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Grid/lib/qcd/utils/Metric.h

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/*************************************************************************************
Grid physics library, www.github.com/paboyle/Grid
Source file: ./lib/qcd/hmc/integrators/Integrator.h
Copyright (C) 2015
Author: Guido Cossu <guido.cossu@ed.ac.uk>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program; if not, write to the Free Software Foundation, Inc.,
51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
See the full license in the file "LICENSE" in the top level distribution
directory
*************************************************************************************/
/* END LEGAL */
//--------------------------------------------------------------------
#ifndef METRIC_H
#define METRIC_H
namespace Grid{
namespace QCD{
template <typename Field>
class Metric{
public:
virtual void ImportGauge(const Field&) = 0;
virtual void M(const Field&, Field&) = 0;
virtual void Minv(const Field&, Field&) = 0;
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virtual void MSquareRoot(Field&) = 0;
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virtual void MInvSquareRoot(Field&) = 0;
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virtual void MDeriv(const Field&, Field&) = 0;
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virtual void MDeriv(const Field&, const Field&, Field&) = 0;
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};
// Need a trivial operator
template <typename Field>
class TrivialMetric : public Metric<Field>{
public:
virtual void ImportGauge(const Field&){};
virtual void M(const Field& in, Field& out){
out = in;
}
virtual void Minv(const Field& in, Field& out){
out = in;
}
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virtual void MSquareRoot(Field& P){
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// do nothing
}
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virtual void MInvSquareRoot(Field& P){
// do nothing
}
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virtual void MDeriv(const Field& in, Field& out){
out = zero;
}
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virtual void MDeriv(const Field& left, const Field& right, Field& out){
out = zero;
}
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};
///////////////////////////////
// Generalised momenta
///////////////////////////////
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template <typename Implementation>
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class GeneralisedMomenta{
public:
typedef typename Implementation::Field MomentaField; //for readability
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typedef typename Implementation::GaugeLinkField MomentaLinkField; //for readability
Metric<MomentaField>& M;
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MomentaField Mom;
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// Auxiliary fields
// not hard coded but inherit the type from the metric
// created Nd new fields
// hide these in the metric?
//typedef Lattice<iVector<iScalar<iMatrix<vComplex, Nc> >, Nd/2 > > AuxiliaryMomentaType;
MomentaField AuxMom;
MomentaField AuxField;
GeneralisedMomenta(GridBase* grid, Metric<MomentaField>& M): M(M), Mom(grid), AuxMom(grid), AuxField(grid){}
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// Correct
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void MomentaDistribution(GridParallelRNG& pRNG){
// Generate a distribution for
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// P^dag G P
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// where G = M^-1
// Generate gaussian momenta
Implementation::generate_momenta(Mom, pRNG);
// Modify the distribution with the metric
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M.MSquareRoot(Mom);
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if (1) {
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// Auxiliary momenta
// do nothing if trivial, so hide in the metric
MomentaField AuxMomTemp(Mom._grid);
Implementation::generate_momenta(AuxMom, pRNG);
Implementation::generate_momenta(AuxField, pRNG);
// Modify the distribution with the metric
// Aux^dag M Aux
M.MInvSquareRoot(AuxMom); // AuxMom = M^{-1/2} AuxMomTemp
}
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}
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// Correct
RealD MomentaAction(){
MomentaField inv(Mom._grid);
inv = zero;
M.Minv(Mom, inv);
LatticeComplex Hloc(Mom._grid);
Hloc = zero;
for (int mu = 0; mu < Nd; mu++) {
// This is not very general
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// hide in the metric
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auto Mom_mu = PeekIndex<LorentzIndex>(Mom, mu);
auto inv_mu = PeekIndex<LorentzIndex>(inv, mu);
Hloc += trace(Mom_mu * inv_mu);
}
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if (1) {
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// Auxiliary Fields
// hide in the metric
M.M(AuxMom, inv);
for (int mu = 0; mu < Nd; mu++) {
// This is not very general
// hide in the operators
auto inv_mu = PeekIndex<LorentzIndex>(inv, mu);
auto am_mu = PeekIndex<LorentzIndex>(AuxMom, mu);
auto af_mu = PeekIndex<LorentzIndex>(AuxField, mu);
Hloc += trace(am_mu * inv_mu);// p M p
Hloc += trace(af_mu * af_mu);
}
}
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Complex Hsum = sum(Hloc);
return Hsum.real();
}
// Correct
void DerivativeU(MomentaField& in, MomentaField& der){
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// Compute the derivative of the kinetic term
// with respect to the gauge field
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MomentaField MDer(in._grid);
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MomentaField X(in._grid);
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X = zero;
M.Minv(in, X); // X = G in
M.MDeriv(X, MDer); // MDer = U * dS/dU
der = Implementation::projectForce(MDer); // Ta if gauge fields
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}
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void AuxiliaryFieldsDerivative(MomentaField& der){
der = zero;
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if (1){
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// Auxiliary fields
MomentaField der_temp(der._grid);
MomentaField X(der._grid);
X=zero;
//M.M(AuxMom, X); // X = M Aux
// Two derivative terms
// the Mderiv need separation of left and right terms
M.MDeriv(AuxMom, der);
// this one should not be necessary (identical to the previous one)
//M.MDeriv(X, AuxMom, der_temp); der += der_temp;
der = -1.0*Implementation::projectForce(der);
}
}
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void DerivativeP(MomentaField& der){
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der = zero;
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M.Minv(Mom, der);
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// is the projection necessary here?
// no for fields in the algebra
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der = Implementation::projectForce(der);
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}
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void update_auxiliary_momenta(RealD ep){
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if(1){
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AuxMom -= ep * AuxField;
}
}
void update_auxiliary_fields(RealD ep){
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if (1) {
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MomentaField tmp(AuxMom._grid);
MomentaField tmp2(AuxMom._grid);
M.M(AuxMom, tmp);
// M.M(tmp, tmp2);
AuxField += ep * tmp; // M^2 AuxMom
// factor of 2?
}
}
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};
}
}
#endif //METRIC_H