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Grid/extras/Hadrons/Modules/MScalar/ScalarVP.cc

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#include <Grid/Hadrons/Modules/MScalar/ScalarVP.hpp>
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using namespace Grid;
using namespace Hadrons;
using namespace MScalar;
/******************************************************************************
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* TScalarVP implementation *
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******************************************************************************/
// constructor /////////////////////////////////////////////////////////////////
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TScalarVP::TScalarVP(const std::string name)
: Module<ScalarVPPar>(name)
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{}
// dependencies/products ///////////////////////////////////////////////////////
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std::vector<std::string> TScalarVP::getInput(void)
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{
std::vector<std::string> in = {par().source, par().emField};
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return in;
}
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std::vector<std::string> TScalarVP::getOutput(void)
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{
std::vector<std::string> out = {getName()};
return out;
}
// setup ///////////////////////////////////////////////////////////////////////
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void TScalarVP::setup(void)
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{
freeMomPropName_ = FREEMOMPROP(par().mass);
GFSrcName_ = "_" + getName() + "_DinvSrc";
prop0Name_ = getName() + "_prop0";
propQName_ = getName() + "_propQ";
propSunName_ = getName() + "_propSun";
propTadName_ = getName() + "_propTad";
phaseName_.clear();
muGFSrcName_.clear();
muProp0Name_.clear();
muPropQName_.clear();
muPropSunName_.clear();
muPropTadName_.clear();
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
phaseName_.push_back("_shiftphase_" + std::to_string(mu));
muGFSrcName.push_back("_" + getName() + "_DinvSrc_" + std::to_string(mu));
muProp0Name_.push_back(getName() + "_prop0_" + std::to_string(mu));
muPropQName_.push_back(getName() + "_propQ_" + std::to_string(mu));
muPropSunName_.push_back(getName() + "_propSun_" + std::to_string(mu));
muPropTadName_.push_back(getName() + "_propTad_" + std::to_string(mu));
}
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if (!env().hasRegisteredObject(freeMomPropName_))
{
env().registerLattice<ScalarField>(freeMomPropName_);
}
if (!env().hasRegisteredObject(phaseName_[0]))
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(phaseName_[mu]);
}
}
if (!env().hasRegisteredObject(GFSrcName_))
{
env().registerLattice<ScalarField>(GFSrcName_);
}
if (!env().hasRegisteredObject(muGFSrcName_[0]))
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(muGFSrcName_[mu]);
}
}
if (!env().hasRegisteredObject(prop0Name_))
{
env().registerLattice<ScalarField>(prop0Name_);
}
if (!env().hasRegisteredObject(muProp0Name_[0]))
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(muProp0Name_[mu]);
}
}
env().registerLattice<ScalarField>(propQName_);
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(muPropQName_[mu]);
}
env().registerLattice<ScalarField>(propSunName_);
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(muPropSunName_[mu]);
}
env().registerLattice<ScalarField>(propTadName_);
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
env().registerLattice<ScalarField>(muPropTadName_[mu]);
}
env().registerLattice<ScalarField>(getName());
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}
// execution ///////////////////////////////////////////////////////////////////
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void TScalarVP::execute(void)
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{
// CACHING ANALYTIC EXPRESSIONS
ScalarField &source = *env().getObject<ScalarField>(par().source);
Complex ci(0.0,1.0);
FFT fft(env().getGrid());
// cache momentum-space free scalar propagator
if (!env().hasCreatedObject(freeMomPropName_))
{
LOG(Message) << "Caching momentum space free scalar propagator"
<< " (mass= " << par().mass << ")..." << std::endl;
freeMomProp_ = env().createLattice<ScalarField>(freeMomPropName_);
Scalar<SIMPL>::MomentumSpacePropagator(*freeMomProp_, par().mass);
}
else
{
freeMomProp_ = env().getObject<ScalarField>(freeMomPropName_);
}
// cache phases
if (!env().hasCreatedObject(phaseName_[0]))
{
std::vector<int> &l = env().getGrid()->_fdimensions;
LOG(Message) << "Caching shift phases..." << std::endl;
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
Real twoPiL = M_PI*2./l[mu];
phase_.push_back(env().createLattice<ScalarField>(phaseName_[mu]));
LatticeCoordinate(*(phase_[mu]), mu);
*(phase_[mu]) = exp(ci*twoPiL*(*(phase_[mu])));
}
}
else
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
phase_.push_back(env().getObject<ScalarField>(phaseName_[mu]));
}
}
// cache G*F*src
if (!env().hasCreatedObject(GFSrcName_))
{
GFSrc_ = env().createLattice<ScalarField>(GFSrcName_);
fft.FFT_all_dim(*GFSrc_, source, FFT::forward);
*GFSrc_ = (*freeMomProp_)*(*GFSrc_);
}
else
{
GFSrc_ = env().getObject<ScalarField>(GFSrcName_);
}
// cache G*exp(i*k_mu)*F*src
if (!env().hasCreatedObject(muGFSrcName_[0]))
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
muGFSrc_.push_back(env().createLattice<ScalarField>(muGFSrcName_[mu]));
fft.FFT_all_dim(*(muGFSrc_[mu]), source, FFT::forward);
*(muGFSrc_[mu]) = (*freeMomProp_)*(*phase_[mu])*(*muGFSrc_[mu]);
}
}
else
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
muGFSrc_.push_back(env().getObject<ScalarField>(muGFSrcName_[mu]));
}
}
// cache position-space free scalar propagators
if (!env().hasCreatedObject(prop0Name_))
{
prop0_ = env().createLattice<ScalarField>(prop0Name_);
fft.FFT_all_dim(*prop0_, *GFSrc_, FFT::backward);
}
else
{
prop0_ = env().getObject<ScalarField>(prop0Name_);
}
if (!env().hasCreatedObject(muProp0Name_[0]))
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
muProp0_.push_back(env().createLattice<ScalarField>(muProp0Name_[mu]));
fft.FFT_all_dim(*(muProp0_[mu]), *(muGFSrc_[mu]), FFT::backward);
}
}
else
{
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
muProp0_.push_back(env().getObject<ScalarField>(muProp0Name_[mu]));
}
}
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// PROPAGATOR CALCULATION
// Propagator from unshifted source
ScalarField &propQ = *env().createLattice<ScalarField>(propQName_);
ScalarField &propSun = *env().createLattice<ScalarField>(propSunName_);
ScalarField &propTad = *env().createLattice<ScalarField>(propTadName_);
chargedProp(propQ, propSun, propTad, *GFSrc_, fft);
// Propagators from shifted sources
std::vector<ScalarField *> muPropQ_, muPropSun_, muPropTad_;
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
muPropQ_.push_back(env().createLattice<ScalarField>(muPropQName_[mu]));
muPropSun_.push_back(env().createLattice<ScalarField>(muPropSunName_[mu]));
muPropTad_.push_back(env().createLattice<ScalarField>(muPropTadName_[mu]));
chargedProp(*(muPropQ_[mu]), *(muPropSun_[mu]), *(muPropTad_[mu]),
*(muGFSrc_[mu]), fft);
}
}
// Calculate O(q) and O(q^2) terms of momentum-space charged propagator
void TScalarVP::chargedProp(ScalarField &prop_q, ScalarField &prop_sun,
ScalarField &prop_tad, ScalarField &GFSrc,
FFT &fft)
{
Complex ci(0.0,1.0);
double q = par().charge;
ScalarField &G = *freeMomProp_;
ScalarField buf(env().getGrid());
LOG(Message) << "Computing charged scalar propagator"
<< " (mass= " << par().mass
<< ", charge= " << q << ")..." << std::endl;
// -q*G*momD1*G*F*Src (momD1 = F*D1*Finv)
buf = GFSrc;
momD1(buf, fft);
buf = G*buf;
prop_q = -q*buf;
// q*q*G*momD1*G*momD1*G*F*Src
momD1(buf, fft);
prop_sun = q*q*G*buf;
// -q*q*G*momD2*G*F*Src (momD2 = F*D2*Finv)
buf = GFSrc;
momD2(buf, fft);
prop_tad = -q*q*G*buf;
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}
void TScalarVP::momD1(ScalarField &s, FFT &fft)
{
EmField &A = *env().getObject<EmField>(par().emField);
ScalarField buf(env().getGrid()), result(env().getGrid()),
Amu(env().getGrid());
Complex ci(0.0,1.0);
result = zero;
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
Amu = peekLorentz(A, mu);
buf = (*phase_[mu])*s;
fft.FFT_all_dim(buf, buf, FFT::backward);
buf = Amu*buf;
fft.FFT_all_dim(buf, buf, FFT::forward);
result = result - ci*buf;
}
fft.FFT_all_dim(s, s, FFT::backward);
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
Amu = peekLorentz(A, mu);
buf = Amu*s;
fft.FFT_all_dim(buf, buf, FFT::forward);
result = result + ci*adj(*phase_[mu])*buf;
}
s = result;
}
void TScalarVP::momD2(ScalarField &s, FFT &fft)
{
EmField &A = *env().getObject<EmField>(par().emField);
ScalarField buf(env().getGrid()), result(env().getGrid()),
Amu(env().getGrid());
result = zero;
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
Amu = peekLorentz(A, mu);
buf = (*phase_[mu])*s;
fft.FFT_all_dim(buf, buf, FFT::backward);
buf = Amu*Amu*buf;
fft.FFT_all_dim(buf, buf, FFT::forward);
result = result + .5*buf;
}
fft.FFT_all_dim(s, s, FFT::backward);
for (unsigned int mu = 0; mu < env().getNd(); ++mu)
{
Amu = peekLorentz(A, mu);
buf = Amu*Amu*s;
fft.FFT_all_dim(buf, buf, FFT::forward);
result = result + .5*adj(*phase_[mu])*buf;
}
s = result;
}