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NAME

Math::GSL::BLAS - Basic Linear Algebra Subprograms

SYNOPSIS

use Math::GSL::BLAS qw/:all/;

DESCRIPTION

The functions of this module are divised into 3 levels:

Level 1 - Vector operations

gsl_blas_sdsdot
gsl_blas_dsdot
gsl_blas_sdot
gsl_blas_ddot($x, $y) - This function computes the scalar product x^T y for the vectors $x and $y. The function returns two values, the first is 0 if the operation suceeded, 1 otherwise and the second value is the result of the computation.
gsl_blas_cdotu
gsl_blas_cdotc
gsl_blas_zdotu($x, $y, $dotu) - This function computes the complex scalar product x^T y for the complex vectors $x and $y, returning the result in the complex number $dotu. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_zdotc($x, $y, $dotc) - This function computes the complex conjugate scalar product x^H y for the complex vectors $x and $y, returning the result in the complex number $dotc. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_snrm2 =item gsl_blas_sasum
gsl_blas_dnrm2($x) - This function computes the Euclidean norm ||x||_2 = \sqrt {\sum x_i^2} of the vector $x.
gsl_blas_dasum($x) - This function computes the absolute sum \sum |x_i| of the elements of the vector $x.
gsl_blas_scnrm2
gsl_blas_scasum
gsl_blas_dznrm2($x) - This function computes the Euclidean norm of the complex vector $x, ||x||_2 = \sqrt {\sum (\Re(x_i)^2 + \Im(x_i)^2)}.
gsl_blas_dzasum($x) - This function computes the sum of the magnitudes of the real and imaginary parts of the complex vector $x, \sum |\Re(x_i)| + |\Im(x_i)|.
gsl_blas_isamax
gsl_blas_idamax
gsl_blas_icamax
gsl_blas_izamax
gsl_blas_sswap
gsl_blas_scopy
gsl_blas_saxpy
gsl_blas_dswap($x, $y) - This function exchanges the elements of the vectors $x and $y. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dcopy($x, $y) - This function copies the elements of the vector $x into the vector $y. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_daxpy($alpha, $x, $y) - These functions compute the sum $y = $alpha * $x + $y for the vectors $x and $y.
gsl_blas_cswap
gsl_blas_ccopy
gsl_blas_caxpy
gsl_blas_zswap
gsl_blas_zcopy
gsl_blas_zaxpy
gsl_blas_srotg
gsl_blas_srotmg
gsl_blas_srot
gsl_blas_srotm
gsl_blas_drotg
gsl_blas_drotmg
gsl_blas_drot($x, $y, $c, $s) - This function applies a Givens rotation (x', y') = (c x + s y, -s x + c y) to the vectors $x, $y.
gsl_blas_drotm
gsl_blas_sscal
gsl_blas_dscal($alpha, $x) - This function rescales the vector $x by the multiplicative factor $alpha.
gsl_blas_cscal
gsl_blas_zscal
gsl_blas_csscal
gsl_blas_zdscal

Level 2 - Matrix-vector operations

gsl_blas_sgemv
gsl_blas_strmv
gsl_blas_strsv
gsl_blas_dgemv($TransA, $alpha, $A, $x, $beta, $y) - This function computes the matrix-vector product and sum y = \alpha op(A) x + \beta y, where op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans (constant values coming from the CBLAS module). $A is a matrix and $x and $y are vectors. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dtrmv($Uplo, $TransA, $Diag, $A, $x) - This function computes the matrix-vector product x = op(A) x for the triangular matrix $A, where op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans (constant values coming from the CBLAS module). When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of the matrix is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dtrsv($Uplo, $TransA, $Diag, $A, $x) - This function computes inv(op(A)) x for the vector $x, where op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans (constant values coming from the CBLAS module). When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of the matrix is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_cgemv
gsl_blas_ctrmv
gsl_blas_ctrsv
gsl_blas_zgemv
gsl_blas_ztrmv
gsl_blas_ztrsv
gsl_blas_ssymv
gsl_blas_sger
gsl_blas_ssyr
gsl_blas_ssyr2
gsl_blas_dsymv
gsl_blas_dger($alpha, $x, $y, $A) - This function computes the rank-1 update A = alpha x y^T + A of the matrix $A. $x and $y are vectors. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dsyr($Uplo, $alpha, $x, $A) - This function computes the symmetric rank-1 update A = \alpha x x^T + A of the symmetric matrix $A and the vector $x. Since the matrix $A is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $A are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $A are used. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dsyr2($Uplo, $alpha, $x, $y, $A) - This function computes the symmetric rank-2 update A = \alpha x y^T + \alpha y x^T + A of the symmetric matrix $A, the vector $x and vector $y. Since the matrix $A is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $A are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $A are used.
gsl_blas_chemv
gsl_blas_cgeru
gsl_blas_cgerc
gsl_blas_cher
gsl_blas_cher2
gsl_blas_zhemv
gsl_blas_zgeru($alpha, $x, $y, $A) - This function computes the rank-1 update A = alpha x y^T + A of the complex matrix $A. $alpha is a complex number and $x and $y are complex vectors. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_zgerc
gsl_blas_zher($Uplo, $alpha, $x, $A) - This function computes the hermitian rank-1 update A = \alpha x x^H + A of the hermitian matrix $A and of the complex vector $x. Since the matrix $A is hermitian only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $A are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $A are used. The imaginary elements of the diagonal are automatically set to zero. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_zher2

Level 3 - Matrix-matrix operations

gsl_blas_sgemm
gsl_blas_ssymm
gsl_blas_ssyrk
gsl_blas_ssyr2k
gsl_blas_strmm
gsl_blas_strsm
gsl_blas_dgemm($TransA, $TransB, $alpha, $A, $B, $beta, $C) - This function computes the matrix-matrix product and sum C = \alpha op(A) op(B) + \beta C where op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans and similarly for the parameter $TransB. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dsymm($Side, $Uplo, $alpha, $A, $B, $beta, $C) - This function computes the matrix-matrix product and sum C = \alpha A B + \beta C for $Side is $CblasLeft and C = \alpha B A + \beta C for $Side is $CblasRight, where the matrix $A is symmetric. When $Uplo is $CblasUpper then the upper triangle and diagonal of $A are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $A are used. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dsyrk($Uplo, $Trans, $alpha, $A, $beta, $C) - This function computes a rank-k update of the symmetric matrix $C, C = \alpha A A^T + \beta C when $Trans is $CblasNoTrans and C = \alpha A^T A + \beta C when $Trans is $CblasTrans. Since the matrix $C is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dsyr2k($Uplo, $Trans, $alpha, $A, $B, $beta, $C) - This function computes a rank-2k update of the symmetric matrix $C, C = \alpha A B^T + \alpha B A^T + \beta C when $Trans is $CblasNoTrans and C = \alpha A^T B + \alpha B^T A + \beta C when $Trans is $CblasTrans. Since the matrix $C is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dtrmm($Side, $Uplo, $TransA, $Diag, $alpha, $A, $B) - This function computes the matrix-matrix product B = \alpha op(A) B for $Side is $CblasLeft and B = \alpha B op(A) for $Side is $CblasRight. The matrix $A is triangular and op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans. When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of $A is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_dtrsm($Side, $Uplo, $TransA, $Diag, $alpha, $A, $B) - This function computes the inverse-matrix matrix product B = \alpha op(inv(A))B for $Side is $CblasLeft and B = \alpha B op(inv(A)) for $Side is $CblasRight. The matrix $A is triangular and op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans. When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of $A is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_cgemm
gsl_blas_csymm
gsl_blas_csyrk
gsl_blas_csyr2k
gsl_blas_ctrmm
gsl_blas_ctrsm
gsl_blas_zgemm($TransA, $TransB, $alpha, $A, $B, $beta, $C) - This function computes the matrix-matrix product and sum C = \alpha op(A) op(B) + \beta C where op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans and similarly for the parameter $TransB. The function returns 0 if the operation suceeded, 1 otherwise. $A, $B and $C are complex matrices
gsl_blas_zsymm($Side, $Uplo, $alpha, $A, $B, $beta, $C) - This function computes the matrix-matrix product and sum C = \alpha A B + \beta C for $Side is $CblasLeft and C = \alpha B A + \beta C for $Side is $CblasRight, where the matrix $A is symmetric. When $Uplo is $CblasUpper then the upper triangle and diagonal of $A are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $A are used. $A, $B and $C are complex matrices. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_zsyrk($Uplo, $Trans, $alpha, $A, $beta, $C) - This function computes a rank-k update of the symmetric complex matrix $C, C = \alpha A A^T + \beta C when $Trans is $CblasNoTrans and C = \alpha A^T A + \beta C when $Trans is $CblasTrans. Since the matrix $C is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The function returns 0 if the operation suceeded, 1 otherwise.
gsl_blas_zsyr2k($Uplo, $Trans, $alpha, $A, $B, $beta, $C) - This function computes a rank-2k update of the symmetric matrix $C, C = \alpha A B^T + \alpha B A^T + \beta C when $Trans is $CblasNoTrans and C = \alpha A^T B + \alpha B^T A + \beta C when $Trans is $CblasTrans. Since the matrix $C is symmetric only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The function returns 0 if the operation suceeded, 1 otherwise. $A, $B and $C are complex matrices and $beta is a complex number.
gsl_blas_ztrmm($Side, $Uplo, $TransA, $Diag, $alpha, $A, $B) - This function computes the matrix-matrix product B = \alpha op(A) B for $Side is $CblasLeft and B = \alpha B op(A) for $Side is $CblasRight. The matrix $A is triangular and op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans. When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of $A is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise. $A and $B are complex matrices and $alpha is a complex number.
gsl_blas_ztrsm($Side, $Uplo, $TransA, $Diag, $alpha, $A, $B) - This function computes the inverse-matrix matrix product B = \alpha op(inv(A))B for $Side is $CblasLeft and B = \alpha B op(inv(A)) for $Side is $CblasRight. The matrix $A is triangular and op(A) = A, A^T, A^H for $TransA = $CblasNoTrans, $CblasTrans, $CblasConjTrans. When $Uplo is $CblasUpper then the upper triangle of $A is used, and when $Uplo is $CblasLower then the lower triangle of $A is used. If $Diag is $CblasNonUnit then the diagonal of $A is used, but if $Diag is $CblasUnit then the diagonal elements of the matrix $A are taken as unity and are not referenced. The function returns 0 if the operation suceeded, 1 otherwise. $A and $B are complex matrices and $alpha is a complex number.
gsl_blas_chemm
gsl_blas_cherk
gsl_blas_cher2k
gsl_blas_zhemm($Side, $Uplo, $alpha, $A, $B, $beta, $C) - This function computes the matrix-matrix product and sum C = \alpha A B + \beta C for $Side is $CblasLeft and C = \alpha B A + \beta C for $Side is $CblasRight, where the matrix $A is hermitian. When Uplo is CblasUpper then the upper triangle and diagonal of A are used, and when Uplo is CblasLower then the lower triangle and diagonal of A are used. The imaginary elements of the diagonal are automatically set to zero.
gsl_blas_zherk($Uplo, $Trans, $alpha, $A, $beta, $C) - This function computes a rank-k update of the hermitian matrix $C, C = \alpha A A^H + \beta C when $Trans is $CblasNoTrans and C = \alpha A^H A + \beta C when $Trans is $CblasTrans. Since the matrix $C is hermitian only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The imaginary elements of the diagonal are automatically set to zero. The function returns 0 if the operation suceeded, 1 otherwise. $A, $B and $C are complex matrices and $alpha and $beta are complex numbers.
gsl_blas_zher2k($Uplo, $Trans, $alpha, $A, $B, $beta, $C) - This function computes a rank-2k update of the hermitian matrix $C, C = \alpha A B^H + \alpha^* B A^H + \beta C when $Trans is $CblasNoTrans and C = \alpha A^H B + \alpha^* B^H A + \beta C when $Trans is $CblasConjTrans. Since the matrix $C is hermitian only its upper half or lower half need to be stored. When $Uplo is $CblasUpper then the upper triangle and diagonal of $C are used, and when $Uplo is $CblasLower then the lower triangle and diagonal of $C are used. The imaginary elements of the diagonal are automatically set to zero. The function returns 0 if the operation suceeded, 1 otherwise.

You have to add the functions you want to use inside the qw /put_funtion_here /. You can also write use Math::GSL::BLAS qw/:all/ to use all avaible functions of the module. Other tags are also avaible, here is a complete list of all tags for this module :

level1
level2
level3

For more informations on the functions, we refer you to the GSL offcial documentation: http://www.gnu.org/software/gsl/manual/html_node/

Tip : search on google: site:http://www.gnu.org/software/gsl/manual/html_node/ name_of_the_function_you_want

EXAMPLES

 This example shows how to do a matrix-matrix product of double numbers :

 use Math::GSL::Matrix qw/:all/;
 use Math::GSL::BLAS qw/:all/;
 my $A = Math::GSL::Matrix->new(2,2);
 $A->set_row(0, [1, 4]);
   ->set_row(1, [3, 2]);
 my $B = Math::GSL::Matrix->new(2,2);
 $B->set_row(0, [2, 1]);
   ->set_row(1, [5,3]);
 my $C = Math::GSL::Matrix->new(2,2);
 gsl_matrix_set_zero($C->raw);
 gsl_blas_dgemm($CblasNoTrans, $CblasNoTrans, 1, $A->raw, $B->raw, 1, $C->raw);
 my @got = $C->row(0)->as_list;
 print "The resulting matrix is: \n[";
 print "$got[0]  $got[1]\n";
 @got = $C->row(1)->as_list;
 print "$got[0]  $got[1] ]\n";


 This example shows how to compute the scalar product of two vectors :

 use Math::GSL::Vector qw/:all/;
 use Math::GSL::CBLAS qw/:all/;
 use Math::GSL::BLAS qw/:all/;
 my $vec1 = Math::GSL::Vector->new([1,2,3,4,5]);
 my $vec2 = Math::GSL::Vector->new([5,4,3,2,1]);
 my ($status, $result) = gsl_blas_ddot($vec1->raw, $vec2->raw);
 if($status == 0) { 
 print "The function has succeeded. \n";
 }
 print "The result of the vector multiplication is $result. \n";

AUTHORS

Jonathan Leto <jonathan@leto.net> and Thierry Moisan <thierry.moisan@gmail.com>

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.