# This file was automatically generated by SWIG (https://www.swig.org). # Version 4.2.0 # # Do not make changes to this file unless you know what you are doing - modify # the SWIG interface file instead. package Math::GSL::Sys; use base qw(Exporter); use base qw(DynaLoader); package Math::GSL::Sysc; bootstrap Math::GSL::Sys; package Math::GSL::Sys; @EXPORT = qw(); # ---------- BASE METHODS ------------- package Math::GSL::Sys; sub TIEHASH { my ($classname,$obj) = @_; return bless $obj, $classname; } sub CLEAR { } sub FIRSTKEY { } sub NEXTKEY { } sub FETCH { my ($self,$field) = @_; my $member_func = "swig_${field}_get"; $self->$member_func(); } sub STORE { my ($self,$field,$newval) = @_; my $member_func = "swig_${field}_set"; $self->$member_func($newval); } sub this { my $ptr = shift; return tied(%$ptr); } # ------- FUNCTION WRAPPERS -------- package Math::GSL::Sys; *gsl_error = *Math::GSL::Sysc::gsl_error; *gsl_stream_printf = *Math::GSL::Sysc::gsl_stream_printf; *gsl_strerror = *Math::GSL::Sysc::gsl_strerror; *gsl_set_error_handler = *Math::GSL::Sysc::gsl_set_error_handler; *gsl_set_error_handler_off = *Math::GSL::Sysc::gsl_set_error_handler_off; *gsl_set_stream_handler = *Math::GSL::Sysc::gsl_set_stream_handler; *gsl_set_stream = *Math::GSL::Sysc::gsl_set_stream; *gsl_log1p = *Math::GSL::Sysc::gsl_log1p; *gsl_expm1 = *Math::GSL::Sysc::gsl_expm1; *gsl_hypot = *Math::GSL::Sysc::gsl_hypot; *gsl_hypot3 = *Math::GSL::Sysc::gsl_hypot3; *gsl_acosh = *Math::GSL::Sysc::gsl_acosh; *gsl_asinh = *Math::GSL::Sysc::gsl_asinh; *gsl_atanh = *Math::GSL::Sysc::gsl_atanh; *gsl_isnan = *Math::GSL::Sysc::gsl_isnan; *gsl_isinf = *Math::GSL::Sysc::gsl_isinf; *gsl_finite = *Math::GSL::Sysc::gsl_finite; *gsl_nan = *Math::GSL::Sysc::gsl_nan; *gsl_posinf = *Math::GSL::Sysc::gsl_posinf; *gsl_neginf = *Math::GSL::Sysc::gsl_neginf; *gsl_fdiv = *Math::GSL::Sysc::gsl_fdiv; *gsl_coerce_double = *Math::GSL::Sysc::gsl_coerce_double; *gsl_coerce_float = *Math::GSL::Sysc::gsl_coerce_float; *gsl_coerce_long_double = *Math::GSL::Sysc::gsl_coerce_long_double; *gsl_ldexp = *Math::GSL::Sysc::gsl_ldexp; *gsl_frexp = *Math::GSL::Sysc::gsl_frexp; *gsl_fcmp = *Math::GSL::Sysc::gsl_fcmp; # ------- VARIABLE STUBS -------- package Math::GSL::Sys; *GSL_VERSION = *Math::GSL::Sysc::GSL_VERSION; *GSL_MAJOR_VERSION = *Math::GSL::Sysc::GSL_MAJOR_VERSION; *GSL_MINOR_VERSION = *Math::GSL::Sysc::GSL_MINOR_VERSION; *GSL_POSZERO = *Math::GSL::Sysc::GSL_POSZERO; *GSL_NEGZERO = *Math::GSL::Sysc::GSL_NEGZERO; *GSL_SUCCESS = *Math::GSL::Sysc::GSL_SUCCESS; *GSL_FAILURE = *Math::GSL::Sysc::GSL_FAILURE; *GSL_CONTINUE = *Math::GSL::Sysc::GSL_CONTINUE; *GSL_EDOM = *Math::GSL::Sysc::GSL_EDOM; *GSL_ERANGE = *Math::GSL::Sysc::GSL_ERANGE; *GSL_EFAULT = *Math::GSL::Sysc::GSL_EFAULT; *GSL_EINVAL = *Math::GSL::Sysc::GSL_EINVAL; *GSL_EFAILED = *Math::GSL::Sysc::GSL_EFAILED; *GSL_EFACTOR = *Math::GSL::Sysc::GSL_EFACTOR; *GSL_ESANITY = *Math::GSL::Sysc::GSL_ESANITY; *GSL_ENOMEM = *Math::GSL::Sysc::GSL_ENOMEM; *GSL_EBADFUNC = *Math::GSL::Sysc::GSL_EBADFUNC; *GSL_ERUNAWAY = *Math::GSL::Sysc::GSL_ERUNAWAY; *GSL_EMAXITER = *Math::GSL::Sysc::GSL_EMAXITER; *GSL_EZERODIV = *Math::GSL::Sysc::GSL_EZERODIV; *GSL_EBADTOL = *Math::GSL::Sysc::GSL_EBADTOL; *GSL_ETOL = *Math::GSL::Sysc::GSL_ETOL; *GSL_EUNDRFLW = *Math::GSL::Sysc::GSL_EUNDRFLW; *GSL_EOVRFLW = *Math::GSL::Sysc::GSL_EOVRFLW; *GSL_ELOSS = *Math::GSL::Sysc::GSL_ELOSS; *GSL_EROUND = *Math::GSL::Sysc::GSL_EROUND; *GSL_EBADLEN = *Math::GSL::Sysc::GSL_EBADLEN; *GSL_ENOTSQR = *Math::GSL::Sysc::GSL_ENOTSQR; *GSL_ESING = *Math::GSL::Sysc::GSL_ESING; *GSL_EDIVERGE = *Math::GSL::Sysc::GSL_EDIVERGE; *GSL_EUNSUP = *Math::GSL::Sysc::GSL_EUNSUP; *GSL_EUNIMPL = *Math::GSL::Sysc::GSL_EUNIMPL; *GSL_ECACHE = *Math::GSL::Sysc::GSL_ECACHE; *GSL_ETABLE = *Math::GSL::Sysc::GSL_ETABLE; *GSL_ENOPROG = *Math::GSL::Sysc::GSL_ENOPROG; *GSL_ENOPROGJ = *Math::GSL::Sysc::GSL_ENOPROGJ; *GSL_ETOLF = *Math::GSL::Sysc::GSL_ETOLF; *GSL_ETOLX = *Math::GSL::Sysc::GSL_ETOLX; *GSL_ETOLG = *Math::GSL::Sysc::GSL_ETOLG; *GSL_EOF = *Math::GSL::Sysc::GSL_EOF; our @EXPORT = qw(); our @EXPORT_OK = qw/ gsl_log1p gsl_expm1 gsl_hypot gsl_hypot3 gsl_acosh gsl_asinh gsl_atanh gsl_isnan gsl_isinf gsl_finite gsl_posinf gsl_neginf gsl_fdiv gsl_coerce_double gsl_coerce_float gsl_coerce_long_double gsl_ldexp gsl_frexp gsl_fcmp gsl_nan gsl_isnan gsl_inf $GSL_NAN $GSL_POSINF $GSL_NEGINF /; our %EXPORT_TAGS = ( all => \@EXPORT_OK ); our $GSL_NAN = gsl_nan(); our $GSL_POSINF = gsl_posinf(); our $GSL_NEGINF = gsl_neginf(); __END__ =encoding utf8 =head1 NAME Math::GSL::Sys - Misc Math Functions =head1 SYNOPSIS use Math::GSL::Sys qw/:all/; =head1 DESCRIPTION This module contains various useful math functions that are not usually provided by standard libraries. =over =item * C This function computes the value of \log(1+$x) in a way that is accurate for small $x. It provides an alternative to the BSD math function log1p(x). =item * C This function computes the value of \exp($x)-1 in a way that is accurate for small $x. It provides an alternative to the BSD math function expm1(x). =item * C This function computes the value of \sqrt{$x^2 + $y^2} in a way that avoids overflow. It provides an alternative to the BSD math function hypot($x,$y). =item * C This function computes the value of \sqrt{$x^2 + $y^2 + $z^2} in a way that avoids overflow. =item * C This function computes the value of \arccosh($x). It provides an alternative to the standard math function acosh($x). =item * C This function computes the value of \arcsinh($x). It provides an alternative to the standard math function asinh($x). =item * C This function computes the value of \arctanh($x). It provides an alternative to the standard math function atanh($x). =item * C This function returns 1 if $x is not-a-number. =item * C This function returns +1 if $x is positive infinity, -1 if $x is negative infinity and 0 otherwise. =item * C This function returns 1 if $x is a real number, and 0 if it is infinite or not-a-number. =item * C =item * C =item * C =item * C =item * C =item * C =item * C This function computes the value of $x * 2**$e. It provides an alternative to the standard math function ldexp($x,$e). =item * C This function splits the number $x into its normalized fraction f and exponent e, such that $x = f * 2^e and 0.5 <= f < 1. The function returns f and then the exponent in e. If $x is zero, both f and e are set to zero. This function provides an alternative to the standard math function frexp(x, e). =item * C This function determines whether $x and $y are approximately equal to a relative accuracy $epsilon. The relative accuracy is measured using an interval of size 2 \delta, where \delta = 2^k \epsilon and k is the maximum base-2 exponent of $x and $y as computed by the function frexp. If $x and $y lie within this interval, they are considered approximately equal and the function returns 0. Otherwise if $x < $y, the function returns -1, or if $x > $y, the function returns +1. Note that $x and $y are compared to relative accuracy, so this function is not suitable for testing whether a value is approximately zero. The implementation is based on the package fcmp by T.C. Belding. =back For more informations on the functions, we refer you to the GSL official documentation: L =head1 AUTHORS Jonathan "Duke" Leto and Thierry Moisan =head1 COPYRIGHT AND LICENSE Copyright (C) 2008-2024 Jonathan "Duke" Leto and Thierry Moisan This program is free software; you can redistribute it and/or modify it under the same terms as Perl itself. =cut 1;