df/dc3/lapacke__zbbcsd_8c_source.html

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 * Contents: Native high-level C interface to LAPACK function zbbcsd

 * Author: Intel Corporation

 * Generated November 2015

 *****************************************************************************/


 #include "lapacke_utils.h"


 lapack_int LAPACKE_zbbcsd( int matrix_layout, char jobu1, char jobu2,

                            char jobv1t, char jobv2t, char trans, lapack_int m,

                            lapack_int p, lapack_int q, double* theta,

                            double* phi, lapack_complex_double* u1,

                            lapack_int ldu1, lapack_complex_double* u2,

                            lapack_int ldu2, lapack_complex_double* v1t,

                            lapack_int ldv1t, lapack_complex_double* v2t,

                            lapack_int ldv2t, double* b11d, double* b11e,

                            double* b12d, double* b12e, double* b21d,

                            double* b21e, double* b22d, double* b22e )

 {

     lapack_int info = 0;

     lapack_int lrwork = -1;

     double* rwork = NULL;

     double rwork_query;

     lapack_int nrows_u1, nrows_u2, nrows_v1t, nrows_v2t;

     if( matrix_layout != LAPACK_COL_MAJOR && matrix_layout != LAPACK_ROW_MAJOR ) {

         LAPACKE_xerbla( "LAPACKE_zbbcsd", -1 );

         return -1;

     }

 #ifndef LAPACK_DISABLE_NAN_CHECK

     /* Optionally check input matrices for NaNs */

     nrows_u1 = ( LAPACKE_lsame( jobu1, 'y' ) ? p : 1);

     nrows_u2 = ( LAPACKE_lsame( jobu2, 'y' ) ? m-p : 1);

     nrows_v1t = ( LAPACKE_lsame( jobv1t, 'y' ) ? q : 1);

     nrows_v2t = ( LAPACKE_lsame( jobv2t, 'y' ) ? m-q : 1);

     if( LAPACKE_d_nancheck( q-1, phi, 1 ) ) {

         return -11;

     }

     if( LAPACKE_d_nancheck( q, theta, 1 ) ) {

         return -10;

     }

     if( LAPACKE_lsame( jobu1, 'y' ) ) {

         if( LAPACKE_zge_nancheck( matrix_layout, nrows_u1, p, u1, ldu1 ) ) {

             return -12;

         }

     }

     if( LAPACKE_lsame( jobu2, 'y' ) ) {

         if( LAPACKE_zge_nancheck( matrix_layout, nrows_u2, m-p, u2, ldu2 ) ) {

             return -14;

         }

     }

     if( LAPACKE_lsame( jobv1t, 'y' ) ) {

         if( LAPACKE_zge_nancheck( matrix_layout, nrows_v1t, q, v1t, ldv1t ) ) {

             return -16;

         }

     }

     if( LAPACKE_lsame( jobv2t, 'y' ) ) {

         if( LAPACKE_zge_nancheck( matrix_layout, nrows_v2t, m-q, v2t, ldv2t ) ) {

             return -18;

         }

     }

 #endif

     /* Query optimal working array(s) size */

     info = LAPACKE_zbbcsd_work( matrix_layout, jobu1, jobu2, jobv1t, jobv2t,

                                 trans, m, p, q, theta, phi, u1, ldu1, u2, ldu2,

                                 v1t, ldv1t, v2t, ldv2t, b11d, b11e, b12d, b12e,

                                 b21d, b21e, b22d, b22e, &rwork_query, lrwork );

     if( info != 0 ) {

         goto exit_level_0;

     }

     lrwork = (lapack_int)rwork_query;

     /* Allocate memory for work arrays */

     rwork = (double*)LAPACKE_malloc( sizeof(double) * lrwork );

     if( rwork == NULL ) {

         info = LAPACK_WORK_MEMORY_ERROR;

         goto exit_level_0;

     }

     /* Call middle-level interface */

     info = LAPACKE_zbbcsd_work( matrix_layout, jobu1, jobu2, jobv1t, jobv2t,

                                 trans, m, p, q, theta, phi, u1, ldu1, u2, ldu2,

                                 v1t, ldv1t, v2t, ldv2t, b11d, b11e, b12d, b12e,

                                 b21d, b21e, b22d, b22e, rwork, lrwork );

     /* Release memory and exit */

     LAPACKE_free( rwork );

 exit_level_0:

     if( info == LAPACK_WORK_MEMORY_ERROR ) {

         LAPACKE_xerbla( "LAPACKE_zbbcsd", info );

     }

     return info;

 }

LAPACKE_zbbcsd
lapack_int LAPACKE_zbbcsd(int matrix_layout, char jobu1, char jobu2, char jobv1t, char jobv2t, char trans, lapack_int m, lapack_int p, lapack_int q, double *theta, double *phi, lapack_complex_double *u1, lapack_int ldu1, lapack_complex_double *u2, lapack_int ldu2, lapack_complex_double *v1t, lapack_int ldv1t, lapack_complex_double *v2t, lapack_int ldv2t, double *b11d, double *b11e, double *b12d, double *b12e, double *b21d, double *b21e, double *b22d, double *b22e)
Definition: lapacke_zbbcsd.c:36

LAPACK_ROW_MAJOR
#define LAPACK_ROW_MAJOR
Definition: lapacke.h:119

LAPACK_WORK_MEMORY_ERROR
#define LAPACK_WORK_MEMORY_ERROR
Definition: lapacke.h:122

lapack_complex_double
#define lapack_complex_double
Definition: lapacke.h:90

lapacke_utils.h

LAPACKE_zbbcsd_work
lapack_int LAPACKE_zbbcsd_work(int matrix_layout, char jobu1, char jobu2, char jobv1t, char jobv2t, char trans, lapack_int m, lapack_int p, lapack_int q, double *theta, double *phi, lapack_complex_double *u1, lapack_int ldu1, lapack_complex_double *u2, lapack_int ldu2, lapack_complex_double *v1t, lapack_int ldv1t, lapack_complex_double *v2t, lapack_int ldv2t, double *b11d, double *b11e, double *b12d, double *b12e, double *b21d, double *b21e, double *b22d, double *b22e, double *rwork, lapack_int lrwork)
Definition: lapacke_zbbcsd_work.c:36

LAPACKE_free
#define LAPACKE_free(p)
Definition: lapacke.h:113

LAPACKE_malloc
#define LAPACKE_malloc(size)
Definition: lapacke.h:110

LAPACKE_d_nancheck
lapack_logical LAPACKE_d_nancheck(lapack_int n, const double *x, lapack_int incx)
Definition: lapacke_d_nancheck.c:37

LAPACKE_lsame
lapack_logical LAPACKE_lsame(char ca, char cb)
Definition: lapacke_lsame.c:36

LAPACK_COL_MAJOR
#define LAPACK_COL_MAJOR
Definition: lapacke.h:120

LAPACKE_xerbla
void LAPACKE_xerbla(const char *name, lapack_int info)
Definition: lapacke_xerbla.c:37

lapack_int
#define lapack_int
Definition: lapacke.h:47

LAPACKE_zge_nancheck
lapack_logical LAPACKE_zge_nancheck(int matrix_layout, lapack_int m, lapack_int n, const lapack_complex_double *a, lapack_int lda)
Definition: lapacke_zge_nancheck.c:37