Grid/tests/Test_cayley_coarsen_support.cc

#include <Grid.h>

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


template<class d>
struct scal {
  d internal;
};

  Gamma::GammaMatrix Gmu [] = {
    Gamma::GammaX,
    Gamma::GammaY,
    Gamma::GammaZ,
    Gamma::GammaT
  };

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

  const int Ls=8;

  GridCartesian         * UGrid   = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(), GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());
  GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);

  GridCartesian         * FGrid   = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);
  GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);

  // Construct a coarsened grid
  std::vector<int> clatt = GridDefaultLatt();
  for(int d=0;d<clatt.size();d++){
    clatt[d] = clatt[d]/2;
  }
  GridCartesian *Coarse4d =  SpaceTimeGrid::makeFourDimGrid(clatt, GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());;
  GridCartesian *Coarse5d =  SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);

  std::vector<int> seeds4({1,2,3,4});
  std::vector<int> seeds5({5,6,7,8});
  std::vector<int> cseeds({5,6,7,8});
  GridParallelRNG          RNG5(FGrid);   RNG5.SeedFixedIntegers(seeds5);
  GridParallelRNG          RNG4(UGrid);   RNG4.SeedFixedIntegers(seeds4);
  GridParallelRNG          CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);

  LatticeFermion    src(FGrid); random(RNG5,src);
  LatticeFermion result(FGrid); result=zero;
  LatticeFermion    ref(FGrid); ref=zero;
  LatticeFermion    tmp(FGrid);
  LatticeFermion    err(FGrid);
  LatticeGaugeField Umu(UGrid); random(RNG4,Umu);

#if 0
  std::vector<LatticeColourMatrix> U(4,UGrid);
  Umu=zero;
  Complex cone(1.0,0.0);
  for(int nn=0;nn<Nd;nn++){
    if(1) {
      if (nn>2) { U[nn]=zero; std::cout << "zeroing gauge field in dir "<<nn<<std::endl; }
      else      { U[nn]=cone; std::cout << "unit gauge field in dir "<<nn<<std::endl; }
    }
    pokeIndex<LorentzIndex>(Umu,U[nn],nn);
  }
#endif  

  RealD mass=0.5;
  RealD M5=1.8;

  DomainWallFermion Ddwf(Umu,*FGrid,*FrbGrid,*UGrid,*UrbGrid,mass,M5);
  Gamma5R5HermitianLinearOperator<DomainWallFermion,LatticeFermion> HermIndefOp(Ddwf);

  HermIndefOp.Op(src,ref);
  HermIndefOp.OpDiag(src,result);
  
  for(int d=0;d<4;d++){
    HermIndefOp.OpDir(src,tmp,d+1,+1); result=result+tmp; 
    std::cout<<"dir "<<d<<" tmp "<<norm2(tmp)<<std::endl;
    HermIndefOp.OpDir(src,tmp,d+1,-1); result=result+tmp;
    std::cout<<"dir "<<d<<" tmp "<<norm2(tmp)<<std::endl;
  }
  err = result-ref;
  std::cout<<"Error "<<norm2(err)<<std::endl;

  const int nbasis = 2;
  LatticeFermion prom(FGrid);

  std::vector<LatticeFermion> subspace(nbasis,FGrid);

  std::cout<<"Calling Aggregation class" <<std::endl;

  MdagMLinearOperator<DomainWallFermion,LatticeFermion> HermDefOp(Ddwf);
  typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;
  Subspace Aggregates(Coarse5d,FGrid);
  Aggregates.CreateSubspaceRandom(RNG5);

  subspace=Aggregates.subspace;

  std::cout << "Called aggregation class"<< std::endl;

  typedef CoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;
  typedef LittleDiracOperator::CoarseVector CoarseVector;

  LittleDiracOperator LittleDiracOp(*Coarse5d);

  LittleDiracOp.CoarsenOperator(FGrid,HermIndefOp,Aggregates);
  
  CoarseVector c_src (Coarse5d);
  CoarseVector c_res (Coarse5d);
  CoarseVector c_proj(Coarse5d);
  
  Complex one(1.0);
  c_src = one;  // 1 in every element for vector 1.
  
  blockPromote(c_src,err,subspace);

  prom=zero;
  for(int b=0;b<nbasis;b++){
    prom=prom+subspace[b];
  }
  err=err-prom; 
  std::cout<<"Promoted back from subspace err "<<norm2(err)<<std::endl;

  HermIndefOp.HermOp(prom,tmp);
  blockProject(c_proj,tmp,subspace);

  LittleDiracOp.M(c_src,c_res);

  c_proj = c_proj - c_res;
  std::cout<<"Representation of ldop within subspace "<<norm2(c_proj)<<std::endl;

  std::cout << "Multiplying by LittleDiracOp "<< std::endl;
  LittleDiracOp.M(c_src,c_res);

  std::cout<<"Testing hermiticity explicitly by inspecting matrix elements"<<std::endl;
  LittleDiracOp.AssertHermitian();

  std::cout << "Testing Hermiticity stochastically "<< std::endl;
  CoarseVector phi(Coarse5d);
  CoarseVector chi(Coarse5d);
  CoarseVector Aphi(Coarse5d);
  CoarseVector Achi(Coarse5d);

  random(CRNG,phi);
  random(CRNG,chi);


  std::cout<<"Made randoms"<<std::endl;

  LittleDiracOp.M(phi,Aphi);
  LittleDiracOp.Mdag(chi,Achi);

  ComplexD pAc = innerProduct(chi,Aphi);
  ComplexD cAp = innerProduct(phi,Achi);
  ComplexD cAc = innerProduct(chi,Achi);
  ComplexD pAp = innerProduct(phi,Aphi);

  std::cout<< "pAc "<<pAc<<" cAp "<< cAp<< " diff "<<pAc-adj(cAp)<<std::endl;

  std::cout<< "pAp "<<pAp<<" cAc "<< cAc<<"Should be real"<< std::endl;

  std::cout<<"Testing linearity"<<std::endl;
  CoarseVector PhiPlusChi(Coarse5d);
  CoarseVector APhiPlusChi(Coarse5d);
  CoarseVector linerr(Coarse5d);
  PhiPlusChi = phi+chi;
  LittleDiracOp.M(PhiPlusChi,APhiPlusChi);

  linerr= APhiPlusChi-Aphi;
  linerr= linerr-Achi;
  std::cout<<"**Diff "<<norm2(linerr)<<std::endl;


  std::cout << "Done "<< std::endl;
  Grid_finalize();
}
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`#include <Grid.h>`

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


			`template<class d>`
			`struct scal {`
			`d internal;`
			`};`

			`Gamma::GammaMatrix Gmu [] = {`
			`Gamma::GammaX,`
			`Gamma::GammaY,`
			`Gamma::GammaZ,`
			`Gamma::GammaT`
			`};`

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

Some extra tests 2015-06-09 22:43:10 +01:00			`const int Ls=8;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Change the SIMD command correctly with precision = double vs. single and connect the "Real" default precisoin to a configure flag. Have RealF, RealD and Real types, where Real is compile target dependent single/double, RealF is single and RealD is double etc.. 2015-07-01 22:45:15 +01:00			`GridCartesian * UGrid = SpaceTimeGrid::makeFourDimGrid(GridDefaultLatt(), GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`GridRedBlackCartesian * UrbGrid = SpaceTimeGrid::makeFourDimRedBlackGrid(UGrid);`

			`GridCartesian * FGrid = SpaceTimeGrid::makeFiveDimGrid(Ls,UGrid);`
			`GridRedBlackCartesian * FrbGrid = SpaceTimeGrid::makeFiveDimRedBlackGrid(Ls,UGrid);`

			`// Construct a coarsened grid`
			`std::vector<int> clatt = GridDefaultLatt();`
			`for(int d=0;d<clatt.size();d++){`
			`clatt[d] = clatt[d]/2;`
			`}`
Change the SIMD command correctly with precision = double vs. single and connect the "Real" default precisoin to a configure flag. Have RealF, RealD and Real types, where Real is compile target dependent single/double, RealF is single and RealD is double etc.. 2015-07-01 22:45:15 +01:00			`GridCartesian *Coarse4d = SpaceTimeGrid::makeFourDimGrid(clatt, GridDefaultSimd(Nd,vComplex::Nsimd()),GridDefaultMpi());;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`GridCartesian *Coarse5d = SpaceTimeGrid::makeFiveDimGrid(1,Coarse4d);`

			`std::vector<int> seeds4({1,2,3,4});`
			`std::vector<int> seeds5({5,6,7,8});`
Some extra tests 2015-06-09 22:43:10 +01:00			`std::vector<int> cseeds({5,6,7,8});`
			`GridParallelRNG RNG5(FGrid); RNG5.SeedFixedIntegers(seeds5);`
			`GridParallelRNG RNG4(UGrid); RNG4.SeedFixedIntegers(seeds4);`
			`GridParallelRNG CRNG(Coarse5d);CRNG.SeedFixedIntegers(cseeds);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
			`LatticeFermion src(FGrid); random(RNG5,src);`
			`LatticeFermion result(FGrid); result=zero;`
			`LatticeFermion ref(FGrid); ref=zero;`
			`LatticeFermion tmp(FGrid);`
			`LatticeFermion err(FGrid);`
			`LatticeGaugeField Umu(UGrid); random(RNG4,Umu);`
Some extra tests 2015-06-09 22:43:10 +01:00
Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`#if 0`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`std::vector<LatticeColourMatrix> U(4,UGrid);`
Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`Umu=zero;`
			`Complex cone(1.0,0.0);`
			`for(int nn=0;nn<Nd;nn++){`
			`if(1) {`
Some extra tests 2015-06-09 22:43:10 +01:00			`if (nn>2) { U[nn]=zero; std::cout << "zeroing gauge field in dir "<<nn<<std::endl; }`
			`else { U[nn]=cone; std::cout << "unit gauge field in dir "<<nn<<std::endl; }`
Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`}`
			`pokeIndex<LorentzIndex>(Umu,U[nn],nn);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`}`
Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`#endif`
Some extra tests 2015-06-09 22:43:10 +01:00
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`RealD mass=0.5;`
			`RealD M5=1.8;`

			`DomainWallFermion Ddwf(Umu,FGrid,FrbGrid,UGrid,UrbGrid,mass,M5);`
Some extra tests 2015-06-09 22:43:10 +01:00			`Gamma5R5HermitianLinearOperator<DomainWallFermion,LatticeFermion> HermIndefOp(Ddwf);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
			`HermIndefOp.Op(src,ref);`
			`HermIndefOp.OpDiag(src,result);`

			`for(int d=0;d<4;d++){`
Some extra tests 2015-06-09 22:43:10 +01:00			`HermIndefOp.OpDir(src,tmp,d+1,+1); result=result+tmp;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`std::cout<<"dir "<<d<<" tmp "<<norm2(tmp)<<std::endl;`
Some extra tests 2015-06-09 22:43:10 +01:00			`HermIndefOp.OpDir(src,tmp,d+1,-1); result=result+tmp;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`std::cout<<"dir "<<d<<" tmp "<<norm2(tmp)<<std::endl;`
			`}`
			`err = result-ref;`
			`std::cout<<"Error "<<norm2(err)<<std::endl;`

Some unary ops and coarse grid support 2015-06-09 10:26:19 +01:00			`const int nbasis = 2;`
Some extra tests 2015-06-09 22:43:10 +01:00			`LatticeFermion prom(FGrid);`

Patches for beginnings of an overlap multigrid 2015-06-20 22:22:56 +01:00			`std::vector<LatticeFermion> subspace(nbasis,FGrid);`

			`std::cout<<"Calling Aggregation class" <<std::endl;`

			`MdagMLinearOperator<DomainWallFermion,LatticeFermion> HermDefOp(Ddwf);`
			`typedef Aggregation<vSpinColourVector,vTComplex,nbasis> Subspace;`
			`Subspace Aggregates(Coarse5d,FGrid);`
			`Aggregates.CreateSubspaceRandom(RNG5);`

			`subspace=Aggregates.subspace;`

			`std::cout << "Called aggregation class"<< std::endl;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Some extra tests 2015-06-09 22:43:10 +01:00			`typedef CoarsenedMatrix<vSpinColourVector,vTComplex,nbasis> LittleDiracOperator;`
			`typedef LittleDiracOperator::CoarseVector CoarseVector;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Some extra tests 2015-06-09 22:43:10 +01:00			`LittleDiracOperator LittleDiracOp(*Coarse5d);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Patches for beginnings of an overlap multigrid 2015-06-20 22:22:56 +01:00			`LittleDiracOp.CoarsenOperator(FGrid,HermIndefOp,Aggregates);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Some extra tests 2015-06-09 22:43:10 +01:00			`CoarseVector c_src (Coarse5d);`
			`CoarseVector c_res (Coarse5d);`
			`CoarseVector c_proj(Coarse5d);`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
Some extra tests 2015-06-09 22:43:10 +01:00			`Complex one(1.0);`
			`c_src = one; // 1 in every element for vector 1.`

			`blockPromote(c_src,err,subspace);`

			`prom=zero;`
			`for(int b=0;b<nbasis;b++){`
			`prom=prom+subspace[b];`
			`}`
			`err=err-prom;`
			`std::cout<<"Promoted back from subspace err "<<norm2(err)<<std::endl;`

			`HermIndefOp.HermOp(prom,tmp);`
			`blockProject(c_proj,tmp,subspace);`

			`LittleDiracOp.M(c_src,c_res);`

			`c_proj = c_proj - c_res;`
			`std::cout<<"Representation of ldop within subspace "<<norm2(c_proj)<<std::endl;`
Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00
			`std::cout << "Multiplying by LittleDiracOp "<< std::endl;`
			`LittleDiracOp.M(c_src,c_res);`

Some extra tests 2015-06-09 22:43:10 +01:00			`std::cout<<"Testing hermiticity explicitly by inspecting matrix elements"<<std::endl;`
			`LittleDiracOp.AssertHermitian();`

			`std::cout << "Testing Hermiticity stochastically "<< std::endl;`
			`CoarseVector phi(Coarse5d);`
			`CoarseVector chi(Coarse5d);`
			`CoarseVector Aphi(Coarse5d);`
			`CoarseVector Achi(Coarse5d);`

			`random(CRNG,phi);`
			`random(CRNG,chi);`


			`std::cout<<"Made randoms"<<std::endl;`

			`LittleDiracOp.M(phi,Aphi);`
			`LittleDiracOp.Mdag(chi,Achi);`

			`ComplexD pAc = innerProduct(chi,Aphi);`
			`ComplexD cAp = innerProduct(phi,Achi);`
			`ComplexD cAc = innerProduct(chi,Achi);`
			`ComplexD pAp = innerProduct(phi,Aphi);`

			`std::cout<< "pAc "<<pAc<<" cAp "<< cAp<< " diff "<<pAc-adj(cAp)<<std::endl;`

			`std::cout<< "pAp "<<pAp<<" cAc "<< cAc<<"Should be real"<< std::endl;`

			`std::cout<<"Testing linearity"<<std::endl;`
			`CoarseVector PhiPlusChi(Coarse5d);`
			`CoarseVector APhiPlusChi(Coarse5d);`
			`CoarseVector linerr(Coarse5d);`
			`PhiPlusChi = phi+chi;`
			`LittleDiracOp.M(PhiPlusChi,APhiPlusChi);`

			`linerr= APhiPlusChi-Aphi;`
			`linerr= linerr-Achi;`
			`std::cout<<"**Diff "<<norm2(linerr)<<std::endl;`


Conjugate residual algorithm; some more unary functions 2015-06-08 12:04:59 +01:00			`std::cout << "Done "<< std::endl;`
			`Grid_finalize();`
			`}`