LAPACK  3.9.0
LAPACK: Linear Algebra PACKage

◆ LAPACKE_zgelsy()

lapack_int LAPACKE_zgelsy ( int  matrix_layout,
lapack_int  m,
lapack_int  n,
lapack_int  nrhs,
lapack_complex_double a,
lapack_int  lda,
lapack_complex_double b,
lapack_int  ldb,
lapack_int jpvt,
double  rcond,
lapack_int rank 
)

Definition at line 35 of file lapacke_zgelsy.c.

41 {
42  lapack_int info = 0;
43  lapack_int lwork = -1;
44  double* rwork = NULL;
45  lapack_complex_double* work = NULL;
46  lapack_complex_double work_query;
47  if( matrix_layout != LAPACK_COL_MAJOR && matrix_layout != LAPACK_ROW_MAJOR ) {
48  LAPACKE_xerbla( "LAPACKE_zgelsy", -1 );
49  return -1;
50  }
51 #ifndef LAPACK_DISABLE_NAN_CHECK
52  if( LAPACKE_get_nancheck() ) {
53  /* Optionally check input matrices for NaNs */
54  if( LAPACKE_zge_nancheck( matrix_layout, m, n, a, lda ) ) {
55  return -5;
56  }
57  if( LAPACKE_zge_nancheck( matrix_layout, MAX(m,n), nrhs, b, ldb ) ) {
58  return -7;
59  }
60  if( LAPACKE_d_nancheck( 1, &rcond, 1 ) ) {
61  return -10;
62  }
63  }
64 #endif
65  /* Allocate memory for working array(s) */
66  rwork = (double*)LAPACKE_malloc( sizeof(double) * MAX(1,2*n) );
67  if( rwork == NULL ) {
68  info = LAPACK_WORK_MEMORY_ERROR;
69  goto exit_level_0;
70  }
71  /* Query optimal working array(s) size */
72  info = LAPACKE_zgelsy_work( matrix_layout, m, n, nrhs, a, lda, b, ldb, jpvt,
73  rcond, rank, &work_query, lwork, rwork );
74  if( info != 0 ) {
75  goto exit_level_1;
76  }
77  lwork = LAPACK_Z2INT( work_query );
78  /* Allocate memory for work arrays */
79  work = (lapack_complex_double*)
80  LAPACKE_malloc( sizeof(lapack_complex_double) * lwork );
81  if( work == NULL ) {
82  info = LAPACK_WORK_MEMORY_ERROR;
83  goto exit_level_1;
84  }
85  /* Call middle-level interface */
86  info = LAPACKE_zgelsy_work( matrix_layout, m, n, nrhs, a, lda, b, ldb, jpvt,
87  rcond, rank, work, lwork, rwork );
88  /* Release memory and exit */
89  LAPACKE_free( work );
90 exit_level_1:
91  LAPACKE_free( rwork );
92 exit_level_0:
93  if( info == LAPACK_WORK_MEMORY_ERROR ) {
94  LAPACKE_xerbla( "LAPACKE_zgelsy", info );
95  }
96  return info;
Here is the call graph for this function:
LAPACKE_free
#define LAPACKE_free(p)
Definition: lapacke.h:47
lapack_int
#define lapack_int
Definition: lapack.h:21
LAPACKE_zgelsy_work
lapack_int LAPACKE_zgelsy_work(int matrix_layout, lapack_int m, lapack_int n, lapack_int nrhs, lapack_complex_double *a, lapack_int lda, lapack_complex_double *b, lapack_int ldb, lapack_int *jpvt, double rcond, lapack_int *rank, lapack_complex_double *work, lapack_int lwork, double *rwork)
Definition: lapacke_zgelsy_work.c:35
LAPACK_WORK_MEMORY_ERROR
#define LAPACK_WORK_MEMORY_ERROR
Definition: lapacke.h:56
LAPACK_Z2INT
#define LAPACK_Z2INT(x)
Definition: lapacke.h:51
LAPACKE_xerbla
void LAPACKE_xerbla(const char *name, lapack_int info)
Definition: lapacke_xerbla.c:36
MAX
#define MAX(x, y)
Definition: lapacke_utils.h:47
lapack_complex_double
#define lapack_complex_double
Definition: lapack.h:70
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:36
LAPACKE_malloc
#define LAPACKE_malloc(size)
Definition: lapacke.h:44
LAPACKE_d_nancheck
lapack_logical LAPACKE_d_nancheck(lapack_int n, const double *x, lapack_int incx)
Definition: lapacke_d_nancheck.c:36
LAPACKE_get_nancheck
int LAPACKE_get_nancheck()
Definition: lapacke_nancheck.c:42
LAPACK_ROW_MAJOR
#define LAPACK_ROW_MAJOR
Definition: lapacke.h:53
LAPACK_COL_MAJOR
#define LAPACK_COL_MAJOR
Definition: lapacke.h:54