#include namespace Grid { namespace QCD { const std::vector WilsonMatrix::directions ({0,1,2,3, 0, 1, 2, 3,0}); const std::vector WilsonMatrix::displacements({1,1,1,1,-1,-1,-1,-1,0}); // Should be in header? const int WilsonMatrix::Xp = 0; const int WilsonMatrix::Yp = 1; const int WilsonMatrix::Zp = 2; const int WilsonMatrix::Tp = 3; const int WilsonMatrix::Xm = 4; const int WilsonMatrix::Ym = 5; const int WilsonMatrix::Zm = 6; const int WilsonMatrix::Tm = 7; //const int WilsonMatrix::X0 = 8; class WilsonCompressor { public: int mu; void Point(int p) { mu=p; }; vHalfSpinColourVector operator () (const vSpinColourVector &in) { vHalfSpinColourVector ret; switch(mu) { case WilsonMatrix::Xp: spProjXp(ret,in); break; case WilsonMatrix::Yp: spProjYp(ret,in); break; case WilsonMatrix::Zp: spProjZp(ret,in); break; case WilsonMatrix::Tp: spProjTp(ret,in); break; case WilsonMatrix::Xm: spProjXm(ret,in); break; case WilsonMatrix::Ym: spProjYm(ret,in); break; case WilsonMatrix::Zm: spProjZm(ret,in); break; case WilsonMatrix::Tm: spProjTm(ret,in); break; default: assert(0); break; } return ret; } }; WilsonMatrix::WilsonMatrix(LatticeGaugeField &_Umu,double _mass) : Stencil(Umu._grid,npoint,0,directions,displacements), mass(_mass), Umu(_Umu._grid) { // Allocate the required comms buffer grid = _Umu._grid; comm_buf.resize(Stencil._unified_buffer_size); DoubleStore(Umu,_Umu); } void WilsonMatrix::DoubleStore(LatticeDoubledGaugeField &Uds,const LatticeGaugeField &Umu) { LatticeColourMatrix U(grid); for(int mu=0;mu(Umu,mu); pokeIndex(Uds,U,mu); U = adj(Cshift(U,mu,-1)); pokeIndex(Uds,U,mu+4); } } void WilsonMatrix::M(const LatticeFermion &in, LatticeFermion &out) { Dhop(in,out); return; } void WilsonMatrix::Mdag(const LatticeFermion &in, LatticeFermion &out) { Dhop(in,out); return; } void WilsonMatrix::MdagM(const LatticeFermion &in, LatticeFermion &out) { Dhop(in,out); return; } void WilsonMatrix::Dhop(const LatticeFermion &in, LatticeFermion &out) { WilsonCompressor compressor; Stencil.HaloExchange(in,comm_buf,compressor); PARALLEL_FOR_LOOP for(int sss=0;sssoSites();sss++){ vHalfSpinColourVector tmp; vHalfSpinColourVector chi; vSpinColourVector result; vHalfSpinColourVector Uchi; int offset,local,perm, ptype; // int ss = Stencil._LebesgueReorder[sss]; int ss = sss; int ssu= ss; // Xp offset = Stencil._offsets [Xp][ss]; local = Stencil._is_local[Xp][ss]; perm = Stencil._permute[Xp][ss]; ptype = Stencil._permute_type[Xp]; if ( local && perm ) { spProjXp(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjXp(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Xp),&chi()); //prefetch(Umu._odata[ssu](Yp)); spReconXp(result,Uchi); // Yp offset = Stencil._offsets [Yp][ss]; local = Stencil._is_local[Yp][ss]; perm = Stencil._permute[Yp][ss]; ptype = Stencil._permute_type[Yp]; if ( local && perm ) { spProjYp(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjYp(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Yp),&chi()); // prefetch(Umu._odata[ssu](Zp)); accumReconYp(result,Uchi); // Zp offset = Stencil._offsets [Zp][ss]; local = Stencil._is_local[Zp][ss]; perm = Stencil._permute[Zp][ss]; ptype = Stencil._permute_type[Zp]; if ( local && perm ) { spProjZp(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjZp(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Zp),&chi()); // prefetch(Umu._odata[ssu](Tp)); accumReconZp(result,Uchi); // Tp offset = Stencil._offsets [Tp][ss]; local = Stencil._is_local[Tp][ss]; perm = Stencil._permute[Tp][ss]; ptype = Stencil._permute_type[Tp]; if ( local && perm ) { spProjTp(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjTp(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Tp),&chi()); // prefetch(Umu._odata[ssu](Xm)); accumReconTp(result,Uchi); // Xm offset = Stencil._offsets [Xm][ss]; local = Stencil._is_local[Xm][ss]; perm = Stencil._permute[Xm][ss]; ptype = Stencil._permute_type[Xm]; if ( local && perm ) { spProjXm(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjXm(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Xm),&chi()); accumReconXm(result,Uchi); // Ym offset = Stencil._offsets [Ym][ss]; local = Stencil._is_local[Ym][ss]; perm = Stencil._permute[Ym][ss]; ptype = Stencil._permute_type[Ym]; if ( local && perm ) { spProjYm(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjYm(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Ym),&chi()); accumReconYm(result,Uchi); // Zm offset = Stencil._offsets [Zm][ss]; local = Stencil._is_local[Zm][ss]; perm = Stencil._permute[Zm][ss]; ptype = Stencil._permute_type[Zm]; if ( local && perm ) { spProjZm(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjZm(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Zm),&chi()); accumReconZm(result,Uchi); // Tm offset = Stencil._offsets [Tm][ss]; local = Stencil._is_local[Tm][ss]; perm = Stencil._permute[Tm][ss]; ptype = Stencil._permute_type[Tm]; if ( local && perm ) { spProjTm(tmp,in._odata[offset]); permute(chi,tmp,ptype); } else if ( local ) { spProjTm(chi,in._odata[offset]); } else { chi=comm_buf[offset]; } mult(&Uchi(),&Umu._odata[ssu](Tm),&chi()); accumReconTm(result,Uchi); vstream(out._odata[ss],result); } } void WilsonMatrix::Dw(const LatticeFermion &in, LatticeFermion &out) { return; } void WilsonMatrix::MpcDag (const LatticeFermion &in, LatticeFermion &out) { return; } void WilsonMatrix::Mpc (const LatticeFermion &in, LatticeFermion &out) { return; } void WilsonMatrix::MpcDagMpc(const LatticeFermion &in, LatticeFermion &out) { return; } void WilsonMatrix::MDagM (const LatticeFermion &in, LatticeFermion &out) { return; } }}