lapacke_zunmbr_work.c

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******************************************************************************
* Contents: Native middle-level C interface to LAPACK function zunmbr
* Author: Intel Corporation
* Generated October, 2010
*****************************************************************************/

#include "lapacke.h"
#include "lapacke_utils.h"

lapack_int LAPACKE_zunmbr_work( int matrix_order, char vect, char side,
                                char trans, lapack_int m, lapack_int n,
                                lapack_int k, const lapack_complex_double* a,
                                lapack_int lda,
                                const lapack_complex_double* tau,
                                lapack_complex_double* c, lapack_int ldc,
                                lapack_complex_double* work, lapack_int lwork )
{
    lapack_int info = 0;
    if( matrix_order == LAPACK_COL_MAJOR ) {
        /* Call LAPACK function and adjust info */
        LAPACK_zunmbr( &vect, &side, &trans, &m, &n, &k, a, &lda, tau, c, &ldc,
                       work, &lwork, &info );
        if( info < 0 ) {
            info = info - 1;
        }
    } else if( matrix_order == LAPACK_ROW_MAJOR ) {
        lapack_int nq = LAPACKE_lsame( side, 'l' ) ? m : n;
        lapack_int r = LAPACKE_lsame( vect, 'q' ) ? nq : MIN(nq,k);
        lapack_int lda_t = MAX(1,r);
        lapack_int ldc_t = MAX(1,m);
        lapack_complex_double* a_t = NULL;
        lapack_complex_double* c_t = NULL;
        /* Check leading dimension(s) */
        if( lda < MIN(nq,k) ) {
            info = -9;
            LAPACKE_xerbla( "LAPACKE_zunmbr_work", info );
            return info;
        }
        if( ldc < n ) {
            info = -12;
            LAPACKE_xerbla( "LAPACKE_zunmbr_work", info );
            return info;
        }
        /* Query optimal working array(s) size if requested */
        if( lwork == -1 ) {
            LAPACK_zunmbr( &vect, &side, &trans, &m, &n, &k, a, &lda_t, tau, c,
                           &ldc_t, work, &lwork, &info );
            return (info < 0) ? (info - 1) : info;
        }
        /* Allocate memory for temporary array(s) */
        a_t = (lapack_complex_double*)
            LAPACKE_malloc( sizeof(lapack_complex_double) *
                            lda_t * MAX(1,MIN(nq,k)) );
        if( a_t == NULL ) {
            info = LAPACK_TRANSPOSE_MEMORY_ERROR;
            goto exit_level_0;
        }
        c_t = (lapack_complex_double*)
            LAPACKE_malloc( sizeof(lapack_complex_double) * ldc_t * MAX(1,n) );
        if( c_t == NULL ) {
            info = LAPACK_TRANSPOSE_MEMORY_ERROR;
            goto exit_level_1;
        }
        /* Transpose input matrices */
        LAPACKE_zge_trans( matrix_order, r, MIN(nq,k), a, lda, a_t, lda_t );
        LAPACKE_zge_trans( matrix_order, m, n, c, ldc, c_t, ldc_t );
        /* Call LAPACK function and adjust info */
        LAPACK_zunmbr( &vect, &side, &trans, &m, &n, &k, a_t, &lda_t, tau, c_t,
                       &ldc_t, work, &lwork, &info );
        if( info < 0 ) {
            info = info - 1;
        }
        /* Transpose output matrices */
        LAPACKE_zge_trans( LAPACK_COL_MAJOR, m, n, c_t, ldc_t, c, ldc );
        /* Release memory and exit */
        LAPACKE_free( c_t );
exit_level_1:
        LAPACKE_free( a_t );
exit_level_0:
        if( info == LAPACK_TRANSPOSE_MEMORY_ERROR ) {
            LAPACKE_xerbla( "LAPACKE_zunmbr_work", info );
        }
    } else {
        info = -1;
        LAPACKE_xerbla( "LAPACKE_zunmbr_work", info );
    }
    return info;
}