# This file was automatically generated by SWIG (http://www.swig.org). # Version 1.3.37 # # Don't modify this file, modify the SWIG interface instead. package Math::GSL::MatrixComplex; use base qw(Exporter); use base qw(DynaLoader); package Math::GSL::MatrixComplexc; bootstrap Math::GSL::MatrixComplex; package Math::GSL::MatrixComplex; @EXPORT = qw(); # ---------- BASE METHODS ------------- package Math::GSL::MatrixComplex; 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::MatrixComplex; *gsl_vector_alloc = *Math::GSL::MatrixComplexc::gsl_vector_alloc; *gsl_vector_calloc = *Math::GSL::MatrixComplexc::gsl_vector_calloc; *gsl_vector_alloc_from_block = *Math::GSL::MatrixComplexc::gsl_vector_alloc_from_block; *gsl_vector_alloc_from_vector = *Math::GSL::MatrixComplexc::gsl_vector_alloc_from_vector; *gsl_vector_free = *Math::GSL::MatrixComplexc::gsl_vector_free; *gsl_vector_view_array = *Math::GSL::MatrixComplexc::gsl_vector_view_array; *gsl_vector_view_array_with_stride = *Math::GSL::MatrixComplexc::gsl_vector_view_array_with_stride; *gsl_vector_const_view_array = *Math::GSL::MatrixComplexc::gsl_vector_const_view_array; *gsl_vector_const_view_array_with_stride = *Math::GSL::MatrixComplexc::gsl_vector_const_view_array_with_stride; *gsl_vector_subvector = *Math::GSL::MatrixComplexc::gsl_vector_subvector; *gsl_vector_subvector_with_stride = *Math::GSL::MatrixComplexc::gsl_vector_subvector_with_stride; *gsl_vector_const_subvector = *Math::GSL::MatrixComplexc::gsl_vector_const_subvector; *gsl_vector_const_subvector_with_stride = *Math::GSL::MatrixComplexc::gsl_vector_const_subvector_with_stride; *gsl_vector_get = *Math::GSL::MatrixComplexc::gsl_vector_get; *gsl_vector_set = *Math::GSL::MatrixComplexc::gsl_vector_set; *gsl_vector_ptr = *Math::GSL::MatrixComplexc::gsl_vector_ptr; *gsl_vector_const_ptr = *Math::GSL::MatrixComplexc::gsl_vector_const_ptr; *gsl_vector_set_zero = *Math::GSL::MatrixComplexc::gsl_vector_set_zero; *gsl_vector_set_all = *Math::GSL::MatrixComplexc::gsl_vector_set_all; *gsl_vector_set_basis = *Math::GSL::MatrixComplexc::gsl_vector_set_basis; *gsl_vector_fread = *Math::GSL::MatrixComplexc::gsl_vector_fread; *gsl_vector_fwrite = *Math::GSL::MatrixComplexc::gsl_vector_fwrite; *gsl_vector_fscanf = *Math::GSL::MatrixComplexc::gsl_vector_fscanf; *gsl_vector_fprintf = *Math::GSL::MatrixComplexc::gsl_vector_fprintf; *gsl_vector_memcpy = *Math::GSL::MatrixComplexc::gsl_vector_memcpy; *gsl_vector_reverse = *Math::GSL::MatrixComplexc::gsl_vector_reverse; *gsl_vector_swap = *Math::GSL::MatrixComplexc::gsl_vector_swap; *gsl_vector_swap_elements = *Math::GSL::MatrixComplexc::gsl_vector_swap_elements; *gsl_vector_max = *Math::GSL::MatrixComplexc::gsl_vector_max; *gsl_vector_min = *Math::GSL::MatrixComplexc::gsl_vector_min; *gsl_vector_minmax = *Math::GSL::MatrixComplexc::gsl_vector_minmax; *gsl_vector_max_index = *Math::GSL::MatrixComplexc::gsl_vector_max_index; *gsl_vector_min_index = *Math::GSL::MatrixComplexc::gsl_vector_min_index; *gsl_vector_minmax_index = *Math::GSL::MatrixComplexc::gsl_vector_minmax_index; *gsl_vector_add = *Math::GSL::MatrixComplexc::gsl_vector_add; *gsl_vector_sub = *Math::GSL::MatrixComplexc::gsl_vector_sub; *gsl_vector_mul = *Math::GSL::MatrixComplexc::gsl_vector_mul; *gsl_vector_div = *Math::GSL::MatrixComplexc::gsl_vector_div; *gsl_vector_scale = *Math::GSL::MatrixComplexc::gsl_vector_scale; *gsl_vector_add_constant = *Math::GSL::MatrixComplexc::gsl_vector_add_constant; *gsl_vector_isnull = *Math::GSL::MatrixComplexc::gsl_vector_isnull; *gsl_vector_ispos = *Math::GSL::MatrixComplexc::gsl_vector_ispos; *gsl_vector_isneg = *Math::GSL::MatrixComplexc::gsl_vector_isneg; *gsl_vector_isnonneg = *Math::GSL::MatrixComplexc::gsl_vector_isnonneg; *gsl_matrix_complex_alloc = *Math::GSL::MatrixComplexc::gsl_matrix_complex_alloc; *gsl_matrix_complex_calloc = *Math::GSL::MatrixComplexc::gsl_matrix_complex_calloc; *gsl_matrix_complex_alloc_from_block = *Math::GSL::MatrixComplexc::gsl_matrix_complex_alloc_from_block; *gsl_matrix_complex_alloc_from_matrix = *Math::GSL::MatrixComplexc::gsl_matrix_complex_alloc_from_matrix; *gsl_vector_complex_alloc_row_from_matrix = *Math::GSL::MatrixComplexc::gsl_vector_complex_alloc_row_from_matrix; *gsl_vector_complex_alloc_col_from_matrix = *Math::GSL::MatrixComplexc::gsl_vector_complex_alloc_col_from_matrix; *gsl_matrix_complex_free = *Math::GSL::MatrixComplexc::gsl_matrix_complex_free; *gsl_matrix_complex_submatrix = *Math::GSL::MatrixComplexc::gsl_matrix_complex_submatrix; *gsl_matrix_complex_row = *Math::GSL::MatrixComplexc::gsl_matrix_complex_row; *gsl_matrix_complex_column = *Math::GSL::MatrixComplexc::gsl_matrix_complex_column; *gsl_matrix_complex_diagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_diagonal; *gsl_matrix_complex_subdiagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_subdiagonal; *gsl_matrix_complex_superdiagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_superdiagonal; *gsl_matrix_complex_subrow = *Math::GSL::MatrixComplexc::gsl_matrix_complex_subrow; *gsl_matrix_complex_subcolumn = *Math::GSL::MatrixComplexc::gsl_matrix_complex_subcolumn; *gsl_matrix_complex_view_array = *Math::GSL::MatrixComplexc::gsl_matrix_complex_view_array; *gsl_matrix_complex_view_array_with_tda = *Math::GSL::MatrixComplexc::gsl_matrix_complex_view_array_with_tda; *gsl_matrix_complex_view_vector = *Math::GSL::MatrixComplexc::gsl_matrix_complex_view_vector; *gsl_matrix_complex_view_vector_with_tda = *Math::GSL::MatrixComplexc::gsl_matrix_complex_view_vector_with_tda; *gsl_matrix_complex_const_submatrix = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_submatrix; *gsl_matrix_complex_const_row = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_row; *gsl_matrix_complex_const_column = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_column; *gsl_matrix_complex_const_diagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_diagonal; *gsl_matrix_complex_const_subdiagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_subdiagonal; *gsl_matrix_complex_const_superdiagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_superdiagonal; *gsl_matrix_complex_const_subrow = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_subrow; *gsl_matrix_complex_const_subcolumn = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_subcolumn; *gsl_matrix_complex_const_view_array = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_view_array; *gsl_matrix_complex_const_view_array_with_tda = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_view_array_with_tda; *gsl_matrix_complex_const_view_vector = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_view_vector; *gsl_matrix_complex_const_view_vector_with_tda = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_view_vector_with_tda; *gsl_matrix_complex_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_get; *gsl_matrix_complex_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set; *gsl_matrix_complex_ptr = *Math::GSL::MatrixComplexc::gsl_matrix_complex_ptr; *gsl_matrix_complex_const_ptr = *Math::GSL::MatrixComplexc::gsl_matrix_complex_const_ptr; *gsl_matrix_complex_set_zero = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set_zero; *gsl_matrix_complex_set_identity = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set_identity; *gsl_matrix_complex_set_all = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set_all; *gsl_matrix_complex_fread = *Math::GSL::MatrixComplexc::gsl_matrix_complex_fread; *gsl_matrix_complex_fwrite = *Math::GSL::MatrixComplexc::gsl_matrix_complex_fwrite; *gsl_matrix_complex_fscanf = *Math::GSL::MatrixComplexc::gsl_matrix_complex_fscanf; *gsl_matrix_complex_fprintf = *Math::GSL::MatrixComplexc::gsl_matrix_complex_fprintf; *gsl_matrix_complex_memcpy = *Math::GSL::MatrixComplexc::gsl_matrix_complex_memcpy; *gsl_matrix_complex_swap = *Math::GSL::MatrixComplexc::gsl_matrix_complex_swap; *gsl_matrix_complex_swap_rows = *Math::GSL::MatrixComplexc::gsl_matrix_complex_swap_rows; *gsl_matrix_complex_swap_columns = *Math::GSL::MatrixComplexc::gsl_matrix_complex_swap_columns; *gsl_matrix_complex_swap_rowcol = *Math::GSL::MatrixComplexc::gsl_matrix_complex_swap_rowcol; *gsl_matrix_complex_transpose = *Math::GSL::MatrixComplexc::gsl_matrix_complex_transpose; *gsl_matrix_complex_transpose_memcpy = *Math::GSL::MatrixComplexc::gsl_matrix_complex_transpose_memcpy; *gsl_matrix_complex_isnull = *Math::GSL::MatrixComplexc::gsl_matrix_complex_isnull; *gsl_matrix_complex_ispos = *Math::GSL::MatrixComplexc::gsl_matrix_complex_ispos; *gsl_matrix_complex_isneg = *Math::GSL::MatrixComplexc::gsl_matrix_complex_isneg; *gsl_matrix_complex_add = *Math::GSL::MatrixComplexc::gsl_matrix_complex_add; *gsl_matrix_complex_sub = *Math::GSL::MatrixComplexc::gsl_matrix_complex_sub; *gsl_matrix_complex_mul_elements = *Math::GSL::MatrixComplexc::gsl_matrix_complex_mul_elements; *gsl_matrix_complex_div_elements = *Math::GSL::MatrixComplexc::gsl_matrix_complex_div_elements; *gsl_matrix_complex_scale = *Math::GSL::MatrixComplexc::gsl_matrix_complex_scale; *gsl_matrix_complex_add_constant = *Math::GSL::MatrixComplexc::gsl_matrix_complex_add_constant; *gsl_matrix_complex_add_diagonal = *Math::GSL::MatrixComplexc::gsl_matrix_complex_add_diagonal; *gsl_matrix_complex_get_row = *Math::GSL::MatrixComplexc::gsl_matrix_complex_get_row; *gsl_matrix_complex_get_col = *Math::GSL::MatrixComplexc::gsl_matrix_complex_get_col; *gsl_matrix_complex_set_row = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set_row; *gsl_matrix_complex_set_col = *Math::GSL::MatrixComplexc::gsl_matrix_complex_set_col; ############# Class : Math::GSL::MatrixComplex::gsl_complex_long_double ############## package Math::GSL::MatrixComplex::gsl_complex_long_double; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_dat_get = *Math::GSL::MatrixComplexc::gsl_complex_long_double_dat_get; *swig_dat_set = *Math::GSL::MatrixComplexc::gsl_complex_long_double_dat_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new_gsl_complex_long_double(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete_gsl_complex_long_double($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::gsl_complex ############## package Math::GSL::MatrixComplex::gsl_complex; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_dat_get = *Math::GSL::MatrixComplexc::gsl_complex_dat_get; *swig_dat_set = *Math::GSL::MatrixComplexc::gsl_complex_dat_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new_gsl_complex(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete_gsl_complex($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::gsl_complex_float ############## package Math::GSL::MatrixComplex::gsl_complex_float; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_dat_get = *Math::GSL::MatrixComplexc::gsl_complex_float_dat_get; *swig_dat_set = *Math::GSL::MatrixComplexc::gsl_complex_float_dat_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new_gsl_complex_float(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete_gsl_complex_float($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::gsl_vector ############## package Math::GSL::MatrixComplex::gsl_vector; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_size_get = *Math::GSL::MatrixComplexc::gsl_vector_size_get; *swig_size_set = *Math::GSL::MatrixComplexc::gsl_vector_size_set; *swig_stride_get = *Math::GSL::MatrixComplexc::gsl_vector_stride_get; *swig_stride_set = *Math::GSL::MatrixComplexc::gsl_vector_stride_set; *swig_data_get = *Math::GSL::MatrixComplexc::gsl_vector_data_get; *swig_data_set = *Math::GSL::MatrixComplexc::gsl_vector_data_set; *swig_block_get = *Math::GSL::MatrixComplexc::gsl_vector_block_get; *swig_block_set = *Math::GSL::MatrixComplexc::gsl_vector_block_set; *swig_owner_get = *Math::GSL::MatrixComplexc::gsl_vector_owner_get; *swig_owner_set = *Math::GSL::MatrixComplexc::gsl_vector_owner_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new_gsl_vector(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete_gsl_vector($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::_gsl_vector_view ############## package Math::GSL::MatrixComplex::_gsl_vector_view; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_vector_get = *Math::GSL::MatrixComplexc::_gsl_vector_view_vector_get; *swig_vector_set = *Math::GSL::MatrixComplexc::_gsl_vector_view_vector_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new__gsl_vector_view(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete__gsl_vector_view($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::_gsl_vector_const_view ############## package Math::GSL::MatrixComplex::_gsl_vector_const_view; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_vector_get = *Math::GSL::MatrixComplexc::_gsl_vector_const_view_vector_get; *swig_vector_set = *Math::GSL::MatrixComplexc::_gsl_vector_const_view_vector_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new__gsl_vector_const_view(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete__gsl_vector_const_view($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::gsl_matrix_complex ############## package Math::GSL::MatrixComplex::gsl_matrix_complex; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_size1_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_size1_get; *swig_size1_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_size1_set; *swig_size2_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_size2_get; *swig_size2_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_size2_set; *swig_tda_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_tda_get; *swig_tda_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_tda_set; *swig_data_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_data_get; *swig_data_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_data_set; *swig_block_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_block_get; *swig_block_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_block_set; *swig_owner_get = *Math::GSL::MatrixComplexc::gsl_matrix_complex_owner_get; *swig_owner_set = *Math::GSL::MatrixComplexc::gsl_matrix_complex_owner_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new_gsl_matrix_complex(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete_gsl_matrix_complex($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::_gsl_matrix_complex_view ############## package Math::GSL::MatrixComplex::_gsl_matrix_complex_view; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_matrix_get = *Math::GSL::MatrixComplexc::_gsl_matrix_complex_view_matrix_get; *swig_matrix_set = *Math::GSL::MatrixComplexc::_gsl_matrix_complex_view_matrix_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new__gsl_matrix_complex_view(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete__gsl_matrix_complex_view($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } ############# Class : Math::GSL::MatrixComplex::_gsl_matrix_complex_const_view ############## package Math::GSL::MatrixComplex::_gsl_matrix_complex_const_view; use vars qw(@ISA %OWNER %ITERATORS %BLESSEDMEMBERS); @ISA = qw( Math::GSL::MatrixComplex ); %OWNER = (); %ITERATORS = (); *swig_matrix_get = *Math::GSL::MatrixComplexc::_gsl_matrix_complex_const_view_matrix_get; *swig_matrix_set = *Math::GSL::MatrixComplexc::_gsl_matrix_complex_const_view_matrix_set; sub new { my $pkg = shift; my $self = Math::GSL::MatrixComplexc::new__gsl_matrix_complex_const_view(@_); bless $self, $pkg if defined($self); } sub DESTROY { return unless $_[0]->isa('HASH'); my $self = tied(%{$_[0]}); return unless defined $self; delete $ITERATORS{$self}; if (exists $OWNER{$self}) { Math::GSL::MatrixComplexc::delete__gsl_matrix_complex_const_view($self); delete $OWNER{$self}; } } sub DISOWN { my $self = shift; my $ptr = tied(%$self); delete $OWNER{$ptr}; } sub ACQUIRE { my $self = shift; my $ptr = tied(%$self); $OWNER{$ptr} = 1; } # ------- VARIABLE STUBS -------- package Math::GSL::MatrixComplex; *GSL_MAJOR_VERSION = *Math::GSL::MatrixComplexc::GSL_MAJOR_VERSION; *GSL_MINOR_VERSION = *Math::GSL::MatrixComplexc::GSL_MINOR_VERSION; *GSL_POSZERO = *Math::GSL::MatrixComplexc::GSL_POSZERO; *GSL_NEGZERO = *Math::GSL::MatrixComplexc::GSL_NEGZERO; use strict; use Carp qw/croak/; use Scalar::Util 'blessed'; use Math::Complex; use Data::Dumper; use Math::GSL qw/:all/; use Math::GSL::Errno qw/:all/; use Math::GSL::Eigen qw/:all/; use Math::GSL::Test qw/is_similar/; use Math::GSL::BLAS qw/gsl_blas_zgemm/; use Math::GSL::CBLAS qw/$CblasNoTrans/; use Math::GSL::Complex qw/:all/; use Math::GSL::Permutation; use Math::GSL::VectorComplex qw/:all/; use Math::GSL::Linalg qw/ gsl_linalg_complex_LU_decomp gsl_linalg_complex_LU_det gsl_linalg_complex_LU_lndet gsl_linalg_complex_LU_invert /; use overload '*' => \&_multiplication, '+' => \&_addition, '-' => \&_subtract, '==' => \&_equal, '!=' => \&_not_equal, # 'abs' => \&_abs, fallback => 1; our @EXPORT_OK = qw/ gsl_matrix_complex_alloc gsl_matrix_complex_calloc gsl_matrix_complex_alloc_from_block gsl_matrix_complex_alloc_from_matrix gsl_vector_complex_alloc_row_from_matrix gsl_vector_complex_alloc_col_from_matrix gsl_matrix_complex_free gsl_matrix_complex_submatrix gsl_matrix_complex_row gsl_matrix_complex_column gsl_matrix_complex_diagonal gsl_matrix_complex_subdiagonal gsl_matrix_complex_superdiagonal gsl_matrix_complex_subrow gsl_matrix_complex_subcolumn gsl_matrix_complex_view_array gsl_matrix_complex_view_array_with_tda gsl_matrix_complex_view_vector gsl_matrix_complex_view_vector_with_tda gsl_matrix_complex_const_submatrix gsl_matrix_complex_const_row gsl_matrix_complex_const_column gsl_matrix_complex_const_diagonal gsl_matrix_complex_const_subdiagonal gsl_matrix_complex_const_superdiagonal gsl_matrix_complex_const_subrow gsl_matrix_complex_const_subcolumn gsl_matrix_complex_const_view_array gsl_matrix_complex_const_view_array_with_tda gsl_matrix_complex_const_view_vector gsl_matrix_complex_const_view_vector_with_tda gsl_matrix_complex_get gsl_matrix_complex_set gsl_matrix_complex_ptr gsl_matrix_complex_const_ptr gsl_matrix_complex_set_zero gsl_matrix_complex_set_identity gsl_matrix_complex_set_all gsl_matrix_complex_fread gsl_matrix_complex_fwrite gsl_matrix_complex_fscanf gsl_matrix_complex_fprintf gsl_matrix_complex_memcpy gsl_matrix_complex_swap gsl_matrix_complex_swap_rows gsl_matrix_complex_swap_columns gsl_matrix_complex_swap_rowcol gsl_matrix_complex_transpose gsl_matrix_complex_transpose_memcpy gsl_matrix_complex_isnull gsl_matrix_complex_ispos gsl_matrix_complex_isneg gsl_matrix_complex_add gsl_matrix_complex_sub gsl_matrix_complex_mul_elements gsl_matrix_complex_div_elements gsl_matrix_complex_scale gsl_matrix_complex_add_constant gsl_matrix_complex_add_diagonal gsl_matrix_complex_get_row gsl_matrix_complex_get_col gsl_matrix_complex_set_row gsl_matrix_complex_set_col /; sub _multiplication { my ($left,$right) = @_; my $lcopy = $left->copy; if ( blessed $right && $right->isa('Math::GSL::MatrixComplex') ) { if ( $left->cols == $right->cols && $left->rows == $right->rows ) { return _dot_product($left,$right); #gsl_matrix_complex_mul_elements($lcopy->raw, $right->raw); } else { croak "Math::GSL::MatrixComplex - multiplication of elements of matrices must be called with two objects matrices and must have the same number of columns and rows"; } } else { gsl_matrix_complex_scale($lcopy->raw, $right); } return $lcopy; } sub _dot_product { my ($left,$right) = @_; croak "Math::GSL::Matrix - incompatible matrices in multiplication" unless ( blessed $right && $right->isa('Math::GSL::MatrixComplex') and $left->rows == $right->cols ); my $C = Math::GSL::MatrixComplex->new($left->rows, $right->cols); my $complex = gsl_complex_rect(1,0); gsl_blas_zgemm($CblasNoTrans, $CblasNoTrans, $complex, $left->raw, $right->raw, $complex, $C->raw); return $C; } sub _addition { my ($left, $right) = @_; my $lcopy = $left->copy; if ( blessed $right && $right->isa('Math::GSL::MatrixComplex') && blessed $left && $left->isa('Math::GSL::MatrixComplex') ) { if ( $left->cols == $right->cols && $left->rows == $right->rows ) { gsl_matrix_complex_add($lcopy->raw, $right->raw); } else { croak "Math::GSL - addition of matrices must be called with two objects matrices and must have the same number of columns and rows"; } } else { gsl_matrix_complex_add_constant($lcopy->raw, $right); } return $lcopy; } sub _subtract { my ($left, $right) = @_; my $lcopy = $left->copy; if ( blessed $right && $right->isa('Math::GSL::MatrixComplex') && blessed $left && $left->isa('Math::GSL::MatrixComplex') ) { if ( $left->cols == $right->cols && $left->rows == $right->rows ) { gsl_matrix_complex_sub($lcopy->raw, $right->raw); } else { croak "Math::GSL - subtraction of matrices must be called with two objects matrices and must have the same number of columns and rows"; } } else { gsl_matrix_complex_add_constant($lcopy->raw, $right*-1); } return $lcopy; } sub _equal { my ($left, $right) = @_; return is_similar( [ map { Re $_ } $left->as_list ], [ map { Re $_ } $right->as_list ]) && is_similar( [ map { Im $_ } $left->as_list ], [ map { Im $_ } $right->as_list ]); } sub _not_equal { my ($left, $right) = @_; return !_equal($left,$right); } sub copy { my $self = shift; my $copy = Math::GSL::MatrixComplex->new( $self->rows, $self->cols ); if ( gsl_matrix_complex_memcpy($copy->raw, $self->raw) != $GSL_SUCCESS ) { croak "Math::GSL - error copying memory, aborting"; } return $copy; } our %EXPORT_TAGS = ( all => \@EXPORT_OK ); =head1 NAME Math::GSL::MatrixComplex - Complex Matrices =head1 SYNOPSIS use Math::GSL::MatrixComplex qw/:all/; my $matrix1 = Math::GSL::MatrixComplex->new(5,5); # OO interface my $matrix3 = $matrix1 + $matrix1; my $matrix4 = $matrix1 - $matrix1; if($matrix1 == $matrix4) ... if($matrix1 != $matrix3) ... my $matrix2 = gsl_matrix_complex_alloc(5,5); # standard interface =head1 Objected Oriented Interface to GSL Math::GSL::MatrixComplex =head2 new() Creates a new MatrixComplex object of the given size. my $matrix = Math::GSL::MatrixComplex->new(10,10); =cut sub new { my ($class, $rows, $cols) = @_; my $this = {}; my $matrix; if ( defined $rows && defined $cols && $rows > 0 && $cols > 0 && (int $rows == $rows) && (int $cols == $cols)){ $matrix = gsl_matrix_complex_alloc($rows,$cols); } else { croak( __PACKAGE__.'::new($x,$y) - $x and $y must be positive integers'); } gsl_matrix_complex_set_zero($matrix); $this->{_matrix} = $matrix; ($this->{_rows}, $this->{_cols}) = ($rows,$cols); bless $this, $class; } =head2 raw() Get the underlying GSL matrix object created by SWIG, useful for using gsl_matrix_* functions which do not have an OO counterpart. my $matrix = Math::GSL::MatrixComplex->new(3,3); my $gsl_matrix = $matrix->raw; my $stuff = gsl_matrix_complex_get($gsl_matrix, 1, 2); =cut sub raw { (shift)->{_matrix} } =head2 rows() Returns the number of rows in the matrix. my $rows = $matrix->rows; =cut sub rows { (shift)->{_rows} } =head2 cols() Returns the number of columns in the matrix. my $cols = $matrix->cols; =cut sub cols { (shift)->{_cols} } =head2 as_vector() Returns a 1xN or Nx1 matrix as a Math::GSL::VectorComplex object. Dies if called on a matrix that is not a single row or column. Useful for turning the output of C or C into a vector, like so: my $vector1 = $matrix->col(0)->as_vector; my $vector2 = $matrix->row(1)->as_vector; =cut sub as_vector($) { my ($self) = @_; croak(__PACKAGE__.'::as_vector() - must be a single row or column matrix') unless ($self->cols == 1 or $self->rows == 1); # TODO: there is a faster way to do this return Math::GSL::VectorComplex->new([ $self->as_list ] ); } =head2 as_list() Get the contents of a Math::GSL::Matrix object as a Perl list. my $matrix = Math::GSL::MatrixComplex->new(3,3); ... my @matrix = $matrix->as_list; =cut sub as_list($) { my $self = shift; my @matrix; for my $row ( 0 .. $self->rows-1) { push @matrix, map { gsl_matrix_complex_get($self->raw, $row, $_) } (0 .. $self->cols-1 ); } return map { Math::Complex->make( gsl_real($_), gsl_imag($_)) } @matrix; } =head2 row() Returns a row matrix of the row you enter. my $matrix = Math::GSL::MatrixComplex->new(3,3); ... my $matrix_row = $matrix->row(0); =cut sub row { my ($self, $row) = @_; croak (__PACKAGE__.'::$matrix->row($row) - invalid $row value') unless (($row < $self->rows) and $row >= 0); my $rowmat = Math::GSL::MatrixComplex->new(1,$self->cols); for my $n (0 .. $self->cols-1) { gsl_matrix_complex_set( $rowmat->raw, 0, $n, gsl_matrix_complex_get($self->raw, $row, $n) ); } return $rowmat; } =head2 col() Returns a col matrix of the column you enter. my $matrix = Math::GSL::MatrixComplex->new(3,3); ... my $matrix_col = $matrix->col(0); =cut sub col { my ($self, $col) = @_; croak (__PACKAGE__."::\$matrix->col(\$col) - $col not a valid column") unless (defined $col && $col < $self->cols and $col >= 0); my $colmat = Math::GSL::MatrixComplex->new($self->rows, 1); map { gsl_matrix_complex_set($colmat->raw, $_, 0, gsl_matrix_complex_get($self->raw, $_, $col), ) } (0 .. $self->rows-1); return $colmat; } =head2 set_row() Sets a the values of a row with the elements of an array. my $matrix = Math::GSL::MatrixComplex->new(3,3); $matrix->set_row(0, [8, 6, 2]); You can also set multiple rows at once with chained calls: my $matrix = Math::GSL::MatrixComplex->new(3,3); $matrix->set_row(0, [8, 6, 2]) ->set_row(1, [2, 4, 1]); ... =cut sub set_row { my ($self, $row, $values) = @_; my $length = $#$values; die __PACKAGE__.'::set_row($x, $values) - $values must be a nonempty array reference' if $length == -1; die __PACKAGE__.'::set_row($x, $values) - $x must be a valid row number' if ($row < 0 || $row >= $self->rows); die __PACKAGE__.'::set_row($x, $values) - $values must contains the same number of elements as there is columns in the matrix' if($length != $self->cols-1); # $values may have Math::Complex objects @$values = map { Math::GSL::Complex::gsl_complex_rect(Re($_), Im($_)) } @$values; # warn Dumper [ @$values ]; map { gsl_matrix_complex_set($self->raw, $row, $_, $values->[$_]) } (0..$length); return $self; } =head2 set_col() Sets a the values of a column with the elements of an array. my $matrix = Math::GSL::MatrixComplex->new(3,3); $matrix->set_col(0, [8, 6, 2]); You can also set multiple columns at once with chained calls: my $matrix = Math::GSL::MatrixComplex->new(3,3); $matrix->set_col(0, [8, 6, 2]) ->set_col(1, [2, 4, 1]); ... =cut sub set_col { my ($self, $col, $values) = @_; my $length = $#$values; die __PACKAGE__.'::set_col($x, $values) - $values must be a nonempty array reference' if $length == -1; die __PACKAGE__.'::set_col($x, $values) - $x must be a valid column number' if ($col < 0 || $col >= $self->cols); die __PACKAGE__.'::set_col($x, $values) - $values must contains the same number of elements as there is rowss in the matrix' if($length != $self->rows-1); # $values may have Math::Complex objects @$values = map { gsl_complex_rect(Re($_), Im($_)) } @$values; map { gsl_matrix_complex_set($self->raw, $_, $col, $values->[$_]) } (0..$length); return $self; } =head2 is_square() Returns true if a matrix is square, i.e. it has the same number of rows as columns, false otherwise. =cut sub is_square($) { my $self = shift; return ($self->rows == $self->cols) ? 1 : 0 ; } =head2 det() Returns the determinant of a matrix (computed by LU decomposition) or dies if called on a non-square matrix. my $det = $matrix->det(); =cut sub det($) { my $self = shift; croak(__PACKAGE__."- determinant only exists for square matrices") unless $self->is_square; my $p = Math::GSL::Permutation->new( $self->rows ); my $LU = $self->copy; my $s = gsl_linalg_complex_LU_decomp($LU->raw, $p->raw); # $z is a gsl_complex my $z = gsl_linalg_complex_LU_det($LU->raw, $s ); return Math::Complex->make( gsl_real($z), gsl_imag($z) ); } =head2 zero() Set a matrix to the zero matrix. $matrix->zero; =cut sub zero # brrr! { my $self=shift; gsl_matrix_complex_set_zero($self->raw); return $self; } =head2 identity() Set a matrix to the identity matrix, i.e. one on the diagonal and zero elsewhere. my $I = $matrix->identity; =cut sub identity { my $self=shift; gsl_matrix_complex_set_identity($self->raw); return $self; } =head2 inverse() Returns the inverse of a matrix or dies when called on a non-square matrix. my $inverse = $matrix->inverse; =cut sub inverse($) { my $self = shift; croak(__PACKAGE__."- inverse only exists for square matrices") unless $self->is_square; my $p = Math::GSL::Permutation->new( $self->rows ); my $LU = $self->copy; my $inverse = $self->copy; # should check return status gsl_linalg_complex_LU_decomp($LU->raw, $p->raw); gsl_linalg_complex_LU_invert($LU->raw, $p->raw,$inverse->raw); return $inverse; } =head2 is_hermitian() Returns true if the matrix is hermitian, false otherwise my $test = $matrix->is_hermitian; =cut sub is_hermitian() { my ($self) = @_; my $test = $self->is_square; my $transpose = $self->copy; gsl_matrix_complex_transpose($transpose->raw); if($test == 1) { for my $row (0..$self->rows - 1) { map { gsl_matrix_complex_set($transpose->raw, $row, $_, gsl_complex_conjugate(gsl_matrix_complex_get($transpose->raw, $row, $_))) } (0..$self->cols - 1); } if($self != $transpose){ $test = 0; } } return $test; } =head2 eigenvalues() =cut sub eigenvalues($) { my $self=shift; my ($r,$c) = ($self->rows,$self->cols); croak "Math::GSL::MatrixComplex : \$matrix->eigenvalues - \$matrix must be square" unless ($r == $c); my $vector = Math::GSL::Vector->new($r); my $eigen = gsl_eigen_herm_alloc($r); # GSL has no generalized complex matrix routines # can only continue if the matrix is hermitian croak (__PACKAGE__."::eigenvalues : non-hermitian matrices are not currently supported") unless $self->is_hermitian; gsl_eigen_herm($self->raw, $vector->raw, $eigen); return $vector->as_list; } =head2 lndet() Returns the natural log of the absolute value of the determinant of a matrix (computed by LU decomposition) or dies if called on a non-square matrix. my $lndet = $matrix->lndet(); =cut sub lndet($) { my $self = shift; croak(__PACKAGE__."- log determinant only exists for square matrices") unless $self->is_square; my $p = Math::GSL::Permutation->new( $self->rows ); my $LU = $self->copy; gsl_linalg_complex_LU_decomp($LU->raw, $p->raw); return gsl_linalg_complex_LU_lndet($LU->raw); } =head1 DESCRIPTION =over 1 =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =item C =back For more informations on the functions, we refer you to the GSL offcial documentation L =head1 AUTHORS Jonathan Leto and Thierry Moisan =head1 COPYRIGHT AND LICENSE Copyright (C) 2008-2009 Jonathan 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;