWorkspace work);
                public static int transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTComplexWavetable wavetable, FFTComplexWorkspace work, FFTDirection sign);
                public static int backward ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTComplexWavetable wavetable, FFTComplexWorkspace work);
                public static int inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTComplexWavetable wavetable, FFTComplexWorkspace work);
        }
        
        [Compact]
        [CCode (cname="gsl_fft_real_wavetable", cheader_filename="gsl/gsl_fft_real.h")]
        public class FFTRealWavetable
        {
                public size_t n;
                public size_t nf;
                public size_t factor[64];
                public Complex twiddle[64];
                public Complex trig;
                
                [CCode (cname="gsl_fft_real_wavetable_alloc")]
                public FFTRealWavetable (size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_fft_real_workspace", cheader_filename="gsl/gsl_fft_real.h")]
        public class FFTRealWorkspace
        {
                size_t n;
                double *scratch;
                
                [CCode (cname="gsl_fft_real_workspace_alloc")]
                public FFTRealWorkspace (size_t n);
        }
        
        [Compact]
        [CCode (lower_case_cprefix="gsl_fft_real_", cheader_filename="gsl/gsl_fft_real.h")]
        namespace FFTReal
        {
                public static int radix2_forward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTRealWavetable wavetable, FFTRealWorkspace work);
                public static int unpack ([CCode (array_length = false)] double[] real_coefficient, [CCode (array_length = false)] double[] complex_coeficient, size_t stride, size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_fft_halfcomplex_wavetable", cheader_filename="gsl/gsl_fft_halfcomplex.h")]
        public class FFTHalfcomplexWavetable
        {
                public size_t n;
                public size_t nf;
                public size_t factor[64];
                public Complex twiddle[64];
                public Complex trig;
                
                [CCode (cname="gsl_fft_halfcomplex_wavetable_alloc")]
                public FFTHalfcomplexWavetable (size_t n);
        }
        
        [CCode (lower_case_cprefix="gsl_fft_halfcomplex_", cheader_filename="gsl/gsl_fft_halfcomplex.h")]
        namespace FFTHalfcomplex
        {
                public static int radix2_inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_backward ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int radix2_transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static int backward ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTHalfcomplexWavetable wavetable, FFTRealWorkspace work);
                public static int inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTHalfcomplexWavetable wavetable, FFTRealWorkspace work);
                public static int transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, FFTHalfcomplexWavetable wavetable, FFTRealWorkspace work);
                public static int unpack ([CCode (array_length = false)] double[] halfcomplex_coefficient, [CCode (array_length = false)] double[] complex_coefficient, size_t stride, size_t n);
                public static int radix2_unpack ([CCode (array_length = false)] double[] halfcomplex_coefficient, [CCode (array_length = false)] double[] complex_coefficient, size_t stride, size_t n);
        }
        
        
        /*
         * Numerical Integration
         */
        [CCode (cprefix="GSL_INTEG_", cheader_filename="gsl/gsl_integration.h")]
        public enum QAWO
        {
                COSINE,
                SINE
        }
        
        [CCode (cprefix="GSL_INTEG_", cheader_filename="gsl/gsl_integration.h")]
        public enum GaussRules
        {
                GAUSS15,
                GAUSS21,
                GAUSS31,
                GAUSS41,
                GAUSS51,
                GAUSS61
        }
        
        [Compact]
        [CCode (cname="gsl_integration_workspace", cheader_filename="gsl/gsl_integration.h")]
        public class IntegrationWorkspace
        {
                public size_t limit;
                public size_t size;
                public size_t nrmax;
                public size_t i;
                public size_t maximum_level;
                public double* alist;
                public double* blist;
                public double* rlist;
                public double* elist;
                public size_t* order;
                public size_t* level;
                
                [CCode (cname="gsl_integration_workspace_alloc")]
                public IntegrationWorkspace (size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_integration_qaws_table", cheader_filaname="gsl/gsl_integration.h")]
        public class IntegrationQAWSTable
        {
                public double alpha;
                public double beta;
                public int mu;
                public int nu;
                public double ri[25];
                public double rj[25];
                public double rg[25];
                public double rh[25];
                
                [CCode (cname="gsl_integration_qaws_table_alloc")]
                public IntegrationQAWSTable (double alpha, double beta, int mu, int nu);
                public int @set (double alpha, double beta, int mu, int nu);
        }
        
        [Compact]
        [CCode (cname="gsl_integration_qawo_table", unref="gsl_integration_qawo_table_free", cheader_filename="gsl/gsl_integration.h")]
        public class IntegrationQAWOTable
        {
                public size_t n;
                public double omega;
                public double L;
                public double par;
                public QAWO sine;
                public double* chebmo;
                
                [CCode (cname="gsl_integration_qawo_table_alloc")]
                public IntegrationQAWOTable (double omega, double L, QAWO sine, size_t n);
                public int @set (double omega, double L, QAWO sine);
                public int set_length (double L);
        }
        
        [CCode (cname="gsl_integration", cheader_filename="gsl/gsl_integration.h")]
        namespace Integration
        {
                public static void qk15 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qk21 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qk31 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qk41 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qk51 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qk61 (Function* f, double a, double b, out double result, out double abserr, out double resabs, out double resasc);
                public static void qcheb (Function* f, double a, double b, out double cheb12, out double cheb24);
                
                public static void qk (int n, [CCode (array_length = false)] double[] xgk, [CCode (array_length = false)] double[] wg, [CCode (array_length = false)] double[] wgk, [CCode (array_length = false)] double[] fv1, [CCode (array_length = false)] double[] fv2, Function* f, double a, double b, out double result, out double abserr, out double resabs, double resasc);
                public static int qng (Function* f, double a, double b, double epsabs, double epsrel, out double result, out double abserr, out size_t neval);
                public static int qag (Function* f, double a, double b, double epsabs, double epsrel, size_t limit, int key, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qagi (Function* f, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qagiu (Function* f, double a, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qagil (Function* f, double b, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qags (Function* f, double a, double b, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qagp (Function* f, [CCode (array_length = false)] double[] pts, size_t npts, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qawc (Function* f, double a, double b, double c, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qaws (Function* f, double a, double b, IntegrationQAWSTable t, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, out double result, out double abserr);
                public static int qawo (Function* f, double a, double epsabs, double epsrel, size_t limit, IntegrationWorkspace workspace, IntegrationQAWOTable wf, out double result, out double abserr);
                public static int qawf (Function* f, double a, double epsabs, size_t limit, IntegrationWorkspace workspace, IntegrationWorkspace cycle_workspace, IntegrationQAWOTable wf, out double result, out double abserr);
        }
        
        
        /*
         * Random Number Generation
         */
        [CCode (has_target = false)]
        public delegate void RNGSetState (void *state, ulong seed);
        [CCode (has_target = false)]
        public delegate ulong RNGGetState (void* state);
        [CCode (has_target = false)]
        public delegate double RNGGetDouble (void* state);

        [SimpleType]
        [CCode (cname="gsl_rng_type", cheader_filename="gsl/gsl_rng.h")]
        public struct RNGType
        {
                public string name;
                public ulong max;
                public ulong min;
                public size_t size;
                public RNGSetState @set;
                public RNGGetState @get;
                public RNGGetDouble get_double;
        }
        
        [CCode (lower_case_cprefix="gsl_rng_", cheader_filename="gsl/gsl_rng.h")]
        namespace RNGTypes
        {
                public static RNGType* borosh13;
                public static RNGType* coveyou;
                public static RNGType* cmrg;
                public static RNGType* fishman18;
                public static RNGType* fishman20;
                public static RNGType* fishman2x;
                public static RNGType* gfsr4;
                public static RNGType* knuthran;
                public static RNGType* knuthran2;
                public static RNGType* knuthran2002;
                public static RNGType* lecuyer21;
                public static RNGType* minstd;
                public static RNGType* mrg;
                public static RNGType* mt19937;
                public static RNGType* mt19937_1999;
                public static RNGType* mt19937_1998;
                public static RNGType* r250;
                public static RNGType* ran0;
                public static RNGType* ran1;
                public static RNGType* ran2;
                public static RNGType* ran3;
                public static RNGType* rand;
                public static RNGType* rand48;
                public static RNGType* random128_bsd;
                public static RNGType* random128_glibc2;
                public static RNGType* random128_libc5;
                public static RNGType* random256_bsd;
                public static RNGType* random256_glibc2;
                public static RNGType* random256_libc5;
                public static RNGType* random32_bsd;
                public static RNGType* random32_glibc2;
                public static RNGType* random32_libc5;
                public static RNGType* random64_bsd;
                public static RNGType* random64_glibc2;
                public static RNGType* random64_libc5;
                public static RNGType* random8_bsd;
                public static RNGType* random8_glibc2;
                public static RNGType* random8_libc5;
                public static RNGType* random_bsd;
                public static RNGType* random_glibc2;
                public static RNGType* random_libc5;
                public static RNGType* randu;
                public static RNGType* ranf;
                public static RNGType* ranlux;
                public static RNGType* ranlux389;
                public static RNGType* ranlxd1;
                public static RNGType* ranlxd2;
                public static RNGType* ranlxs0;
                public static RNGType* ranlxs1;
                public static RNGType* ranlxs2;
                public static RNGType* ranmar;
                public static RNGType* slatec;
                public static RNGType* taus;
                public static RNGType* taus2;
                public static RNGType* taus113;
                public static RNGType* transputer;
                public static RNGType* tt800;
                public static RNGType* uni;
                public static RNGType* uni32;
                public static RNGType* vax;
                public static RNGType* waterman14;
                public static RNGType* zuf;
                public static RNGType* @default;
                public static ulong default_seed;
        }

        [Compact]
        [CCode (cname="gsl_rng", cheader_filename="gsl/gsl_rng.h")]
        public class RNG
        {
                public RNGType* type;
                public void* state;
                
                [CCode (cname="gsl_rng_alloc")]
                public RNG (RNGType* T);
                public void @set (ulong s);
                public ulong @get ();
                public double uniform ();
                public double uniform_pos ();
                public ulong uniform_int (ulong n);
                public string name ();
                public ulong max ();
                public ulong min ();
                public size_t size ();
                public static RNGType* env_setup ();
                public int memcpy (RNG src);
                public RNG clone ();
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                
                public void print_state ();
        }
        
        [CCode (lower_case_cprefix="gsl_cdf_", cheader_filename="gsl/gsl_cdf.h")]
        namespace CDF
        {
                public static double ugaussian_P (double x);
                public static double ugaussian_Q (double x);
                
                public static double ugaussian_Pinv (double P);
                public static double ugaussian_Qinv (double Q);
                
                public static double gaussian_P (double x, double sigma);
                public static double gaussian_Q (double x, double sigma);
                
                public static double gaussian_Pinv (double P, double sigma);
                public static double gaussian_Qinv (double Q, double sigma);
                
                public static double gamma_P (double x, double a, double b);
                public static double gamma_Q (double x, double a, double b);
                
                public static double gamma_Pinv (double P, double a, double b);
                public static double gamma_Qinv (double Q, double a, double b);
                
                public static double cauchy_P (double x, double a);
                public static double cauchy_Q (double x, double a);
                
                public static double cauchy_Pinv (double P, double a);
                public static double cauchy_Qinv (double Q, double a);

                public static double laplace_P (double x, double a);
                public static double laplace_Q (double x, double a);
                
                public static double laplace_Pinv (double P, double a);
                public static double laplace_Qinv (double Q, double a);
                
                public static double rayleigh_P (double x, double sigma);
                public static double rayleigh_Q (double x, double sigma);
                
                public static double rayleigh_Pinv (double P, double sigma);
                public static double rayleigh_Qinv (double Q, double sigma);
                
                public static double chisq_P (double x, double nu);
                public static double chisq_Q (double x, double nu);
                
                public static double chisq_Pinv (double P, double nu);
                public static double chisq_Qinv (double Q, double nu);
                
                public static double exponential_P (double x, double mu);
                public static double exponential_Q (double x, double mu);
                
                public static double exponential_Pinv (double P, double mu);
                public static double exponential_Qinv (double Q, double mu);
                
                public static double exppow_P (double x, double a, double b);
                public static double exppow_Q (double x, double a, double b);
                
                public static double tdist_P (double x, double nu);
                public static double tdist_Q (double x, double nu);
                
                public static double tdist_Pinv (double P, double nu);
                public static double tdist_Qinv (double Q, double nu);
                
                public static double fdist_P (double x, double nu1, double nu2);
                public static double fdist_Q (double x, double nu1, double nu2);
                
                public static double fdist_Pinv (double P, double nu1, double nu2);
                public static double fdist_Qinv (double Q, double nu1, double nu2);
                
                public static double beta_P (double x, double a, double b);
                public static double beta_Q (double x, double a, double b);
                
                public static double beta_Pinv (double P, double a, double b);
                public static double beta_Qinv (double Q, double a, double b);
                
                public static double flat_P (double x, double a, double b);
                public static double flat_Q (double x, double a, double b);
                
                public static double flat_Pinv (double P, double a, double b);
                public static double flat_Qinv (double Q, double a, double b);
                
                public static double lognormal_P (double x, double zeta, double sigma);
                public static double lognormal_Q (double x, double zeta, double sigma);

                public static double lognormal_Pinv (double P, double zeta, double sigma);
                public static double lognormal_Qinv (double Q, double zeta, double sigma);

                public static double gumbel1_P (double x, double a, double b);
                public static double gumbel1_Q (double x, double a, double b);

                public static double gumbel1_Pinv (double P, double a, double b);
                public static double gumbel1_Qinv (double Q, double a, double b);

                public static double gumbel2_P (double x, double a, double b);
                public static double gumbel2_Q (double x, double a, double b);

                public static double gumbel2_Pinv (double P, double a, double b);
                public static double gumbel2_Qinv (double Q, double a, double b);

                public static double weibull_P (double x, double a, double b);
                public static double weibull_Q (double x, double a, double b);

                public static double weibull_Pinv (double P, double a, double b);
                public static double weibull_Qinv (double Q, double a, double b);

                public static double pareto_P (double x, double a, double b);
                public static double pareto_Q (double x, double a, double b);

                public static double pareto_Pinv (double P, double a, double b);
                public static double pareto_Qinv (double Q, double a, double b);

                public static double logistic_P (double x, double a);
                public static double logistic_Q (double x, double a);

                public static double logistic_Pinv (double P, double a);
                public static double logistic_Qinv (double Q, double a);

                public static double binomial_P (uint k, double p, uint n);
                public static double binomial_Q (uint k, double p, uint n);

                public static double poisson_P (uint k, double mu);
                public static double poisson_Q (uint k, double mu);

                public static double geometric_P (uint k, double p);
                public static double geometric_Q (uint k, double p);
        
                public static double negative_binomial_P (uint k, double p, double n);
                public static double negative_binomial_Q (uint k, double p, double n);

                public static double pascal_P (uint k, double p, uint n);
                public static double pascal_Q (uint k, double p, uint n);

                public static double hypergeometric_P (uint k, uint n1, uint n2, uint t);
                public static double hypergeometric_Q (uint k, uint n1, uint n2, uint t);
        }
        
        
        /*
         * Quasi-Random Sequences
         */
        [CCode (has_target = false)]
        public delegate size_t QRNGStateSize (uint dimension);
        [CCode (has_target = false)]
        public delegate int QRNGInitState (void* state, uint dimension);
        [CCode (has_target = false)]
        public delegate int QRNGGetState2 (void* state, uint dimension, out double x);
        
        [SimpleType]
        [CCode (cname="gsl_qrng_type", cheader_filename="gsl/gsl_qrng.h")]
        public struct QRNGType
        {
                public string name;
                public uint max_dimension;
                public QRNGStateSize state_size;
                public QRNGInitState init_state;
                public QRNGGetState2 @get;
        }

        [CCode (lower_case_cprefix="gsl_qrng_", cheader_filename="gsl/gsl_qrng.h")]
        namespace QRNGAlgorithms
        {
                public static QRNGType* niederreiter_2;
                public static QRNGType* sobol;
                public static QRNGType* halton;
                public static QRNGType* reversehalton;
        }
        
        [Compact]
        [CCode (cname="gsl_qrng", cheader_filename="gsl/gsl_qrng.h")]
        public class QRNG
        {
                public QRNGType* type;
                public uint dimension;
                size_t state_size;
                void* state;
                
                [CCode (cname="gsl_qrng_alloc")]
                public QRNG (QRNGType* T, uint d);
                public void init ();
                public int memcpy (QRNG src);
                public QRNG clone ();
                public string name ();
                public size_t size ();
                public int @get ([CCode (array_length = false)] double[] x);
        }
        
        
        /*
         * Random Number Distributions
         */
        [CCode (lower_case_cprefix="gsl_ran_", cheader_filename="gsl/gsl_randist.h")]
        namespace Randist
        {
                public static uint bernoulli (RNG r, double p);
                public static double bernoulli_pdf (uint k, double p);
                
                public static double beta (RNG r, double a, double b);
                public static double beta_pdf (double x, double a, double b);
                
                public static uint binomial (RNG r, double p, uint n);
                public static uint binomial_knuth (RNG r, double p, uint n);
                public static uint binomial_tpe (RNG r, double p, uint n);
                public static double binomial_pdf (uint k, double p, uint n);

                public static double exponential (RNG r, double mu);
                public static double exponential_pdf (double x, double mu);

                public static double exppow (RNG r, double a, double b);
                public static double exppow_pdf (double x, double a, double b);
                
                public static double cauchy (RNG r, double a);
                public static double cauchy_pdf (double x, double a);
                
                public static double chisq (RNG r, double nu);
                public static double chisq_pdf (double x, double nu);
                
                public static void dirichlet (RNG r, size_t K, out double alpha, out double theta);
                public static double dirichlet_pdf (size_t K, out double alpha, out double theta);
                public static double dirichlet_lnpdf (size_t K, out double alpha, out double theta);
                
                public static double erlang (RNG r, double a, double n);
                public static double erlang_pdf (double x, double a, double n);
                
                public static double fdist (RNG r, double nu1, double nu2);
                public static double fdist_pdf (double x, double nu1, double nu2);
                
                public static double flat (RNG r, double a, double b);
                public static double flat_pdf (double x, double a, double b);
                
                public static double gamma (RNG r, double a, double b);
                public static double gamma_int (RNG r, uint a);
                public static double gamma_pdf (double x, double a, double b);
                public static double gamma_mt (RNG r, double a, double b);
                public static double gamma_knuth (RNG r, double a, double b);
                
                public static double gaussian (RNG r, double sigma);
                public static double gaussian_ratio_method (RNG r, double sigma);
                public static double gaussian_ziggurat (RNG r, double sigma);
                public static double gaussian_pdf (double x, double sigma);
                
                public static double ugaussian (RNG r);
                public static double ugaussian_ratio_method (RNG r);
                public static double ugaussian_pdf (double x);
                
                public static double gaussian_tail (RNG r, double a, double sigma);
                public static double gaussian_tail_pdf (double x, double a, double sigma);
                
                public static double ugaussian_tail (RNG r, double a);
                public static double ugaussian_tail_pdf (double x, double a);
                
                public static void bivariate_gaussian (RNG r, double sigma_x, double sigma_y, double rho, out double x, out double y);
                public static double bivariate_gaussian_pdf (double x, double y, double sigma_x, double sigma_y, double rho);
                
                public static double landau (RNG r);
                public static double landau_pdf (double x);
                
                public static uint geometric (RNG r, double p);
                public static double geometric_pdf (uint k, double p);
                
                public static uint hypergeometric (RNG r, uint n1, uint n2, uint t);
                public static double hypergeometric_pdf (uint k, uint n1, uint n2, uint t);
                
                public static double gumbel1 (RNG r, double a, double b);
                public static double gumbel1_pdf (double x, double a, double b);
                
                public static double gumbel2 (RNG r, double a, double b);
                public static double gumbel2_pdf (double x, double a, double b);
                
                public static double logistic (RNG r, double a);
                public static double logistic_pdf (double x, double a);
                
                public static double lognormal (RNG r, double zeta, double sigma);
                public static double lognormal_pdf (double x, double zeta, double sigma);
                
                public static uint logarithmic (RNG r, double p);
                public static double logarithmic_pdf (uint k, double p);
                
                public static void multinomial (RNG r, size_t K, uint N, [CCode (array_length = false)] double[] p, [CCode (array_length = false)] uint[] n);
                public static double multinomial_pdf (size_t K, [CCode (array_length = false)] double[] p, [CCode (array_length = false)] uint[] n);
                public static double multinomial_lnpdf (size_t K, [CCode (array_length = false)] double[] p, [CCode (array_length = false)] uint[] n);
                
                public static uint negative_binomial (RNG r, double p, double n);
                public static double negative_binomial_pdf (uint k, double p, double n);
                
                public static uint pascal (RNG r, double p, uint n);
                public static double pascal_pdf (uint k, double p, uint n);
                
                public static double pareto (RNG r, double a, double b);
                public static double pareto_pdf (double x, double a, double b);
                
                public static uint poisson (RNG r, double mu);
                public static void poisson_array (RNG r, size_t n, [CCode (array_length = false)] uint[] array, double mu);
                public static double poisson_pdf (uint k, double mu);
                
                public static double rayleigh (RNG r, double sigma);
                public static double rayleigh_pdf (double x, double sigma);
                
                public static double rayleigh_tail (RNG r, double a, double sigma);
                public static double rayleigh_tail_pdf (double x, double a, double sigma);
                
                public static double tdist (RNG r, double nu);
                public static double tdist_pdf (double x, double nu);
                
                public static double laplace (RNG r, double a);
                public static double laplace_pdf (double x, double a);
                
                public static double levy (RNG r, double c, double alpha);
                public static double levy_skew (RNG r, double c, double alpha, double beta);
                
                public static double weibull (RNG r, double a, double b);
                public static double weibull_pdf (double x, double a, double b);
                
                public static void dir_2d (RNG r, out double x, out double y);
                public static void dir_2d_trig_method (RNG r, out double x, out double y);
                public static void dir_3d (RNG r, out double x, out double y, out double z);
                public static void dir_nd (RNG r, size_t n, out double x);
                
                public static void shuffle (RNG r, void* b, size_t nmembm, size_t size);
                public static int choose (RNG r, void* dest, size_t k, void* src, size_t n, size_t size);
                public static void sample (RNG r, void* dest, size_t k, void* src, size_t n, size_t size);
        }

        [Compact]
        [CCode (cname="gsl_ran_discrete_t", cprefix="gsl_ran_discrete_", cheader_filename="gsl/gsl_randist.h")]
        public class RanDiscrete
        {
                public size_t K;
                public size_t* A;
                public double* F;
                
                [CCode (cname="gsl_ran_discrete_preproc")]
                public RanDiscrete (size_t K, double* P);
                [CCode (cname="gsl_ran_discrete")]
                public size_t discrete (RNG g);
                [CCode (instance_pos=-1)]
                public double pdf (size_t k);   
        }
        
        
        /*
         * Statistics
         */
        [CCode (lower_case_cprefix="gsl_stats_", cheader_filename="gsl/gsl_statistics.h")]
        namespace Stats
        {
                public static double mean ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double variance ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double variance_m ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double sd ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double sd_m ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double tss ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double tss_m ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double variance_with_fixed_mean ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double sd_with_fixed_mean ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double absdev ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double absdev_m ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double skew ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double skew_m_sd ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean, double sd);
                public static double kurtosis ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double kurtosis_m_sd ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean, double sd);
                public static double lag1_autocorrelation ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double lag1_autocorrelation_m ([CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double covariance ([CCode (array_length = false)] double[] data1, size_t stride1, [CCode (array_length = false)] double[] data2, size_t stride2, size_t n);
                public static double covariance_m ([CCode (array_length = false)] double[] data1, size_t stride1, [CCode (array_length = false)] double[] data2, size_t stride2, size_t n, double mean1, double mean2);
                public static double correlation ([CCode (array_length = false)] double[] data1, size_t stride1, [CCode (array_length = false)] double[] data2, size_t stride2, size_t n);
                
                public static double wmean ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wvariance ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wvariance_m ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean);
                public static double wsd ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wsd_m ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean);
                public static double wtss ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wtss_m ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double mean);
                public static double wvariance_with_fixed_mean ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean);
                public static double wsd_with_fixed_mean ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean);
                public static double wabsdev ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wabsdev_m ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean);
                public static double wskew ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wskew_m_sd ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean, double wsd);
                public static double wkurtosis ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double wkurtosis_m_sd ([CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] data, size_t stride, size_t n, double wmean, double wsd);
                
                public static double max ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static double min ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static void minmax (out double min, out double max, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static size_t max_index ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static size_t min_index ([CCode (array_length = false)] double[] data, size_t stride, size_t n);
                public static void minmax_index (out size_t min, out size_t max, [CCode (array_length = false)] double[] data, size_t stride, size_t n);
                
                public static double median_from_sorted_data ([CCode (array_length = false)] double[] sorted_data, size_t stride, size_t n);
                public static double quantile_from_sorted_data ([CCode (array_length = false)] double[] sorted_data, size_t stride, size_t n, double f);
        }
        
        
        /*
         * Histograms
         */
        [Compact]
        [CCode (cname="gsl_histogram", cheader_filename="gsl/gsl_histogram.h")]
        public class Histogram
        {
                public size_t n;
                public double* range;
                public double* bin;
                
                [CCode (cname="gsl_histogram_alloc")]
                public Histogram (size_t n);
                [CCode (cname="gsl_histogram_calloc")]
                public Histogram.with_zeros (size_t n);
                [CCode (cname="gsl_histogram_calloc_uniform")]
                public Histogram.uniform (size_t n, double xmin, double xmax);
                [CCode (cname="gsl_histogram_calloc_range")]
                public Histogram.with_range (size_t n, [CCode (array_length = false)] double[] range);
                
                public int increment (double x);
                public int accumulate (double x, double weight);
                public int find (double x, out size_t i);
                public double @get (size_t i);
                public int get_range (size_t i, out double lower, out double upper);
                public double max ();
                public double min ();
                public size_t bins ();

                public void reset ();

                public int set_ranges (double[] range);
                public int set_ranges_uniform (double xmin, double xmax);

                public int memcpy (Histogram source);
                public Histogram clone();
                
                public double max_val ();
                public size_t max_bin ();
                public double min_val ();
                public size_t min_bin ();
                
                public int equal_bins_p (Histogram h2);
                public int add (Histogram h2);
                public int sub (Histogram h2);
                public int mul (Histogram h2);
                public int div (Histogram h2);
                public int scale (double scale);
                public int shift (double shift);

                public double sigma ();
                public double mean ();
                public double sum ();

                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Histogram h, string range_format, string bin_format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
        }
        
        [Compact]
        [CCode (cname="gsl_histogram_pdf", cheader_filename="gsl/gsl_histogram.h")]
        public class HistogramPDF
        {
                public size_t n;
                public double* range;
                public double* sum ;
                
                [CCode (cname="gsl_histogram_pdf_alloc")]
                public HistogramPDF (size_t n);
                public int init (Histogram h);
                public double sample (double r);
        }
        
        [Compact]
        [CCode (cname="gsl_histogram2d", cheader_filename="gsl/gsl_histogram2d.h")]
        public class Histogram2d
        {
                public size_t nx;
                public size_t ny;
                public double* xrange;
                public double* yrange;
                public double* bin;
                
                [CCode (cname="gsl_histogram2d_alloc")]
                public Histogram2d (size_t nx, size_t ny);
                [CCode (cname="gsl_histogram2d_calloc")]
                public Histogram2d.with_zeros (size_t nx, size_t ny);
                [CCode (cname="gsl_histogram2d_calloc_uniform")]
                public Histogram2d.uniform (size_t nx, size_t ny, double xmin, double xmax, double ymin, double ymax);
                [CCode (cname="gsl_histogram2d_calloc_range")]
                public Histogram2d.range (size_t nx, size_t ny, out double xrange, out double yrange);
                
                public int increment (double x, double y);
                public int accumulate (double x, double y, double weight);
                public int find (double x, double y, out size_t i, out size_t j);
                public double @get (size_t i, size_t j);
                public int get_xrange (size_t i, out double xlower, out double xupper);
                public int get_yrange (size_t j, out double ylower, out double yupper);
                
                public double xmax ();
                public double xmin ();
                public double ymax ();
                public double ymin ();
                
                public void reset ();
                
                public int set_ranges_uniform (double xmin, double xmax, double ymin, double ymax);
                public int set_ranges (double[] xrange, double[] yrange);
                
                public int memcpy (Histogram2d source);
                public Histogram2d clone ();
                
                public double max_val();
                public void max_bin (out size_t i, out size_t j);
                public double min_val();
                public void min_bin (out size_t i, out size_t j);
                
                public double xmean ();
                public double ymean ();
                public double xsigma ();
                public double ysigma ();
                public double cov ();
                
                public double sum ();
                public int equal_bins_p (Histogram h2) ;
                public int add (Histogram h2);
                public int sub (Histogram h2);
                public int mul (Histogram2d h2);
                public int div (Histogram2d h2);
                public int scale (double scale);
                public int shift (double shift);
                
                [CCode (instance_pos=-1)]
                public int fwrite (GLib.FileStream stream);
                [CCode (instance_pos=-1)]
                public int fread (GLib.FileStream stream);
                public static int fprintf (GLib.FileStream stream, Histogram h, string range_format, string bin_format);
                [CCode (instance_pos=-1)]
                public int fscanf (GLib.FileStream stream);
        }
        
        [Compact]
        [CCode (cname="gsl_histogram2d_pdf", cheader_filename="gsl/gsl_histogram2d.h")]
        public class Histogram2dPDF
        {
                public size_t nx;
                public size_t ny;
                public double* xrange;
                public double* yrange;
                public double* sum;
                
                [CCode (cname="gsl_histogram2d_pdf_alloc")]
                public Histogram2dPDF (size_t nx, size_t ny);
                public int init (Histogram2d h);
                public int sample (double r1, double r2, out double x, out double y);
        }
        
        
        /*
         * N-Tuples
         */
        [CCode (has_target = false)]
        public delegate int NTupleFunc (void* ntuple_data, void* params);
        
        [SimpleType]
        [CCode (cname="gsl_ntuple_select_fn", cheader_filename="gsl/gsl_ntuple.h")]
        public struct NTupleSelectFn
        {
                public NTupleFunc function;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_ntuple_value_fn", cheader_filename="gsl/gsl_ntuple.h")]
        public struct NTupleValueFn
        {
                public NTupleFunc function;
                public void* params;
        }

        [Compact]
        [CCode (cname="gsl_ntuple", free_function="gsl_ntuple_close", cheader_filename="gsl/gsl_ntuple.h")]
        public class NTuple
        {
                public GLib.FileStream file;
                public void* ntrupel_data;
                public size_t size;
                
                public static NTuple open (string filename, void* ntuple_data, size_t size);
                public static NTuple create (string filename, void* ntuple_data, size_t size);
                public int write ();
                public int read ();
                public int bookdata ();
                
                public static int project (Histogram h, NTuple ntuple, NTupleValueFn* value_func, NTupleSelectFn* select_func);
        }
        
        
        /*
         * Monte Carlo Integration
         */
        [CCode (cprefix="GSL_VEGAS_MODE_", cheader_filename="gsl/gsl_monte_vegas.h")]
        public enum MonteVegasMode
        {
                IMPORTANCE, 
                IMPORTANCE_ONLY,
                STRATIFIED
        }
        
        [CCode (has_target = false)]
        public delegate double MonteFunc ([CCode (array_length = false)] double[] x_array, size_t dim, void* params);
        
        [SimpleType]
        [CCode (cname="gsl_monte_function", cheader_filanema="gsl/gsl_monte.h")]
        public struct MonteFunction
        {
                public MonteFunc f;
                public size_t dim;
                public void* params;
        }

        [Compact]
        [CCode (cname="gsl_monte_plain_state", cprefix="gsl_monte_plain_", cheader_filename="gsl/gsl_monte_plain.h")]
        public class MontePlainState
        {
                public size_t dim;
                public double* x;
                
                [CCode (cname="gsl_monte_plain_alloc")]
                public MontePlainState (size_t dim);
                public int init ();
                public static int integrate (MonteFunction* f, [CCode (array_length = false)] double[] xl, [CCode (array_length = false)] double[] xu, size_t dim, size_t calls,  RNG r, MontePlainState state, out double result, out double abserr);
        }
        
        [Compact]
        [CCode (cname="gsl_monte_miser_state", cprefix="gsl_monte_miser_", cheader_filename="gsl/gsl_monte_miser.h")]
        public class MonteMiserState
        {
                public size_t min_calls;
                public size_t min_calls_per_bisection;
                public double dither;
                public double estimate_frac;
                public double alpha;
                public size_t dim;
                public int estimate_style;
                public int depth;
                public int verbose;
                public double* x;
                public double* xmid;
                public double* sigma_l;
                public double* sigma_r;
                public double* fmax_l;
                public double* fmax_r;
                public double* fmin_l;
                public double* fmin_r;
                public double* fsum_l;
                public double* fsum_r;
                public double* fsum2_l;
                public double* fsum2_r;
                public size_t* hits_l;
                public size_t* hits_r;
                
                [CCode (cname="gsl_monte_miser_alloc")]
                public MonteMiserState (size_t dim);
                public int init ();
                public static int integrate (MonteFunction* f, [CCode (array_length = false)] double[] xl, [CCode (array_length = false)] double[] xh, size_t dim, size_t calls, RNG r, MonteMiserState state, out double result, out double abserr);
        }
        
        [Compact]
        [CCode (cname="gsl_monte_vegas_state", cprefix="gsl_monte_vegas_", cheader_filename="gsl/gsl_monte_vegas.h")]
        public class MonteVegasState
        {
                public size_t dim;
                public size_t bins_max;
                public uint bins;
                public uint boxes;
                public double* xi;
                public double* xin;
                public double* delx;
                public double* weight;
                public double vol;
                public double* x;
                public int* bin;
                public int* box;
                public double* d;
                public double alpha;
                public int mode;
                public int verbose;
                public uint iterations;
                public int stage;
                public double jac;
                public double wtd_int_sum;
                public double sum_wgts;
                public double chi_sum;
                public double chisq;
                public double result;
                public double sigma;
                public uint it_start;
                public uint it_num;
                public uint samples;
                public uint calls_per_box;
                public GLib.FileStream ostream;

                [CCode (cname="gsl_monte_vegas_alloc")]
                public MonteVegasState (size_t dim);
                public int init ();
                public static int integrate (MonteFunction* f, [CCode (array_length = false)] double[] xl, [CCode (array_length = false)] double[] xu, size_t dim, size_t calls, RNG r, MonteVegasState state, out double result, out double abserr);
        }
        
        
        /*
         * Simulated Annealing
         */
        [SimpleType]
        [CCode (cname="gsl_siman_params_t", cheader_filename="gsl/gsl_siman.h")]
        public struct SimanParams
        {
                public int n_tries;
                public int iters_fixed_T;
                public double step_size;
                public double k;
                public double t_initial;
                public double mu_t;
                public double t_min;
        }
        
        [CCode (lower_case_cprefix="gsl_siman_", cheader_filename="gsl/gsl_siman.h")]
        namespace Siman
        {
                [CCode (has_target = false)]
                public delegate double Efunc_t (void *xp);
                [CCode (has_target = false)]
                public delegate void step_t (RNG r, void *xp, double step_size);
                [CCode (has_target = false)]
                public delegate double metric_t (void *xp, void* yp);
                [CCode (has_target = false)]
                public delegate void print_t (void* xp);
                [CCode (has_target = false)]
                public delegate void copy_t (void* source, void* dest);
                [CCode (has_target = false)]
                public delegate void copy_construct_t (void* xp);
                [CCode (has_target = false)]
                public delegate void destroy_t (void* xp);
        
                public static void solve(RNG r, void *x0_p, Efunc_t Ef, step_t take_step, metric_t distance, print_t print_position, copy_t copyfunc, copy_construct_t copy_constructor, destroy_t destructor, size_t element_size, SimanParams params);
                public static void solve_many (RNG r, void *x0_p, Efunc_t Ef, step_t take_step, metric_t distance, print_t print_position, size_t element_size, SimanParams params);
        }
        
        
        /*
         * Ordinary Differential Equations
         */
        [CCode (cprefix="GSL_ODEIV_HADJ_", cheader_filename="gsl/gsl_odeiv.h")]
        public enum OdeivHadjustTypes
        {
                INC,
                NIL,
                DEC
        }
        
        [CCode (has_target = false)]
        public delegate int OdeivFunction (double t, [CCode (array_length = false)] double[] y, [CCode (array_length = false)] double[] dydt, void* params);
        [CCode (has_target = false)]
        public delegate int OdeivJacobian (double t, [CCode (array_length = false)] double[] y, [CCode (array_length = false)] double[] dfdy, [CCode (array_length = false)] double[] dfdt, void* params);
        [CCode (has_target = false)]
        public delegate void* OdeivStepAlloc (size_t dim);
        [CCode (has_target = false)]
        public delegate int OdeivStepApply (void* state, size_t dim, double t, double h, [CCode (array_length = false)] double[] y, [CCode (array_length = false)] double[] yerr, [CCode (array_length = false)] double[] dydt_in, [CCode (array_length = false)] double[] dydt_out, OdeivSystem* dydt);
        [CCode (has_target = false)]
        public delegate int OdeivStepReset (void* state, size_t dim);
        [CCode (has_target = false)]
        public delegate uint OdeivStepOrder (void* state);
        [CCode (has_target = false)]
        public delegate void OdeivStepFree (void* state);
        [CCode (has_target = false)]
        public delegate void* OdeivControlAlloc ();
        [CCode (has_target = false)]
        public delegate int OdeivControlInit (void* state, double eps_abs, double eps_rel, double a_y, double a_dydt);
        [CCode (has_target = false)]
        public delegate int OdeivControlHadjust (void* state, size_t dim, uint ord, [CCode (array_length = false)] double[] y, [CCode (array_length = false)] double[] yerr, [CCode (array_length = false)] double[] yp, [CCode (array_length = false)] double[] h);
        [CCode (has_target = false)]
        public delegate void OdeivControlFree (void* state);
        
        [SimpleType]
        [CCode (cname="gsl_odeiv_system", cheader_filename="gsl/gsl_odeiv.h")]
        public struct OdeivSystem
        {
                public OdeivFunction function;
                public OdeivJacobian jacobian;
                public size_t dimension;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_odeiv_step_type", cheader_filename="gsl/gsl_odeiv.h")]
        public struct OdeivStepType
        {
                public string name;
                public int can_use_dydt_in;
                public int gives_exact_dydt_out;
                public OdeivStepAlloc alloc;
                public OdeivStepApply apply;
                public OdeivStepReset reset;
                public OdeivStepOrder order;
                public OdeivStepFree free;
        }
        
        [CCode (lower_case_cprefix="gsl_odeiv_step_", cheader_filename="gsl/gsl_odeiv.h")]
        namespace OdeivStepTypes
        {
                public static OdeivStepType* rk2;
                public static OdeivStepType* rk4;
                public static OdeivStepType* rkf45;
                public static OdeivStepType* rkck;
                public static OdeivStepType* rk8pd;
                public static OdeivStepType* rk2imp;
                public static OdeivStepType* rk2simp;
                public static OdeivStepType* rk4imp;
                public static OdeivStepType* bsimp;
                public static OdeivStepType* gear1;
                public static OdeivStepType* gear2;
        }

        [Compact]
        [CCode (cname="gsl_odeiv_step", cheader_filename="gsl/gsl_odeiv.h")]
        public class OdeivStep
        {
                public OdeivStepType* type;
                public size_t dimension;
                public void* state;
                
                [CCode (cname="gsl_odeiv_step_alloc")]
                public OdeivStep (OdeivStepType* T, size_t dim);
                public int reset ();
                public string name ();
                public uint order ();
                
                public int apply (double t, double h, [CCode (array_length = false)] double[] y, [CCode (array_length = false)] double[] yerr, [CCode (array_length = false)] double[] dydt_in, [CCode (array_length = false)] double[] dydt_out, OdeivSystem* dydt);
        }
        
        [SimpleType]
        [CCode (cname="gsl_odeiv_control_type", cheader_filename="gsl/gsl_odeiv.h")]
        public struct OdeivControlType
        {
                public string name;
                public OdeivControlAlloc alloc;
                public OdeivControlInit init;
                public OdeivControlHadjust hadjust;
                public OdeivControlFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_odeiv_control", cheader_filename="gsl/gsl_odeiv.h")]
        public class OdeivControl
        {
                public OdeivControlType* type;
                public void* state;
                
                [CCode (cname="gsl_odeiv_control_alloc")]
                public OdeivControl (OdeivControlType* T);
                [CCode (cname="gsl_odeiv_control_standard_new")]
                public OdeivControl.standard (double eps_abs, double eps_rel, double a_y, double a_dydt);
                [CCode (cname="gsl_odeiv_control_y_new")]
                public OdeivControl.y (double eps_abs, double eps_rel);
                [CCode (cname="gsl_odeiv_control_yp_new")]
                public OdeivControl.yp (double eps_abs, double eps_rel);
                [CCode (cname="gsl_odeiv_control_scaled_new")]
                public OdeivControl.scaled (double eps_abs, double eps_rel, double a_y, double a_dydt, double[] scale_abs);
                
                public int init (double eps_abs, double eps_rel, double a_y, double a_dydt);
                public int hadjust (OdeivStep s, out double y, out double yerr, out double dydt, out double h);
                public string name ();
        }
        
        [Compact]
        [CCode (cname="gsl_odeiv_evolve", cheader_filename="gsl/gsl_odeiv.h")]
        public class OdeivEvolve
        {
                public size_t dimension;
                public double* y0;
                public double* yerr;
                public double* dydt_in;
                public double* dydt_out;
                public double last_step;
                public ulong count;
                public ulong failed_steps;
                
                [CCode (cname="gsl_odeiv_evolve_alloc")]
                public OdeivEvolve (size_t dim);
                public int apply (OdeivControl con, OdeivStep step, OdeivSystem* dydt, [CCode (array_length = false)] double[] t, double t1, [CCode (array_length = false)] double[] h, [CCode (array_length = false)] double[] y);
                public int reset ();
        }
        
        
        /*
         * Interpolation
         */
        [CCode (has_target = false)]
        public delegate void* InterpAlloc (size_t size);
        [CCode (has_target = false)]
        public delegate int InterpInit (void* t, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size);
        [CCode (has_target = false)]
        public delegate int InterpEval (void* t, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size, double x, InterpAccel* i, out double y);
        [CCode (has_target = false)]
        public delegate int InterpEvalDeriv (void* t, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size, double x, InterpAccel* i, out double y_p);
        [CCode (has_target = false)]
        public delegate int InterpEvalDeriv2 (void* t, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size, double x, InterpAccel* i, out double y_pp);
        [CCode (has_target = false)]
        public delegate int InterpEvalInteg (void* t, [CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size, InterpAccel* i, double a, double b, out double result);
        [CCode (has_target = false)]
        public delegate void InterpFree (void* t);
        
        [Compact]
        [CCode (cname="gsl_interp_accel", cheader_filname="gsl/gsl_interp.h")]
        public class InterpAccel
        {
                public size_t cache;
                public size_t miss_count;
                public size_t hit_count;
                
                [CCode (cname="gsl_interp_accel_alloc")]
                public InterpAccel ();
                public size_t find (double[] x_array, double x);
                public int reset ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_interp_type", cheader_filename="gsl/gsl_interp.h")]
        public struct InterpType
        {
                public string name;
                public uint min_size;
                public InterpAlloc alloc;
                public InterpInit init;
                public InterpEval eval;
                public InterpEvalDeriv eval_deriv;
                public InterpEvalDeriv2 eval_deriv2;
                public InterpEvalInteg eval_integ;
                public InterpFree free;
        }

        [CCode (lower_case_cprefix="gsl_interp_", cheader_filename="gsl/gsl_interp.h")]
        namespace InterpTypes
        {
                public static InterpType* linear;
                public static InterpType* polynomial;
                public static InterpType* cspline;
                public static InterpType* cspline_periodic;
                public static InterpType* akima;
                public static InterpType* akima_periodic;
        }
        
        [Compact]
        [CCode (cname="gsl_interp", cheader_filename="gsl/gsl_interp.h")]
        public class Interp
        {
                InterpType* type;
                public double xmin;
                public double xmax;
                public size_t size;
                public void* state;
                
                [CCode (cname="gsl_interp_alloc")]
                public Interp (InterpType T, size_t n);
                public int init ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size);
                public string name ();
                public uint min_size ();
                public int eval_e ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a, out double y);
                public double eval ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a);
                public int eval_deriv_e ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a, out double d);
                public double eval_deriv ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a);
                public int eval_deriv2_e ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a, out double d2);
                public double eval_deriv2 ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double x, InterpAccel a);
                public int eval_integ_e ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double a, double b, InterpAccel acc, out double result);
                public double eval_integ ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, double a, double b, InterpAccel acc);
                public static size_t bsearch([CCode (array_length = false)] double[] x_array, double x, size_t index_lo, size_t index_hi);
        }
        
        [Compact]
        [CCode (cname="gsl_spline", cheader_filename="gsl/gsl_spline.h")]
        public class Spline
        {
                public Interp interp;
                public double* x;
                public double* y;
                public size_t size;
                
                [CCode (cname="gsl_spline_alloc")]
                public Spline (InterpType* T, size_t size);
                public int init ([CCode (array_length = false)] double[] xa, [CCode (array_length = false)] double[] ya, size_t size);
                public string name ();
                public uint min_size ();
                public int eval_e (double x, InterpAccel a, out double y);
                public double eval (double x, InterpAccel a);
                public int eval_deriv_e (double x, InterpAccel a, out double y);
                public double eval_deriv (double x, InterpAccel a);
                public int eval_deriv2_e (double x, InterpAccel a, out double y);
                public double eval_deriv2 (double x, InterpAccel a);
                public int eval_integ_e (double a, double b, InterpAccel acc, out double y);
                public double eval_integ (double a, double b, InterpAccel acc);
        }
        
        /*
         * Numerical Differentiation
         */
        [CCode (lower_case_cprefix="gsl_deriv_", cheader_fileame="gsl/gsl_deriv.h")]
        namespace Deriv
        {
                public static int central (Function* f, double x, double h, out double result, out double abserr);
                public static int backward (Function* f, double x, double h, out double result, out double abserr);
                public static int forward (Function* f, double x, double h, out double result, out double abserr);
        }
        
        
        /*
         * Chebyshev Approximations
         */
        [Compact]
        [CCode (cname="gsl_cheb_series", cprefix="gsl_cheb_", cheader_filename="gsl/gsl_chebyshev.h")]
        public class ChebSeries
        {
                public double* c;
                public size_t order;
                public double a;
                public double b;
                public size_t order_sp;
                public double *f;
                
                [CCode (cname="gsl_cheb_alloc")]
                public ChebSeries (size_t order);
                public int init (Function* func, double a, double b);
                public double eval (double x);
                public int eval_err (double x, out double result, out double abserr);
                public double eval_n (size_t order, double x);
                public int eval_n_err (size_t order, double x, out double result, out double abserr);
                public double eval_mode (double x, Mode mode);
                public int eval_mode_e (double x, Mode mode, out double result, out double abserr);
                public int calc_deriv (ChebSeries cs);
                public int calc_integ (ChebSeries cs);
        }
        
        
        /*
         * Series Acceleration
         */
        [Compact]
        [CCode (cname="gsl_sum_levin_u_workspace", free_function="gsl_sum_levin_u_free", cheader_filename="gsl/gsl_sum.h")]
        public class SumLevinUWorkspace
        {
                public size_t size;
                public size_t i;
                public size_t terms_used;
                public double sum_plain;
                public double* q_num;
                public double* q_den;
                public double* dq_num;
                public double* dq_den;
                public double* dsum;
                
                [CCode (cname="gsl_sum_levin_u_alloc")]
                public SumLevinUWorkspace (size_t n);
        }
                
        [CCode (lower_case_cprefix="gsl_sum_levin_u_", cheader_filename="gsl/gsl_sum.h")]
        namespace SumLevinU
        {
                public static int accel (double[] array, SumLevinUWorkspace w, out double sum_accel, out double abserr);
                public static int minmax (double[] array, size_t min_terms, size_t max_terms, SumLevinUWorkspace w, out double sum_accel, out double abserr);
                public static int step (double term, size_t n, size_t nmax, SumLevinUWorkspace w, out double sum_accel);
        }
        
        [Compact]
        [CCode (cname="gsl_sum_levin_utrunc_workspace", free_function="gsl_sum_levin_utrunc_free", cheader_filename="gsl/gsl_sum.h")]
        public class SumLevinUtruncWorkspace
        {
                public size_t size;
                public size_t i;
                public size_t terms_used;
                public double sum_plain;
                public double* q_num;
                public double* q_den;
                public double* dsum;
                
                [CCode (cname="gsl_sum_levin_utrunc_alloc")]
                public SumLevinUtruncWorkspace (size_t n);
        }
        
        [CCode (lower_case_cprefix="gsl_sum_levin_utrunc_", cheader_filename="gsl/gsl_sum.h")]
        namespace SumLevinUtrunc
        {
                public static int accel (double[] array, SumLevinUtruncWorkspace w, out double sum_accel, out double abserr_trunc);
                public static int minmax (double[] array, size_t min_terms, size_t max_terms, SumLevinUtruncWorkspace w, out double sum_accel, out double abserr_trunc);
                public static int step (double term, size_t n, SumLevinUtruncWorkspace w, out double sum_accel);
        }
        
        
        /*
         * Wavelet Transforms
         */
        public enum WaveletDirection
        {
                forward = 1,
                backward = -1
        }
        
        [CCode (has_target = false)]
        public delegate int WaveletInit (double** h1, double** g1, double** h2, double** g2, size_t* nc, size_t* offset, size_t member);
        
        [SimpleType]
        [CCode (cname="gsl_wavelet_type", cheader_filename="gsl/gsl_wavelet.h")]
        public struct WaveletType
        {
                public string name;
                public WaveletInit init;
        }

        [CCode (lower_case_cprefix="gsl_wavelet_", cheader_filename="gsl/gsl_wavelet.h")]
        namespace WaveletTypes
        {
                public static WaveletType* daubechies;
                public static WaveletType* daubechies_centered;
                public static WaveletType* haar;
                public static WaveletType* haar_centered;
                public static WaveletType* bspline;
                public static WaveletType* bspline_centered;
        }
        
        [Compact]
        [CCode (cname="gsl_wavelet_workspace", cheader_filename="gsl/gsl_wavelet.h")]
        public class WaveletWorkspace
        {
                public double* scratch;
                public size_t n;
                
                [CCode (cname="gsl_wavelet_workspace_alloc")]
                public WaveletWorkspace (size_t n);
        }
        
        [Compact]
        [CCode (cname="gsl_wavelet", cheader_filename="gsl/gsl_wavelet.h,gsl/gsl_wavelet2d.h")]
        public class Wavelet
        {
                public WaveletType* type;
                public double* h1;
                public double* g1;
                public double* h2;
                public double* g2;
                public size_t nc;
                public size_t offset;

                [CCode (cname="gsl_wavelet_alloc")]
                public Wavelet (WaveletType* T, size_t k);
                public string name ();
                public int transform ([CCode (array_length = false)] double[] data, size_t stride, size_t n, WaveletDirection dir, WaveletWorkspace work);
                public int transform_forward ([CCode (array_length = false)] double[] data, size_t stride, size_t n, WaveletWorkspace work);
                public int transform_inverse ([CCode (array_length = false)] double[] data, size_t stride, size_t n, WaveletWorkspace work);
                
                [CCode (cname="gsl_wavelet2d_transform")]
                public int transform_2d ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletDirection dir, WaveletWorkspace work);
                [CCode (cname="gsl_wavelet2d_transform_forward")]
                public int transform_forward_2d ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletWorkspace work);
                [CCode (cname="gsl_wavelet2d__transform_inverse")]
                public int transform_inverse_2d ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletDirection dir,WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform_forward ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform_inverse ([CCode (array_length = false)] double[] data, size_t tda, size_t size1, size_t size2, WaveletWorkspace * work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int transform_matrix (Matrix a, WaveletDirection dir, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int transform_matrix_forward (Matrix a, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int transform_matrix_inverse (Matrix a, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform_matrix (Matrix a, WaveletDirection dir, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform_matrix_forward (Matrix a, WaveletWorkspace work);
                [CCode (cprefix="gsl_wavelet2d_")]
                public int nstransform_matrix_inverse (Matrix a, WaveletWorkspace work);
        }
        
        
        /*
         * Discrete Hankel Transforms
         */
        [Compact]
        [CCode (cname="gsl_dht", cheader_filename="gsl/gsl_dht.h")]
        public class DHT
        {
                public size_t size;
                public double nu;
                public double xmax;
                public double kmax;
                public double* j;
                public double* Jjj;
                public double* J2;
                
                [CCode (cname="gsl_dht_alloc")]
                public DHT (size_t size);
                [CCode (cname="gsl_dht_new")]
                public DHT.recalc (size_t size, double nu, double xmax);
                public int init (double nu, double xmax);
                public double x_sample (int n);
                public double k_sample (int n);
                public int apply ([CCode (array_length = false)] double[] f_in, [CCode (array_length = false)] double[] f_out);
        }
        
        
        /*
         * One dimensional Root-Finding
         */
        [CCode (has_target = false)]
        public delegate int RootFsolverSet (void* state, Function* f, double* root, double x_lower, double x_upper);
        [CCode (has_target = false)]
        public delegate int RootFsolverIterate (void* state, Function* f, double* root, double* x_lower, double* x_upper);
        [CCode (has_target = false)]
        public delegate int RootFdfsolverSet (void* state, FunctionFdf* f, double* root);
        [CCode (has_target = false)]
        public delegate int RootFdfsolverIterate (void* state, FunctionFdf* d, double* root);
        
        [SimpleType]
        [CCode (cname="gsl_root_fsolver_type", cheader_filename="gsl/gsl_roots.h")]
        public struct RootFsolverType
        {
                public string name;
                public size_t size;
                public RootFsolverSet @set;
                public RootFsolverIterate iterate;
        }
        
        [Compact]
        [CCode (cname="gsl_root_fsolver", cheader_filename="gsl/gsl_roots.h")]
        public class RootFsolver
        {
                public RootFsolverType* type;
                public Function* function;
                public double root;
                public double x_lower;
                public double x_upper;
                public void* state;
                
                [CCode (cname="gsl_root_fsolver_alloc")]
                public RootFsolver (RootFsolverType* T);
                public int @set (Function* f, double x_lower, double x_upper);
                public int iterate ();
                public unowned string name ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_root_fdfsolver_type", cheader_filename="gsl/gsl_roots.h")]
        public struct RootFdfsolverType
        {
                public string name;
                public size_t size;
                public RootFdfsolverSet @set;
                public RootFdfsolverIterate iterate;
        }
        
        [Compact]
        [CCode (cname="gsl_root_fdfsolver", cheader_filename="gsl/gsl_roots.h")]
        public class RootFdfsolver
        {
                public RootFdfsolverType* type;
                public FunctionFdf* fdf;
                public double root;
                public void* state;
                
                [CCode (cname="gsl_root_fdfsolver_alloc")]
                public RootFdfsolver (RootFdfsolverType* T);
                public int @set (FunctionFdf* fdf, double root);
                public int iterate ();
                public unowned string name ();
        }
        
        [CCode (lower_case_cprefix="gsl_root_test_", cheader_filename="gsl/gsl_roots.h")]
        namespace RootTest
        {
                public static int interval (double x_lower, double x_upper, double epsabs, double epsrel);
                public static int residual (double f, double epsabs);
                public static int delta (double x1, double x0, double epsabs, double epsrel);
        }
        
        [CCode (lower_case_cprefix="gsl_root_fsolver_", cheader_filename="gsl/gsl_roots.h")]
        namespace RootFsolverTypes
        {
                public static RootFsolverType* bisection;
                public static RootFsolverType* brent;
                public static RootFsolverType* falsepos;
        }
        
        [CCode (lower_case_cprefix="gsl_root_fdfsolver_", cheader_filename="gsl/gsl_roots.h")]
        namespace RootFdfsolverTypes
        {
                public static RootFdfsolverType* newton;
                public static RootFdfsolverType* secant;
                public static RootFdfsolverType* steffenson;
        }
        
        
        /*
         * One dimensional Minimization
         */
        [CCode (has_target = false)]
        public delegate int MinSet (void* state, Function* f, double xminimun, double f_minimum, double x_lower, double f_lower, double x_upper, double f_upper);
        [CCode (has_target = false)]
        public delegate int MinIterate (void *state, Function* f, double* x_minimum, double* f_minimum, double* x_lower, double* f_lower, double* x_upper, double* f_upper);
        [CCode (has_target = false)]
        public delegate int MinBracketingFunction (Function* f, double* x_minimum, double* f_minimum, double* x_lower, double* f_lower, double* x_upper, double* f_upper, size_t eval_max);
        
        [SimpleType]
        [CCode (cname="gsl_min_fminimizer_type", cheader_filename="gsl/gsl_min.h")]
        public struct MinFminimizerType
        {
                public string name;
                public size_t size;
                public MinSet @set;
                public MinIterate iterate;
        }
        
        [Compact]
        [CCode (cname="gsl_min_fminimizer", cheader_filename="gsl/gsl_min.h")]
        public class MinFminimizer
        {
                public MinFminimizerType* type;
                public Function* function;
                public double x_minimum;
                public double x_lower;
                public double x_upper;
                public double f_minimum;
                public double f_lower;
                public double f_upper;
                public void* state;
                
                [CCode (cname="gsl_min_fminimizer_alloc")]
                public MinFminimizer (MinFminimizerType* T) ;
                public int @set (Function* f, double x_minimum, double x_lower, double x_upper);
                public int set_with_values (Function* f, double x_minimum, double f_minimum, double x_lower, double f_lower, double x_upper, double f_upper);
                public int iterate ();
                public unowned string name ();
        }
        
        [CCode (lower_case_cprefix="gsl_min_test_", cheader_filename="gsl/gsl_min.h")]
        namespace MinTest
        {
                public static int interval (double x_lower, double x_upper, double epsabs, double epsrel);
        }
        
        [CCode (lower_case_cprefix="gsl_min_fminimizer_", cheader_filename="gsl/gsl_min.h")]
        namespace MinFminimizerTypes
        {
                public static MinFminimizerType* goldensection;
                public static MinFminimizerType* brent;
        }
        
        [CCode (cname="gsl_min_find_bracket", cheader_filename="gsl/gsl_min.h")]
        public static int find_bracket (Function* f, double* x_minimum, double* f_minimum, double* x_lower, double* f_lower, double* x_upper, double* f_upper, size_t eval_max);
        
        
        /*
         * Multidimensional Root-Finding
         */
        [CCode (has_target = false)]
        public delegate int MultirootF (Vector x, void* params, Vector f);
        [CCode (has_target = false)]
        public delegate int MultirootFAlloc (void* state, size_t n);
        [CCode (has_target = false)]
        public delegate int MultirootFSet (void* state, MultirootFunction* function, Vector x, Vector f, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultirootFIterate (void* state, MultirootFunction* function, Vector x, Vector f, Vector dx);
        [CCode (has_target = false)]
        public delegate void MultirootFFree (void* state);
        [CCode (has_target = false)]
        public delegate int MultirootDF (Vector x, void* params, Matrix df);
        [CCode (has_target = false)]
        public delegate int MultirootFDF (Vector x, void* params, Vector f, Matrix df);
        [CCode (has_target = false)]
        public delegate int MultirootFdfAlloc (void* state, size_t n);
        [CCode (has_target = false)]
        public delegate int MultirootFdfSet (void* state, MultirootFunctionFdf* fdf, Vector x, Vector f, Matrix J, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultirootFdfIterate (void* state, MultirootFunctionFdf* fdf, Vector x, Vector f, Matrix J, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultirootFdfFree (void* state);
        
        [SimpleType]
        [CCode (cname="gsl_multiroot_function", cheader_filename="gsl/gsl_multiroots.h")]
        public struct MultirootFunction
        {
                public MultirootF f;
                public size_t n;
                public void* params;
        }

        [CCode (cname="gsl_multiroot_fdjacobian", cheader_filename="gsl/gsl_multiroots.h")]
        public static int multiroot_fdjacobian (MultirootFunction* F, Vector x, Vector f, double epsrel, Matrix jacobian);
        
        [SimpleType]
        [CCode (cname="gsl_multiroot_fsolver_type", cheader_filename="gsl/gsl_multiroots.h")]
        public struct MultirootFsolverType
        {
                public string name;
                public size_t size;
                public MultirootFAlloc alloc;
                public MultirootFSet @set;
                public MultirootFIterate iterate;
                public MultirootFFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_multiroot_fsolver", cheader_filename="gsl/gsl_multiroots.h")]
        public class MultirootFsolver
        {
                public MultirootFsolverType* type;
                public MultirootFunction* function;
                public Vector x;
                public Vector f;
                public Vector dx;
                public void* state;
                
                [CCode (cname="gsl_multiroot_fsolver_alloc")]
                public MultirootFsolver (MultirootFsolverType* T, size_t n); 
                public int @set (MultirootFunction* f, Vector x);
                public int iterate ();
                public unowned string name ();
                public Vector root ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_multiroot_function_fdf", cheader_filename="gsl/gsl_multiroots.h")]
        public struct MultirootFunctionFdf
        {
                public MultirootF f;
                public MultirootDF df;
                public MultirootFDF fdf;
                public size_t n;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_multiroot_fdfsolver_type", cheader_filename="gsl/gsl_multiroots.h")]
        public struct MultirootFdfsolverType
        {
                public string name;
                public size_t size;
                public MultirootFdfAlloc alloc;
                public MultirootFdfSet @set;
                public MultirootFdfIterate iterate;
                public MultirootFdfFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_multiroot_fdfsolver", cheader_filename="gsl/gsl_multiroots.h")]
        public class MultirootFdfsolver
        {
                public MultirootFdfsolverType* type;
                public MultirootFunctionFdf* fdf;
                public Vector x;
                public Vector f;
                public Matrix J;
                public Vector dx;
                public void* state;
                
                [CCode (cname="gsl_multiroot_fdfsolver_alloc")]
                public MultirootFdfsolver (MultirootFdfsolverType* T, size_t n);
                public int @set (MultirootFunctionFdf* fdf, Vector x);
                public int iterate ();
                public unowned string name ();
                public Vector root ();
        }
        
        [CCode (lower_case_cprefix="gsl_multiroot_test_", cheader_filename="gsl/gsl_multiroots.h")]
        namespace MultirootTest
        {
                public static int delta (Vector dx, Vector x, double epsabs, double epsrel);
                public static int residual (Vector f, double epsabs);
        }
        
        [CCode (lower_case_cprefix="gsl_multiroot_fsolver_", cheader_filename="gsl/gsl_multiroots.h")]
        namespace MultirootFsolverTypes
        {
                public static MultirootFsolverType* dnewton;
                public static MultirootFsolverType* broyden;
                public static MultirootFsolverType* hybrid;
                public static MultirootFsolverType* hybrids;
        }
        
        [CCode (lower_case_cprefix="gsl_multiroot_fdfsolver_", cheader_filename="gsl/gsl_multiroots.h")]
        namespace MultirootFdfsolverTypes
        {
                public static MultirootFdfsolverType* newton;
                public static MultirootFdfsolverType* gnewton;
                public static MultirootFdfsolverType* hybridj;
                public static MultirootFdfsolverType* hybridsj;
        }
        
        
        /*
         * Multidimensional Minimization
         */
        [CCode (has_target = false)]
        public delegate double MultiminF (Vector x, void* params);
        [CCode (has_target = false)]
        public delegate void MultiminDf (Vector x, void* params, Vector df);
        [CCode (has_target = false)]
        public delegate void MultiminFdf (Vector x, void* params, double* f, Vector df);
        [CCode (has_target = false)]
        public delegate int MultiminFAlloc (void *state, size_t n);
        [CCode (has_target = false)]
        public delegate int MultiminFSet (void* state, MultiminFunction* f, Vector x, double* size);
        [CCode (has_target = false)]
        public delegate int MultiminFIterate (void* state, MultiminFunction* f, Vector x, double* size, double* fval);
        [CCode (has_target = false)]
        public delegate int MultiminFFree (void* state);
        
        [SimpleType]
        [CCode (cname="gsl_multimin_function", cheader_filename="gsl/gsl_multimin.h")]
        public struct MultiminFunction
        {
                public MultiminF f;
                public size_t n;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_multimin_function_fdf", cheader_filename="gsl/gsl_multimin.h")]
        public struct MultiminFunctionFdf
        {
                public MultiminF f;
                public MultiminDf df;
                public MultiminFdf fdf;
                public size_t n;
                public void* params;
        }
        
        [CCode (cname="gsl_multimin_diff", cheader_filename="gsl/gsl_multimin.h")]
        public static int multimin_diff (MultiminFunction* f, Vector x, Vector g);
        
        [SimpleType]
        [CCode (cname="gsl_multimin_fminimizer_type", cheader_filename="gsl/gsl_multimin.h")]
        public struct MultiminFminimizerType
        {
                public string name;
                public size_t size;
                public MultiminFAlloc alloc;
                public MultiminFSet @set;
                public MultiminFIterate iterate;
                public MultiminFFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_multimin_fminimizer", cheader_filename="gsl/gsl_multimin.h")]
        public class MultiminFminimizer
        {
                public MultiminFminimizerType* type;
                public MultiminFunction* f;
                public double fval;
                public Vector x;
                public double size;
                public void* state;
                
                [CCode (cname="gsl_multimin_fminimizer_alloc")]
                public MultiminFminimizer (MultiminFminimizerType* T, size_t n);
                public int @set (MultiminFunction* f, Vector x, Vector step_size);
                public unowned string name ();
                public int iterate ();
                public double minimum ();
        }
        
        [CCode (lower_case_cprefix="gsl_multimin_test_", cheader_filename="gsl/gsl_multimin.h")]
        namespace MultiminTest
        {
                public static int gradient(Vector g, double epsabs);
                public static int size (double size, double epsabs);
        }
        
        [CCode (has_target = false)]
        public delegate int MultiminFdfAlloc (void *state, size_t n);
        [CCode (has_target = false)]
        public delegate int MultiminFdfSet (void* state, MultiminFunctionFdf* fdf, Vector x, double* f, Vector gradient, double step_size, double tol);
        [CCode (has_target = false)]
        public delegate int MultiminFdfIterate (void* state, MultiminFunctionFdf* fdf, Vector x, double* f, Vector gradient, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultiminFdfRestart (void* state);
        [CCode (has_target = false)]
        public delegate int MultiminFdfFree (void* state);
        
        [SimpleType]
        [CCode (cname="gsl_multimin_fdfminimizer_type", cheader_filename="gsl/gsl_multimin.h")]
        public struct MultiminFdfminimizerType
        {
                public string name;
                public size_t size;
                public MultiminFdfAlloc alloc;
                public MultiminFdfSet @set;
                public MultiminFdfIterate iterate;
                public MultiminFdfRestart restart;
                public MultiminFdfFree free;    
        }
        
        [Compact]
        [CCode (cname="gsl_multimin_fdfminimizer", cheader_filename="gsl/gsl_multimin.h")]
        public class MultiminFdfminimizer
        {
                public MultiminFdfminimizerType* type;
                public MultiminFunctionFdf* fdf;
                public double f;
                public Vector x;
                public Vector gradient;
                public Vector dx;
                public void* state;
                
                [CCode (cname="gsl_multimin_fdfminimizer_alloc")]
                public MultiminFdfminimizer (MultiminFdfminimizerType* T, size_t n);
                public int @set (MultiminFunctionFdf* fdf, Vector x, double step_size, double tol);
                public unowned string name ();
                public int iterate ();
                public int restart ();
                public double minimum ();
        }
        
        [CCode (lower_case_cprefix="gsl_multimin_fdfminimizer_", cheader_filename="gsl/gsl_multimin.h")]
        namespace MultiminFdfminimizerTypes
        {
                public static MultiminFdfminimizerType* steepest_descent;
                public static MultiminFdfminimizerType* conjugate_pr;
                public static MultiminFdfminimizerType* conjugate_fr;
                public static MultiminFdfminimizerType* vector_bfgs;
                public static MultiminFdfminimizerType* vector_bfgs2;
        }
        
        [CCode (lower_case_cprefix="gsl_multimin_fminimizer_", cheader_filename="gsl/gsl_multimin.h")]
        namespace MultiminFminimizerTypes
        {
                public static MultiminFminimizerType* nmsimplex;
        }
        
        
        /*
         * Least-Squares Fitting
         */
        [CCode (lower_case_cprefix="gsl_fit_", cheader_filename="gsl/gsl_fit.h")]
        namespace Fit
        {
                public static int linear ([CCode (array_length = false)] double[] x, size_t xstride, [CCode (array_length = false)] double[] y, size_t ystride, size_t n, out double c0, out double c1, out double cov00, out double cov01, out double cov11, out double sumsq);
                public static int wlinear ([CCode (array_length = false)] double[] x, size_t xstride, [CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] y, size_t ystride, size_t n, out double c0, out double c1, out double cov00, out double cov01, out double cov11, double chisq);
                public static int linear_est (double x, double c0, double c1, double cov00, double cov01, double cov11, out double y, out double y_err);
                public static int mul ([CCode (array_length = false)] double[] x, size_t xstride, [CCode (array_length = false)] double[] y, size_t ystride, size_t n, out double c1, out double cov11, out double sumsq);
                public static int wmul ([CCode (array_length = false)] double[] x, size_t xstride, [CCode (array_length = false)] double[] w, size_t wstride, [CCode (array_length = false)] double[] y, size_t ystride, size_t n, out double c1, out double cov11, out double sumsq);
                public static int mul_est (double x, double c1, double cov11, out double y, out double y_err);
        }
        
        [Compact]
        [CCode (cname="gsl_multifit_linear_workspace", cheader_filename="gsl/gsl_multifit.h")]
        public class MultifitLinearWorkspace
        {
                public size_t n;
                public size_t p;
                public Matrix A;
                public Matrix Q;
                public Matrix QSI;
                public Vector S;
                public Vector t;
                public Vector xt;
                public Vector D;
                
                [CCode (cname="gsl_multifit_linear_workspace_alloc")]
                public MultifitLinearWorkspace (size_t n, size_t p);
        }
        
        [CCode (lower_case_cprefix="gsl_multifit_", cheader_filename="gsl/gsl_multifit.h")]
        namespace Multifit
        {
                public static int linear (Matrix X, Vector y, Vector c, Matrix cov, out double chisq, MultifitLinearWorkspace work);
                public static int linear_svd (Matrix X, Vector y, double tol, out size_t rank, Vector c, Matrix cov, out double chisq, MultifitLinearWorkspace work);
                public static int wlinear (Matrix X, Vector w, Vector y, Vector c, Matrix cov, out double chisq, MultifitLinearWorkspace work);
                public static int wlinear_svd (Matrix X, Vector w, Vector y, double tol, out size_t rank, Vector c, Matrix cov, out double chisq, MultifitLinearWorkspace work);
                public static int linear_est (Vector x, Vector c, Matrix cov, out double y, out double y_err);
                public int linear_residuals (Matrix X, Vector y, Vector c, Vector r);
        }
        
        
        /*
         * Nonlinear Least-Squares Fitting
         */
        [CCode (has_target = false)]
        public delegate int MultifitF (Vector x, void* params, Vector f);
        [CCode (has_target = false)]
        public delegate int MultifitFAlloc (void* state, size_t n, size_t p);
        [CCode (has_target = false)]
        public delegate int MultifitFSet (void* state, MultifitFunction* function, Vector x, Vector f, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultifitFIterate (void* state, MultifitFunction* function, Vector x, Vector f, Vector dx);
        [CCode (has_target = false)]
        public delegate void MultifitFFree (void* state);
        [CCode (has_target = false)]
        public delegate int MultifitDf (Vector x, void* params, Matrix df);
        [CCode (has_target = false)]
        public delegate int MultifitFdf (Vector x, void* params, Vector f, Matrix df);
        [CCode (has_target = false)]
        public delegate int MultifitFdfAlloc (void* state, size_t n, size_t p);
        [CCode (has_target = false)]
        public delegate int MultifitFdfSet (void* state, MultifitFunctionFdf fdf, Vector x, Vector f, Matrix J, Vector dx);
        [CCode (has_target = false)]
        public delegate int MultifitFdfIterate (void* state, MultifitFunctionFdf fdf, Vector x, Vector f, Matrix J, Vector dx);
        [CCode (has_target = false)]
        public delegate void MultifitFdfFree (void* state);

        [CCode (lower_case_cprefix="gsl_multifit_", cheader_filename="gsl/gsl_multifit_nlin.h")]
        namespace Multifit
        {
                public static int gradient (Matrix J, Vector f, Vector g);
                public static int covar (Matrix J, double epsrel, Matrix covar);
        }
        
        [SimpleType]
        [CCode (cname="gsl_multifit_function", cheader_filename="gls/gsl_multifit_nlin.h")]
        public struct MultifitFunction
        {
                public MultifitF f;
                public size_t n;
                public size_t p;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_multifit_fsolver_type", cheader_filename="gsl/gsl_multifit_nlin.h")]
        public struct MultifitFsolverType
        {
                public string name;
                public size_t size;
                public MultifitFAlloc alloc;
                public MultifitFSet @set;
                public MultifitFIterate iterate;
                public MultifitFFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_multifit_fsolver", cheader_filename="gsl/gsl_multifit_nlin.h")]
        public class MultifitFsolver
        {
                public MultifitFsolverType* type;
                public MultifitFunction* function;
                public Vector x;
                public Vector f;
                public Vector dx;
                public void* state;
                
                [CCode (cname="gsl_multifit_fsolver_alloc")]
                public MultifitFsolver (MultifitFsolverType* T,  size_t n, size_t p);
                public int @set (MultifitFunction* f, Vector x);
                public int iterate ();
                public unowned string name ();
                public Vector position ();
        }
        
        [SimpleType]
        [CCode (cname="gsl_multifit_function_fdf", cheader_filename="gsl/gsl_multifit_nlin.h")]
        public struct MultifitFunctionFdf
        {
                public MultifitF f;
                public MultifitDf df;
                public MultifitFdf fdf;
                public size_t n;
                public size_t p;
                public void* params;
        }
        
        [SimpleType]
        [CCode (cname="gsl_multifit_fdfsolver_type", cheader_filename="gsl/gsl_multifit_nlin.h")]
        public struct MultifitFdfsolverType
        {
                public string name;
                public size_t size;
                public MultifitFdfAlloc alloc;
                public MultifitFdfSet @set;
                public MultifitFdfIterate iterate;
                public MultifitFdfFree free;
        }
        
        [Compact]
        [CCode (cname="gsl_multifit_fdfsolver", cheader_filename="gsl/gsl_multifit_nlin.h")]
        public class MultifitFdfsolver
        {
                public MultifitFdfsolverType* type;
                public MultifitFunctionFdf* fdf;
                public Vector x;
                public Vector f;
                public Vector J;
                public Vector dx;
                public void* state;
                
                [CCode (cname="gsl_multifit_fdfsolver_alloc")]
                public MultifitFdfsolver (MultifitFdfsolverType* T, size_t n, size_t p);
                public int @set (MultifitFunctionFdf* fdf, Vector x);
                public int iterate ();
                public unowned string name ();
                public Vector position ();
        }
        
        [CCode (lower_case_cprefix="gsl_multifit_test_", cheader_filename="gsl/gsl_multifit_nlin.h")]
        namespace MultifitTest
        {
                public static int delta (Vector dx, Vector x, double epsabs, double epsrel);
                public static int gradient (Vector g, double epsabs);
        }
        
        [CCode (lower_case_cprefix="gsl_multifit_fdfsolver_", cheader_filename="gsl/gsl_multifit_nlin.h")]
        namespace MultifitFdfsolverTypes
        {
                public static MultifitFdfsolverType* lmder;
                public static MultifitFdfsolverType* lmsder;
        }
        
        
        /*
         * Basis Splines
         */
        [Compact]
        [CCode (cname="gsl_bspline_workspace", cprefix="gsl_bspline_", cheader_filename="gsl/gsl_bspline.h")]
        public class BsplineWorkspace
        {
                public size_t k;
                public size_t km1;
                public size_t l;
                public size_t nbreak;
                public size_t n;
                public Vector knots;
                public Vector deltal;
                public Vector deltar;
                public Vector B;
                
                [CCode (cname="gsl_bspline_alloc")]
                public BsplineWorkspace (size_t k, size_t nbreak);
                public size_t ncoeffs ();
                public size_t order ();
                [CCode (instance_pos=-1)]
                public double breakpoint (size_t i);
                [CCode (instance_pos=-1)]
                public int knots_uniform (double a, double b);
                [CCode (instance_pos=-1)]
                public int eval (double x, Vector B);
        }
}