LAPACKE_zuncsd()

lapack_int LAPACKE_zuncsd	(	int	matrix_layout,
		char	jobu1,
		char	jobu2,
		char	jobv1t,
		char	jobv2t,
		char	trans,
		char	signs,
		lapack_int	m,
		lapack_int	p,
		lapack_int	q,
		lapack_complex_double *	x11,
		lapack_int	ldx11,
		lapack_complex_double *	x12,
		lapack_int	ldx12,
		lapack_complex_double *	x21,
		lapack_int	ldx21,
		lapack_complex_double *	x22,
		lapack_int	ldx22,
		double *	theta,
		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
	)

Definition at line 35 of file lapacke_zuncsd.c.

{
    lapack_int info = 0;
    lapack_int lrwork = -1;
    lapack_int lwork = -1;
    lapack_int* iwork = NULL;
    double* rwork = NULL;
    lapack_complex_double* work = NULL;
    double rwork_query;
    lapack_complex_double work_query;
    int lapack_layout;
    if( matrix_layout != LAPACK_COL_MAJOR && matrix_layout != LAPACK_ROW_MAJOR ) {
        LAPACKE_xerbla( "LAPACKE_zuncsd", -1 );
        return -1;
    }
    if( LAPACKE_lsame( trans, 'n' ) && matrix_layout == LAPACK_COL_MAJOR ) {
        lapack_layout = LAPACK_COL_MAJOR;
    } else {
        lapack_layout = LAPACK_ROW_MAJOR;
    }
#ifndef LAPACK_DISABLE_NAN_CHECK
    if( LAPACKE_get_nancheck() ) {
        /* Optionally check input matrices for NaNs */
        if( LAPACKE_zge_nancheck( lapack_layout, p, q, x11, ldx11 ) ) {
            return -11;
        }
        if( LAPACKE_zge_nancheck( lapack_layout, p, m-q, x12, ldx12 ) ) {
            return -13;
        }
        if( LAPACKE_zge_nancheck( lapack_layout, m-p, q, x21, ldx21 ) ) {
            return -15;
        }
        if( LAPACKE_zge_nancheck( lapack_layout, m-p, m-q, x22, ldx22 ) ) {
            return -17;
        }
    }
#endif
    /* Allocate memory for working array(s) */
    iwork = (lapack_int*)LAPACKE_malloc( sizeof(lapack_int) * MAX(1,m-MIN(MIN(p,m-p),MIN(q,m-q))) );
    if( iwork == NULL ) {
        info = LAPACK_WORK_MEMORY_ERROR;
        goto exit_level_0;
    }
    /* Query optimal working array(s) size */
    info = LAPACKE_zuncsd_work( matrix_layout, jobu1, jobu2, jobv1t, jobv2t,
                                trans, signs, m, p, q, x11, ldx11, x12, ldx12,
                                x21, ldx21, x22, ldx22, theta, u1, ldu1, u2,
                                ldu2, v1t, ldv1t, v2t, ldv2t, &work_query,
                                lwork, &rwork_query, lrwork, iwork );
    if( info != 0 ) {
        goto exit_level_1;
    }
    lrwork = (lapack_int)rwork_query;
    lwork = LAPACK_Z2INT( work_query );
    /* Allocate memory for work arrays */
    rwork = (double*)LAPACKE_malloc( sizeof(double) * lrwork );
    if( rwork == NULL ) {
        info = LAPACK_WORK_MEMORY_ERROR;
        goto exit_level_1;
    }
    work = (lapack_complex_double*)
        LAPACKE_malloc( sizeof(lapack_complex_double) * lwork );
    if( work == NULL ) {
        info = LAPACK_WORK_MEMORY_ERROR;
        goto exit_level_2;
    }
    /* Call middle-level interface */
    info = LAPACKE_zuncsd_work( matrix_layout, jobu1, jobu2, jobv1t, jobv2t,
                                trans, signs, m, p, q, x11, ldx11, x12, ldx12,
                                x21, ldx21, x22, ldx22, theta, u1, ldu1, u2,
                                ldu2, v1t, ldv1t, v2t, ldv2t, work, lwork,
                                rwork, lrwork, iwork );
    /* Release memory and exit */
    LAPACKE_free( work );
exit_level_2:
    LAPACKE_free( rwork );
exit_level_1:
    LAPACKE_free( iwork );
exit_level_0:
    if( info == LAPACK_WORK_MEMORY_ERROR ) {
        LAPACKE_xerbla( "LAPACKE_zuncsd", info );
    }
    return info;

Here is the call graph for this function: