Grid/tests/test_Grid_stencil.cc

#include "Grid.h"

using namespace std;
using namespace Grid;
using namespace Grid::QCD;


int main (int argc, char ** argv)
{
  Grid_init(&argc,&argv);

  std::vector<int> latt_size  (4);
  std::vector<int> simd_layout(4);
  std::vector<int> mpi_layout (4);

  int omp=1;
  int lat=8;

  mpi_layout[0]=1;
  mpi_layout[1]=1;
  mpi_layout[2]=1;
  mpi_layout[3]=1;

    latt_size[0] = lat;
    latt_size[1] = lat;
    latt_size[2] = lat;
    latt_size[3] = lat;
    double volume = latt_size[0]*latt_size[1]*latt_size[2]*latt_size[3];
    
#ifdef AVX512
    simd_layout[0] = 1;
    simd_layout[1] = 2;
    simd_layout[2] = 2;
    simd_layout[3] = 2;
#endif
#if defined (AVX1)|| defined (AVX2)
    simd_layout[0] = 1;
    simd_layout[1] = 1;
    simd_layout[2] = 2;
    simd_layout[3] = 2;
#endif
#if defined (SSE2)
    simd_layout[0] = 1;
    simd_layout[1] = 1;
    simd_layout[2] = 1;
    simd_layout[3] = 2;
#endif
    
    GridCartesian Fine(latt_size,simd_layout,mpi_layout);
    GridRedBlackCartesian rbFine(latt_size,simd_layout,mpi_layout);
    
    LatticeColourMatrix Foo(&Fine);
    LatticeColourMatrix Bar(&Fine);
    LatticeColourMatrix Check(&Fine);
    LatticeColourMatrix Diff(&Fine);
    
    random(Foo);
    gaussian(Bar);


    for(int dir=0;dir<4;dir++){
      for(int disp=0;disp<Fine._rdimensions[dir];disp++){

	// start to test the Cartesian npoint stencil infrastructure
	int npoint=1;
	std::vector<int> directions(npoint,dir);
	std::vector<int> displacements(npoint,disp);

	CartesianStencil myStencil(&Fine,npoint,0,directions,displacements);

	printf("STENCIL: osites %d %d dir %d disp %d\n",Fine.oSites(),(int)myStencil._offsets[0].size(),dir,disp);
	std::vector<int> ocoor(4);
	for(int o=0;o<Fine.oSites();o++){
	  Fine.oCoorFromOindex(ocoor,o);
	  ocoor[dir]=(ocoor[dir]+disp)%Fine._rdimensions[dir];
	  int nbr = Fine.oIndexReduced(ocoor);
	  int stcl= myStencil._offsets[0][o];
	  if(nbr!=stcl){
	    printf("STENCIL: nbr %d stencil._offset %d\n",nbr,stcl);
	  }
	}
	
	printf("allocating %d buffers\n",myStencil._unified_buffer_size);
	fflush(stdout);
	std::vector<vColourMatrix,alignedAllocator<vColourMatrix> >  comm_buf(myStencil._unified_buffer_size);
	printf("calling halo exchange\n");fflush(stdout);
	myStencil.HaloExchange(Foo,comm_buf);

	Bar = Cshift(Foo,dir,disp);

	// Implement a stencil code that should agree with cshift!
	for(int i=0;i<Check._grid->oSites();i++){

	  int offset = myStencil._offsets [0][i];
	  int  local = myStencil._is_local[0][i];
	  int permute_type = myStencil._permute_type[0];
	  int perm =myStencil._permute[0][i];
	  if ( local && perm )
	    permute(Check._odata[i],Foo._odata[offset],permute_type);
	  else if (local)
	    Check._odata[i] = Foo._odata[offset];
	  else 
	    Check._odata[i] = comm_buf[offset];
	  

	}

	Real nrmC = norm2(Check);
	Real nrmB = norm2(Bar);
	Real nrm  = norm2(Check-Bar);
	printf("N2diff = %le (%le, %le) \n",nrm,nrmC,nrmB);fflush(stdout);

	Real snrmC =0;
	Real snrmB =0;
	Real snrm  =0;

	std::vector<int> coor(4);
	for(coor[3]=0;coor[3]<latt_size[3]/mpi_layout[3];coor[3]++){
	for(coor[2]=0;coor[2]<latt_size[2]/mpi_layout[2];coor[2]++){
	for(coor[1]=0;coor[1]<latt_size[1]/mpi_layout[1];coor[1]++){
	for(coor[0]=0;coor[0]<latt_size[0]/mpi_layout[0];coor[0]++){

	  Complex diff;
	  ColourMatrix check,bar;
	  peekSite(check,Check,coor);
	  peekSite(bar,Bar,coor);

	  for(int r=0;r<3;r++){
	  for(int c=0;c<3;c++){
            diff =check()()(r,c)-bar()()(r,c);
            double nn=real(conj(diff)*diff);
            if ( nn > 0){
	      printf("Coor (%d %d %d %d) \t rc %d%d \t %le %le %le\n",
		     coor[0],coor[1],coor[2],coor[3],r,c,
		     nn,
		     real(check()()(r,c)),
		     real(bar()()(r,c))
		     );
	    }
	    snrmC=snrmC+real(conj(check()()(r,c))*check()()(r,c));
	    snrmB=snrmB+real(conj(bar()()(r,c))*bar()()(r,c));
	    snrm=snrm+nn;
	  }}
	 
	}}}}

	printf("scalar N2diff = %le (%le, %le) \n",snrm,snrmC,snrmB);fflush(stdout);


      }
    }

 Grid_finalize();
}