#ifndef Hadrons_MSource_Gauss_hpp_ #define Hadrons_MSource_Gauss_hpp_ #include #include #include BEGIN_HADRONS_NAMESPACE /****************************************************************************** * Gauss * * result[n] = 1/(sqrt(2*pi)*width)^dim * * * exp(-|n-position|^2/(2*width^2)) * * * exp(i*2*pi/L*mom*n) * * where: * * n=(n[0],n[1],...,n[dim-1]) (lattice coordinate) * * dim=Nd-1 * ******************************************************************************/ BEGIN_MODULE_NAMESPACE(MSource) class GaussPar: Serializable { public: GRID_SERIALIZABLE_CLASS_MEMBERS(GaussPar, std::string, position, std::string, mom, int, tA, int, tB, double, width); }; template class TGauss: public Module { BASIC_TYPE_ALIASES(FImpl,); public: // constructor TGauss(const std::string name); // destructor virtual ~TGauss(void) {}; // dependency relation virtual std::vector getInput(void); virtual std::vector getOutput(void); // setup virtual void setup(void); // execution virtual void execute(void); private: std::vector position_; std::vector mom_; }; MODULE_REGISTER_TMP(Gauss, TGauss, MSource); MODULE_REGISTER_TMP(ScalarGauss, TGauss, MSource); /****************************************************************************** * TGauss implementation * ******************************************************************************/ // constructor ///////////////////////////////////////////////////////////////// template TGauss::TGauss(const std::string name) : Module(name) {} // dependencies/products /////////////////////////////////////////////////////// template std::vector TGauss::getInput(void) { std::vector in; return in; } template std::vector TGauss::getOutput(void) { std::vector out = {getName()}; return out; } // setup /////////////////////////////////////////////////////////////////////// template void TGauss::setup(void) { auto parse_vector = [](const std::string &vec, int dim, const std::string &desc) { std::vector res = strToVec(vec); if(res.size() != dim) { HADRONS_ERROR(Size, desc + " has " + std::to_string(res.size()) + " instead of " + std::to_string(dim) + " components"); } return res; }; position_ = parse_vector(par().position, env().getNd()-1, "position"); mom_ = parse_vector(par().mom, env().getNd(), "momentum"); envCreateLat(PropagatorField, getName()); envTmpLat(ComplexField, "component"); envTmpLat(ComplexField, "ScalarRho"); envTmp(LatticeInteger, "compHelper", 1, envGetGrid(ComplexField)); } // execution /////////////////////////////////////////////////////////////////// template void TGauss::execute(void) { auto &rho = envGet(PropagatorField, getName()); envGetTmp(ComplexField, component); envGetTmp(ComplexField, ScalarRho); envGetTmp(LatticeInteger, compHelper); const int dim=env().getNd()-1; const Real fact=-0.5/std::pow(par().width,2); const Complex i(0.0, 1.0); const SitePropagator idMat=[](){ SitePropagator s; s=1.; return s; }(); const vTInteger vTtA=par().tA; const vTInteger vTtB=par().tB; ScalarRho=zero; for(int mu=0; mu=0 && position_[mu]vTLmuHalf), component-Complex(Lmu), component); } else { component=where((compHelper<=-vTLmuHalf), component+Complex(Lmu), component); } ScalarRho+=component*component*fact; } //time component of momentum phase LatticeCoordinate(component, dim); ScalarRho+=(i*(mom_.at(dim)*2*M_PI/env().getDim(dim)))*component; //compute scalar result ScalarRho=exp(ScalarRho)*Complex(std::pow(sqrt(2*M_PI)*par().width,-dim)); //select time slices LatticeCoordinate(compHelper, dim); ScalarRho=where((compHelper>=vTtA && compHelper<=vTtB), ScalarRho, 0.*ScalarRho); //compute output field rho rho=ScalarRho*idMat; } END_MODULE_NAMESPACE END_HADRONS_NAMESPACE #endif // Hadrons_MSource_Gauss_hpp_