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#include "cs_mex.h"
/* cs_lusol: solve A*x=b using a sparse LU factorization */
void mexFunction
(
int nargout,
mxArray *pargout [ ],
int nargin,
const mxArray *pargin [ ]
)
{
double tol ;
CS_INT order ;
if (nargout > 1 || nargin < 2 || nargin > 4)
{
mexErrMsgTxt ("Usage: x = cs_lusol(A,b,order,tol)") ;
}
order = (nargin < 3) ? 2 : mxGetScalar (pargin [2]) ;
order = CS_MAX (order, 0) ;
order = CS_MIN (order, 3) ;
if (nargin == 2)
{
tol = 1 ; /* normal partial pivoting */
}
else if (nargin == 3)
{
tol = (order == 1) ? 0.001 : 1 ; /* tol = 0.001 for amd(A+A') */
}
else
{
tol = mxGetScalar (pargin [3]) ;
}
if (mxIsComplex (pargin [0]) || mxIsComplex (pargin [1]))
{
#ifndef NCOMPLEX
cs_cl *A, Amatrix ;
cs_complex_t *x ;
A = cs_cl_mex_get_sparse (&Amatrix, 1, pargin [0]) ; /* get A */
x = cs_cl_mex_get_double (A->n, pargin [1]) ; /* x = b */
if (!cs_cl_lusol (order, A, x, tol)) /* x = A\x */
{
mexErrMsgTxt ("failed (singular or out of memory)") ;
}
cs_cl_free (A->x) ; /* complex copy no longer needed */
pargout [0] = cs_cl_mex_put_double (A->n, x) ; /* return x */
#else
mexErrMsgTxt ("complex matrices not supported") ;
#endif
}
else
{
cs_dl *A, Amatrix ;
double *x, *b ;
A = cs_dl_mex_get_sparse (&Amatrix, 1, 1, pargin [0]) ; /* get A */
b = cs_dl_mex_get_double (A->n, pargin [1]) ; /* get b */
x = cs_dl_mex_put_double (A->n, b, &(pargout [0])) ; /* x = b */
if (!cs_dl_lusol (order, A, x, tol)) /* x = A\x */
{
mexErrMsgTxt ("failed (singular or out of memory)") ;
}
}
}
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