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/*@@
@file jacobi_wrapper.c
@date Tue Aug 24 12:50:07 1999
@author Gerd Lanfermann
@desc
The C wrapper, which calles the core Fortran routine, which
performs the actual solve.
We cannot derive the pointers to the GF data from the indeces in
Fortran. So we do this here in C and then pass the everything
over to the Fortran routine.
This wrapper is registers with the Elliptic solver registry
(not the Fortran file) , as coded up in ./CactusElliptic/EllBase
@enddesc
@@*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "cctk.h"
#include "cctk_parameters.h"
#include "cctk_FortranString.h"
/* We pass in the arguments that are neccessary for this class of elliptic eq.
this solver is intended to solve. See ./CactusElliptic/EllBase/src/ for the
classes of elliptic eq. */
void sor_confmetric(cGH *GH, int *MetricPsiI, int *FieldIndex,
int *MIndex, int *NIndex, int *AbsTol,int *RelTol) {
CCTK_REAL *gxx=NULL, *gxy=NULL, *gxz=NULL;
CCTK_REAL *gyy=NULL, *gyz=NULL, *gzz=NULL;
CCTK_REAL *psi=NULL;
CCTK_REAL *Mlinear=NULL, *Nsources=NULL;
CCTK_REAL *var=NULL;
CCTK_REAL tolerance;
int i;
int toltype;
int Mlinear_lsh[3], Nsource_lsh[3];
int retcode;
/* derive the metric data pointer from the index array. Note the ordering.
Also get datapointers to the field to solve for.
All of these are mandatory */
gxx = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[0]);
gxy = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[1]);
gxz = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[2]);
gyy = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[3]);
gyz = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[4]);
gzz = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[5]);
psi = (CCTK_REAL*) CCTK_VarDataPtrI(GH, 0, MetricPsiI[6]);
var = (CCTK_REAL*) CCTK_VarDataPtrI(GH,0,*FieldIndex);
if ((!gxx)||(!gxy)||(!gxz)||(!gyy)||(!gyz)||(!gzz)||(!psi)||(!var))
CCTK_WARN(0,"SOR_WRAPPER: One of the metric data fields, or the GF to solve could not be found!");
/* derive the data pointer for the fields. the M/N fields are not
allocated (better: are of size 1), if the passed index is negative,
or we get back an empty GF of size 1 */
if (*MIndex>0) Mlinear = (CCTK_REAL*) CCTK_VarDataPtrI(GH,0,*MIndex);
if (*NIndex>0) Nsources = (CCTK_REAL*) CCTK_VarDataPtrI(GH,0,*NIndex);
/* we pass the size of M/N through to frotran, so F can
tell the difference between an allocated GF (Mlinear_lsh=cctk_lsh) or
unallocated GF (Mlinear_lsh=1) maximal dimension is three. */
/* FIXME: for testing we should make sure that storage is allocated
for the GF M/N */
if (GH->cctk_dim>3)
CCTK_WARN(0,"This elliptic solver implementation does not do dimension>3!");
for (i=0;i<GH->cctk_dim;i++) {
if((*MIndex<0)) Mlinear_lsh[i]=1;
else Mlinear_lsh[i]=GH->cctk_lsh[i];
if((*NIndex<0)) Nsource_lsh[i]=1;
else Nsource_lsh[i]=GH->cctk_lsh[i];
printf("%d %d \n",Nsource_lsh[i],Mlinear_lsh[i]);
}
/* call the fortran routine */
FORTRAN_NAME(sor_confmetric_core3d)(_PASS_CCTK_C2F(GH),
Mlinear_lsh, Mlinear,
Nsource_lsh, Nsources,
gxx,gxy,gxz,gyy,gyz,gzz,psi,
var, AbsTol, RelTol);
}
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