Grid/lib/qcd/smearing/StoutSmearing.h

/*
  @file stoutSmear.hpp
  @brief Declares Stout smearing class
*/
#ifndef STOUT_SMEAR_
#define STOUT_SMEAR_

namespace Grid {
  namespace QCD {

    /*!  @brief Stout smearing of link variable. */
    template <class Gimpl> 
    class Smear_Stout: public Smear<Gimpl> {
    private:
      const std::vector<double> d_rho;
      const Smear < Gimpl > * SmearBase;
      

      
    public:
      INHERIT_GIMPL_TYPES(Gimpl)
      
      Smear_Stout(Smear < Gimpl >* base):SmearBase(base){}
      
      /*! Default constructor */
      Smear_Stout():SmearBase(new Smear_APE < Gimpl > ()){}
      
      ~Smear_Stout(){}
      
      void smear(GaugeField& u_smr,const GaugeField& U) const{
	GaugeField C(U._grid);
	GaugeLinkField tmp(U._grid), q_mu(U._grid), Umu(U._grid);
	
	std::cout<< GridLogDebug << "Stout smearing started\n";
	
	//Smear the configurations
	SmearBase->smear(C, U);
	for (int mu = 0; mu<Nd; mu++){
	  tmp = peekLorentz(C,mu);
	  Umu = peekLorentz(U,mu);
	  q_mu = Ta(tmp * adj(Umu)); // q_mu = Ta(Omega_mu)
	  exponentiate_iQ(tmp, q_mu);  
	  pokeLorentz(u_smr, tmp*Umu, mu);// u_smr = exp(iQ_mu)*U_mu
	}
	
	std::cout<< GridLogDebug << "Stout smearing completed\n";
      }
      void derivative(GaugeField& SigmaTerm,
		      const GaugeField& iLambda,
		      const GaugeField& Gauge) const{
	SmearBase->derivative(SigmaTerm, iLambda, Gauge);
      }
      
      
      void BaseSmear(GaugeField& C,
		     const GaugeField& U) const{
	SmearBase->smear(C, U);
      }
      
      void exponentiate_iQ(GaugeLinkField& e_iQ,
			   const GaugeLinkField& iQ) const{
	// Put this outside 
	// only valid for SU(3) matrices

	// only one Lorentz direction at a time 

	GridBase *grid = iQ._grid;
	GaugeLinkField unity(grid);
	unity=1.0;

	GaugeLinkField iQ2(grid), iQ3(grid);
	LatticeReal u(grid), w(grid);
	LatticeComplex f0(grid), f1(grid), f2(grid);

	iQ2 = iQ * iQ;
	iQ3 = iQ * iQ2;

	set_uw(u, w, iQ2, iQ3);
	set_fj(f0, f1, f2, u, w);
	e_iQ = f0*unity + timesMinusI(f1) * iQ - f2 * iQ2;
      };


      void set_uw(LatticeReal& u, LatticeReal& w,
		  GaugeLinkField& iQ2, GaugeLinkField& iQ3) const{
	Real one_over_three = 1.0/3.0;
	Real one_over_two = 1.0/2.0;

	GridBase *grid = u._grid;
	LatticeReal c0(grid), c1(grid), tmp(grid), c0max(grid), theta(grid);
	
	
	c0    = - toReal(imag(trace(iQ3))) * one_over_three;
	c1    = - toReal(real(trace(iQ2))) * one_over_two;
	tmp   = c1 * one_over_three;
    	c0max = 2.0 * pow(tmp, 1.5);
	
	theta = acos(c0/c0max);
	u = sqrt(tmp) * cos( theta * one_over_three);
	w = sqrt(c1) * sin ( theta * one_over_three);
      }

      void set_fj(LatticeComplex& f0, LatticeComplex& f1, LatticeComplex& f2,
		  const LatticeReal& u, const LatticeReal& w) const{

	GridBase *grid = u._grid;
	LatticeReal xi0(grid), u2(grid), w2(grid), cosw(grid), tmp(grid);
	LatticeComplex fden(grid);
	LatticeComplex h0(grid), h1(grid), h2(grid);
	LatticeComplex e2iu(grid), emiu(grid), ixi0(grid), qt(grid);
	
	xi0   = func_xi0(w);
	u2    = u * u;
	w2    = w * w;
	cosw  = cos(w);
	
	ixi0  = timesI(toComplex(xi0));
	emiu  = toComplex(cos(u)) - timesI(toComplex(u));
	e2iu  = toComplex(cos(2.0*u)) + timesI(toComplex(2.0*u));
	
	h0    = e2iu * toComplex(u2 - w2) + emiu *( toComplex(8.0*u2*cosw) +
						    toComplex(2.0*u*(3.0*u2 + w2))*ixi0);
	
	h1    = toComplex(2.0*u) * e2iu - emiu*( toComplex(2.0*u*cosw) -
						 toComplex(3.0*u2-w2)*ixi0);
	
	h2    = e2iu - emiu * (toComplex(cosw) + toComplex(3.0*u)*ixi0);
	
	
	tmp   = 9.0*u2 - w2;
	fden  = toComplex(pow(tmp, -1.0));
	f0    = h0 * fden;
	f1    = h1 * fden;
	f2    = h2 * fden;	
      }


      LatticeReal func_xi0(LatticeReal w) const{
	// Define a function to do the check
	//if( w < 1e-4 ) std::cout << GridLogWarning<< "[Smear_stout] w too small: "<< w <<"\n";
	return  sin(w)/w;
      }

      LatticeReal func_xi1(LatticeReal w) const{
	// Define a function to do the check
	//if( w < 1e-4 ) std::cout << GridLogWarning << "[Smear_stout] w too small: "<< w <<"\n";
	return  cos(w)/(w*w) - sin(w)/(w*w*w);
      }
      
    };

  }
}

#endif