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Grid/lib/qcd/hmc/integrators/Integrator.h
neo 490009745c Small change in the HMC interface.
Example of multiple levels in the WilsonFermion hmc test.

Merge remote-tracking branch 'upstream/master'

Conflicts:
	lib/qcd/hmc/HMC.h
	lib/qcd/hmc/integrators/Integrator.h
	lib/qcd/hmc/integrators/Integrator_algorithm.h
	tests/Test_simd.cc
2015-07-30 17:16:57 +09:00

153 lines
4.0 KiB
C++

//--------------------------------------------------------------------
/*! @file Integrator.h
* @brief Classes for the Molecular Dynamics integrator
*
* @author Guido Cossu
* Time-stamp: <2015-07-30 16:21:29 neo>
*/
//--------------------------------------------------------------------
#ifndef INTEGRATOR_INCLUDED
#define INTEGRATOR_INCLUDED
class Observer;
#include <memory>
namespace Grid{
namespace QCD{
typedef Action<LatticeGaugeField>* ActPtr; // now force the same colours as the rest of the code
struct ActionLevel{
int multiplier;
public:
std::vector<ActPtr> actions;
explicit ActionLevel(int mul = 1):multiplier(mul){assert (mul > 0);};
void push_back(ActPtr ptr){
actions.push_back(ptr);
}
};
typedef std::vector<ActionLevel> ActionSet;
typedef std::vector<Observer*> ObserverList;
struct IntegratorParameters{
int Nexp;
int MDsteps; // number of outer steps
RealD trajL; // trajectory length
RealD stepsize;
IntegratorParameters(int Nexp_,
int MDsteps_,
RealD trajL_):
Nexp(Nexp_),MDsteps(MDsteps_),trajL(trajL_),stepsize(trajL/MDsteps){};
};
namespace MDutils{
void generate_momenta(LatticeGaugeField&,GridParallelRNG&);
void generate_momenta_su3(LatticeGaugeField&,GridParallelRNG&);
}
/*! @brief Class for Molecular Dynamics management */
template< class IntegratorAlgorithm >
class Integrator{
private:
IntegratorParameters Params;
const ActionSet as;
std::unique_ptr<LatticeGaugeField> P;
GridParallelRNG pRNG;
//ObserverList observers; // not yet
IntegratorAlgorithm TheIntegrator;
void register_observers();
void notify_observers();
void update_P(LatticeGaugeField&U, int level,double ep){
for(int a=0; a<as[level].actions.size(); ++a){
LatticeGaugeField force(U._grid);
as[level].actions.at(a)->deriv(U,force);
*P -= force*ep;
}
}
void update_U(LatticeGaugeField&U, double ep){
//rewrite exponential to deal automatically with the lorentz index?
LatticeColourMatrix Umu(U._grid);
LatticeColourMatrix Pmu(U._grid);
for (int mu = 0; mu < Nd; mu++){
Umu=PeekIndex<LorentzIndex>(U, mu);
Pmu=PeekIndex<LorentzIndex>(*P, mu);
Umu = expMat(Pmu, ep, Params.Nexp)*Umu;
PokeIndex<LorentzIndex>(U, Umu, mu);
}
}
friend void IntegratorAlgorithm::step (LatticeGaugeField& U,
int level, std::vector<int>& clock,
Integrator<IntegratorAlgorithm>* Integ);
public:
Integrator(GridBase* grid, IntegratorParameters Par,
ActionSet& Aset):
Params(Par),as(Aset),P(new LatticeGaugeField(grid)),pRNG(grid){
pRNG.SeedRandomDevice();
};
~Integrator(){}
//Initialization of momenta and actions
void init(LatticeGaugeField& U){
std::cout<<GridLogMessage<< "Integrator init\n";
MDutils::generate_momenta(*P,pRNG);
for(int level=0; level< as.size(); ++level){
for(int actionID=0; actionID<as[level].actions.size(); ++actionID){
as[level].actions.at(actionID)->init(U, pRNG);
}
}
}
// Calculate action
RealD S(LatticeGaugeField& U){
LatticeComplex Hloc(U._grid);
Hloc = zero;
// Momenta
for (int mu=0; mu <Nd; mu++){
LatticeColourMatrix Pmu = peekLorentz(*P, mu);
Hloc -= trace(Pmu*Pmu);
}
Complex Hsum = sum(Hloc);
RealD H = Hsum.real();
std::cout<<GridLogMessage << "Momentum action H_p = "<< H << "\n";
// Actions
for(int level=0; level<as.size(); ++level)
for(int actionID=0; actionID<as[level].actions.size(); ++actionID)
H += as[level].actions.at(actionID)->S(U);
std::cout<<GridLogMessage << "Total action H = "<< H << "\n";
return H;
}
void integrate(LatticeGaugeField& U){
std::vector<int> clock;
clock.resize(as.size(),0);
for(int step=0; step< Params.MDsteps; ++step) // MD step
TheIntegrator.step(U,0,clock, (this));
}
};
}
}
#endif//INTEGRATOR_INCLUDED